DC DS EN 02 2014 002 4 Jeti 16

User Manual: jeti-ds-16

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computer radio control system EN
DC-16, DS-16, DS-14
ENFW 3.00
CZECH REPUBLIC
computer radio control system EN
1. Introduction ........................................................................................... 07
1.1 DC/DS .................................................................................................07
1.2 DS-14 ................................................................................................. 07
1.2.1 Activation method for software modules of JETI model 08
1.3 Features ............................................................................................. 09
1.4 Table of Contents ............................................................................. 10
1.5 Technical Support ........................................................................... 11
1.6 DC-16 Package Contents ............................................................... 11
1.7 DS-16 Package Contents ............................................................... 12
1.8 DS-14 Package Contents ............................................................... 12
2. System Specifications .......................................................................... 13
2.1 DC-16 ................................................................................................. 13
2.2 DS-16 ................................................................................................. 13
2.3 DS-14 ................................................................................................. 14
3. Description of Transmitter DC-16 ................................................... 15
3.1 Control Identification ................................................................... 15
3.2 Assembly Identification ................................................................ 16
3.3 Control Stick Assembly .................................................................. 17
3.3.1 Control Stick Length Adjustment ...................................... 17
3.3.2 Swivel Control Stick Adjustment ........................................ 17
3.3.3 Control Stick Tension Adjustment ..................................... 18
3.3.4 Ratchet Tension Adjustment .............................................. 18
3.3.5 Throttle stick travel adjustment ........................................ 19
3.3.6 Transmitter Mode Switch .................................................... 19
3.3.7 Transmitter Gimbals with Switch or Button Installation
.................................................................................................... 20
3.4 Swappable and Assignable Switches ........................................ 22
3.5 Digital Trims .................................................................................... 23
3.6 Transmitter Battery Pack ............................................................... 24
3.6.1 Charging ............................................................................... 24
3.6.2 Battery Replacement .......................................................... 24
3.7 PPM Output Connector .......................................................... 25
3.8 Handling ..................................................................................... 25
ver. 5.0 - 2014-04, FW ver. 3.0
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computer radio control system EN
4. Description of Transmitter DS-16 .................................................... 26
4.1 Control Identification ................................................................... 26
4.2 Control Identification DS-14 ........................................................ 27
4.3 Assembly Identification ................................................................ 28
4.4 Control Stick Assembly .................................................................. 29
4.4.1 Control Stick Length Adjustment ...................................... 29
4.4.2 Swivel Control Stick Adjustment ........................................ 29
4.4.3 Control Stick Tension Adjustment ..................................... 30
4.4.4 Ratchet Tension Adjustment .............................................. 31
4.4.5 Throttle stick travel adjustment ....................................... 31
4.4.6 Transmitter Mode Switch .............................................. 33
4.4.7 Transmitter Gimbals with Switch or Button Installation
.................................................................................................... 34
4.5 Swappable and Assignable Switches ........................................ 37
4.5.1 Switch Removal Procedure ................................................. 38
4.5.2 Assembly Procedure ............................................................. 38
4.6 Digital Trims .................................................................................... 39
4.7 Transmitter Battery Pack ............................................................... 40
4.7.1 Charging ............................................................................... 40
4.7.2 Battery Replacement ........................................................... 40
4.8 PPM Output Connector ................................................................ 41
4.9 Handling .......................................................................................... 41
5. RF Transmitter Modules ..................................................................... 42
6. Transmitter Powering ON/OFF .......................................................... 43
6.1 Transmitter, Powering-ON ........................................................... 43
6.2 Transmitter Turning-OFF ............................................................... 43
6.3 Transmitter Restart ...................................................................... 43
7. Initial switching-on ............................................................................... 44
7.1 Main display ..................................................................................... 44
7.2 Navigation in the Menu ................................................................. 44
7.2.1 Browsing through the Menu ............................................... 46
7.2.2 Basic Menu Structure ........................................................ 46
7.3 Model Set-up Guide ....................................................................... 47
7.3.1 Airplane .................................................................................. 47
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7.3.2 Helicopter ................................................................................ 49
7.3.3 General .................................................................................... 51
7.3.4 Set up of Receiver Outputs .................................................. 53
8. Duplex Receivers .................................................................................... 55
8.1 Description ....................................................................................... 55
8.2 Installation ....................................................................................... 55
8.3 Binding .............................................................................................. 55
8.3.1 Standard pairing procedure .............................................. 55
8.3.2 Al te rnative pair ing procedu re through the
transmitter menu ............................................ 56
8.4 Range test ......................................................................................... 56
8.5 Fail safe .............................................................................................. 56
8.6 Technical data receivers ................................................................. 58
8.6.1 Technical data receivers outside the U.S. ......................... 58
8.6.2 Technical data receivers for the U.S. ................................... 59
8.7 Using Device Explorer To Configure the Receiver ...................... 60
8.7.1 Support of remote commands for EX Bus devices ........... 63
8.8 RC-Switch ........................................................................................ 65
9. Main menu ............................................................................................... 67
9.0 .1 Pa ss wo rd p ro te c ti on a ga ins t a cc i de nt a l
configuration changes .................................................................. 68
9.1 Model ................................................................................................. 69
9.1.1 Model Selection ..................................................................... 69
9.1.2 New Model .............................................................................. 70
9.1.3 Basic configuration- AIRPLANE ......................................... 71
9.1.4 Basic Configuration - HELICOPTER .................................... 72
9.1.5 Swash mix ............................................................................... 74
9.1.6 Basic Configuration-GENERAL ........................................... 74
9.1.7 Assignment of functions ...................................................... 75
9.1.8 Servo Assignment ................................................................. 76
9.1.9 Servo Setup ............................................................................. 77
9.1.10 Servo balancer ................................................................... 78
9.2 Fine Tuning ....................................................................................... 80
9.2.1 Flight Modes ......................................................................... 80
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computer radio control system EN
9.2.2 Digital trim .............................................................................. 83
9.2.3 Flight Mode Trims .................................................................. 85
9.2.4 Dual Rate/Exponential ........................................................ 86
9.2.5 Programmable Function Curves ....................................... 88
9.2.6 Aileron Differential ................................................................ 90
9.2.7 Ailevator Function ............................................................... 90
9.2.8 V-Tail Mix ................................................................................. 91
9.2.9 Delta/Elevon Mix ................................................................... 92
9.2.10 Butterfly Mix ......................................................................... 92
9.2.11 Free Mixes ............................................................................. 94
9.2.12 Governor/Gyro ..................................................................... 97
9.2.13 Throttle Limiter .................................................................... 98
9.2.14 Snap Roll .............................................................................. 98
9.3 Advanced Properties .................................................................... 100
9.3.1 Other Model Options .......................................................... 100
9.3.2 Sticks / Switches Setup ..................................................... 101
9.3.3 Wireless Modes/Trainer .................................................... 102
9.3.4 Logical Switches ................................................................. 107
9.3.5 Sounds on Event (Sound Assignments) .......................... 109
9.3.6 Sequencer ............................................................................. 110
9.3.7 Accelerometer (DS only) ................................................... 111
9.3.8 Telemetry Controls .............................................................. 112
9.3.9 Sound of Proportional Controls ....................................... 113
9.4 Timers/Sensors .............................................................................. 115
9.4.1 Timer ...................................................................................... 115
9.4.2 Alarms ................................................................................... 117
9.4.3 Vario ....................................................................................... 118
9.4.4 Voice Output ........................................................................ 119
9.4.5 Sensors/Logging Setup .................................................... 120
9.4.6 Displayed Telemetry ........................................................... 121
9.4.7 Main Screen ......................................................................... 124
9.5 Applications ................................................................................... 125
9.5.1 Data Analyzer ...................................................................... 125
9.5.2 Audio Player ........................................................................ 126
9.5.3 JETIBOX ................................................................................. 126
9.5.4 Games ................................................................................... 127
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9.6 System ............................................................................................ 127
9.6.1 Configuration ..................................................................... 127
9.6.2 Servo & Range Test ............................................................. 129
9.6.3 View Inputs ........................................................................... 130
9.6.4 Receiver Output (Servo Monitor) .................................... 131
9.6.5 System sound ....................................................................... 131
9.6.6 Sound Volume ..................................................................... 132
9.6.7 Installed Modules ............................................................... 132
9.6.8 Limitations in copying models between transmitters . 133
9.6.9 USB ......................................................................................... 133
9.6.10 Info ....................................................................................... 133
9.7 Throttle Lock .................................................................................. 135
9.8 Select Input control ..................................................................... 135
9.9 Trim Menu ..................................................................................... 139
9.10 How Transmitter Output Functions are Processed .............. 139
10. Transmitter to PC Connection ....................................................... 140
10.1 Memory & System Files ............................................................. 140
10.2 Update Firmware ....................................................................... 140
10.3 Sounds, Alarms & Acoustic Updates ....................................... 140
10.4 System Backup ............................................................................ 141
10.5 PC Joystick ..................................................................................... 141
10.6 Telemetry Data Logging ............................................................. 141
10.7 Copying models between the transmitters ............................. 141
11. Battery Safety Handling Rules ........................................................ 142
11.1 Transmitter Battery Pack .......................................................... 142
11.2 General Safety Rules ..................................................................... 142
11.3 Flight Safety Check ..................................................................... 143
11.4 Application ..................................................................................... 143
11.5 FCC /IC Information ....................................................................... 143
12. Model Menu Airplane/Sailplane .............................................. 145
12.1 Butterfly Mix (Crow Mix) .............................................................. 145
12.2 Aileron Differential ....................................................................... 145
12.3 Ailevator ....................................................................................... 146
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computer radio control system EN
6
12.4 V-Tail Mix ..................................................................................... 146
12.5 Delta/Elevon Mix .......................................................................... 147
12.6 Spoilers to Elevator Mix ............................................................. 147
12.7 Ailerons to Rudder Mix ................................................................ 148
12.8 Rudder to Ailerons Mix ................................................................. 149
12.9 Butterfly (Crow) Mix ..................................................................... 150
12.10 Rudder to Elevator Mix ............................................................. 151
12.11 Aileron to Flap Mix ..................................................................... 152
12.12 Aileron to Flap Mix (Brake Variation) ................................... 153
12.13 Elevator to Flap Mix ................................................................... 153
12.14 Flaps Mix – Camber Control .................................................... 154
12.15 Throttle Cut (Kill Switch) ........................................................... 155
12.16 Throttle Idle ................................................................................. 155
13. Accessories for Transmitters ........................................................... 156
13.1 Tray for DC-16 ................................................................................ 156
13.2 Stick Ends for DC/DS ............................................................... 156
13.3 Replacement switches ................................................................ 156
13.4 Straps for DC/DS .................................................................... 157
13.5 Charging ......................................................................................... 157
13.6 Other .............................................................................................. 157
13.7 O v e r v i e w o f t h e D S - 1 4 e x p a n s i o n m o d u l e s
(tran smitter equ ipmen t compa rison )............ 1 58
computer radio control system EN
The DC/DS transmitters were developed and produced with the
cooperation of professional and world champion pilots. These
transmitters were created with the goals of maximum utility, simple
handling, maximum durability and the ultimate reliability of their
mechanical parts. The metal case, with its chemically resistant
outside surface treatment, provides maximum protection for the
interior components. The straightforward case shape makes
servicing easy. The metal, quad ball bearing equipped, stick gimbals
with their magnetic Hall sensors are another revolutionary design
concept used to make the DC/DS among the world’s most advanced
R/C systems.
Purposefully placed at the top of the transmitter, the 3.8“ backlit LCD
display with its wide viewing angle offers nearly perfect visibility in
just about any lighting condition. Thanks to its high resolution
display and use of a relatively large number of graphic images it was
possible to create a simple and intuitive setup procedure for
displaying telemetric data.
The DUPLEX EX family of products have been equipped with an
improved telemetric data transfer system which can be viewed on
the LCD transmitter display or saved for later analysis on a PC. The
transmitter allows the setup of audible notifications (optionally
created by the user), which can be related to actual telemetric values
or to sound alarms or signals which have been assigned to
conditions of various control elements.
The DS-14 hand-held transmitter expands the range of model
transmitters equipped with the JETI Duplex system, this new design
is based on the high-end model DS-16. Unlike the DS-16, the DS-14
offers a unique concept of individual feature setup based upon the
requirements of each customer. The transmitter is available in a basic
configuration that will meet the needs of most users for most model
types. For individual setting of the transmitter there is a configurator
available at swshop.jetimodel.com. After the simple registration of
your transmitter it is possible to select additional features based
upon your individual demands. For example, if you fly only
helicopter models, select such features as "Throttle Limiter" or
"Gyro Settings" but you will probably not need to increase the
number of flight modes. These are more suitable for controlling
glider models.
The DS-14 features newly designed gimbal sticks. We managed to
keep all the characteristics of the full metal sticks used in the DS-16,
mainly thanks to high-quality materials and Hall sensors inside the
sticks which are fully supported by high quality ball bearings.
As a result, the DS-14 becomes a powerful tool with the possibility to
individually select many features at a very attractive price.
1 Introduction
1.1.
1.1 DC/DS
1.2 DS-14
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computer radio control system EN
1.2.1 Activation method for software modules of JETI model
1. Make sure you have the most current firmware version in your
transmitter.
2. Register on swshop.jetimodel.com.
3. After clicking on the „Register
new product“ button you will be
redirected to a form where you
enter a product type (DS-14),
followed by the serial number
(SN: xxxxxxxxx) (to be found on the
back of the transmitter behind the
screen) and then enter the 16
digit registration code (xxxx-
xxxx-xxxx-xxxx) (see the menu
System -> Installed Modules
highlighted by the frame). After
registering your transmitter, you
can select individual function
modules that you want to activate.
4. Mark selected modules and
proceed to checkout.
5. Then you will be asked to pay
the relevant amount. After
p a y m e n t , a u n i q u e
nontransferable file named
A c t i v a t i o n . b i n ” w i l l b e
generated. It will then be sent to your e-mail.
6. Connect the DS-14 to your computer and enable USB mode.
7. Copy the Activation.bin” file to the transmitter SD card into the
root folder. The contents of the transmitter SD card can then look like
this:
8. Disconnect the transmitter from the computer (Do not forget to
confirm the safe hardware removal). Then confirm in your
transmitter that you want to update and restart it.
If the activation is successful, an informative table with a list of
modules appears immediately after switching on. Then it is
possible to operate the transmitter as usual.
1.1.
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computer radio control system EN
Duplex 2.4GHz the DC/DS transmitters feature the Duplex 2.4GHz,
frequency hopping, digital, data stream system originally developed
by JETI model in the Czech Republic. This system has been reliably
used for many years.
Built-in Telemetry from the start, the DC/DS transmitters were
designed and built with many attractive features and include the full
integration of all Duplex telemetry sensors.
Transmitters - these designs emphasize use comfort, state-of-the-
art appearance and use premium quality materials.
Precise Gimbals the transmitter gimbals are equipped with Hall
sensors and ball bearings for precision movement with an almost
unlimited lifespan.
LCD Display – oversized 3.8“ backlit LCD display with 320x240
resolution which is highly visable under any light conditions.
Li-Ion Battery provides a proven and reliable energy source with a
high capacity (3200mAh) and a long service life.
Easy Charging simply connect the wall power supply to the
transmitter. The DC/DS may also be charged through their USB to PC
interface.The charging progress is shown on the DC/DS display.
Integrated Antenna the antennas are located behind fully
integrated covers in both the DC-16 and DS-14/16 cases for
protection against mechanical damage.
1.1.
1.3 Features Large Memory 4GB memory space for storing models, sounds, and
telemetry data.
USB Connector convenient connection to your PC. Fast firmware &
sound upgrades, telemetry data downloads.
Fast Navigation – 3D wheel-style interface combined with function
keys allow for speedy navigation within the DC/DS menu.
Digital Trims fully programmable trims and a revolutionary
automatic trimming function.
Swappable and Assignable Switches all of the switches on the
DC/DS transmitters (2- or 3-position) can be easily moved and
assigned to create a custom configuration that works best for your
application.
Programming the logical and intuitive transmitter firmware is
designed to be simple to use. Just follow the step-by-step screens.
The creation of a new model can be accomplished with just a few
easy steps.
Sounds/Alarms the DC/DS transmitters are equipped with audible
alarms and also allows the use of user-recordable alarms and sounds
to keep you fully informed while also keeping distractions to a
minimum. "
Depends on equipment - The specific function is available if the
corresponding module is activated. The DC-16 and DS-16
transmitters in their basic version have all the modules activated on
maximum possible values. With the DS-14 transmitter it is possible
to take advantage of the system that enables purchasing of the
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1.4 Table of Contents
extended functions from swshop.jetimodel.com.
To make navigation faster, the DC/DS transmitter Instruction Manual
has been divided into 5 basic groups:
1 . Introduction and product support.
2. Basic description and mechanical adjustments.
3. First time switch-on. Basic helicopter and airplane set up.
4. Advanced programming. Detailed descriptions.
5. PC upgrade/upload, safety information, and special mixes.
Important parts of the instructions are separated from the text and
highlighted according to importance.
Advice Note Warning
Advanced modelers may want to begin with group 3 where you will
get all of the basic information for model setup. This is the quickest
way to understand the basic ideas of the DC/DS transmitter
programming and with this basic information you can begin to
create your own model. More advanced programming functions are
found in group 4. This is where you can find detailed descriptions of
all of the DC/DS functions. The last section provides detailed
description of firmware upgrades, downloads, and special mixes.
1.1.
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If you feel uncertain about how to set up particular transmitter
functions, do not hesitate to take advantage of our technical
support:
1. Web Site
Either the JETI model (manufacturer) or your local distributors web
sites offer a wide range of support for the DC/DS transmitters. You will
find advice, tips or frequently asked questions (FAQ) which, in most
cases, contain the answers to your questions.
2. Distributor, Manufacturer
You may also find support at your local hobby shop, distributor, or
directly with the manufacturer JETI model s.r.o.
3. Service and Warranty Coverage
JETI model CZ exclusively warranties that the products purchased will be
free from defects in materials and workmanship for a period of 24 months
from the date of purchase by the customer. This warranty covers only
those products purchased from an authorized JETI model CZ distributor
or dealer. Third party transactions are not covered by this warranty. Proof
of purchase is required for warranty claims. Repair or replacement
decisions are at the sole discretion of JETI model CZ or an authorized
service provider. This warranty does not cover cosmetic damage or
damage due to an accident, misuse, abuse, negligence, commercial or
research use, or modification of or to any part of the product. This
warranty does not cover damage due to improper installation, operation,
maintenance, or attempted repair by anyone other than JETI model CZ or
an authorized service provider.
JETI model CZ reserves the right to change or modify this warranty
without notice and disclaims all other warranties, expressed or implied.
1. 2. 3. JETI DC-16 Transmitter, Wall Power Supply, JETI DC-16
Transmitter Aluminum Case, USB PC Cable, Installation Hex Key 4. 5.
Set (1,5mm; 2mm), Cleaning Cloth, Instruction Manuals 6.
1. 2.
1.5 Technical Support 1.6 DC-16 Package Contents
1
3
2
4
5
6
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2.2.
1.7 DS-16 Package Contents
1
3
2
4
56
1. 2. 3. JETI DS-16 Transmitter, Wall Power Supply, JETI DS-16
Transmitter Aluminum Case, USB PC Cable, Installation Hex 4. 5.
Key Set (1,5mm; 2mm), Cleaning Cloth, Instruction Manuals 6.
1.8 DS-14 Package Contents
1. 2. 3. 4. JETI DS-14 Transmitter, Wall Power Supply, USB PC Cable,
Installation Hex Key Set (1,5mm; 2mm), Instruction Manuals.
1
23
4
1
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2 System Specifications
Frequency
2.4GHz
Dimensions
WxLxH
(with Antenna)
180x270x40 mm
7.1x10.6x1.6",
(230x270x40mm)
(9.1x10.6x1.6")
Weight
1.5kg (53 oz)
Number of Channels
16
Number of control directions
using all Sticks/Switches/Knobs
Up to 20
Resolution
4096 steps
Battery
Li-on 3200mAh 3.6V
Operating Time
Up to 11 hours
Internal Memory
microSD 4GB
Telemetry
Yes
PC Connection
USB mini
Graphic Display
3.8" - 320x240px
Operational Temperature
-10 up to 60 °C
(14 up to140°F)
2.2.
2.1 DC-16 2.2 DS-16
Frequency
2.4GHz
Dimensions
WxLxH
(with Display)
194x172x40 mm
7.7x6.8x1.6"
(194x233x40 mm)
(7.7x9.2x1.6")
Weight
1.25kg (44 oz)
Number of Channels
16
Number of control directions
using all Sticks/Switches/Knobs
Up to 18
Resolution
4096 steps
Battery
Li-on 3200mAh 3.6V
Operating Time
Up to 11 hours
Internal Memory
microSD 4GB
Telemetry
Yes
PC Connection
USB mini
Graphic Display
3.8" - 320x240px
Operational Temperature
-10 up to 60 °C
(14 up to 140°F)
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2.3 DS-14
Frequency
2.4GHz
Dimensions
WxLxH
(with Display)
194x172x40 mm
7.7x6.8x1.6"
(194x233x40 mm)
(7.7x9.2x1.6")
Weight
1.25kg (44 oz)
Number of Channels
Up to 14
Number of control directions
using all Sticks/Switches/Knobs
Up to 18
Resolution
4096 steps
Battery
Li-on 3200mAh 3.6V
Operating Time
Up to 11 hours
Internal Memory
microSD 4GB
Telemetry
Yes
PC Connection
USB mini
Graphic Display
3.8" - 320x240px
Operational Temperature
-10 up to 60 °C
(14 up to140°F)
2.2.
Software modules
Basic
Extended
Number of channels
8
14
Accelerometer
m
l
Secondary transmitter module in
*)
Trainer/Student or „Double Path“
function
m
l
Number of flight modes
3
6
Free mixes
5
12
Telemetry analysis via graphs
m
l
Audio player
m
l
Logical switches
0
10
Number of control commands
0
8
Sequencer
0
3
Timers
3
6
Number of telemetry items on the LCD
10
20
Sounds on events
5
10
Alarms
10
20
Voice output
m
l
Gyro setting function
1
3
Servo balancer
m
l
Function curves
m
l
Telemetry controls
0
5
Throttle limiter
m
l
Vario
m
l
*) Double Path mode allows the operation of two separately paired receivers in a model. Even if this
module is not activated, both transmitter modules communicate with the receiver for the best possible
connection quality and safety.
m - The module is not included in the basic version
l - This function is available after purchasing the module
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2.2.
3 Description of Transmitter DC-16
1. Right Stick 1, 2 the DC-16 Transmitter Supports Modes 1-4, see Control
Sticks -> mode change
2. Left Stick 3, 4 the DC-16 Transmitter Supports Modes 1-4, see Control
Sticks -> mode change
3. Swappable and Assignable Switches: Sa, Sb, Sc, Sd, Se, Sf, Sg, Sh, Si, Sj
4. Digital Trims for the Left Stick T3, T4
5. Digital Trims for the Right Stick T1, T2
6. Right Side Control Lever 5
7. Left Side Control Lever 6
8. Rotary Control Knob 7
9. Rotary Control Knob 8
10. LCD Display
11. Function Buttons F1 F5
12. Transmitter On/Off Power Switch
13. 3D Control Selector
14. Menu Button
15. ESC Button
16. Antenna/ Transmitter Handle
17. Charge Jack
18. USB PC Interface
19. Earphone Jack
20. ON/OFF & Charging LED Indicators
21. Speaker
22. Transmitter Neck Strap Bracket Installation Holes
3
1
2
3
45
67
89
10
11 12 13
15 14
16
17
18
1921 2020
22 22
3.1. Control Identification
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23. Battery Connector
24. Transmitter Battery Pack
25. PPM Output Connector
26. Left Gimbal Assembly
27. Right Gimbal Assembly
2.2.
24 23
25 2627
3.2. Assembly Identification
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3.3 Control Stick Assembly
When handling with back cover removed always
switch off the transmitter and disconnect the
battery (unplug the connector). Also do not connect
the charging adapter or the USB cable.
Note:
Restrict your contact with the printed circuit
boards to a minimum. You can damage your
radio by electrostatic discharge!
Warning:
3.3.1 Control Stick Length Adjustment
The stick length is adjustable to suit your flying style. The stick end
separates into two parts. 1. Hold the top part of the
st i ck e nd f ir mly a nd
u n s c r e w ( t u r n i t
counterclockwise).
2. Turn the stick end
clockwise to shorten or
c o u n t e r c l o c k w i s e t o
lengthen the overall stick
length.
3. Adjust the lower part
to support the top part of
the stick end.
4. Fi na lly s ecu re b y
tightening both parts to
each other.
1
2
3
4
If you have installed optional sticks with switch or button ends,
make sure that while adjusting the stick length you observe the
wires that pass through the stick shaft and through the gimbal
opening in order to prevent damaging the connecting cables.
The safest method is to remove the small set-screw from the
side of the stick housing to allow the switch or knob internals to
remain stationary while you rotate the stick housing for height
adjustment.. (See 4.3.6)
Warning:
3.3.2 Swivel Control Stick Adjustment
In order to customize the feel of your radio you may adjust the angle
of the stick control assemblies.
1. switch off the transmitter and remove the 10 screws that secure
the radio back cover. Next, remove the radio back cover.
Be sure to disconnect the transmitter battery pack connector.
2.2.
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computer radio control system EN
2.2.
2. Loosen both machine screws securing the control stick
assembly.
3. Adjust (rotate) to desired position.
4. Securely tighten both machine screws securing the control stick
assembly.
5. Reconnect transmitter battery pack and reinstall radio back
cover and cover screws.
3
4
2
4
2
3.3.4 Ratchet Tension Adjustment
Do you prefer smooth throttle feel or ratchet throttle feel? You can
adjust the DC-16 transmitter either way you like allowing you to fully
customize your radio‘s handling. Each tension is set by a different
machine screw.
3.3.3 Control Stick Tension Adjustment
The stick gimbal tension is fully adjustable for each axis. This allows
you to fully customize your radio‘s control feel. Simply adjust each
gimbal‘s spring to your desired tension.
1. Switch off the transmitter and remove the 10 screws that secure
the radio back cover. Next, remove the radio back cover.
Be sure to disconnect the transmitter battery pack
connector.
2. Use indicated machine adjustment screws to change the
desired spring tension.
By turning the screw anticlockwise, you will loosen spring
tension. As a result the moving resistance of the control stick will
3. Reconnect transmitter battery pack and reinstall radio back
cover and cover screws.
1. Switch off the transmitter and remove the 10 screws that secure
the radio back cover. Next, remove the radio back cover.
Be sure to disconnect the transmitter battery pack
connector.
2
2
2. For ratchet tension adjustment use the machine screw A.
Turn slowly (anticlockwise) until you achieve the desired
ratchet tension. For smooth tension adjustment, use the
achine screw “B”. Turn slowly (clockwise) until you achieve
decrease. By turning the screw clockwise, you will tighten
spring tension. As a result the moving resistance of the control
stick will increase.
18
computer radio control system EN
2.2.
AB
3.3.6 Transmitter Mode Switch
The DC-16 transmitter allows you to switch between Mode 1, 2, 3
and 4 stick configurations with just few simple steps. In order to do
some of these, the stick control assemblies will need to be swapped.
1. Switch off the transmitter and remove the 10 screws that secure
the radio back cover. Next, remove the radio back cover.
Be sure to disconnect the transmitter battery pack
connector.
2. Disconnect the control stick assembly wires from the Tx board.
(3 wires X, Y, S)
3. Remove the stick assembly connecting wires from their holders.
2
34
4
XYS
the desired smooth tension.
3. Reconnect transmitter battery pack and reinstall radio back
cover and cover screws.
3.3.5 Throttle stick travel adjustment
The throttle stick travel is adjustable to suit your flying style.
1. Switch off the transmitter and remove the 8 screws that secure the
radio back cover. Next, remove the radio back cover. Be sure to
disconnect the transmitter battery pack connector.
2. Use indicated machine adjustment screws to limit the throttle
stick travel. By turning the screw clockwise, you will shorten the
throttle stick travel.
3. Reconnect transmitter battery pack and reinstall radio back cover
and cover screws.
After making a limit the throttle stick travel you must re-calibrate the
transmitter stick in the software menu, see section 9.6.3
–Calibration of Proportional Controls.
2
2
19
computer radio control system EN
8
97
7
5. Carefully remove both control stick assemblies. Gently pull in
your direction (toward the transmitter back side).
6. Swap both stick unit assemblies and install them back into
correct positions.
After making a mode switch you must re-calibrate the
transmitter stick assemblies and setup the correct mode
in the software menu, see section 9.6.1 – Configuration.
The switch between Modes 1 to 3 or Modes 2 to 4 are
done with the software only (NO manual stick change is
necessary).
Note:
3.3.7 Transmitter Gimbals with Switch or Button
Installation
If you want to operate the DC-16 transmitter using the optional stick
end switch or button functions, you must purchase one or more of
these separately:
Stick with 2-position switch
Stick with 3-position switch
Stick with push-button
Stick with potenciometer
For installation of the optional gimbal stick ends with
switches/buttons we recommend that you send your
transmitter to one of the factory authorized service
centers or to your authorized dealer.
Advice:
XYS
2.2.
1. Switch off the transmitter and remove the 10 screws that secure
the radio back cover. Next, remove the radio back cover.
Be sure to disconnect the transmitter battery pack
connector.
It may be necessary to remove the screws securing the RF circuit
board to release the wire group.
4. Remove both machine installation screws for each of the
control stick assemblies.
5
6
7. Reinstall and secure the machine screws for each of the control
stick assemblies.
20
computer radio control system EN
5. Carefully remove both control stick assemblies. Gently pull in
your direction (toward the transmitter back side). This upgrade
will be done outside of the transmitter case.
6. Unscrew the upper part of the stick assembly (anticlockwise).
7. Insert the connecting wires through the hollow opening of the
transmitter stick.
6
7
8. Adjust length of the stick to suit your flying style. (See 4.3)
8
9
10
11
2.2.
2. Disconnect the control stick assembly wires from the Tx board.
(3 wires )X, Y, S
3. Remove the stick assembly connecting wires from their holders.
4. Remove both machine installation screws for each of the
control stick assemblies.
After installation of the optional stick ends with switch or
button make sure that while adjusting the stick length you
observe the wires that pass through the stick shaft and
through the gimbal opening in order to prevent damaging
the connecting cables. The safest method is to remove the
small set-screw from the side of the stick housing to allow
the switch or knob internals to remain stationary while you
rotate the stick housing for height adjustment.
9. Pass the switch wires through the same gimbal opening as the
hall sensor cable (through the center of the gimbal assembly).
10. Next insert wire ends through the opening of the printed circuit
board and solder them to the matching soldering points in such
a way that the same color wires lay on the top of each other.
11. Carefully move transmitter sticks to their full outside positions
in order to make sure that you have sufficient wire length and, if
needed, adjust accordingly. The connecting cables for
all moving parts of the unit should have sufficient length in
order not to be exposed to any mechanical damage and any
bending stresses.
Note:
2
34
4
XYS
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computer radio control system EN
3.4 Swappable and Assignable Switches
One of the most important features of a JETI transmitter is the switch
function assignment flexibility. The DC-16 transmitter automatically
detects the type of switch and assigns the selected function. The
following switch types are available:
2-position short or long switch
2-position spring-loaded long switch
3-position short or long switch
You may either swap the existing switches around or take advantage
of the optional accessories and create your own custom
configuration.
Factory Switch Configurations for the DC-16 Transmitter
Sa - 2- position spring-loaded long switch
Sb - 3- position short switch
Sc - 2- position short switch
Sd - 2- position long switch
Se - 3- position short switch
Sf - 3- position short switch
Sg - 3- position long switch
Sh - 2- position short switch
Si - 2- position short switch
Sj - 3- position long switch
2.2.
Installation and Configuration of Gimbals Switches
After the switch has been installed into the stick assembly you have
to re-configure and enable it in the transmitter software before it will
function properly. This can be done in the transmitter menu „Main
menu->Advanced setup->Sticks/ switches setup“, see section
9.3.2.
12. Install stick unit assembly back to correct position.
13. Install and secure the machine screws for the control stick
assembly.
14. Connect control stick assembly wires to the Tx board connector
(3 wires ). Pay close attention to the wire lengths. Connect X, Y, S
the longest wire as the first one from the outside of the
transmitter (3 connectors ).X, Y, S
15. Secure the stick assembly wires into their holders.
16. Reconnect transmitter battery pack and reinstall radio back
cover and cover screws.
14 XY
S15
13
13
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computer radio control system EN
2.2.
3
Switch Exchange:
1. Switch off the transmitter and remove the 10 screws that secure
the radio back cover. Next, remove the radio back cover.
Be sure to disconnect the transmitter battery pack
connector.
2. With the specialized wrench (not included) carefully loosen and
remove the switch installation nut.
3. Carefully hold the switch by its printed circuit board assembly
and slowly pull it out. Use this method to also remove and
exchange all of the other switches. After re-assembling and
turning on your transmitter the software will sound a warning
reminding you that you have executed a change. Always re-
inspect all assigned functions of the switches before
attempting to fly.
2
3.5 Digital Trims
Transmitter gimbals are used for controlling the basic flight
functions like throttle, roll(aileron), pitch(elevator), and yaw(rudder).
Immediately under the transmitter gimbal sticks you can see four
push-buttons which are the programmable, digital trim buttons.
The digital trims are used for fine trimming of the flying model. When
the transmitter is turned off, the trim values are stored in memory
and are recalled when the system is turned back on.
Every model has its own trim setup. Also all flight modes may be
configured to use different trim configurations. By pressing one of
the buttons, the screen will automatically change to display the
graphic position of that trim. The transmitter trims feature an
acoustic step and centre beep alarm.
In the „Digital trim“ menu it‘s possible to enable a special
function used as automatic trimming. Digital trim steps and trim
range setting is explained in „Main menu->Fine tuning/flight
modes->Digital trim“
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computer radio control system EN
3.6.2 Battery Replacement
Should you decide to replace the transmitter battery, please follow
these steps:
1. Switch off the transmitter and remove the 10 screws that
secure the radio back cover. Next, remove the radio back cover.
2. Disconnect the transmitter battery connector.
3. Loosen the battery fastening strap and remove the battery.
32
DC-16 transmitters should only be operated only
with original or manufacturer approved battery
packs. The use of other battery packs will void the
warranty.
Warning:
If the transmitter battery has been disconnected for
longer than 1 minute, the time, and date will be deleted.
Note:
2.2.
3.6 Transmitter Battery Pack
The DC-16 transmitter is powered by a Li-Ion type battery pack and
comes equipped with its own built-in advanced battery
management and charging circuit. In switched-on position, the
transmitter LCD display shows the status and condition of the
battery pack. The Li-Ion battery is factory installed.
3.6.1 Charging
The DC-16 transmitter can be charged with the included wall power
supply or through the built-in USB port.
For fast charging use the included wall power supply. Charging time
is around 3 hours. During the charging process the transmitter can
be in switched-on or off position. The charging status is clearly
shown by lit red and green LEDs. If the transmitter is switched on
during the charging process you can see the charging progress
directly on the LCD display.
Transmitter Charging:
1. Plug in the included power supply to a wall outlet.
2. Plug the main charging connector into the transmitter. If the
green LED goes out, the transmitter is not fully charged. The
red LED indicates the battery charging status.
Discharged battery – red LED is slow blinking, the green LED
is OFF
Close to full charge – red LED is permanently ON, the green
LED is OFF
Fully charged battery the red and green LEDs are ON
24
computer radio control system EN
3.8 Handling
The DC-16 transmitter can be comfortably carried by holding it for
the antenna cover/handle as shown on the picture.
Before each flying session, and especially with a new
model, its important to perform a range check.
If you are operating a model with a DC-16
transmitter do not shield and avoid contact of the
transmitter antenna with your body.
This might increase likelihood of range problem.
Warning:
2.2.
3.7 PPM Input/Output Connector
The PPM output is accessible via connector labeled „B“. This
connector features the non-stabilized battery voltage output in the
range of 3.2V - 4.2V (max. 1A) which can be used as power supply for
the connected HF module as well as for the PPM signal output. The
transmitter output functions are in the form of a standard PPM
signal.
3
1. PPM input (3V logics)
2. Positive (+) pin
3. Negative (-) pin
4. PPM signal output (3V logics, configurable in System
->Configuration)
4
2
1
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computer radio control system EN
2.2.
4 Description of Transmitter DS
1. Right Stick 1, 2 the DS-16 Transmitter Supports Modes 1-4, see Control
Sticks -> mode change
2. Left Stick 3, 4 the DS-16 Transmitter Supports Modes 1-4, see Control
Sticks -> mode change
3. Swappable and Assignable Switches: Sa, Sb, Sc, Sd, Se, Sf, Sg, Sh
4. Digital Trims for the Left Stick T3, T4
5. Digital Trims for the Right Stick T1, T2
6. Right Side Control Lever 5
7. Left Side Control Lever 6
8. Rotary Control Knob 7
9. Rotary Control Knob 8
10. LCD Display
11. Function Buttons F1 F5
12. Transmitter On/Off Power Switch
13. 3D Control Selector
14. Menu Button
15. ESC Button
16. Shows the Antenna but NOT the handle.
Add the handle and assign it a number and pointer in the photo.
17. Charge Jack
18. USB PC Interface
19. Earphone Jack
20. ON/OFF & Charging LED Indicators
21. Speaker
22. Transmitter Neck Strap Bracket Installation Holes
23. Neckstrap Hook
4.1 Control Identification DS-16
3
45
7
8
10
12 13
15 14
16
17
18
21 22 22
21
3
6
9
11
19
20
23
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computer radio control system EN
3
45
7
8
10
12 13
15 14
16
17
18
21 22 22
21
3
6
9
11
19
20
23
4.2 Control Identification DS-14
1. Right Stick 1, 2 the DS-14 Transmitter Supports Modes 1-4, see Control
Sticks -> mode change
2. Left Stick 3, 4 the DS-14 Transmitter Supports Modes 1-4, see Control
Sticks -> mode change
3. Swappable and Assignable Switches: Sa, Sb, Sc, Sf, Sg, Sh
4. Digital Trims for the Left Stick T3, T4
5. Digital Trims for the Right Stick T1, T2
6. Right Side Control Lever 5
7. Left Side Control Lever 6
8. Rotary Control Knob 7
9. Rotary Control Knob 8
10. LCD Display
11. Function Buttons F1 F5
12. Transmitter On/Off Power Switch
13. 3D Control Selector
14. Menu Button
15. ESC Button
16. Shows the Antenna but NOT the handle.
Add the handle and assign it a number and pointer in the photo.
17. Charge Jack
18. USB PC Interface
19. Earphone Jack
20. ON/OFF & Charging LED Indicators
21. Speaker
22. Transmitter Neck Strap Bracket Installation Holes
23. Neckstrap Hook
2.2.
27
computer radio control system EN
24 23
25
26
27
DS-14
24 23
25
26
27
DS-16
23. Battery Connector
24. Transmitter Battery Pack
25. PPM Output Connector
26. Left Gimbal Assembly
27. Right Gimbal Assembly
2.2.
4.3 Assembly Identification
28
computer radio control system EN
4.4 Control Stick Assembly
When handling with back cover removed always
switch off the transmitter and disconnect the
battery (unplug the connector). Also do not connect
the charging adapter or the USB cable.
Note:
Restrict your contact with the printed circuit
boards to a minimum. You can damage your
radio by electrostatic discharge!
Warning:
4.4.1 Control Stick Length Adjustment
The stick length is adjustable to suit your flying style. The stick end
separates into two parts. 1. Hold the top part of the
st i ck e nd f ir mly a nd
u n s c r e w ( t u r n i t
anticlockwise).
2. Turn the stick end
clockwise to shorten or
c o u n t e r c l o c k w i s e t o
lengthen the overall stick
length.
3. Adjust the lower part
to support the top part of
the stick end.
4. Fi na lly s ecu re b y
tightening both parts to
each other.
1
2
3
4
If you have installed optional sticks with switch or
button ends; make sure that while adjusting the stick
length you observe the wires that pass through the
stick shaft and through the gimbal opening in order
to prevent damaging the connecting cables. The
safest method is to remove the small set-screw from
the side of the stick housing to allow the switch or
knob internals to remain stationary while you rotate
the stick housing for height adjustment.. (See 4.3.6)
Warning:
4.4.2 Swivel Control Stick Adjustment
In order to customize the feel of your radio you may adjust the angle
of the stick control assemblies.
1. Switch off the transmitter and remove the 8 screws that secure
the radio back cover. Next, remove the radio back cover.
Be sure to disconnect the transmitter battery pack connector.
2.2.
29
computer radio control system EN
2.2.
2. Loosen both machine screws securing the control stick
assembly.
3. Adjust (rotate) to desired position.
4. Securely tighten both machine screws securing the control stick
assembly.
5. Reconnect transmitter battery pack and reinstall radio back
cover and cover screws.
4.4.3 Control Stick Tension Adjustment
The stick gimbal tension is fully adjustable for each axis. This allows
you to fully customize your radio‘s control feel. Simply adjust each
gimbal‘s spring to your desired tension.
1. Switch off the transmitter and remove the 8 screws that secure
the radio back cover. Next, remove the radio back cover.
Be sure to disconnect the transmitter battery pack
connector.
2. Use indicated machine adjustment screws to change the
desired spring tension.
By turning the screw anticlockwise, you will loosen spring
tension. As a result the moving resistance of the control stick will
3. Reconnect transmitter battery pack and reinstall radio back
cover and cover screws.
decrease. By turning the screw clockwise, you will tighten
spring tension. As a result the moving resistance of the control
stick will increase.
3
4
2
4
2
DS-16DS-16DS-16 DS-14DS-14DS-14
2
2
2
2
DS-16DS-16DS-16
DS-14DS-14DS-14
DS-16DS-16DS-16
DS-14DS-14DS-14
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computer radio control system EN
2.2.
1. Switch off the transmitter and remove the 8 screws that secure
the radio back cover. Next, remove the radio back cover.
Be sure to disconnect the transmitter battery pack
connector.
2. For ratchet tension adjustment use the machine screw A. Turn
slowly (anticlockwise) until you achieve the desired ratchet
tension. For smooth tension adjustment, use the machine screw
“B”. Turn slowly (clockwise) until you achieve the desired
smooth tension.
4.4.4 Ratchet Tension Adjustment
Do you prefer smooth throttle feel or ratchet throttle feel? You can
adjust the DS-16 transmitter either way you like allowing you to fully
customize your radio‘s handling. Each tension is set by a different
machine screw.
3. Reconnect transmitter battery pack and reinstall radio back
cover and cover screws.
4.4.5 Throttle stick travel adjustment
The throttle stick travel is adjustable to suit your flying style.
1. Switch off the transmitter and remove the 8 screws that secure the
radio back cover. Next, remove the radio back cover. Be sure to
disconnect the transmitter battery pack connector.
2. Use indicated machine adjustment screws to limit the throttle
stick travel. By turning the screw clockwise, you will shorten the
throttle stick travel.
3. Reconnect transmitter battery pack and reinstall radio back cover
and cover screws.
AB
DS-14DS-14DS-14
DS-16DS-16DS-16
AB
2
2
DS-14DS-14DS-14
DS-14DS-14DS-14
DS-16DS-16DS-16
DS-16DS-16DS-16
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computer radio control system EN
2.2.
After making a limit change to the throttle stick travel you must re-
calibrate the transmitter stick in the software menu, see section
9.6.3 –Calibration of Proportional Controls.
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computer radio control system EN
4.4.6 Transmitter Mode Switch
The DS-16 transmitter allows you to switch between Mode 1, 2,
3 and 4 stick configurations with just few simple steps. In order to do
some of these, the stick control assemblies will need to be swapped.
1. Switch off the transmitter and remove the screws that secure
the radio back cover. Next, remove the radio back cover.
Be sure to disconnect the transmitter battery pack.
2. Release and pull out the screws of the upper printed circuit
board (the "T" plate).
3. Remove the "T" circuit board by grasping the plate by its edges
near where the bottom fastener goes. Gently lift the board to
disconnect its connectors from the board below. Once
disconnected, tilt the board upward toward the display so that
it is out of the way.
4. Disconnect the control stick assembly wires from the Tx board.
(3 wires ).X, Y , S
5. Remove the stick assembly connecting wires from their holders
on the main board.
6. Remove both machine installation screws for each of the
control stick assemblies.
7. Carefully remove both installation machine screws. Gently lift
in your direction (toward the transmitter back side).
8. Swap both stick assembly units an install them back into their
correct positions.
2.2.
2
3
XXX
YYYSSSSSSYYY
XXX
XXX
YYY
SSS
4
5
6
7
8
33
computer radio control system EN
9. Reinstall and secure the machine screws for each of the control
stick assemblies.
10. Connect the control stick assembly wires to the Tx board
connector (3 wires . The orientation of the wires is X, Y , S)
labeled on the board.
11. Secure the stick assembly wires into their holders.
12. Mount the "T" plate back into place. First insert the connectors
of the "T" printed circuit board into the body of transmitter and
then carefully insert the "T" plate into its connectors on the
main board. Be careful while handling the wires underneath the
"T" plate to avoid any resistance when installing the "T" plate. If
the wires cause any resistance or if the wires are pinched or
stressed in any way, please re-route the wires and try the "T"
board installation again.
13. Reinstall the "T" plate mounting screws.
14. Reconnect transmitter battery pack and reinstall radio back
cover and cover screws.
After making a mode switch you must re-calibrate the
transmitter stick assemblies and setup the correct mode
in the software menu, see section 9.6.1 – Configuration.
The switch between Modes 1 to 3 or Modes 2 to 4 are
done with the software only (NO manual stick change is
necessary).
Note:
2.2.
4.4.7 Transmitter Gimbals with Switch or Button
Installation
If you want to operate the DS-16 transmitter using the optional stick
end switch or button functions, you must purchase one or more of
these separately:
Stick with 2-position switch
Stick with 3-position switch
Stick with push-button
Stick with potenciometer
For installation of the optional gimbal stick ends with
switches/buttons we recommend that you send your
transmitter to one of the factory authorized service
centers or to your authorized dealer.
Advice:
1. Switch off the transmitter and remove the 8 screws that secure
the radio back cover. Next, remove the radio back cover. Be sure
to disconnect the transmitter battery pack connector .
2. Release and pull out the screws of the upper printed circuit
board (the "T" plate).
3. Remove the "T" circuit board by grasping the plate by its edges
near where the bottom fastener goes. Gently lift the board to
disconnect its connectors from the board below. Once
disconnected, tilt the board upward toward the display so that
it is out of the way.
4. Disconnect the control stick assembly wires from the Tx board.
(3 wires ).X, Y, S
5. Remove the stick assembly connecting wires from their holders
on the main board.
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computer radio control system EN
2.2.
6
8. Unscrew the upper part of the stick assembly (anticlockwise).
9. Insert the connecting wires through the hollow opening of the
transmitter stick.
8
9
10. Adjust length of the stick to suit your flying style. (See 4.3)
After installation of the optional stick ends with switch or
button, make sure that while adjusting the stick length
Note:
10
11
12
13
6. Remove both installation machine screws for each of the
control stick assemblies.
7. Carefully remove both control stick assemblies. Gently lift in
your direction (toward the transmitter back side).
2
3
4
XXXYYYSSSSSSYYY
XXX
XXX
YYY
SSS
5
7
35
computer radio control system EN
2.2.
you observe the wires that pass through the stick shaft and
through the gimbal opening in order to prevent damaging
the connecting cables. The safest method is to remove the
small set-screw from the side of the stick housing to allow
the switch or knob internals to remain stationary while
you rotate the stick housing for height adjustment.
11. Pass the switch wires through the same gimbal opening as the
hall sensor cable (through the center of the gimbal assembly).
12. Next insert wire ends through the opening of the printed circuit
board and solder them to the matching soldering points in such
a way that the same color wires lay on the top of each other.
13. Carefully move transmitter sticks to their full outside positions
in order to make sure that you have sufficient wire length and, if
needed, adjust accordingly. The connecting cables for
all moving parts of the unit should have sufficient length in
order not to be exposed to any mechanical damage and any
bending stresses.
14. Install the stick unit assembly back into its correct position.
15. Install and secure the machine screws for the control stick
assembly.
Installation and Configuration of Gimbals Switches
After the switch has been installed into the stick assembly you have
to re-configure and enable it in the transmitter software before it will
function properly. This can be done in the transmitter menu „Main
menu->Advanced setup->Sticks/ switches setup“, see section
9.3.2.
16. Connect the control stick assembly wires to the Tx board
connector (3 wires ). Pay close attention to the wire X, Y, S
lengths. Connect the longest wire as the first one from the
outside of the transmitter (3 connectors ).X, Y, S
17. Secure the stick assembly wires into their holders.
18. Mount the "T" plate back into place. First insert the connectors
of the "T" printed circuit board into the body of transmitter and
then carefully insert the "T" plate into its connectors on the
main board. Be careful while handling the wires underneath the
"T" plate to avoid any resistance when installing the "T" plate. If
the wires cause any resistance or if the wires are pinched or
stressed in any way, please re-route the wires and try the "T"
board installation again.
19. Reinstall the "T" plate mounting screws.
20. Reconnect transmitter battery pack and reinstall radio back
cover and cover screws.
16
XXX
YYY
SSS
17
15
15
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computer radio control system EN
4.5 Swappable and Assignable Switches
One of the most important features of a JETI transmitter is the switch
function assignment flexibility. The DS-16 transmitter automatically
detects the type of switch and assigns the selected function. The
following switch types are available:
2-position short or long switch
2-position spring-loaded long switch
3-position short or long switch
2-position locking switch
potenciometer
You may either swap the existing switches around or take advantage
of the optional accessories and create your own custom
configuration.
Factory Switch Configuration for the DS-16 Transmitter
Sa - 3 - position short switch
Sb - 2 - position long switch
Sc - 2 - position short switch
Sd - 2 - position long switch
Se - 3 - position long switch
Sf - 2 - position short switch
Sg - 2 - position spring-loaded long switch
Sh - 2 - position short switch
Factory Switch Configuration for the DS-14 Transmitter
Sa - 3 - position short switch
Sb - 3 - position long switch
Sc - 2 - position short switch
Sf - 3 - position short switch
Sg - 2 - position spring-loaded long switch
Sh - 2 - position short switch
2.2.
You should keep the wire placement as shown in the
picture. The wires must be placed as far as possible
from the magnetic element Please avoid a).
permanent contact of the wire with magnetic the
element. It could be damaged isolating of the wires.
Warning:
a)
a)
a)
a)
a)
Proper arrangement
of the display flat,
flexible cable.
37
computer radio control system EN
2.2.
4.5.1 Switch Removal Procedure
1. Switch off the transmitter and remove the 8 screws that secure
the radio back cover. Next, remove the radio back cover.
Be sure to disconnect the transmitter battery pack
connector.
2. With the specialized wrench (not included) carefully loosen and
remove the switch installation nut.
3. Hold the switch from the back side of the transmitter and pull it
towards you, so that the switch is released from the body of
transmitter.
4. Disconnect the flat flexible cable from its connector on the
main board.
The flat flexible cables that link the main printed circuit board
with the switches are oriented as shown in the picture The (4a).
wire is always color coded on one side of both ends The (4b).
markings must be oriented as shown below.
4.5.2 Assembly Procedure
1. Insert the flat flexible cable to the switch connector of the
switch. See the orientation above.
2. Push the switch onto its spot in the transmitter housing.
3. Tighten the switch installation nut from the front of the
transmitter. Use the specialized wrench (not included).
4. Connect the flat flexible cable to the main printed circuit board
of the transmitter. See the orientation above.
The cable has to be inserted to the connector that matches the
position on the front panel where the switch is installed.
5. Reconnect transmitter battery pack and reinstall radio back
cover and cover screws.
2 2
3
4b
4a
4b
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computer radio control system EN
When replacing the switch it is also necessary to Sa
remove the switches and from the transmitter Sb Sc
body.
When replacing the switch it is also necessary to Sc
remove the switch from the transmitter body.Sb
When replacing the switch it is also necessary to Sh
remove the switches and from the transmitter Sg Sf
body.
When replacing the switch it is also necessary to Sf
remove the switch from the transmitter body.Sg
Note:
After you turn on the transmitter for the first time after any switches
have been modified, you will notice that the configuration for a
selected model no longer matches.
4.6 Digital Trims
Transmitter gimbals are used for controlling the basic flight
functions like throttle, roll(aileron), pitch(elevator), and yaw(rudder).
Immediately under the transmitter gimbal sticks you can see four
push-buttons which are the programmable, digital trim buttons.
The digital trims are used for fine trimming of the flying model. When
the transmitter is turned off, the trim values are stored in memory
and are recalled when the system is turned back on.
Every model has its own trim setup. Also all flight modes may be
configured to use different trim configurations. By pressing one of
the buttons, the screen will automatically change to display the
graphic position of that trim. The transmitter trims feature an
acoustic step and centre beep alarm.
In the „Digital trim“ menu it‘s possible to enable a special
function used as automatic trimming. Digital trim steps and trim
range setting is explained in „Main menu->Fine tuning/flight
modes->Digital trim“
2.2.
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4.7.2 Battery Replacement
Should you decide to replace the transmitter battery, please follow
these steps:
1. Switch off the transmitter and remove the 8 screws that
secure the radio back cover. Next, remove the radio back cover.
2. Disconnect the transmitter battery connector.
3. Loosen the battery fastening strap and remove the battery.
DS-16 transmitters should only be operated only
with original or manufacturer approved battery
packs. The use of other battery packs will void the
warranty.
Warning:
If the transmitter battery has been disconnected for
longer than 1 minute, the time and date will be deleted.
Note:
2.2.
4.7 Transmitter Battery Pack
The DS-16 transmitter is powered by a Li-Ion type battery pack and
comes equipped with its own built-in advanced battery
management and charging circuit. In switched-on position, the
transmitter LCD display shows the status and condition of the
battery pack. The Li-Ion battery is factory installed.
4.7.1 Charging
The DS-16 transmitter can be charged with the included wall power
supply or through the built-in USB port.
For fast charging use the included wall power supply. Charging time
is around 3 hours. During the charging process the transmitter can
be in switched-on or off position. The charging status is clearly
shown by lit red and green LEDs. If the transmitter is switched on
during the charging process you can see the charging progress
directly on the LCD display.
Transmitter Charging:
1. Plug-in the included power supply to a wall outlet.
2. Plug the main charging connector into the transmitter. If the
green LED goes out, the transmitter is not fully charged. The
red LED indicates the battery charging status.
Discharged battery – red LED is slow blinking, the green LED
is OFF
Close to full charge – red LED is permanently ON, the green
LED is OFF
Fully charged battery the red and green LEDs are ON
3
2
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4.9 Handling
2.2.
4.8 PPM Input/Output Connector
The PPM output is accessible via connector labeled „B“. This
connector features the non-stabilized battery voltage output in the
range of 3.2V - 4.2V (max. 1A) which can be used as power supply for
the connected HF module as well as for the PPM signal output. The
transmitter output functions are in the form of a standard PPM
signal.
1. PPM input (3V logics)
2. Positive (+) pin
3. Negative (-) pin
4. PPM signal output (3V logics, configurable in
System->Configuration)
The DS-16 is equipped with a metal handle for practical
manipulation as shown in the picture.
Before each flying session, and especially with a
new model, it's important to perform a range
check. If you are operating a model with a DS-16
transmitter do not shield and avoid contact of the
transmitter antennas (see Photo)with your body.
Warning:
The transmitter antenna locations are shown in the picture below.
3
4
2
1
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5 RF Transmitter Modules
In order to achieve the highest transmission quality and reliability of
the DC/DS transmitters, we have decided to equip the radio with two
independent DUPLEX 2.4GHz transmitter modules. The transmitter
modules have separate antennas. From the point of transmission
they are fully independent from each other. The RF modules of the
transmitter can operate in following modes:
Default“mode the primary and secundary transmitter RF
modules are active. Both modules alternately communicate
with the receiver. This improves safety and helps to cover dead
angles as well.
Double Pathmode the transmitter RF modules
communicate independently from each other with two
different receivers. The receivers can be interconnected via an
intelligent synthesizer, for instance the JETI Enlink, or the basic
control functions can be divided between two independent
receivers. In this mode one part of a model can be controlled
with one receiver using the first transmitter RF module, the
other part of a model with a second receiver and the second RF
module. In an instant you have created a dual, redundant
flying system with two receivers and two RF modules.
This greatly improves safety and reliability since both RF
modules alternate their communication with both receivers.
Trainer“mode one of the RF transmitter modules is
assigned to communicate with the instructor/student
transmitter only. Communication with the model takes place
via instructor’s transmitter only. If the DC/DS transmitter is in
the „Instructor“ mode, the primary RF module communicates
with the model and the secondary RF module communicates
with the students transmitter. In the „Student“ mode the
DC/DS transmitter communicates via the primary RF module
with the instructor’s transmitter. If you operate two of the
DC/DS transmitters, one of them in the „Instructor“ mode and
the other one in the „Student“ mode, the transmitters
communicate between each other via dedicated RF
transmitter module. With this advanced system NO additional
equipment is necessary.
2.2.
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6 Transmitter Powering ON/OFF
Switching-on is achieved by pressing and holding the „Power“
button . The green LED turns ON and the initial screen appears on (1)
the LCD display. At this point transmitter is waiting for final
confirmation press the F5 (Yes) button . After confirmation, the (2)
main screen is displayed and the transmitter is ready. The power-on
status of the DC/DS transmitter is indicated by the lit green LED.
The transmitter is switched-off by pressing the „Power“ main
button. Before complete power-down is achieved you will be asked
for additional confirmation. In case of an emergency, a fast turn-off
can be achieved by simultaneously pressing and holding the
„Power“ and „esc buttons. NEVER use this alternative during
normal working conditions.
* If you do not confirm powering-on witinin a certain time limit, the
transmitter will turn off automatically. In the DC/DS transmitter
setup you may disable the confirmation by changing in the setup
menu „Main menu->System-> Configuration->Fast switch-on“.
(2)
(1)
If you want to find out the battery status on a switched-off
transmitter just push the button „Power“ and the initial screen
with the battery status will appear. If you do not confirm
turning-on, the transmitter will shut down automatically.
During the charging process this function is always activated.
Advice:
6.1 Transmitter Powering-ON
We recommend that you leave the transmitter with the switch-
on confirmation enabled, as this function prevents accidental
turning-on and discharging of the transmitter battery.
Advice:
6.2 Transmitter Turning-OFF
6.3 Transmitter Restart
2.2.
In case of erratic behavior we recommend that you restart the DC/DS
to reboot the operation system.
1. Standard switch-OFF and ON with main „Power“ button.
2. If necessary, use the Emergency Switch-OFF by simultaneously
pressing and holding the „Power“ and „escbuttons.
3. Disconnect and reconnect the transmitter battery connector.
[ Remove the screws that secure the radio back cover. Next, remove a)
the radio back cover, Disconnect the transmitter battery connector, b)
c) d)Press the „Power“ button to discharge the internal capacitors,
Reconnect the transmitter battery, Reconnect transmitter battery e)
pack and reinstall radio back cover and cover screws, Restart the f)
system. ]
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7 Initial switching-on 7.1 Main display
Turn the transmitter on by pressing and holding the „Power“ button
for a couple of seconds and then press the "F5 (Yes)" button to
confirm, see chapter 6.1. The display shows the Main screen and
displays the currently loaded model aircraft.
The main screen displays basic information about operation of your
transmitter, such as the battery level, time, flight mode, etc. This
screen will also display the user defined information you want to
monitor, for example: stopwatch, telemetry values, etc. The main
screen consists of three main sections: the status bar, the desktop
and the lower bar.
1. Signal strength
2. Battery status
3. Time
4. Telemetry recording icon
5. Model Name
6. Name of actual flight
mode
The status bar at the top of the main display displays the following
information: 7
2
3
4
5
6
1
8
The Desktop is the largest part of the screen. This is where you can
see your telemetry data and where any programmed alarms are
displayed. The Desktop displays your user-defined information
through the use of multiple pages. As you add or remove telemetry
items or alarms, the number of available pages will automatically
increase or decrease as needed.
In this example, the desktop page displays the following
information:
3.3.
You can also immediately select a different model after the
transmitter starts by pressing the "F3" button.
By pressing the "F2" button you are able to disable the logging
feature for a current session. If you are just making adjustments to
the model configuration, press the "F2" button and confirm. The
logging will be disabled until restart of the transmitter.
To make the start-up screen visible, in the Configuration Menu, you
have to select "No" for the "Disable startup question" option.
7. Throttle Lock
8. Motor cut-off indication, idle
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3.3.
The lower bar is found at the bottom of the main display.
The lower bar shows:
1. Opt.-fast transmitter setup: Contrast, Telemetry,
Volume, Duration of Backlighting, Backlighting Brightness.
2. Left Arrow-move left within the desktop pages.
3. Right Arrow-move right within the desktop pages.
4. Clr-resets the timers or opens the Data Analyzer application in
the main desktop window.
5. Stop/Start-begin and end flight timer, triggering timers or
telemetry recording.
Use the corresponding F1-F5 buttons to select these options
From the main display you may access the main menu by pressing
the „menu“ button. To return from the main menu press either the
„menu“ or „esc button.
From the main display, when you push any of the trim buttons or the
3D button the Trim menu” will be displayed.
1
2
3
4
5
7.2 Navigation in the Menu
To navigate within the transmitter menus, use the following
buttons:
1. The „menu“ button allows you to switch between the main
display and the transmitter‘s main menu.
2. The „esc button allows you to move one level back within the
menu. If you push this button while you are editing a value you
will return one menu level and the edited value will NOT be
stored.
3. 3D Control Selector
3a - by turning the selector anticlockwise you will move up
in the menu. Turning the selector this direction will also
decrease any value you are editing.
- by turning the selector clockwise you will move down in 3b
the menu. Turning the selector this direction will also
increase any value you are editing.
by pressing the selector you will confirm your 3c
choice/enter the selected menu.
4. The „F1 - F5“ functions buttons located below the display are
used to select various options based upon the current display.
Also, If you push this button while turning the 3D Control
Selector to edit values, the values can be changed faster. With
the menu button pressed, 10 more values are changed per turn.
Advice:
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3.3.
1
3
23b
3a
3c
7.2.1 Browsing through the Menu
The current selection within the menu (cursor) is designated by
reversed text/shaded graphics. By turning the 3D control selector
left/right you will move through the lines of a menu.
To select an item, first highlight the line and then press the „3D
button“, to select the line. Rotate the 3D control selector to
highlight your selected item within the line, then press the „3D
button“ to select the item. Rotate the 3D control selector either left
or right to change the value of your chosen item. By pressing the
„3D button“ again you will confirm the storage of your selected
value and go back to your previously selected menu item. If you
want to go back to select another line within the previous menu
press the „esc button.
4
1
3
23b
3a
3c
4
Note: For each press of the „esc“ button, you are taken back one
menu level.
* Model
- Select Model
- New Model
- Basic Properties
- Functions Assignment
- Servo Assignment
- Servo Setup
- Device Explorer
* Fine Tuning
- Flight Modes
- Digital Trim
- Flight Mode Trim
- Dual Rate/Expo
- Function Curves
- Aileron Differential
- Gyro Settings (Heli)
- Throttle Limiter (Heli)
- V-Tail, Delta Mix, Ailevator Mix
(Aero)
- Butterfly (Aero)
- Snap Roll
- Free Mixes
* Advanced Properties
- Other Model Options
- Sticks/Switches Setup
- Wireless Modes/Trainer
- Logical Switches
7.2.2 Basic Menu Structure
- Sound on Event
- Sound of Prop. Controls
- Telemetry Controls
- Sequencer
- Accelerometer (DS-16 only)
* Timers/Sensors
- Timers
- Alarms
- Vario
- Voice Output
- Sensors/Logging Setup
- Displayed Telemetry
- Main Screen
* Applications
- Data Analyzer
- Audio Player
- JETIBOX
- Games (Snake, Tetris, Chess...)
* System
- Configuration
- Servo & Range Test
- View Inputs
- Receiver Output
- System Sound
- Sound Volume
- USB
- Info
*) The items displayed in the menu depend on the actual transmitter
equipment and the model functions that are active.
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7.3 Model Set-up Guide
7.3.1 Airplane
Let’s create a simple model airplane. Our example will be a motor
glider with ailerons controlled by two servos, an elevator and a
rudder each controlled by one servo.
In this section we will guide you, step by step, through the process of
creating a new model airplane and helicopter. Each step of the guide
will be complete with associated transmitter menu photos. If you
follow the step by step guide you should become familiar with how
to create a model profile. You may even use these concepts and the
„General“ model type to create your own, user-defined model
profile.
Servo assignment:
1. Throttle
2. Aileron 1
3. Aileron 2
4. Elevator
5. Rudder
Before you begin creating a model, make sure that you have set up
the correct transmitter mode in „Main menu -> System ->
Configuration -> MODE 1-4“. The basic, standardized, assignment
of transmitter inputs to flight controls are based upon this selection.
First it is necessary to create a model in the transmitter and then bind
the DC/DS transmitter with the receiver which will control the given
model. See chapter 8.3: „Receiver->Binding.
For safety reasons we recommend first removing the propeller.
Warning:
1. Switch-on the transmitter. In the main
display push the key „menu“. Select the
item „Model“ and push the „3D button“.
2. Select the item „New model“ and push
the „3D button“.
3. Enter the name of your model and press
„F5(OK)“ (Note: you must enter a model
name to proceed.) Then select the model
type „AERO“. Confirm by pushing the
„F5(Next)“ button.
4. Select your wing type. Because this
example has 2 aileron servos, select Wing
type“ 0FLP/2WING. Do not change any
other setup items like tail assembly,
number of motors, number of spoilers or
number of landing gear servos. Continue
by pushing the „F5(Next)“ button.
3.3.
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5. This page displays the flight control
functions and their transmitter switch
assignments. Here you can verify that your
flight control functions are correctly assigned
to the transmitter switches/sticks. If they are
not, check and make sure that you have
selected the proper transmitter mode.
Confirm the assignments by pushing the
„F5(Next)“ button.
6. This page displays the assignment of
functions to your receiver outputs (servos).
You may change the assignments by editing
the output assignment for each receiver
channel. Otherways confirm with the
„F5(Next)“ button.
7. The screen will now display a request which
asks if you really want to create and activate
the new model. Confirm with the „F5(Yes)“
button.
8. The Servo Setup menu is where you set the
servo neutral positions, servo output travel
limits, servo reversing, delay etc. You will
come back to this menu after binding the
receiver with your transmitter. Press the
„F5(OK)“ button and you are taken to the main
screen where your new model is displayed in a
desktop page.
Bind transmitter with the receiver, see chapter 8.4 Receiver->Binding.
Once your transmitter has been bound with the receiver and you have
re-applied power to the receiver, the last setup phase is the tuning of
your servo output functions, see chapter 7.3.4 Setup of receiver
outputs.
With this type of wing configuration there is usually a mixer used to also
raise the ailerons as spoilers (spoilerons). Follow the steps below the set
up this mixer. In this example we will use the „right side control
lever(5)“ for the proportional control of the spoilerons.
a. From the main screen, push the „menu“
button. Select „Fine tuning“ and push the
„3D button“.
b. Next, select „Butterfly“ and push the „3D
button.
c. In the first menu line push the „3D button“
,select „Switch“ and push the „3D button“
again. Next, move the „right side control
lever(5)“. Confirm with the „F5(OK)” button.
The last step in this menu is to set the amount
of travel that your ailerons will move as
spoilerons (or flaperons) and to set any
desired elevator compensation.
3.3.
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When setting up your spoilerons be sure that the ailerons still
have enough travel to control your airplane when the spoilerons
are deployed. In this menu the „(Sym) F1“ button will link or
unlink the spoilerons if you need to set them independently
Note:
7.3.2 Helicopter
Let’s create a simple model helicopter. In this example, the
helicopter is controlled by a swash plate with three servos at 120°
orientation and the motor has no governor.
Servo assignment for the receiver channels:
1. Throttle
2. Elevator (Swash 1F)
3. Collective (Swash 2L)
4. Aileron (Swash 3R)
5. Rudder (Yaw)
6. Gyro(Gyro sens.)
Before you begin creating a model, make sure that you have setup
the correct transmitter mode in „Main menu -> System ->
Configuration -> MODE 1-4“. The basic, standardized, assignment
of transmitter inputs to flight controls are based upon this selection.
First it is necessary to create a model in the transmitter and then bind
the DC/DS transmitter with the receiver which will control the given
model. See chapter 8.3: „Receiver->Binding”.
For safety reasons we strongly recommend removing the
main/tail blades or disconnecting the motor when working
with an electric helicopter.
Notice:
1. Switch on the transmitter. In the main
display push the key „menu“. Select the
item Model“ and push the „3D button“.
2. Select the item „New model“ and push
the „3D button“.
3. Enter the name of your model and press
„F5(OK)“ (Note: you must enter a model
name to proceed.) Then select the model
type „Heli“. Confirm by pushing the
„F5(Next)“ button.
4. Select the helicopter swash plate type „3
servos (def 120°)“. Change the second
menu item „Position of front servo“ to
„Rear“ the swash plate servo orientation
will be turned 180°. Confirm the change by
pressing the „F5(Next)” button.
3.3.
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5. The„Functions Assignment“ menu lists
the flight functions and their control
switch/stick assignments. If you want to
change any of the switch/stick assign-
ments, select the „Control“ item for your
flight function and then select your desired
switch/stick for that flight function. Press
„F5(Next)“ to confirm.
When you create a new helicopter model, you are required to define
the swash plate configuration for the model. Please refer to your
helicopter’s instructions and verify that you have the correct swash
plate configuation. If you find that you need to change your swash
plate configuration, you can always go to the „Model -> Basic
Properties“ menu to make the change.
6. The „Servo assignment“ menu displays
the receiver channels and their transmitter
output assignments. If you want to change
any of the output assignments, select the
channel you want to edit and reassign its
output. Otherways press „F5(Next)“ to
confirm.
7. The „Swash Mix“ menu displays the travel
range of each particular helicopter flight
function for the swash plate. The travel
range is displayed as a percentage. You can
use these travel range adjustments to
prevent linkage binding and to tune the
helicopter to suit your flying style. You can
8. The screen will display a question which
asks if you really want to create and activate
the new model. Press the „F5(Yes)“ button
to confirm.
9. The „Servo Setup“ menu is where you
can set all of your servo neutral positions,
servo output throw limits, servo reversing,
delay etc. You should return to this menu
after you have bound your receiver and
transmitter. See chapter 8.4: Receiver-
>Binding.
3.3.
also activate a cyclic reduction of the rotor head travels (Swash Ring)
so the servos cannot be damaged by large simultaneous movements
of the sticks.(Refer to your helicopters instruction manual.) Press the
„F5(Next)“ button to confirm.
10. Once your transmitter has been bound with a receiver and has
been connected to its power supply, the last step consists of tuning
the servo output functions, see chapter 7.3.4: Setup of receiver
outputs.
In the „Fine tuning -> Flight modes“ menu you will setup these
advanced model control functions for your helicopter:
Collective pitch curve, see: Fine tuning -> Flight Modes->Function
Curves
Throttle curve, see: Fine tuning -> Flight Modes->Function Curves
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3.3.
Dual rates, see: Fine tuning -> Flight Modes -> Dual Rate/Expo
Autorotation, see: Fine tuning -> Flight Modes
Gyro/Governor see: Fine tuning -> flight modes -> Gyro/Governor
For convenience, a quick link to all of these function settings has been
made through the Heli Tuning menu.
7.3.3 General
The DC/DS transmitter are not only equipped with the assistants for
airplanes or helicopters, but they also have a „General“ assistant
which can be used to create just about any other type of model. If
your model cannot be assigned to the category of an airplane or
helicopter, select the general model. The following setup describes
the creation of a boat model. This process could also be used to
create a profile for any other land/water/air model craft. In this
example, the model is controlled by basic functions like throttle and
rudder as well as by extended functions like a motor sound
generator, lighting system, siren, and a smoke generator. The first
three above mentioned functions are controlled proportionally and
the rest are non proportional.
Servo assignment to receiver channels:
1. Motor
2. Rudder
3. Motor Sound Module
4. Lighting System
5. Siren Sound Module
6. Smoke Module
Before creating a model, make sure that you have setup the correct
transmitter mode in „Main menu -> System -> Configuration ->
MODE 1-4“. The basic, standardized, assignment of transmitter
inputs to flight controls are based upon this selection.
First it is necessary to create a model in the transmitter and then bind
the DC/DS transmitter with the receiver which will control the given
model, see chapter 8.3: „Receiver->Binding.
1. Switch-on the transmitter. In the main
display push the key „menu“. Select the
item „Model“ and push the „3D button“.
2. Select the item „New model“ and push
the „3D button“.
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3.3.
3. Enter the name of your model and press
„F5(OK)“ (Note: you must enter a model
name to proceed.) Then select the model
type „General“. Confirm by pushing the
„F5(Next)“ button.
4. The first item in the „Basic Properties“
menu is the number of motors in the
model. In this example, this item will not be
edited and we will proceed to the second
item, which is how the motor needs to be
controlled i.e. whether the motor turns
only one direction (Single) or both
directions (Double). Edit the item „Motor
type“ by selecting „Double direction“.
Press the „F5(Next)“ button to confirm.
5. In the „Function Assignment“ menu
use the „F3(Add)“ button to create all of
your desired functions. Then you can assign
transmitter control switches/sticks to the
functions by editing each function’s
„Control item, see chapter: Select
control input“. The only exception is the motor sound module
function, which you cannot simply assign to a control switch/stick,
because it wil be controlled by a mixer. The mixer will allow the
motor sound will be played proportionally to the motor speed. For
the siren function you may take advantage of the switch „Sa“
(spring-loaded switch). After you create all of your desired functions,
press the „F5(Next)“ button to confirm.
6. The „Servo assignment“ menu displays
the receiver channels and their transmitter
output assignments. The channels are
assigned in the order that you created the
functions in the previous menu. If you want
to change any of the output assignments,
select the channel you want to edit and
reassign its output. Otherways press
„F5(Next)“ to confirm.
7. The screen will display a question which
asks if you really want to create and activate
the new model. Press the „F5(Yes)“ button
to confirm.
8. The „Servo Setup“ menu is where you
can set all of your servo neutral positions,
servo output throw limits, servo reversing,
delay etc. You should return to this menu
after you have bound your receiver and
transmitter. See the chapter 8.4: Receiver-
>Binding.
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You should mechanically adjust all of your servo arms and servo
linkages to be as close to neutral or center as possible so that you
will need as little subtrim as possible. Using large amounts of
subtrim can limit the overall throw of your servo.
Note:
a. Use the „F2(Add)“ button to create a
new mixer. Select „Engine“ in the „From“
item. Then select „Sound M“ (the name of
the sound function) in the To“ item. The
item Master Value represents the
amount of mixing from the input function
Once your transmitter has been bound with a receiver and has been
connected to its power supply, the last step consists of tuning the
servo output functions, see chapter 7.3.4: Setup of receiver
outputs.
To complete this model we just need to configure a free mixer from
the throttle function to the motor sound module. In this example we
will set a switch to enable/disable the mixer so that when the switch
is „on“, the motor sound module is controlled with the throttle
(motor speed). Go to the „Fine tuning -> Free mixers“ menu.
3.3.
b. To assign a switch for the activation and
deactivation of the free mixer, press the
„F4(Edit)“ button. Select and edit the
„Switch“ item to assign a switch/stick to
enable/disable the mixer.
to the output function for this mixer. With the „F5(Next)“ button you
will create the mixer and the display will change to show the
overview of your programmed free mixers.
7.3.4 setup of Receiver Outputs
Go to the „Model->Servo Setup“ menu. Use the „F2“ and „F3“
buttons to brows through the receiver outputs (channels).
You can scrol through the following servo adjustment items for each
channel:
„Servo reversing“ reverses the servo throw direction.
Move the stick for your selected channel and observe the direction
of the servo movement. If the servo moves in the opposite of your
desired direction, change the direction by editing the „Reverse“ item
for that particular servo. Continue with each channel until all of the
servos travel in the required directions.
„Center (Subtrim)“- adjusts the center position of each servos
output.
With your sticks in their neutral positions, scroll through each servo’s
page and use the „Center (Subtrim)“ item to correctly set all of your
servo‘s center or neutral positions.
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3.3.
„Max/Min. limit“ sets the absolute maximum servo output throw
Use these to limit the maximum range of servo throw in order to
keep your servos from exceeding their mechanical limits or to keep
your servos from binding when moving their arms or linkages to
their full travel. You should use the dual rate function to set your
model’s useable control throws.
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8 Receiver
3.3.
1. JETI Duplex receivers use the universal or JR Type“ servo
connectors.
2. Bat - receiver and servo power supply input. Whenever
possible, always supply power to your receiver using more than one
of these inputs. You can either supply power through the use of a Y-
cable or through any unused receiver channel connection. To power
the receiver you may use NiCd packs, the BEC from your ESC or Li-xx
cells used with a voltage regulator, such as the JETI MAXBEC or
similar.
3. SAT - auxillary input/output for PPM signals. This input allows
you to connect an additional JETI DUPLEX Rsat2 satellite receiver or
an additional US version Duplex receiver.This allows you to increase
the number of receiver antennas in your system for increased
reliabilty in installations with shielded or badly oriented antennas.
4. EXT - input for telemetry sensors. If you want to connect more
than one telemetry sensor then use the JETI EXPANDER E4. You can
„daisy-chain“ several of the E4 Expanders to support many, many
sensors.
8.1 Description
1
5 4
3
2
5. A1/A2 - receiver antennas. The antennas should be installed
so that the wires form a 90° angle relative to each other.
8.2 Installation
Whenever possible, you should wrap the receiver in foam and place
it as far as possible from sources of interference (servos, electric
motors). Arrange the receiver antennas so that their active ends form
a 90° angle and try to put them as far as possible away from each
other. Take care not to bend them with a radius smaller than 1 cm.
The active part of the antenna should not be placed close to metal
parts. If your model has a carbon fuselage it is very important to
place the active antenna ends outside the fuselage.
8.3 Binding
In order to achieve communication between transmitter and
receiver you must bind them. During this process the transmitter
learns the receiver address and will automatically find it again when
switched back on. Communication begins with this receiver
automatically if the transmitter is not already communicating with
another receiver. The binding process needs only to be done once
for each receiver.
8.3.1 Standard pairing procedure
1. Switch off the transmitter and receiver.
2. Plug the „BIND PLUG“ into the EXT receiver input.
3. Connect receiver power supply.
4. Switch on the transmitter. The receiver will bind with the
primary transmitter module.
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8.3.2 Alternative pairing procedure through the
transmitter menu
1. Turn off the receiver. Keep the transmitter turned on.
2. Plug the "BIND PLUG" into the EXT receiver input.
3. Connect receiver power supply.
4. Locate the transmitter menu Advanced Properties -> Wireless
Modes/Trainer
5. Highlight "Pair primary TX module" and press the 3D button.
6. The receiver will bind with the transmitter. Confirm the registered
device.
8.4 Range Test
The range test will verify that the transmitter and receiver are
functioning properly.
Before the first flight of each flying session or if have any doubts
about the transmitter or receiver function, you should always check
the range. During the range test the transmitter’s output power is
decreased to 10%.
When performing a range test, both the model and the transmitter
should be at a minimum height of 80 cm (31.5“) above the ground. A
correctly functioning transmitter and receiver in range test mode
should safely control a model to a minimum distance of 50m (164‘).
If not, check your model’s antenna installation first. If the test is still
not successful, don´t fly the equipment and contact your retail shop
or one of the JETI authorized service centers.
8.5 Fail safe
All Duplex 2.4GHz system receivers are equipped with „fail safe“, a
function which reacts to control signal transmission interruptions.
When your receiver for any reason does not receive transmitter
information, it changes, after a pre-set time period, to one of the
following modes.
„Repeat“ This mode holds the last valid control throw signal ( this is
the default mode for all receivers)
„Out off“ – There is no output signal provided by the receiver, i. e.
servos do not keep their positions
„Failsafe“ receiver outputs change to preset positions
3.3.
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computer radio control system EN
3.3.
Each receiver channel can be configured to one of the modes
described above. We recommend that you setup „fail safe“ positions
for every output, which enables your model to stay in a stable
condition. For instance, the elevator and rudder in neutral positions,
electric motor switched-off, gas engine idling, spoilers extended.
Configuration Method of the receiver failsafe function.
1. Bind receiver with transmitter. See chapter: 8.4 Binding. Leave
receiver and transmitter in switched-on condition.
2. In the transmitter, go to the menu „System->JETIbox“ and
proceed according to picture. Use the F1-F4 function buttons to
move within the menu.
3. In the „Set Output Pin“ menu select the receiver output which
you want to configure (use the left/right buttons) and proceed (by
using the down-button).
4. In the „Signal Fault Yn“ menu where n denotes the channel
number which has to be configured, use the right-button to edit the
output function showing a signal failure (setup „fail safe“). You have
now activated the „fail safe“ function on receiver channel output n.
5. The „fail safe“ is adjusted by pressing the down-button and
changing to the „fail safe“ menu. With the left/right buttons edit the
„fail safe“ value in a range of 0.8ms to 2.2 ms. Adjust all of the
connected receiver outputs by repeating steps 3-5.
The last parameter to be set up is the elapsed time after signal failure
when the „fail safe“ or other actions after signal failure will be
initiated. In the „SignalFault Delay“ menu you can define the length
of time after a signal fault occurrs in which the preset throws are
applied. The values in this menu are changed by pressing the
left/right buttons.
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3.3.
8.6 Technical data receivers
Basic Data
R4
R4C
(R4C
mini)
R6
(R6 EPC*)
R7
(R7
indoor)
R8
(R8 EPC*)
R9
R10
R11 EPC*
R12 EPC*
R14*
R18*
Rsat2
(RMK2)
Dimensions [mm]
35x 20x7
30x23x13
45x24x12
44x20x7
50x30x12
51x24x11
50x28x13
51x24x11
50x28x13
62x38x16
62x38x16
35x23x6
Weight [g]
4,8
8 (7)
11 (14)
5,5
15 (18)
13
17
15
22
30
30
12
Antenna Length [mm]
2x100
1x200
(internal)
2x100
2x100
(2x45)
2x200
2x200
2x200
2x200
2x400
2x400
2x400
2x200
(2x75,
2x150)
# of Channel Outputs
4
4
6
7
8
9
10
11
12
14
18
PPM 8/16
Temperature Range [°C]
-10 to +85
-10 to +85
-10 to +85
-10 to +85
-10 to +85
-10 to +85
-10 to +85
-10 to +85
-10 to +85
-10 to +85
-10 to +85
-10 to +85
Supply Voltage [V]
3.2 – 8.4
3.2 – 8.4
3.2 – 8.4
3.2 – 8.4
3.2 – 8.4
3.2 – 8.4
3.2 – 8.4
3.2 – 8.4
3.2 – 8.4
3.2 – 8.4
3.2 – 8.4
3.2 – 8.4
Average Current [mA]
40
40
45
40
30
30
30
30
30
40
40
30
Real Time Transmission of
Telemetric Data
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Programming
JETIBOX
JETIBOX
JETIBOX
JETIBOX
JETIBOX
JETIBOX
JETIBOX
JETIBOX
JETIBOX
JETIBOX
JETIBOX
JETIBOX
Support Satellite Receiver
Rsat
no
no
no
no
no
Yes
Yes
Yes
Yes
Yes
Yes
-
Power Output [dBm]
6
6
15
6
15
15
15
15
15
15
15
15
Receiver Sensitivity [dBm]
-98
-98
-106
-98
-106
-106
-106
-106
-106
-106
-106
-106
* xternal ower onnector E P C
8.6.1 Technical data receivers outside the U.S.
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Basic Data
R4L
(R4L indoor)
R5L
(R5L indoor)
R6L
(R6L indoor)
R7plus
R9
R11 EPC*
R14*
R18*
Dimensions [mm]
38x20x7
47x20x7
43x24x11
51x24x11
51x24x11
51x24x11
62x38x16
62x38x16
Weight [g]
4,8 (4,5)
5,4 (5)
13
13
13
15
30
30
Antenna Length [mm]
2x100 (2x45)
2x100 (2x45)
2x200 (2x50)
2x200
2x200
2x200
2x400
2x400
# of Channel Outputs
5
5
6
7
9
11
14
18
Temperature Range [°C]
-10 to +85
-10 to +85
-10 to +85
-10 to +85
-10 to +85
-10 to +85
-10 to +85
-10 to +85
Supply Voltage [V]
3.2 – 8.4
3.2 – 8.4
3.2 – 8.4
3.2 – 8.4
3.2 – 8.4
3.2 – 8.4
3.2 – 8.4
3.2 – 8.4
Average Current [mA]
30
30
30
30
30
30
40
40
Real Time Transmission of Telemetric
Data
No
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Programming
Tx
JETIBOX
JETIBOX
JETIBOX
JETIBOX
JETIBOX
JETIBOX
JETIBOX
Support Satellite Receiver Rsat
no
no
no
Yes
Yes
Yes
Yes
Yes
Support PPM/EX bus
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Yes
Power Output [dBm]
15
15
15
15
15
15
15
15
Receiver Sensitivity [dBm]
-106
-106
-106
-106
-106
-106
-106
-106
* xternal ower onnector E P C
8.6.2 Technical data receivers for the U.S.
3.3.
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8.7 Using Device Explorer To Configure the Receiver
The Device Explorer utilizes the latest
data/command EX Bus protocol to
wirelessly configure remote devices such as
receivers, sensors and other EX Bus
compatible devices. You can check the
label of your device to see if it supports the
EX Bus protocol.
Basically, the Device Explorer (located in
the Model menu) replaces the integrated
JETIBOX emulation and brings additional,
more intelligent ways to communicate
with your remote devices. The main Device
Explorer window shows a list of available
devices. The recognized devices are labeled with their registered
name, others are not displayed or only displayed as a device ID. The
check mark tells you that the device is ready and that you can
configure it. By using the F3" Refresh button you can reset the
displayed devices, this forces the auto-detection function to explore
all attached devices. The remote sensor and device detection
process is always running in the background.
In the picture above, two receivers R8 EX and R9 EX have been
detected and are recognized. When you press the rotary button, you
are able to configure them in detail. Here is the example how to use
the Device Explorer to configure an "R8 EX"receiver:
First, the transmitter downloads all settings from the receiver. After
that operation is completed you should be able to see the basic
configuration of the receiver as shown in the picture . Every a)
modification that you make is automatically uploaded back to the
receiver, so that you can immediately see results of the steps you are
a)
doing and there is no need to continuously "save" your changes. For
your convenience, there is a "Refresh" button „F3", which causes all
of the data to be downloaded from the receiver once again. This is
beneficial mainly if you are modifying the configuration by using a
JETIBOX device and the Device Explorer simultaneously.
The "F2" Tools button is used to enter a special dialog where you can
import and export settings of the particular device. If you want to
export the configuration of your (for example) receiver, just enter the
"Export settings" menu item, set the file name and confirm.
Similarly you can import this configuration to the device. All the
exported files are stored in the "Export" folder on the SD card.
3.3.
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3.3.
Before a device can be recognized, a special predefined
configuration scheme must be present on the SD card in the
/Devices folder. If the scheme doesn't match or doesn't exist, an
error message "Unknown device" is displayed. If such an error
occurs, please download the latest software for your DC/DS
which, by default, has all the definitions included, or contact your
dealer for assistance. This text describes properties introduced in
receiver version 3.20.
Note:
The picture shows the following adjustable parameters:a)
- Serial Link This determines the operational mode of the
receiver. You can choose from these options:
JETIBOX & Servo The standard mode for direct servocontrol.
PPM Positive, PPM negative the servo signal is summed into
a standard or inversed PPM signal. This option is for devices
which can use single line servo output data. Direct connection of
servos in this mode is supported as well.
EX Bus Tells the receiver that it should send all data onto a fast
digital serial link for further processing. This is the recommended
option if you are connecting the receiver to the Central Box or
another EX Bus intelligent device.
UDI - Universal Data Interface. - This is a unidirectional digital
serial protocol that can transmit up to 12 channels on a single
wire. The UDI is compatible with several stabilization systems for
helicopters and airplanes.
-General Settings - redirects you to screen b)
- Fail-Safe - redirects you to screen c)
- Alternative Pin Config - redirects you to screen d)
- Receiver Outputs - redirects you to screen e)
- Reset to factory settings... After confirmation, the receiver's
configuration will be restored to its factory settings.
The next page (General Settings) shows basic properties of the
receiver (picture . b)
- Output Period Determines how often the servo signal will
be repeated to the outputs of the receiver. You can select periods
from 5ms to 30ms (in 5ms steps). Recommended option:
Auto.
PPM Settings
- Number of channels if the output mode selected is either
positive or negative PPM, you can set how many channels will show
on the output.
- SAT1/SAT2 - Some types of receivers support input of backup PPM
signal. This signal can be captured via SAT1 or SAT2 ports. Here you
can define the mode of operation for the particular ports. The PPM
input can be accepted only in standard servo mode and EX Bus
mode. Additionally, the SAT2 port can be configured as a PPM
output. In this case the SAT2 outputs all 16 channels if not specified
otherwise.
b)
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3.3.
- PPM/UDI Mode - determines processing and additional logic
applied to the PPM and UDI protocols.
- Direct - signals received from the transmitter are not further on
processed in the receiver, they are generated without any
change at the output of the receiver in form of PPM/digital
signals. If a signal loss occurs, no PPM/digital data will be generated
by the receiver.
- Computed - the signals received from the transmitter can be
processed further on in the receiver and its menus "Channel set"
and "Out Pin Set" programmable channel outputs, gains etc.)
Alarm Settings
- Low Voltage Alarm - the value serves for the setup of the alert
decision threshold. As soon as during operation the actual voltage
decreases below the set threshold, the receiver will generate an
alarm. The transmitter may announce this situation by an acoustic
tone (this depends on transmitter alarm settings, please refer to
chapter describing Timers/Sensors -> Alarms).
On the next page (picture ) shows the fail-safe function c)
parameters.
- Fail-Safe This parameter tells the receiver how to react when a
signal loss event occurs. If you set “Enabled" then you will be
able to set the behavior of every channel independently. The
“Disabled" option says that if no signal is being received from
the transmitter, no driving signal for the servos (or PPM) will
be present.
- Fail-Safe Delay The number of seconds that must elapse from the
moment of losing signal until the fail-safe is activated. This
option is available only if the Individual mode is selected.
- Each output position of the receiver has three adjustable
parameters:
Mode (Hold, Out OFF or Fail-Safe) – Dictates, how the specific
output behaves if a signal loss occurs. Using the Hold mode, the
latest known servo position will be held. Out Off option means that
there will be no signal to the particular servo channel. The last
option, Fail-Safe, will set the servo to (user) predefined position (set
in the "Value" column).
Value The position of the servo after a signal loss occurs.
This is available only when the Fail-Safe mode is selected. For
„F4 convenience, you can press the Apply” button while you are
editing this column. The selected value will then appear directly
on the servo output without the need to turn off the RF modules
which would eventually activate the fail-safe and show the set
position. The Apply function makes it faster to set your fail-
safe positions.
c)
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3.3.
Slope This slows down the speed of servo movement while the
output is moving from the normal position to the fail-safe
position.
The screen , "Alternative Pin Config", allows you to modify the d)
modes of receiver output pins. The servo outputs can be configured
into Digital input and Digital output modes.
- Digital input mode: a logical value of a given signal pin (0 or 1 as a
result) is transmitted to the DC/DS in form of EX telemetry so that it
can be further on processed (displayed and stored to the SD card).
The receiver pins are equipped with internal pull-up resistors. To
detect logical value of a given pin it is enough to connect the signal
pin with the ground.
- Digital output mode: The channel value of a given output pin is
discretized into two values. If the channel value is greater than
1.5ms, the pin output will be log.1. Otherwise the signal pin will stay
at logical 0. Using this way you can simply control for example lights
consisting of several LEDs. The fail-safe configuration is applied in
this mode as well as in servo mode.
d)
The page Receiver Outputs (picture ) allows you to redirect your e)
transmitter’s channels to any output of the receiver. For convenience
the transmitters channel numbers are displayed together with the
appropriate function names, making it easier to adjust. In addition,
you can also set the servo group for each channel. For more
information please refer to your receiver manual.
e)
8.7.1 Support of remote commands for EX Bus devices
(*depends on equipment)
The DC transmitters support up to 16 universal commands for /DS
wirelessly connected devices supporting EX Bus. To view the list of
active commands, press the F4 CMD button when in the Model „ ” -
> Device Explorer menu. However, the command must be
detected before it can be activated. As an example of the use of
wireless commands, the Central Box can be used and its command
that resets the minimum, maximum values and battery capacity
(Clear MIN / MAX values).
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computer radio control system EN
3.3.
1. The list of active commands.
2. Sa switch is assigned to reset
minimums, maximums, and the measured
capacity. For the reset command only the
Control mode is available (the position of
the control/switch is taken as an input),
other devices may accept a proportional
value specified as a constant or as the
channel number on the transmitter.
3. Scroll to view minimums and maximums.
4. Pushing the 3D button enables you to
add the command into the list of active
commands and it is possible to assign a
transmitter control to it.
On the main screen of the Central Box settings scroll down to display
the maximum telemetry values (Telemetry Min/Max). Here you will
find a choice to assign a switch to the command for deleting
measured minimums and maximums (Clear Min/Max switch).
Pushing the 3D button on this item you are moved to the list of
active commands where this command is already listed and is
inversely highlighted with a cursor.
Pushing the 3D button moves you to the choice to assign the
control/switch that will further on take care of the command for
resetting. Here we have chosen the Sa switch.
Further operation of the command will look like this:
- Moving the Sa switch into the ON position makes the transmitter
detect that it should send the command for resetting telemetry
minimums and maximums to the model. However, before the
command is applied, it is necessary to confirm the choice by the pilot
to avoid unwanted resetting of the data.
- The transmitter displays a dialog asking if you want to execute the
command for resetting the telemetry. If you press NO or you do not
manage to respond in time, the dialog closes and the command is
not executed.
- Conversely, if you press YES, the command is sent to the model
where it is processed by the Central Box which resets its telemetry.
The result of this command can be displayed on the main screen of
the transmitter in the telemetry window – the item Capacity of the
Central Box will now be set to zero.
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3.3.
8.8 RC-Switch
The RC Switch is a special wireless device that allows you to remotely
connect or disconnect the receiver power supply of your model.
There are currently two variants of the device: RC Switch and RC
Power Switch. The difference is noticeable in the picture below. The
simple RC Switch is suitable for applications where a Central Box,
Max Bec 2D plus, SBEC 40 or other intelligent electronic device is
being used. It offers a single output pin that might be wirelessly
driven high or low according to the situation.
When connected in place of a magnetic key, the RC Switch can turn
the electronics in the model on and off.
Variant of the RC Switch
RC Switch
Magnetic key plug
RC Power Switch
Standard receiver
Receiver battery
Central Box
Max Bec 2D
SBEC 40, etc. Battery plug
Power In
Power Out
This text describes receiver properties introduced in
DC/DS V3.0 and receivers version 3.20. Earlier versions
of the firmware might offer different properties, or the
described configuration might be entirely inaccessible.
Receiver software is updated through a PC with the aid of
the JETI USBa adapter. For more details refer to the USBa
adapter manual.
Note:
The second variant, the RC Power Switch, can fully replace a standard
physical switch. It can directly drive servos and electronics since it
includes a couple of low-resistant MOSFETS. Just plug the RC Power
Switch between the battery and the receiver, configure the switch-
related settings in your transmitter and bind it as a standard receiver.
The switch-related settings are located in Model-> Device Explorer -
> RC-Switch. First, you have to enable the switch by pushing the
rotary button on your transmitter with the first row of the transmitter
display highlighted.
Then you should bind the RC Switch:
Put the bind plug into RC Switch and then turn it on.
Push the rotary button with the "Pair RC Switch" row
highlighted on your transmitter display.
The ID of the switch is automatically saved.
The Transmitter control switch function is a source of events:
If you want to turn the model on, then flip the assigned control
switch and confirm the question that appears. If you want to turn the
model off, just flip the switch back and also confirm the question.
You can invert polarity of the switch (if high logical level doesn’t turn
the device on) and also set the audible signals that will be activated
every time the status of RC Switch is changed (turned on or off).
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3.3.
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You reach the basic menu from the main display by pressing the
„menu“ key.
1. The main menu is divided into a basic and a user section. In
the basic menu, the menu items are divided into sub-menus.
Model
Heli Tuning
(only for model helis)
Fine Tuning
Advanced Properties
Timers/sensors
Applications
System
9 Main menu
2. You enter into the user section of the main menu by pressing
the „F3(User)” button. In this section you may create a custom,
user defined menu according to your needs.
3. In the basic setup the
menu contains no items.
4. By pressing the „F5(Edit)
button you will enter into the User
Menu Setup section.
5. The numbers on the left side
of the display shows the sequence
of the menu items.
6. With the „F1“ and „F2“ buttons you may change the sequence
of the selected menu items.
7. With the „F3(Add)“ you will create a new item in the user
section of the main menu. By pressing the „3D button“ when the
menu item is selected, you will change to the selection menu of that
item.
8. With the „F4(Delete)“ button you will delete the selected
menu item.
9. With the „F5(All)“ button you will insert all of the possible sub-
menu items into the user menu.
In both sections there are functions like throttle lock and servo
monitor which are accessible by using the F1(THR)“ and
„F2(Receiver output)“ buttons.
4. 4.
1
2
34
98
7
66
5
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This function cannot in any case be used to increase
safety, eg. against the theft of the transmitter. The
transmitter is locked against configuration changes
from the moment you enter the code until the
transmitter is subsequently switched off or the code is re-
entered. As soon as the transmitter is switched off, (eg.
pushing the combination of POWER+ESC or removing
the power supply), the transmitter is automatically
unlocked.
Note:
4. 4.
9.0.1 Pa sswo rd protection again st accidenta l
configuration changes
If you lend the transmitter to another person and you want to ensure
that no changes in the model configuration that could influence the
function of the transmitter or the model can be done, you can take
advantage of the Model Lock function.
1. In the main menu, push the F4" button
to display the dialog for entering the one-
time password.
2. Here, enter the two-digit code using the
"F1" 1/2/3, "F2" 4/5/6 and "F3" 7/8/9. This
code appears on the display and will later
be used to unlock the transmitter.
Pushing F4 Clear enables you to delete
the specified number and you can start up
again.
3. Remember the code and push F5" OK.
Now confirm the safety prompt “Apply
changes?”.
From now on the transmitter will be
locked against:
- changes in configuration
- selection of the model
- creating a new model
4. Unlocking the model is possible via the
F4" button in the Main Menu. Now you
need to enter the same code as when
locking the model. Confirm with OK
button.
Now you are asked whether you want to save the changes to the
configuration of the model or not.
Pushing F1" NO button makes all the changes discarded and all the
data from the SD card will be reloaded.
- calibration of controls
- logging telemetry
- USB connection
- switching off
All the work with the SD card therefore takes place in read-only
mode.
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The „Model“ menu contains basic functions for working with your
model, like:
Select Model
New Model
Basic Properties
Functions Assignments
Servo Assignment
Servo Setup
Device Explorer
9.1 Model
9.1.1 Model Selection
The menu displays a list of your models stored in the memory with
their names, setup dates and model types. The currently selected
model is marked by a check mark. In the menu you may select a
model and manage all of your models. You can copy models, delete
models (except for the currently selected model) and change the
storage sequence of your models.
1. Model selection
In the list of models, select the required model and confirm it by
pressing the „3D button“ or „F1(Ok)“ button. You will be prompted
to confirm loading of the selected model.
The DC/DS transmitters offer a „Model checking“ function, which
compares the series number of the receiver in the model profile with
the series number of the receiver with which it is starting to
communicate. If the two series numbers do not match, the
transmitter displays a warning that a different receiver has been
detected for the model. In this situation, you the user will decide
whether to:
Confirm the change – this assigns the new receiver to the
model.
Reject the change the transmitter will not communicate with
the newly detected receiver and model will not be switched on.
Select another model from the transmitter register.
The information about receiver discrepancies will also be displayed
after the creation of a new model and binding or establishing
communication with the receiver.
Through the use of this function, if you choose, the new receiver will
be assigned to the given model for future checks.
2. Copying a model
The complete setup information of a model can be copied and used
to create a new model with the same programming. Select the
model from the model list that you want to copy and then create the
copy by pressing the „F3(Copy)“ button. You will need to edit the
name of your copied model before it can be saved. Once you edit the
4. 4.
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If you would like to make set-up changes in an existing
model, you should first make a copy of the original
setup. This will help you if you would like to return to the
original model setup.
Note:
Try to arrange your most frequently used models at
the beginning of the model list in order to avoid having
to browse the whole list when selecting a model.
Note:
name, press the „F5(Ok)“ button to continue. Your model copy will
appear at the end of your model list.
9.1.2 New Model
Selecting this menu item starts the new model creation assistant.
The assistant begins creating a new model profile as soon as you
select „New model“. However, the new model will only be created
after the confirmation in the last assistant menu, Servo
Assignment“. Until you make the final confirmation, the new model
is NOT created or stored in the memory.
The setup possibilities of the DC/DS transmitters are very extensive.
For simplicity, some of the possible adjustments are accessible only
for certain combinations of wing and tail arrangements,
aerodynamic brakes, landing gears, and number of motors or
engines.
For safety, start creating a model with the receiver in the model
switched off. Be careful when handling electric models or servo
binding, where an improper linkage connection may cause
damage when power is applied. When handling electric models
it is safer to remove the propeller or disconnect the motor during
model creation and tuning.
Note:
1. Model name
Use the „3D Control Selector“ to select the model name menu. You
4. 4.
1
2
If you would like to copy a model from one transmitter to
another you should notice that the transmitters may not
have the same software equipment, so the configuration
of activated modules may not match each other. In this
case it is necessary to check the individual functions of
the model, since an attempt to load the model file by
another transmitter may end up with an error message
(see System -> Installed Modules).
Note:
3. Deleting a Model
A model can be removed from the memory. In the model list select
the model you want to delete and press the „F5(Delete)“ button. For
safety reasons it is impossible to delete the currently selected model.
4. Choice of model sequence
The sequence of models can be changed by using the „F1()“ button
to move the selected model one position downwards or by using the
„F2()“ button to move the model one position upwards. The
transmitter allows storing of many models in the memory.
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4. 4.
will enter the model name that you want the transmitter to use when
the model is stored in the transmitter‘s memory. The maximum
available space for a model name is 12 characters, including spaces.
When you select the „Name“ item, the screen will change into the
„Edit“ menu, where you can use the „3D button“ to enter a name
for your model. Use the „F1()“ and „F2()“buttons to move the
cursor, if needed, within the name box.
Use the „F3(ABC)“ button to change between lower case letters and
capital letters.
Use the „F4()“ button to delete the character at the current cursor
position.
When you finished editing your model’s name, use the „F5(OK)“
button to confirm the name and return to the „New model“ menu.
The model name can be changed even after the model is stored by
going to: „Main menu->Model->Basic configuration“ and
selecting the model name.
2. Model type
The model type selection makes the setup of your model more
efficient by populating the menus with many of the popular options
for each type of model. The possible choices are: Aero, Heli and
General. Once your model is stored it is not possible to change that
model’s type.
Once your model’s name is entered and the type is selected, press
the „F5(Next)“ button to go to the next menu assistant step: „Basic
Properties“. The software will only allow this step if both the model
name and type have been set up.
In this menu you will setup the wing configuration, tail type,
number of motor/engines, number of spoilers, and number of
landing gear servos. Your model’s flight control functions are
generated according to your configuration choices in this menu and
the necessary fixed mixers become accessible.
9.1.3 Basic configuration - AIRPLANE
Type
Description
0FLAP.|1AIL
Only one aileron servo
0FLAP.|2AIL
Two aileron servos
1FLAP.|2AIL
One flap servo, two aileron servos
2FLAP.|2AIL
Two flap servos, two aileron servos
2FLAP.|4AIL
Two flap servos, four aileron servos
4FLAP.|2AIL
Four flap servos, two aileron servos
4FLAP.|4AIL
Four flap servos, four aileron servos
1. Wing Type
The following wing type options are available:
1
2
3
4
5
6
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Type
Description
Standard 1H1V
Standard tail assembly with one horizontal control
(elevator) and one vertical control (rudder)
V-tail 2H
Traditional V-tail
Note: The V-Tail Mix is automatically enabled.
Ailevator 2H1V
Tail assembly with two elevator servos and one rudder
servo
Note: The Ailevator Mix is automatically enabled.
Standard 2H2V
Tail assembly with two elevator servos and two rudder
servos
None –
Elevon/Delta
The model is controlled by the combined control of the
wing surfaces
Note: The Delta/Elevon Mix is automatically enabled.
None
Model without a tail assembly
2. Tail Assembly
The following tail option are available:
3. Number of Engines/Motors in the model
You can select the number of engines/motors in the model. You can
select up to 4 engines/motors. You can then assign the control of
each throttle to a different receiver channel if needed.
4. Number of Spoiler Servos in the model
You can select up to 2 spoilers servos. You can then assign the control
of each spoiler to a different receiver channel if needed.
5. Number of Landing Gear Servos in the model
You can select up to 4 landing gear servos. You can then assign the
control of each landing gear servo to a different receiver channel if
needed.
4. 4.
9.1.4 Basic Configuration - HELICOPTER
6. Use gyro (1 - 3)
It is possible to create up to three independent functions for
controlling gyro gain. The detailed configuration of individual gyro
gains is then available in Fine Tuning -> Gyro Setting.
Press the „F5(Next)“ button proceed to the next step of the menu
assistant: „Functions Assignment“.
If you activate the additional function of the gyro in the
active model, after leaving the Basic Properties menu it
is necessary to carry out the control assignment
(Functions Assignment) and then select the appropriate
output channel (Servo Assignment).
Note:
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4. 4.
Swash Plate Type
Enter the type of swash plate your helicopter is using. Refer to your
helicopter’s manual if necessary.
„3 servos (default 120°)“ the swash plate controls the
elevator, aileron and collective pitch functions by coordinating three
servos. In the swash plate configuration, the servo control points can
be shifted closer to or farther away from each other around the main
shaft axis using a parameter "Lever length". In case your heli requires
a swash plate configuration of 3 servos (140°) or 3 servos (90°) you
can use the parameter angle with increments.
Within this menu you can also change the effective swash plate
servo „lever lengths“ to compensate for any nonlinear servo arm
travel.
· „ 4 servos (90°) - the swash plate controls the elevator, roll
and collective pitch functions by coodinating four servos in 90°
orientation. You can make the same changes to this type as with the
swash plate described above.
„Mechanical“ - this swash plate type uses a single servo for
each flight function. This is the swash plate type to select if you are
using a flybarless controller.
Reverse swash plate orientation by 180°
The „Front servo position“ item is accessible only for the swash
plate type „3 servos (default 120°)“. If your helicopter requires, it is
possible with a single button to turn the swash plate configuration in
the setup by 180°.
Swash plate angle
The „Angle“ item is only accessible in the „3 servos (default 120°)“
swash plate type. The angle formed by swash plate points 1 - 2 and 1
3 can be configured by the user in increments. This allows you to
fine tune your swash plate configuration as needed.
Rotation
The „Rotation“ Item is only accessible in the „3 servos (default
120°)“ and „4 servos (default 90°)“ swash plate types. This item
allows you to rotate the entire swash plate by a defined angle. This
allows you to add fine tune your swash plate as required by some
scale models.
Servo arm lengths (servo 1 4)
This item allows you move your swash plate control points either
closer to or farther away from the axis of rotation. This allows you to
compensate for any nonlinear servo movements.
Governor
In some helicopter setups a governor function is used for motor
control this allows the motor to run at a constant speed
independently from any collective pitch. If your model helicopter
setup includes a governor which can be controlled through the
receiver then switch on this function. Once you enable this function,
the governor configuration becomes accessible in the Fine Tuning
-> Governor Setting menu.
Use gyro (2 - 3)
It is possible to create up to three independent functions for
controlling gyro gain. By default, gyro No. 1 is always active. The
others are activated in the Model -> Basic Properties menu
together with the Governor function.
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4. 4.
9.1.5 Swash mix
Here is where you set up the swashplate CCPM (=Cyclic/collective
pitch mixing) throws for Aileron, Elevator and Pitch. You can fine
tune each of these functions by changing their percentages. If
needed, you can reverse the throws by setting a negative
percentage.
If you activate the additional function of the gyro in the
active model, after leaving the Basic Properties menu it
is necessary to carry out the control assignment
(Functions Assignment) and then select the appropriate
output channel (Servo Assignment). Setting the gyro
gain itself is carried out in the Fine Tuning-> Gyro
Setting menu.
Note:
Swash Ring
It is possible to activate the function of the cyclic limitation for a
helicopter rotor head. Activating this function causes the restriction
of servo travel in the combined full deflection of the roll and pitch
controls so that the total size of the deflection is always within the
inner area of the displayed circle. Outside the circle there is a kind of a
dead zone of the flight controls.
Editing an item "Value" affects the diameter of the displayed circle,
ie. size of the maximum allowed deflection. The setting is global for
the whole model.
1. Number of Motors in the Model
This is where you select the number of motors in your model. It is
possible to select 0-4 motors. The number of transmitter control
outputs used to control the motors are automatically increased or
decreased according to number of motors that you select.
2. Motor Type
Do the motors in your model only turn in one direction or are they
able to rotate in both directions?
9.1.6 Basic Configuration-GENERAL
1
2
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9.1.7 Assignment of functions
Based on your selected configuration a list of all flight functions will
be created with basic transmitter channel assignments.
The menu allows you to rename flight functions, assign a flight
function to any arbitratry transmitter stick, switch, knob or slider and
also allows you to set up additional flight function trims.
You can allow the software to automatically assign your flight
functions by pressing the „F2(Auto)“ button and then press the
„F5(Yes)“ button.
1. Flight function Renaming
By editing each „Function“ item you can rename a flight function
from its original name to any name that you choose.
2. Assignment of a Control Element to a Flight Function
By editing each „Control“ item you can assign any arbitrary stick,
switch, knob or slider to a given flight function. The proportional
channels 1 8 are marked P1–P8. The markings Sa-Sj designate
switches with the same designation as on the transmitter front
panel.
4. 4.
1
2
4
3
5 6
When you select one of these items, you will enter the menu: „Select
control input“, see chapter 9.7. The assignments can easily be
verified by the graphic found beside the control element description
in the „Control section, which shows the actual setup of the
assigned control element.
3. Choice of an Additional Trim
The transmitter allows you to also create a trim function for any
arbitrary flight function. By editing one of the Trim“ items you can
assign an arbitrary control element (stick, switch, knob or slider) to
control the trim of the selected flight function. When you select one
of these items, you will enter the menu: „Select control input“, see
chapter 9.7. The assignments can easily be verified by the graphic
found beside the control element description in the Trim section,
which shows the actual setup of the assigned control element.
The trim functions for the gimbal sticks P1-P4 are automatically
assigned to the quad push-buttons located below the gimbals.
It is not necessary to assign them manually.
4. Range of Additional Trim
If you set up a trim function, you can use the Trim-Max“ to set the
maximum trim influence on the given flight function. The default
value is 50%. If you set the value to 0%, the trim control element will
not have any effect on the flight function at all. If you set a value of
100%, the trim control element will control the flight function to its
full travel.
5. Adding a Function
With the „F3(New)“ button you can create (add) your own flight
function.
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4. 4.
Make sure that you have assigned all of your flight functions to the
correct transmitter control elements (stick, switch, knob or slider)
and make sure that the trims are assigned and functioning as you
wish. By pressing the „F5(Next)“ button you will enter the next
assistant step, the „Servo assignment menu.
The initial assignment is carried out in accordance with your
selected transmitter mode. If the initial assignment is incorrect,
check the transmitter mode setup in the „Main menu->System-
>Configuration- >MODE 1-4 menu.
Note:
9.1. 8 Servo Assignment
This menu shows the assignment of transmitter output functions to
the receiver channels. This assignment can be changed as you wish.
The order number at the beginning of the column shows the
channel number and the assigned transmitter output function is
next to it. In this menu you can rearrange your output functions as
needed, i. e. any transmitter function can be assigned to any of the
receiver channels. The only restriction is the number of channels
which the transmitter can control (16 channels). The transmitter can
automatically set up your servo configuration based on your
previous model setup. If you want the transmitter to automatically
assign the servos in the same order as the last model that you set up,
press the „F3(Auto)“ button and then press the „F5(Yes)“ button.
1
a)
6. Deleting a Function
With the „F4(Delete)“ button you may delete the selected flight
function.
1. Assignment of Transmitter Output Functions to Receiver
Channels
Select the required receiver channel and press the „3D button“.
Now you can choose which function you want assigned to the
selected receiver channel.
With the „F5(Next)“ button you will enter the next step of the
assistant which creates and stores the model into transmitter
memory.
a) The assistant asks you to confirm the creation of the model by
displaying the questionCreate and select a model?“. If you answer
by pressing the „F1(No)“ button, the model will not be saved and
you will return to the assistant to continue with further
configuration of your model.
If you press the „F5(Yes)“ button, the model will be stored in the
memory and at the same time will be activated. After that, you are
automatically taken to the „Servo Setup“ menu. Your stored model
can, of course, at any time be configured by selecting the „Main
menu->Model“> „Servo Setup“ menu.
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4. 4.
Once your model is created and activated, you should
bind your receiver with the transmitter and then
proceed with „Servo Setup“.
Advice:
9.1.9 Servo Setup
This menu is for the additional tuning of output functions of the
transmitter->receiver channels->servos. The assignment of a
transmitter output function to a receiver channel is shown in the
upper part of the menu (first item below the menu description).
1. Display of a Receiver Channel Throw
In the upper part of the menu the actual throw of the selected
channel is displayed using a live graphic. If you make a change to
your setup in this menu, you will immediately see how the output
will be influenced by the change.
2. Selection of Receiver Channel
In the first position F1 in the lower bar you see the actual selected
channel. With the F2() or F3()buttons or by editing the item „Servo
#“ you will select the receiver channel which you intend to
configure.
3. Center (Subtrim)
With this item you can adjust the servo neutral position of the
selected receiver channel.
When building a model try to mechanically adjust the
neutral positions as perfectly as possible. If you are
going to use a high „Center (Subtrim)“ value in order to
set up a servo neutral, the resulting servo throw will be
restricted.
Advice:
4. Max Positive/Max Negative Throw
This item sets the useable end points of the transmitter output
function, i.e. how far the transmitter control element can move each
surface. This functon is used to set your maximum control throws for
flight and to limit any potential binding of a linkage or surface. This
limit can be exceeded by the use of mixes or combined functions.
The size of the maximum throw can influence trim
settings, dual rate throws and other proportional
setups.
Note:
5. Max Positive/Max Negative Limit
These restrict the absolute throw of the receiver channel output.
This limit can never be exceeded by any combination of functions or
mixes.
You can adjust the throw limit to prevent a surface or
linkage from hitting a mechanical stop or to prevent the
servo from over-driving its mechanical throw range.
This allows you to prevent mechanical servo damage.
Advice:
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4. 4.
This function is great for timing retract gear servos.
Advice:
6. Servo Reversing
Use this item to reverse the direction of a servo’s travel.
7. Delay of positive/negative
This item allows you to delay the servo channel‘s travel time
between both end points. This can be defined for the positive and for
the negative value (each travel direction). For instance, the opening
of a landing gear can be slower than when it retracts.
9.1.10 Servo balancer (*depends on equipment)
The function of the servo balancer is designed for large models that
have control surfaces driven by mechanically linked servos. Since
each servo can be preset from the factory in a different way and
mounting servos into the model is not always accurate, it is now
possible to set servo travel algorithmically to ensure minimum
mechanical stress during the movement of the controls.
Thus it is possible to assign a separate curve to each output channel,
which is applied as the last operation before sending the deflections
to the model. Because it is applied last, the curve is ultimately
applied to trims, mixes, dual rates, etc., so that servos of the same
control surface always move together equally. The Servo balancer
can alter the curve of the servo by a maximum of ±10% with a
resolution of 0.1%.
1. After you highlight the graph of the servo balancer, push the 3D
button. This enables editing of the servo curve. Now, always one
control point is highlighted according to current servo deflection. If
the current servo position is -30%, the nearest highlighted control
2. After pushing the F1 button
when the servo balancer is
highlighted, the speed dial is
displayed. Here is where you can
select one telemetry parameter,
which will appear at location of the
digital clock on the top bar of the
screen. This way you can select eg.
displaying the instant current draw
from the batteries, which is very
helpful when balancing different
servo travels.
point is located in -25%. It is then possible to move the point
upwards or downwards by turning the 3D button to the right, or
respectively to the left. In "Auto" mode (the F2 button is
highlighted) simultaneous shifting of neighboring control points
occurs, so that the resulting curve is precisely smoothed. Then you
can select another control point by moving the servo control and
alter this point until the mutual mechanical stress of servos during
the movement is minimal.
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4. 4.
Setting the display of the
telemetry data on the top
menu bar of the screen is saved
a s a par t of th e m o d e l
c o n f i g u ra ti o n a n d i t i s
displayed again when the
transmitter is switched on.
Alternatively, it is possible to
adjust the displayed data in the
Timer s/Sensor s -> Main
Screen menu. It is possible to
select any simple numerical
value, except GPS coordinates.
Note: If you use several mechanically
linked servos to control a single
wing surface in the model as
shown in this example, we
recommend setting all the
ser vos belo nging to this
surface into one output group
(Group A-C). In the picture this
is done via the Device Explorer
application. In this way the
servos will receive control
pulses at the same time and
their movement will thus be
synchronous.
Advice:
3. The F2 Auto button enables switching between automatic and
manual selection of control points in the servo balancer edit mode.
When selecting control points manually, push the 3D button to
move to the next point; pushing the ESC button activates the
previous check point. When editing in the manual mode, you move
(as opposed to the automatic mode) only one control point, the
others remain unchanged.
If the F3 Clear” button is pushed for a short time, it quickly clears a
control point (which must be highlighted). If the F3 Clear” button is
pushed and held for longer time, the whole curve is cleared to a
default state.
To optimize the servo travels via servo balancer, we
recommend that you use an ampermeter (or eg. the
current measurement from the MUI sensor displayed in
the telemetry window) and always try to make sure that
the current running through servos as low as possible.
Advice:
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9.2. Fine Tuning
9.2.1 Flight Modes (*depends on equipment)
The purpose of programming Flight Modes is to provide the ability
to activate a group of settings that will optimize your flight control of
your model. Flight Modes can just as easily represent settings for
Take Off, Soaring, Landing and much more. They can be used in any
particular situation where different settings of basic flight
parameters is desirable. The DC/DS gives you the advantage of a
wide variety of programing options.
Flight Mode Configuration
Some of the configuration settings come in two options. G-
global (globe symbol) and S-Separate. Switching from G to S, system
let you set up each flight mode individually.
4. 4.
When you switch from Global to Separate settings, all
values will be copied directly to existing flight modes.
Warning:
- Extended program functions for fine tuning your models
Flight Modes
Digital Trims
Flight Mode Trims
Dual Rate/Expo
Function Curves
Aileron Differential (This menu is only accessible in the wing configuration
0FLAP2AIL and higher)
Free Mixers
V-Tail (This menu is only accessible in the V-tail“ tail configuration.)
Butterfly (This menu is only accessible in wing configuration 2FLAP2AIL and
higher)
Ailevator (This menu is only accessible in the „Ailevator“ tail configuration)
Delta/Elevon (This menu is only accessible in wing configuration „None-
Elevon/Delta“)
Gyro/Governor
(*depends on equipment) Throttle Limiter(Helicopters only)
Snap Roll
9.2 Fine Tuning Up to 10 different flight modes (depends on activated transmitter
equipment) are available for every single model. Each one of these
flight modes can be named differently for instant recognition. Only
one of the flight modes can be active at any given time. With a little
practice you will discover that creating your flight modes in logical
order can prevent confusion in a critical situation. Flight mode
control can be assigned to any of the switches, sticks, or knobs of the
transmitter.
If the flight mode configuration is set to S, each flight mode’s
values can be set independently from the other flight modes. When
you switch to different flight modes, the pre-set position of an
output (a control surface, for example) can be changed to optimize
the control system of your model.
Also, if the flight mode configuration is set to S, different
variables for each function can be assigned to each flight mode. The
assigned control switch can control multiple values within each
flight mode.
After creating a flight mode, this will become system wide
settings for all future models.
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Adding Flight Modes1.
Pressing the “F3 (Add)” button creates a new flight mode. Simply
highlight existing mode and press “F3 (New)” button. A copy
confirmation menu appears on the screen, use the function keys to
continue.
Press the “F5 (Yes)” button to create copy of the existing flight
mode.
Press the“F3 (No)” button to create a new flight mode.
Press the“F1 (Esc)” button to be taken to main flight mode menu
screen.
Naming Flight Modes 2.
We recommend naming flight modes according to their function, for
example: Take Off, Soaring, Autorotation….
Flight mode names/labels can be easily edited at any time.
3. Flight Mode Delays
The time delay function can help smooth the transition from one
flight control state to another. Sudden changes in the positions of
your control surfaces can negatively affect performance or even
create a critical situation. The Time delay can help you avoid this
situation.
4. 4.
1
2
3
If no flight mode is required, do not change the pre-set
configuration.
Advice:
If the desired result is not already tested or fully known
(maiden flight), always make sure that you have set
enough time delay for all of the changes to be
implemented and that you have plenty of time to
respond properly.
Advice:
Throttle hold is not affected by the time delay. This
function will always be performed instantly.
Warning:
4. Flight Mode Activation
A flight mode can be activated by any control device
(Switch/Knob/Stick). When you select a switch and by editing its
desired assignment you can activate and pick the position at which
this Switch/Knob/Stick or Logical Switch will turn flight mode ON or
OFF (see chapter 9.7). You can use the visual indicator in the switch
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Flight Mode Activation Priorities5.
If you have created multiple flight modes that can match a given
flight condition but that vary in their specific details (Landing in
strong or light wind). You can create the order in which those modes
can be turned on. The Numeric order will determine your priorities.
A lower number equals a higher mode priority. The initial flight
mode has always the lowest priority.
6. Flight Mode Default and Reset
Any of the created flight modes can be pre-set as a future default.
Simply highlight your choice and press the “F4 (Opt.)” button to see
confirmation menu. Pick the, “Set as a Default Flight Modeoption
and the flight mode is now set as your new default.
7. Deleting a Flight Mode
To delete a flight mode:
Highlight the desired flight mode and press the “F4 (Opt.)” a)
button to see the options menu.
Scroll and select the “Delete flight mode” option and press the b)
“F5 (OK)” button to make the final confirmation.
The initial flight mode is set as a default and can not be deleted.
4. 4.
column to help you determinate the ON or OFF switch position for
each flight mode.
Check Mark ON Position
X Mark OFF Position
When the flight mode is activated, the flight mode name can be seen
at the top of the desktop screen.
5
4
Name of the
current flight mode.
6
7
8
8. Flight Mode Reset
All of the flight modes can be reset to basic settings at the same time.
Simply highlight any flight mode and press the “F4 (Opt.)” button
then use the “Reset all flight modes” option to reset all flight modes
to their basic settings. All previous changes will be deleted and the
flight modes will be reset to the G (Global) setting.
9
9. Announcement of the current flight mode
It is possible to assign a WAV file to each flight mode, which is played
at the moment when the selected mode is activated.
After you make a configuration change or perform a
reset, always check all flight modes.
Advice:
This is useful when you are setting up a new model from a copied
model and you want different flight modes.
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9.2.2 Digital trim
Fully programmable digital trims are located right under the
transmitter gimbals as a set of four directional buttons. All
adjustments and step changes are made in the “Digital Trim” menu.
You can assign different trim ranges and trim steps to every trim
control function.
The trim dialogue has been divided into two You screens, a) and b).
can switch between each of them by using the "F1 Left" and "F2
Right" buttons. The “F3 (Trim)” button switches your desktop
display to the main trim screen where you can instantly observe
your setup changes.
As you can see from the screen , you can assign any function that a)
will be influenced by that particular trim. It is also possible to
deactivate the trim so that it doesn’t influence any function (simply
unselect the assigned function). This is mostly important for pilots of
various multicopters or helicopters equipped with advanced
stabilization electronics.
Special trim functions
Digital trims can be used independently as controls for any function.
It is possible to assign the special functions "Trim.Ctrl" or
"Trim.RstOn" (Trim Automatic reset) to any digital trim.
- Trim.Ctrl (Trim control) enables using a specific trim
independently from model functions. The transmitter remembers
4. 4.
10. Flight mode announcement after flipping a switch
It is possible to assign an arbitrary switch to the flight mode voice
announcement. After switching on, the actual flight mode will be
announced (the selected WAV file will be played back).
the trim value after shutdown. After pressing the trim button no
superior functions are trimmed, only internal state of trim is
incremented.
- Trim.RstOn (trim control with automatic reset) enables using
the specific trim independently from model functions. The
transmitter does not remember the value of trim after shutdown.
After loading the model, the trim value is always 0%. In combination
with the logical switches this option is suitable for a sequential
switching between flight modes or playing sound sequences.
The operational modes of the trims have also been extended (see
picture ). There are currently these options:c)
Global the specified trim will have equal settings for all flight
modes.
Separate every flight mode has its own independent
configuration of the trim.
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For the maiden flight we recommend using larger trim
steps. After familiarizing yourself with your model’s
behavior you can switch to smaller steps for finer
trimming.
Advice:
a) b)
1 2 3 4 5
If you change a flight mode from Global to either of the
Flight-Mode groups the trim mode for the rest of the
flight modes (except for the one you are currently
editing) will change to Separate.
Note:
Flight-Mode Group (A/B) if you are using several flight modes and
you want to share trim settings among a few of them just
set one of the groups FA or FB for the particular trim. Each
group has its own settings which are then shared. Note: If
you change from Global to any Flight-Mode Group, the trim
mode in other flight modes than the current one will
become Separate.
The rest of the parameters are described below:
1. Value shows the actual trim rate.
2. Stored shows the stored value of trim memory function.
3. Mode here you can specify a basic behavior of the trim:
Centered modeby default, the trim affects only the servo
center, the endpoints remain untouched.
Linear shifts the whole servo travel, including endpoints.
Thro-Low affects the servo low endpoint and the entire
curve, except for the high endpoint.
Thr-L50%affects the servo low endpoint and curve below
.50%. This does not affect the curve above 50%
Thro-High affects the servo high endpoint and the entire
curve, except for the low endpoint.
4. Step – indicates, how much the value of trim changes each time
the trim button is pressed.
5. Rate (+,-) determines maximum limits used for the trim.
In the picture below you can see how various trim modes influence
the servo output (trimmed to ca 50% of range). However, you
cannot use any trim mode at any time:
V-Tail configuration - You can specify the trim mode only for the
elevator function, not for rudder since these functions are linked
together.
Delta/Elevon configuration - You can specify the mode only for
ailerons, not for elevator.
Helicopter using CCPM mix - You can specify the mode only for
pitch function, not for elevator nor roll function.
If you use two or more trims to adjust a single function, the resulting
trim rate equals to a sum of all rates that are participating on this
function. However, the transmitter uses always only a mode defined
for the first trim.
4. 4.
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Press the "F4 button" to display additional trim options. See picture
d). You can store the currently highlighted trim (for example Ailerons
in the picture) to trim memory, or you can apply the trim memory
function to all trims.
How it works: The actual rate of the highlighted trim (or all trims,
respectively) is copied into a special register. (See the last colum of
picture ). Once the rate is stored, the trim rate column value will be a)
cleared. This applies always to all flight modes. The trim memory
function is beneficial if you want your trims zeroed although some
offsets have been set. When processing, the transmitter sums the
actual trim rate and its stored value.
c) d)
In the picture there are two more options available: Clear highlighted trim and Clear all d),
trims. After confirmation, this option clears the actual trim value (or all trim values,
respectively) and similarly zeroes the previously stored values (trim memory). This always
applies to all flight modes.
4. 4.
High Endpoint
Low Endpoint
Center
Centered mode Linear mode Throttle Low Throttle Lower 50% Throttle High
Center Center Center Center
The Autotrim feature, when active, always influences the
model functions currently assigned to the particular trim
buttons (except for throttle function which is never affected by
this feature). The Autotrim function does not take effect on the
auxiliary incremental trims. Please be very careful if you
assign trim buttons to any function that is not controlled by a
spring centered stick. It is advised to disable the Autotrim
completely in such a case.
Warning:
9.2.3 Flight Mode Trims
This menu allows you to set the function output position (if needed)
for each flight mode individually. For example: if your elevator
needs to be raised in one of your flight modes but not the others.
Each function output can be set either globally or separately.
1. Servo Position
A transmitter output channel can be assigned to more than one
receiver output channel if needed. Adjusting the values in the
individual columns marked “S1-S4” will change the position of the
servo (surface) for each output function. The servo position is
displayed as a percentage of the total servo travel.
Pressing the “F3 (Clr)” button resets the highlighted lines travel
values to 0%.
Pressing the “F1 (Sym.)” turns ON/OFF the lock which allows each
output to be adjusted either together (symmetrically), or
independantly.
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2. Trim Travel Global or Separate Setting
The servo trim position for each function output can be set either
collectively for all flight modes by selecting the “G-(globe symbol)”
or individually for each separate flight mode by selecting “S-
Separate”.
9.2.4 Dual Rate/Exponential
This menu allows you to set up dual or triple rates for any of your
created output functions. Any of the channels can be set with
dual/triple rates and custom exponential settings. Exponential
settings can significantly increase your control precision by making
your stick movements (around center point) yield less control
movement. At the same time, the end points of the control surface
throw can be set to its extremes.
4. 4.
Channel namea)
Dual/Triple rate travel settingb)
Exponential settingc)
Global or separate flight mode settingd)
By highlighting one of the channels and either pressing the “F4
(Edit)” button or by pressing the “3D Control” button you will
access the individual control‘s settings page.
Channel name and global/separate settinga)
Current switch positionb)
c
d
a
b
a
f
b
c
d
e
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4. 4.
Percentage of travelc)
Exponential rate settingd)
Assignable switch optione)
Graphic interfacef)
1. Expo Global or Separate Setting
Expo configuration for all channels can be set collectively for all
flight modes by selecting the “G-Global (globe)” symbol or you can
allow individual expo settings in each separate flight mode by
sellecting the “S-Separate” symbol.
2. Expo/Dual Rates Switch Assignment
By selecting “Switch Option” you will access the“Select Input (e)
Control” screen where you can select the control element that you
wish to control the dual rate and/or expo for the selected function.
For simple dual rates, a 2-position switch is sufficient. For more
complex triple-rates, any 3-position switch or one of the fully
proportional channels can be selected. Then your selected switch is
assigned. While the “Select Input Control” screen is still visible you
can change the switch travel by using “F2 (Prop.)” button to select
the proportional setting. The correct function can be verified in the
“Dual Rate Edit” screen by activating the switch and observing the
position number change to “Position 1-2” for a two position switch
or, if 3-position switch is used, to “Position 1-2-3”. For a 3-position
switch you will also need to use the F1 (Centr)“ button before all
three positions are correctly displayed.
Expo/Dual Rates Travel Setting 3.
Every switch position can define a different function and (b)
exponential value. Any change made to the settings can be directly
observed on graphic interface .(f)
Dual/Triple rate setting is defined by percentage of the travel . A (c)
higher number increases travel, a lower number decreases travel.
Expo rate is defined by percentage of the function curve Zero (d).
rate represents linear function. As expo rate increases linear travel
changes to exponential “curve” travel.
Exponential and Dual rate settings combined with flight modes
create virtually unlimited customizability.
For smooth, precise flight we highly recommend setting
up exponential and dual rates.
Advice:
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4. 4.
9.2.5 Programmable Function Curves
(* depending on equipment)
Function curves define the relationship between the actual position
of your stick/switch/knob and the position of the servo. This screen
displays the menu of all assigned functions , graphic interfaces (a)
(b) (c), and programmable time delays . All adjustments can be
visually inspected right away in the servo monitor page by pressing
the “F2 (Servo)” button.
a) Function name.
Graphic interfaces.b)
Time delay.c)
Global or Separate setting.d)
e) Flight Mode Delay Enable
c
a
b
e
Flight Mode Delay Enable
In the menu Fine Tuning->Function Curves, it is possible to
activate/deactivate a delay for a specific function while switching
between flight modes. Specifically, in the picture, it is the 5th column
(FM. Delay) that allows this. The activation of a delay also might be
flight-mode specific (i.e.: in the first flight mode the delay is
1. Programming Function Curves
The Function Curves programming screen can be accessed by
highlighting “Curve” window and pressing “3D Control” button or
directly accessed by simply pressing “F4” button. Either way, you will
be taken to the highlighted functions curve option screen.
activated and in the second mode it is disabled). There are some
specific conditions where setting this option for one function has an
effect in another function.
If V-Tail is selected, the option influences both rudder and
elevator.
If Delta wing is selected, the option influences both elevator
and aileron.
If electronic heli swash mix is selected, the option influences all
functions of the swash plate (roll, pitch, and elevator).
b
a
a) Function curve type.
b) Graphic interface.
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4. 4.
The function curve can be selected from the existing list or from
custom, previously modified options.
Available Options:
Standard
Linear values, set In/Out point
Constant
Constant value, set point
3-Point, x>0,
x<0, |x|
3-Point curve, set value for 3 points
5-Point
5-Point curve, set value for 5 points
7-Point
7-Point curve, set value for 7 points
9-Point
9-Point curve, set value for 9 points
+Pos, - neg,
+-Symmetrical
4-Point end to end curve, set value for 4 points
2. Function Curve Setting
You can select the function curve which best fits your application.
You can choose one of the pre-programmed 3-9 point ones or select
any of custom symmetrical curves.
You can edit a function curve from inside the graphic interface by
moving the displayed control points.
All of the points can be moved in both horizontal and vertical
directions. Using the “3D Control” or the “F3” and “F4” buttons you
can move the curve points in a vertical direction and in a horizontal
direction by using the “F1” and “F2” buttons.
By pressing the “3D Control” button you can switch between the
individual curve points. Pressing the “Esc function will return you to
the previous control point. On the left side of the graphic interface
you will see the percentage representation of your selected control
point’s position. “In” and Out” percentage numbers represent
actual input and output position of a given control point.
3. Function Curve Delay
The time delay function can help smooth the transition from one
state to another. The function of the “Delay” is to slow down the
movement of a control surface in relationship to the position of the
stick. Example: a negative number “-” slows movement of the
rudder from moving right to left, a positive “+” number slows rudder
movement from left to right.
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4. 4.
4. Global or Separate Function Curve Setting
The function curve configuration for all channels can be set
collectively for all flight modes by selecting the G-Global (globe)”
symbol or you can set individual function curve settings in each
separate flight mode by sellecting the “S-Separate symbol.
9.2.6 Aileron Differential
The aileron differential function reduces the downward travel of the
aileron(s) to help eleminate any adverse yaw tendencies in rolling
maneuvers. Semi-Symmetrical airfoils with an aileron in the down
position induce higher drag than when the aileron is in the up
position. Therefore, the aileron travel up and down has to be set
differently. The number of aileron servos displayed depends upon
the selected wing type of your airplane; the maximum number is
four “S1-S4”.
1. Aileron Differential Global or Separate Setting
The aileron differential for all channels can be set collectively for all
flight modes by selecting the “G-Global (globe)” symbol or you can
allow individual aileron differential settings in each separate flight
mode by sellecting the “S-Separate symbol.
2. Aileron Differential Setting
All of the ailerons can have different travel ranges. The different
adjustments are displayed in columns marked „S1-S4”. The number
of servos in use is equal to the number of displayed setup columns.
The travel range for each servo can be set. Scroll and highlight either
the “Upor “Downmenu line with “3D Control” button. Press the
„3D Control“ button to access and edit the settings for each servo. If
the servos need to be adjusted independantly, use the “F1 (Sym.)”
button to unlock the servo travel for adjusting the individual values
in the selected menu line.
3. Tuning of Aileron Differential
You can now assign a proportional control and the adjustment rate.
When moving the control, the differential rates are updated
accordingly: up-rate is increased and the down-rate is decreased
depending on the adjustment rate and position of the control. In the
picture the real differential rates are enclosed in parenthesis.
The F(3) Apply button clears the adjustment rate and stores the
real differential values into the editable fields so that the control no
longer has any influence.
9.2.7 Ailevator Function
The ailevator function uses two servos for the elevator channel. Both
sides can be programmed to be controlled independently. With
ailevator function both servos can be mixed together with ailerons
and work in sync for better roll control. The Ailevator mix has to be
activated by choosing the Ailevator2H1V” tail setting. Unless you
have previously chosen a different percentage for one of the tail
mixes, the initial settings for Ailevator” function are 100% of the
elevator travel and 0% of the aileron travel.
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4. 4.
1. Ailevator Global or Separate Setting
The Ailevator configuration for both channels can be set collectively
for all flight modes by selecting the “G (globe)” symbol or you can
set individual Ailevator settings in each separate flight mode by
sellecting the “S-Separate” symbol.
2. Ailevator Setting
Ailevator configuration has four different adjustable parameters.
The lines marked “Elevator” and Aileron” contain two columns
“S1” and “S2” which represent the elevator and aileron surface
throws as a percentage. Scroll and highlight the lines marked as
“Elevator” or Aileron” with the “3D Control” button and press the
“3D Control” button to access the individual setting of each servo. If
the servos need to be adjusted independantly, use the “F1 (Sym.)”
button to unlock the servo travel for adjusting the individual values
in the selected menu line.
9.2.8 V-Tail Mix
If your model is equipped with a V-Tail, The two basic tail functions
(rudder and elevator) are mixed to control the tail of the airplane.
The V-Tail mix has to be activated by choosing the V-Tail 2H” tail
setting. Unless you have previously chosen a different percentage
for one of the tail mixes, the initial settings for “V-Tail” function are
50% of the rudder and elevator travels.
1. V-Tail Global or Separate Setting
The V-Tail configuration for both channels can be set collectively for all
flight modes by selecting the “G (globe)” symbol or you can set
individual V-Tail settings in each separate flight mode by sellecting the
“S-Separate” symbol.
2. V-Tail Setting
The V-Tail configuration has four different adjustable parameters. The
lines marked “Elevator” and “Rudder” contain two columns “S1” and
“S2” which represent the elevator and aileron surface throws as a
percentage. Scroll and highlight the lines marked as “Elevator” or
“Rudder” with the “3D Control” button and press the “3D Control”
button to access the individual setting of each servo. If the servos need
to be adjusted independently, use the “F1 (Sym.)” button to unlock the
servo travel for adjusting the individual values in the selected menu line.
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4. 4.
1. Delta/Elevon Global or Separate Setting
The Delta/Elevon configuration for both channels can be set
collectively for all flight modes by selecting the “G (globe)” symbol
or you can set individual Delta/Elevon settings in each separate
flight mode by sellecting the “S-Separate” symbol.
2. Delta/Elevon Setting
Delta/Elevon configuration has four different adjustable
parameters. The lines marked “Elevator” and Aileron” contain two
columns “S1” and “S2” which represent the elevator and aileron
surface throws as a percentage. Scroll and highlight the lines
marked as “Elevator” or Aileron” with the “3D Control” button and
press the “3D Control” button to access the individual setting of
9.2.9 Delta/Elevon Mix
The Delta/Elevon Mix uses two servos for the control of both the
elevator and aileron functions. This mix is most commonly used for
Delta type aircraft. The elevon mix has to be activated by choosing
the “None Elevon/Delta” tail setting. Unless you have previously
chosen a different percentage for one of the tail mixes, the default
settings for the “Delta/Elevon” function are 50% of the aileron and
elevator travels.
9.2.10 Butterfly Mix (Crow Mix)
The basic configuration of the butterfly mix (also known as crow) is
created by using ailerons, flaps, and elevator flying surfaces. The
Butterfly/Crow mix is helpful for maintaining speed during fast
descends and creating controlled drag for spot landings.
1. Butterfly/Crow Activation
The Butterfly mix can be activated by any control element
(Switch/Knob/Stick). By selecting the switch and by editing the
desired assignment you can activate and select the position at which
this Switch/Knob/Stick or Logical Switch will turn the Butterfly mix
ON or OFF. This menu line includes a visual graphic to show the ON
or OFF position of your selected switch.
2. Butterfly/Crow Delay
The time delay function can help smooth the transition from one
state to another. Function of the “Delay” is to slow down the
each servo. If the servos need to be adjusted independantly, use the
“F1 (Sym.)” button to unlock the servo travel for adjusting the
individual values in the selected menu line.
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movement of the control surfaces during the change. Increasing the
number on the positive side “+” slows the deployment while
increasing the number on the negative side “-” slows return of the
surfaces to their original positions.
3. Butterfly/Crow Global or Separate Setting
The Butterfly/Crow mix configuration settings can be set collectively
for all flight modes by selecting the “G-(globe)” symbol or you can
allow individual aileron differential settings in each separate flight
mode by sellecting the “S-Separatesymbol.
4. Butterfly/Offset
Due to the request of many sailplane pilots this function was
updated. Now expanded to four screens, there are several added
options in this menu.
4. 4.
a. You can set an offset to the butterfly control so that there will be
a specified dead zone at the beginning of the control sticks travel.
b. Ailerons/Flaps Adjustment
In the Ailerons/Flaps Adjustment menu you can set all the travel
needed for butterfly braking (for the flaps and ailerons). Also, you
can set a parameter called Diff. adjust which influences the aileron
differential. Positive values increase the upper travel of the aileron
servos, negative values increase the lower travel of the aileron
servos.
Actual values of
airbrake rates.
T h e v a l u e s
shown depend
on adjustments
m a d e i n
Butterfly Tuning
m e n u (see
below).
c. Elevator compensation
The butterfly mixing is always from zero to the full stick position so
the curve is a little bit modified to control the whole travel range. You
can choose between a standard curve, constant and X-point curve
types.
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d. Butterfly Tuning menu
Screen of the Butterfly menu allows you to fine tune all braking
travels through one proportional control (stick, knob or switch). The
values you set in this screen are added/subtracted to the
appropriate butterfly travels. The way these values influence servo
deflections depends on the position of the butterfly's control stick
and the position of the butterfly's Tuning control.
The F3Apply button operates similarly as in the Aileron
Differential menu. If you press this button, the values set in the
Butterfly Tuning menu are copied into the appropriate travels in
the Butterfly Ailerons/Flaps/Elevator Adjustment menu. After
that, all values in the Butterfly Tuning menu are initially set to zero (so
that the tuning control no longer has an effect).
4. 4.
9.2.11 Free Mixes (*depends on equipment)
The Free (programmable) mixes are used to make a second or „slave“
channel react as a result of the original channel’s input or by moving
any Switch, Knob or Stick. Any of the channels can be (Freely) mixed
with any other function, assignment or logical switch. Up to 20 free
mixes can be programmed for any given model. The primary
channel (“Master/From”) specifies the control or input function,
while the channel that reacts to the Master is called the “Slave/To”
channel. The “Master Value” represents the percentage of „slave“
channel travel output performed when the „Master“ channel
function is used.
1. Copying a Free Mix
Highlight an existing free mix and use the “F1 (Copy)” button to
create a copy of the existing mix.
2. Creating a Free Mix
Use the “F2 (Add)” button to create a new free mix. The Primary
channel called “Master/From specifies the input function, while
the channel that reacts to the Master is called the “Slave/To
channel. The last variable on the screen is the “Master Value” which
represents the percentage of the slave channel’s mix/travel. After
your model‘s basic configuration is finished, use the “F5 (Next)”
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4. 4.
button to exit the free mix screen. If you need to make any changes
simply highlight the desired free mix and press the “F4 (Edit)”
button to reach the advanced settings menu for that free mix.
a). Free Mix Setting
The free mix configuration settings can be set collectively for all
flight modes by selecting the “G-(globe)” symbol or you can allow
individual free mix settings in each separate flight mode by
sellecting the “S-Separate” symbol.
b) Free Mix Activation
A free mix can be activated by any Switch/Knob/Stick. By selecting
“Switch and by editing the desired assignment you can activate
and choose the position at which this Switch/Knob/Stick or Logical
Switch will turn the mix ON or OFF or even control its throw
proportionally. This menu line includes a visual graphic to show the
ON or OFF position of your selected switch. If you do not select any
switch, then the mix is always ON.
c) Free Mix Curve Programming
This programming screen can be accessed by highlighting the
“Curve” item and by either using the “3D Control” button or by
pressing the “F4 (Curve)” button. By accessing the “Mixer Curve”
function screen you can select the mix curve which best fits your
application.
d) Free Mix Deployment Delay
The time delay function can help smooth the transition from one
state to another. Values adjusted in the “Source” item will slow
down full mix deployment when the mix is ON (switched ON or
always ON) and the master channel changes its value. In this item,
when you add a delay to only one side (- or +), the mix deployment
will be slow in one direction only (-100% to 100%) or (100% to -
100%). When you add a delay to both the negative (-) and the
positive (+) sides, then your mix will be slowed in both throw
directions.
e) Free Mix Activation/Deactivation Delay
The „Switch“ values can only be when you have assigned a switch to
turn the mix ON and OFF. This delay operates independently from
the „Source“ values. The positive side of a delay is applied if the mix
is activated using Activation Switch. The negative side is used if the
mix is deactivated and both slow down any fast reactions while
turning the mix ON and OFF.
a
c
b
de
h
i
j
g
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f) Free Mix Multiple Servo Settings
If the mix uses more than one output function as the slave, then the
“Output Mix” menu will appear. This menu allows you to edit the
settings for the individual slave servos (S1-S4).
g) Free Mix Directional Positive/Negative Movements
Once the free mix function is created you can edit the advanced
settings menu so that the mix will either add to or reduce a slave
function‘s movement. To do this, you can set the mix value as a
positive percentage or a negative percentage.
h) Using Another Free Mix to control a Free Mix
A free mix can be controlled by just a control input function (Master)
or it can also be controlled by another free mixs control function
(Slave). Here is how to create a free mix whose input is controlled by
an existing free mixer output:
To allow a free mix to control another free mix you must enable
the “Slave Link” option. This allows the free mix to act as input for
other free mixes. Use the “3D button to highlight and select this
option. You will see a check mark if the option is enabled and an X if it
is disabled. You will also use the (+) or (-) to determine the mix
direction.
To allow a free mix to be controlled by another mix you must
enable the “Master Link” option. This allows the free mix to accept
the input from other free mixes. Use the “3D button to highlight
and select this option. You will see a check mark if the option is
enabled and an X if it is disabled. You will also use the (+) or (-) to
determine the mix direction.
4. 4.
i) Free Mix Trim Settings
This item allows you to enable or disable whether trim functions will
influence the free mix or not.
j) Free Mix Control by Dual Rates
With this item you can activate or deactivate the “Slave Dual-Rate”
function for the free mix. This settings allows the slave output to be
affected by dual rate inputs. All adjustments can be visually
inspected right away in the servo monitor page by pressing the “F2
(Servo)” button. Pressing the “F5 (Ok)” button returns you back to
free mix screen.
k) Aileron Differential
This option is displayed only after you create a mix from any function
to Ailerons. When this option is activated, the output of the mix will
be influenced by the aileron differential settings. If this option is
deactivated, the output of the mix is transmitted directly to the servo
without any modifications. Uncheck this option if you want to use
aileron differential fine tuning without affecting throws of the mixes
applied on ailerons.
3. Deleting a Free Mix
Press the “F3 (Del)” button to delete the highlighted free mix.
4. Configuration & Setting
A free mix programming screen can be accessed by highlighting the
selected mix and then pressing the “F4 (Edit)” button.
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4. 4.
9.2.12 Governor/Gyro (*depends on equipment)
Typically, a gyro is used to stablize a model helicopter along its
vertical axis (rudder). One channel is reserved so that you may adjust
the gyro sensitivity (gain) from the transmitter. Also, a separate
channel can be reserved for the control of a throttle governor. The
governor can be enabled when you create the model or later from
the „Model >Basic Properties“ menu. This menu allows you to
adjust the settings for both of these output channels. The
Governor/Gyro settings can be set collectively for all flight modes by
selecting the G-(globe)” symbol or you can allow individual
Governor/Gyro settings in each separate flight mode by sellecting
the “S-Separate” symbol.
1. Gyro Settings
By default, the gyro sensitivity is assigned to the three position „Si“
switch. This allows you to have three different settings (Position 1,
Position 2, Position 3) for the gyro sensitivity. You can always assign
this function to a different transmitter control element (knob, slider,
switch) in the „Model, >Function Assignment“ menu. The Gyro
settings can be set collectively for all flight modes by selecting the
G-(globe)” symbol or you can allow individual Gyro settings in
each separate flight mode by sellecting the “S-Separate symbol.
In the Gyro settings menu it is possible to edit up to three main
values for each gyro function in all flight modes separately according
to the position of the main control/switch.
Moving the switch to the selected position causes an automatic
update of the depicted values in the appropriate line. Set the main
value of the gyro gain to the needed value (highlighted in the
picture), eventually also assign an appropriate control for fine tuning
– here it is necessary to set also the percentage range of the control
influence. For each position of the main control it is possible to
individually assign an independent control for fine tuning of the
gyro gain. The resulting applied gain value is displayed in
parentheses (-50% in this case).
Negative values of gyro gain indicate the gain in
"Normal" mode, positive values indicate the gain in the
"Heading-lock" mode.
Note:
If you have the governor function enabled, by default, the governor
sensitivity is assigned to the three position „Sg“ switch. This allows
2. Governor Settings
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4. 4.
you to have three different settings (Position 1, Position 2, Position 3)
for the governor sensitivity. You can always assign this function to a
different transmitter control element (knob, slider, switch) in the
„Model, >Function Assignment“ menu. The governor settings can
be set collectively for all flight modes by selecting the “G-(globe)”
symbol or you can allow individual governor settings in each
separate flight mode by sellecting the “S-Separate symbol.
Like in Gyro gain settings, it is also possible to select up to three main
values for governor RPM control in the Governor settings menu (0%
means zero RPM, 100% means full throttle). It is also possible to
assign a specific control to each governor position (switch, stick or
knob), which can precisely tune required RPM in this case it is
necessary also to specify the range of the influence of the tuning
control to the RPM. The resulting applied value of the Governor
function is displayed in the parentheses. The setting can be global
for all flight modes or separate for each mode.
9.2.13 Throttle Limiter (* depending on equipment)
If you have several flight modes and all of them have specific throttle
curves, the Throttle Limiter might help you to get the motor's RPM
safely from the lowest to the maximum RPM that is controlled by
your throttle curve.
You are free to choose any control device (proportional or a switch)
that will operate as a speed limiter. It doesn't allow the throttle to go
any higher than the position that this control shows. The limiter
operates within a specified range (negative and positive rate, “- Rate
+”). Using the “-” rate you can set the lowest motor RPM you want to
use. This is the point where the limiter begins its operation. The “+”
rate represents the maximum possible output of your throttle
channel. If your application needs full throttle, you should set the
“+” rate to a value higher than 100% so that the full throttle output is
not limited.
It is possible to set some delay for this control (if it is assigned to a
switch) so that the motor goes smoothly from low to high RPM (and
vice versa). Finally, the Exponential parameter enables you to fine-
tune the output at lower RPM and the whole acceleration curve.
The throttle limiter also influences mixes where the throttle acts as
the source. The trim function is not influenced by the throttle limiter.
If a control device is not assigned, the throttle limiter function is
disabled.
9.2.14 Snap Roll
The snap roll function is intended for aerobatic pilots who want an
instant stunt controlled by a single switch. There are two modes of
the snap roll function:
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4. 4.
Separate switches for every
direction. The priority goes from
up/right direction (highest) and
continues until down/left (lowest).
Master modethe stunt itself is done by activating a master 1.
switch (Sa in this case). The other switches are taking care of the
direction of the stunt.
Single mode the stunt is done immediately after any 2.
direction switch is activated.
You may enter your desired properties for ailerons, elevator and
rudder separately for every direction. There are four directions
available (up/right, down/right, up/left and down/left), each one is
controlled by a separate direction switch. Each element may store its
own fade-in/fade-out ramp which is defined by the rows “Delay +”
and “Delay -”.
All options may be either flight-mode-specific or global. You can see
the current state of the snap roll function in the bottom left corner of
the display.
This function is not available for helicopters, v-tails or delta
wings.
Note:
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4. 4.
9.3 Advanced Properties
Advanced programming menu for DC/DS. (*depends on equipment)
9.3.1 Other Model Options
This menu contains additional, special features of the DC/DS
transmitters.
1
2
3
4
5
3a
1. Auto-Trim Function
Auto-Trim function can be activated using any assigned switch,
knob or stick. Once this function has been activated you can trim
your model using transmitter gimbals. The direction and speed of
the trim adjustment is determined by stick movement. Larger stick
movements equal a faster trim response. When the Auto-Trim
function is active, the transmitter gimbals do not change their
standard response. The transmitter is still in normal operation mode.
It is advised to use the automatic trim function only for
the maiden flight, after proper trimming is done we
recommend disabling this function.
Advice:
2. Trainer Function
The Trainer function can be set so that it may be activated using any
assigned switch, knob or stick.
3. Telemetry Recording
The Telemetry recording function can be set so that it may be
activated using any assigned switch, knob or stick. The data stream is
recorded on the internal SD memory card. All data can be found in
the “Log” directory of the transmitter software after connecting the
Tx to the PC via a USB port. Active data recording is indicated on the
upper edge of the main desktop screen by a blinking circle. A solid
square graphic indicates that recording is stopped.
3a. Mode
By default ("Auto" mode), the telemetry starts recording after any
timer is activated, Start-logging switch is flipped or Start button on
the main screen is pressed. If the "Start/Stop" mode is selected, the
status of recording is always controlled by the position of your
selected Start-logging switch.
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4. 4.
4. Throttle Cut Setting
This safety feature is mainly for models using glow or gasoline
engines as their main source of power. Electric models can also
highly benefit from this safety feature. The Throttle Cut function can
be activated using any assigned switch, knob or stick. By editing the
“Output Value” item, the throttle output will move to the user
defined (completely off) throttle position once the assigned switch
is activated.
5. Throttle Idle Setting
This feature is used to set the idle position for your throttle and will
prevent your engine from shutting-off when you move throttle stick
to its low position. The minimum throttle setting is defined by
editing the “Idle Offset” value. When this function has been
activated, the minimum throttle setting (idle point) is defined by the
offset value as a percentage. Standard throttle function is not
affected by the idle offset setting.
9.3.2 Sticks / Switches Setup
This menu contains System Stick/Switch settings and configuration.
Various functions can be activated by any Switch, Stick or Knob
position. Switch setting enables you to set the points when your
desired function/timer/telemetry can be turned ON or OFF.
1
2
3
4
1. Switch & Stick Type
The first menu line item lists the control’s number and the second
item lists the type of control element. Using the “F2” and “F3”
function buttons you can scroll through channels, with the “F5 (Ok)”
button you can exit the menu screen.
By default, the switch types are always automatically detected,
however, it is also possible to overwrite any of the auto-detected
switch types with a user-defined type. The choices are: "Auto" which
keeps the auto-detection running, "None" that disables the
particular input control, standard "Std. Switch", "3-Pos. Switch",
"Button" and "Proportional". Any value other than Auto will disable
auto-detection for the specified control. Remember, these settings
are global and are applied to all models. The only model-specific
"Type of control" property applies to stick-switches Sk and Sl. This
feature is useful, for example, if you want to have a standard switch
that behaves like a spring loaded switch equipped with button
memory.
2. Switch ON/OFF Points
Any proportional function can be set as a system switch. This menu
item enables you to assign the travel percentage at which a desired
function can be turned ON or OFF.
“Switch-ON” The point when the control element positon will
switch a function ON.
“Switch-OFF” The point when the control element positon will
switch a function OFF.
By default, the system setting for all proportional channels and for all
inputs is set to function the same as a 3-position switch.
a) A function above this point is considered to be “Switch ON”
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4. 4.
b) A function in this range (middle) can be considered to be either
“Switch ON” or “Switch OFF”
c) A Function below this point is considered to be“Switch OFF”
If the switch setting is set at same level for “Switch ON” and “Switch
OFF”, the proportional channel/function output will be the same as
a 2-position switch.
3. Required Preflight Position
For any functions assigned to the Switch, Knob or Stick, any preflight
initial position can be programmed. If the pre-programed Switches,
Knobs or Sticks are not in required preflight position while model is
being activated, system will refuse to switch to this model. The
transmitter screen will display the function that is not in pre-
programmed, correct preflight position.
4. Function Status Display
Position and status of the control is displayed in the status bar. On
the right side of this menu you can see the status of the switch
function as an “x or check mark.
1) Setting Example
If you have installed the optional a button/switch in your left or right
stick, scroll thru the Control No. Menu line and pick the function
switch “Sk” or “Sl” if the button switch is installed in your right stick.
Pick one of the “Type of Control” switch options:
“2-Position Switch
“3-Position Switch
“Button
For any functions assigned to the chosen switch, knob or stick, any
preflight initial position can be programmed.
9.3.3 Wireless Modes/Trainer (*depends on equipment)
The transmitter RF modules can operate in one of three modes. For a
detailed explanation. (see section 5) The wireless RF setting is
programmed to the memory of individual models (receivers). While
programming a selected model you will need to configure the RF
module settings. The only exception for the system is the Trainer
mode. If the particular model has been programmed in Trainer
mode, this setting will not change if the Tx is turned ON or OFF.
For safety reasons, the “Trainer RF mode will be switched
automatically to “Initial” RF mode when a different model is
selected in the transmitter.
DS/DC radio systems are excellent tools for instructor pilots. Basic
training for a student is not different from flying his own model.
Both the instructor and student have their own JETI transmitters, all
communication between the transmitters is done wirelessly. The
instructor decides when to give control of the model to the student
and when it’s time to step in. The instructor’s primary transmitter RF
module communicates with model and the secondary RF module
communicates with student’s transmitter. The Student’s transmitter,
if set to “Student mode, disables its secondary RF module and uses
only the primary RF module to communicate with instructors
transmitter.
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“Default” Wireless Mode
a. Selection
b. Primary RF module bind control menu line
4. 4.
“Student” Wireless Mode
If student’s transmitter if set to “Student” mode, any dual-rates, mixes
or any other advanced features are disabled in the student’s
transmitter.
a) Mode Selection.
b) Binding initialization of the Instructor transmitter‘s primary RF
module or special wireless Trainer” module by JETI.
c) Channel function assignment.
a) Mode Selection.
b) Assigned trainer function switch, when the switch is activated,
control of the model is transferred to the student.
c) Binding initialization of the Instructor transmitter‘s secondary
RF module with student’s transmitter.
d) Channel function assignment. Some or all of the functions can
be controlled by student.
e) Instructor/Student control authority values. This setting limits
the amount of control for the student. If the instructor is
assigned a 60% control value to a particular channel, and
student is assignedonly a 40% value. The instructor can easily
override students input and correct the models flight.
“Instructor Wireless Mode (* depending on equipment)
a
b
a
b
c
a
b
d
c
f
e
g
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f) Assignment for the input channel from the student’s
transmitter to the Control function of the instructors
transmitter.
g) The Trainer Mode allows you to directly assign an arbitrary
control (switch, stick even a logical switch) which will be ,
emulated for further use in the student's or teacher's
transmitter. The list of emulated inputs is located at the bottom
of the Function list. The behaviour depends on the mode
setting of transmitter:
1) Student mode. Here you can simply assign an arbitrary
control which will directly output its position/value to a
defined channel of the student's transmitter. In the picture,
the proportional control P8 is assigned to the seventh
channel. You can disable the output by un-checking the
"Enabled" button.
2) Teacher mode. Here you can decide which controls will
be emulated by any of the student's channels. At the
moment the student takes control of the model, the values
of these controls are fully overwritten by the values of the
appropriate student's channel. In the picture you can see
that channel seven emulates the proportional control P8
and thus all functions that rely on this control knob. With
this option, the student may switch the flight modes,
operate the Butterfly function directly etc.
Disable RF Transmission
You can manually disable the wireless transmission by pressing the
F1 button followed by a confirmation of the choice. The RF system
turns Off automatically when the USB connection is activated.
Caution: If you disable the transmission with a model attached,
you may cause a signal loss alarm.
Trainer Mode with two JETI DS/DC Radios
Make sure that the instructor’s transmitter is bound to the 1.
aircraft in the “Default” wireless mode and that all flying
surfaces are functioning properly.
Change the instructors transmitter wireless mode to“Teacher2.
and authorize the secondary TX module to bind with the
student’s transmitter.
Switch ON the student’s transmitter, change its wireless mode 3.
to “Student” and allow the instructor’s transmitter to bind
properly. Verify that all of the aircrafts surfaces are correctly
controlled by the students transmitter. If they are not correct,
make the necessary changes in the student’s transmitter.
Trainer Mode for JETI DS/DC as the Instructor Radio
Other brands of transmitters can be used by the student with a JETI
Duplex EX 2.4GHz radio system by using a special wireless Trainer
communication module by JETI.
4. 4.
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4. 4.
a
b
c
d
1. Make sure that the instructor’s transmitter is bound to the
aircraft in the “Default” wireless mode and that all flying
surfaces are functioning properly.
Change the instructors transmitter wireless mode to“Teacher2.
and authorize the secondary TX module to bind with the
student’s transmitter.
Connect the wireless trainer module to the student Tx Trainer 3.
Jack” (see Tx manual), then prepare the module for binding to
the instructor Tx by inserting the bind plug into the “Ext port
(see the module guide).
Verify that all of the aircrafts surfaces are correctly controlled by 4.
the student’s transmitter. If they are not correct, make the
necessary changes in the student’s transmitter.
Double Path Wireless Mode (*depends on equipment)
a) Mode Selection.
b) Primary RF module bind control menu line
c) Secondary RF module bind control menu line
d) Optional signal loss alarm settings.
Signal Loss Alarm Settings
It is possible to define a specific response from the transmitter after
one or more receivers disconnect or lose signal. The options are:
Loss of any receiver – the alarm is activated every time any of the
receivers loses a connection. This mode is sufficient for applications
where two receivers control separate functions of the model. Both
receivers must be connected for proper function.
Loss of receiver Rx1an alarm is triggered only if the primary Rx
loses connection. This mode is intended for competition pilots who
use the primary Rx in the model while the second receiver is acting as
a reference for the judges. In this mode, the receivers are
independent and you can control your model with only one receiver
connected.
Loss of receiver Rx2 an alarm is triggered only if the secondary Rx
loses connection. The intended use and behaviour of this mode is
similar to the previous mode.
Loss of both receivers – an alarm is triggered after the signal from
both receivers is lost. You should use this option if you want to join
servo signals redundantly using the Enlink plug or any other central
control unit. Both receivers must be connected for proper function.
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Pairing the transmitter with receivers in Double Path mode
1. Make sure that receivers are set in Normal mode, not in Clone
mode.
2. Note down which receiver is the first and which is the second
because of later easier identification. Keep the receivers switched
off.
3. Switch on the transmitter with created model, in Advanced
properties - Wireless modes/Trainer menu item select Double
Path mode.
4. Plug the BIND PLUG interconnection into EXT output of the first
receiver. Switch on the receiver. Now the receiver expects a
sequence for pairing (in case you have Rx firmware version 3.11 and
newer, this period is limited up to 60s).
5. Press 3D pushbutton on the transmitter over "Pair primary TX
module" command. As soon as the receiver is identified, you will be
asked for confirmation now push OK button. Switch off the receiver
and remove pairing interconnection.
6. Plug the BIND PLUG interconnection into EXT output of the
second receiver. Switch on the receiver.
7. Press 3D pushbutton on the transmitter over "Pair secondary
TX module" command. As soon as the receiver is identified, you will
be asked for confirmation now push OK button. Switch off the
receiver and remove pairing interconnection.
8. Switch on both receivers. The connection should be established
immediately, eventually servo control is allowed.
9. Now you can specify additional parameters of the Double Path
mode so that the transmitter correctly responds to the signal loss
from any of the receivers.
4. 4.
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4. 4.
9.3.4 Logical Switches (* depending on equipment)
If you want to have single or multiple transmitter functions which are
controlled based upon the condition of other control conditions,
then setting up a logical switch is the way to go. Each logical switch is
defined by a logical expression. The logical expression contains a
logical function and the relationship of the other conditions which
must exist for the logical function to be activated. The end result is
that your logical switch can either work like a 2-positon switch
(ON/OFF) or like a proportional 3-position switch (ON/Center/OFF).
1. Creating a Logical Switch
Up to 16 independent logical switches can be created. Select one of
the numbered lines and press the „3D button“ to access the logic
switch setup menu. To enable the switch highlight and change the
enabled value to Yes”. Once activated you can see the control
inputs and conditions on the menu screen. First set the control
inputs #1 and #2 by assigning functions to switches, sticks or knobs.
After that, select your desired logic statement (OR, YES, Multi). On
the bottom of the screen the result of your logical expression is
displayed by either a check mark or an X“, depending upon the
current conditon state.
2. Logical Switch Proportion Calculation
Logical rules can also be created when your logical switch uses
proportional channels. To enable proportional evaluation press the
„F2(Prop)“ button when you select your input controls. When you
allow the use of proportional controls, an additional condition menu
will appear. In this menu the conditions can be set by percentage
value of the channel as well as by the value from which the switch
will be in its full ON/OFF position. Those conditions will then be used
to calculate the logical result.
Example: This figure shows the use of proportional processing by a logical switch. In this
example, if the P2 stick is moved between 20% and 80% of its travel, the logical switch is in the
ON position. If the P2 stick is moved from 0% to 20% or from 80% to 100% then, the logical
switch is in the OFF position. All 16 logical switches can be configured this way if needed.
(number of available logical switches depends on actual transmitter equipment)
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4. 4.
Switch 1
Switch 2
The result of the operator
AND
OR
Multi
\
\
\
\
\
\
]
\
]
#
]
\
\
]
#
]
]
]
]
]
3. Emulating a 3-Position Switch
You can use the logic function “Multi” to allow the logic switch to act
as a 3-position switch. The “Multi” logic function can combine the
output from two 2-position switches to create a logic switch with
three output conditions.
]
]]
]
4. Using Proportional Logical Switches
The logical switches also offer the option of a complete proportional
evaluation that could be applied to both controls. Just select an
input stick/slider, press the F2 “Prop. button in the same menu
(picture ) and confirm. Then edit the selection box with options e)
“X<”, “X>”, “Lin” and make sure that you select the “Lin” option
(picture ). At this point, the logical switch starts to act as a c)
proportional control.
You can combine more controls using logical conditions:
a) b)
c) d)
e) f)
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The AND condition: The resulting value of the switch is
calculated as minimum value from both controls. If you have two
sliders, the first one has +25% and the second one has -25%, the
result returned by the logical switch will then be -25% . (picture )c)
The OR Condition: The resulting value of the logical switch is
calculated as maximum value from both controls. The higher value
will be returned (picture ). d)
The Multi condition: This option still emulates a 3-position
switch. The output values of the logical switch are then in range -
100%, 0% and 100% (picture ).b)
Example: How to enable or disable the Butterfly function using
a switch.
Many people want to have the ability to turn the Butterfly function
on and off independently from any flight mode. So here we show the
way to do that (see picture ).c)
Select an arbitrary switch as Control 1. In the picture, Sj was 1.
chosen. This switch will overwrite the function of Control 2.
As a Control 2 select a proportional unit that will operate the 2.
Butterfly function (P2 in this example). Make sure it is evaluated
proportionally (see picture ).e)
Control 1 and Control 2 are linked together using AND logical 3.
function. That means, if the switch Sj is deactivated, the operation of
P2 will be blocked. Otherwise, P2 will function normally.
In menu assign the newly created 4. Fine Tuning -> Butterfly
switch L1 in the standard way and try its operation.
4. 4.
9.3.5 Sounds on Event (Sound Assignments)
(* depending on equipment)
You can assign an audio file to be played based on any transmitter
condition. This means that any music file stored in the transmitter
can be assigned to any switch, stick, knob, logical switch, alarm or
any other special function. Since you can also upload music files the
the DC/DS, you can fully customize how your transmitter
communicates with you. If multiple sound files are triggered at the
same time, they will play at the same time and their sounds will
overlay each other.
1. Sound Switch Assignment
Select the “Switch menu item and assign the switch that you want
to use to trigger the sound playback.
2. Select the Sound File
Select the “File menu item and select the sound file that you want
assigned to the switch. The available audio files are stored in
Directory/Audio. This is important to remember if you upload your
own files.
3. Sound Playback Delay
The playback of any sound, after activation, can be delayed by
editing the “Delay” menu item.
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4. 4.
4. Sound Repeat
This menu item allows you to repeatedly play any sound after it has
been activated. This can be useful if your selected sound’s playing
time is short.
9.3.6 Sequencer (* depending on equipment)
While this function can be used for direct control of landing gear
servos, its usage is almost limitless. Two independent sequences
might be used when you turn the source switch on and off.
You can define up to 6 sequencers Q1-Q6 and within each
sequencer you can define up to 16 control points for each path.
Switching between different sequencers is possible by pressing the
F1 Down and F2 Up buttons.
To make a sequencer active, you should do the following steps:
Assign a source switch. In the picture the Sg was selected. 1. a),
After this switch is activated, sequencer starts running. But first it has
to know a path that consists of control points which are distributed
over a period of time.
a) b)
2. To add control points, you should move the timeline (edit
“Time” column) so that it reaches the desired time. Then press the
F3 Add button. The newly created control point will be
highlighted and you can change its value (edit the “Value” column).
Generally said, the point located closest to the timeline is
highlighted and made editable.
You cannot move the control points in a time domain but you 3.
are able to delete any point by pressing F4 Delete button.
Now, when you activate the source switch, the timeline begins 4.
moving and the output of the sequencer is updated accordingly. If
you deactivate (turn off) the switch, the sequencer moves in the
opposite way.
There are some additional options that you can now set in the
Advanced menu:
You can label the sequencer to simplify identification.
The option to overwrite a specific channel. Example: If you
have several gear servos installed in your model, here is where you
can define which servo will be directly controlled by the sequencer.
Any other operations (like mixing or DR/Expo) will not be applied to
the output.
Type of path (Symmetrical / Asymmetrical) this option tells
the sequencer that there is either one symmetrical path, or there are
two independent paths one path is used after you activate the
switch and another one after the switch is turned off. If you choose
the Asymmetrical option, the sequence will always start from the
very beginning and it doesn't matter whether the previous
sequence is completed or not. It is recommended to use this option
in conjunction with the Always finish sequence option.
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Cycling if you wish a cyclic behaviour for your beacons,
turrets or radar assemblies just check this option.
Always finish sequence – After checking this option, the
sequencer will never be interrupted and always will travel from the
beginning to the end of its path.
The button clears all data from the sequencer and F3 Clr
resets it to the default state.
4. 4.
9.3.7 Accelerometer (DS only) (* depending on equipment)
The DS is equipped with an inertial unit that allows you to precisely
determine the orientation of the device in space. This unit consists of
a 3-axis gyroscope, 3-axis accelerometer and additional mathematic
operations. You can freely use this inertial unit to control any
function, trigger any voice announcements or you can simply flip
pages on the main screen.
You can configure some of the
inertial unit parameters in
A d v a n c e d P r o p e r t i e s - >
Accelerometer. In the picture a),
the actual orientation of the
transmitter is displayed. The axes
GX, GY, GZ are defined as roll, pitch
and yaw in the same order. The
graph shows the final values after
all corrections have been made.
a)
Within this menu, you can edit
following parameters:
Filtering This increases
smoothness of the movement for
each axis separately. You can set
values in range from 0 to 10. Zero
value means no filtering and gives
fast reactions. The higher the
filtering setting, the movement
becomes slower and smoother.
Sensitivity This influences
the gain of the inertial unit for each
axis separately. If you feel that the
reactions of the controlled
function are too small for the
particular movement, you can
simply increase the corresponding
value of sensitivity, numerically up
to 400%.
c)
b)
Dead Zone This means that as the value is increased, the more
you can move the transmitter around the middle position and the
output of the inertial unit will remain zero.
Pitch Offset - This shifts the GY axis so that you don’t have to hold
or keep the transmitter in a completely horizontal position all the
time.
You can also view the raw data coming from accelerometer and
gyroscope by pressing the F1 button (see picture ). This might b)
help you to fine tune your setup.
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4. 4.
After you have finished setting the inertial unit itself, you can assign
the resulting variables to any function using a standard input dialog
(picture ). To see the variables of the inertial unit, you have to press c)
the F2 Gsens. button. The axes GX, GY, GZ correspond to the graph
shown in the picture ). The last parameters are called Shake L/R a)
and represent a motion gesture. If you quickly shift the transmitter to
the left, the G/L switch will be activated for a short time. Similarly, a
single movement to the right activates the G/R switch. You can use
these gestures to trigger voice announcements, flip pages of the
main screen etc.
The parameters "Axis X<<" and "Axis X>>" represent virtual two-
state switches which are activated when the transmitter is tilted to
the left or to the right along the X-axis.
GY
30° Pitch Offset
GX
GZ
100%
0%
Roll (GX)
Sensitivity = 100%
Dead Zone
-90° 0° 90°
-100%
Sensitivity = 200%
9.3.8 Telemetry Controls (*depends on equipment)
Not only can you display telemetry data, record it to your SD card or
have it voice announced, now it is possible to control specific model
functions using sensor inputs. This way, some tasks that previously
required manual adjustment via visual estimation or alarms can now
be automated.
Up to 8 controls labeled MX1 MX8 are available, depending on the
type of transmitter and equipment. Telemetry controls offer
functionality in two modes: The Switch mode enables you
to create a virtual two-position
switch using the value of one
telemetry parameter. This switch is
always active based on the
fulfillment of defined logical
conditions.
The Proportional Control mode
enables you to transform a certain
range of sensor values into a fully
proportional control. It can
automatically and smoothly
control any kind of function using
telemetry feedback.
Examples for the possible use of
telemetry controls
If the model speed is less than X
m / s , f l a p s w i l l b e ra i s e d
automatically.
If the current is larger than X
amperes, the motor run timer
starts.
If the motor temperature is
higher than 80 °C, the maximum
throttle will be limited by the mix.
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If the on-state of the limit switch is detected, the sequencer
automatically starts. (eg after opening the landing gear doors, the
main gear will be deployed).
Setting the parameters of telemetry controls
Description Sensor name that will be displayed in the list for easier
orientation.
Active Tick to enable the telemetry control function.
Sensor Here you can select a specific telemetry parameter.
Type of control – Select Switch or Proportional control according to
the required functionality.
Condition (X<, X>, X=) Select the condition under which you want
the control to be active (ie switched on). In the same line, fill in the
numerical value of the decision levels and the hysteresis value
(prefixed with ±). Available in Switch mode.
Example 1: The entry “X < 20.0m/s ± 2.0m/s” means that
telemetry control switches precisely when the telemetry parameter
value is less than 18 m/s (due to hysteresis of 2 m/s). The control then
symmetrically switches off when the speed exceeds 22 m/s.
Example 2: The entry “X > 0 ± 0” indicates a switch that is
activated whenever the telemetry value is positive.
Duration – minimum time of being switched on. If an event takes a
very short time, it is possible to extend the time of the telemetry
control being switched on for the time specified by this parameter.
Available in the Switch mode.
Range Set the operating range of the sensor (minimum value,
center value, and maximum value). This level will then be
transformed into a proportional range of the control (-100%, 0%,
100%). Available in Proportional control mode.
Filtering Determines the level of received telemetry values
smoothing (filtering). The higher the level of filtration, the smoother
the course, but the response will be slower. Available in Proportional
control mode.
Default The default control value, if the sensor is not present in the
model or the model is not turned on.
Switch This parameter can specify any switch, which will activate or
deactivate the operation of the telemetry control.
9.3.9 Sound of Proportional Controls
In this menu, you can set a sound notification for up to four
independent controls. You can choose a basic beep in the middle
control position (Center-Beep mode), but voice announcements of
the current position is also available (Voice mode).
4. 4.
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Center-Beep mode the transmitter beeps whenever the
control goes to a central position (its deflection is thus 0%).
Voice mode the transmitter will vocally announce the
numeric value of the current position of the control. The value is
reported after every change of the control position and only after
the movement is stopped. In this mode, you can also select an audio
file that will alert you when changes in control positions are
detected.
Example: If you generate the CONTROL.WAV” file and then assign
it as the File parameter, the transmitter announces eg “Control:
twenty-five”.
The setting is always valid for the current model.
4. 4.
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4. 4.
9.4 Timers/Sensors
- Set up of Timers and Telemetry Sensors (*depends on equipment)
9.4.1 Timers (*depends on equipment)
The DC/DS allows you to simultaneously use up to 10 different
timers. This is useful to separately track motor run times, individual
lap times, total flight time or just about anything else you could
want. You can also name each of the timers. Once you create a timer,
it is displayed in its own box on the desktop screen. The timer values
are stored in each model’s setup. The Timers“ menu displays a list
of all of the timers you have created.
1. Model Time/Reset Timers at Power Up
By pressing F1() button you can choose which timers will be reset
after turning on the TX or after selecting the model. By default, all
timers with specified Short Reset option are cleared. In addition, it is
possible to have all timers cleared or none. This option is model
specific. The model time runs incrementally during flight (after
pressing F(4) Start button on main screen or after starting any timer).
Button F(3) clears the model time.
It is possible to show the model time on the main screen
Timers/Sensors->Displayed Telemetry.
2. Creating a new Timer
From the „Main Menu > Timers/Sensors > Timers“ menu, press the
„F2(Add)“ button to create a new timer.
3. Deleting a Timer
Use the „F3(Del.)“ button to delete the selected timer.
4. Editing Timer Settings
Use either the „F3(Edit)“ button or the „3D button“ to enter the
Timer Detail“ menu. Then use the „3D button“ to select and edit
the timer settings.
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4. 4.
1. Editing a New Timer
a. Timer Name
When you add or change the timer name, the name is automatically
displayed in that timers box on the main desktop.
b. Initial Timer Value
This is where you can set the starting value for the timer. You can set
a negative or positve value for this starting point.
Target Timer Valuec.
Here is where you can set the target value for the timer. This can be
set as a positive value or a negative value. The initial value and target
value will determine the timer‘s direction. If the target value is
smaller than the initial value, the timer will count down. If the target
value is larger than the initial value, the timer will count up.
d. Timer type
There are three possible timer types:
Standard The timer starts or resumes when the chosen switch
is triggered and the timer pauses when the switch is turned off. The
timers value is not reset when the timer is paused. Use the
„F4(Stop)“ button to stop the timer.
Laps - The timer starts when the chosen switch is triggered.
Once the timer is started, each time the switch is triggered, the
elapsed time is stored in memory and the timer resets to your chosen
initial value. The lap number changes and the current lap time is
displayed each time the switch is triggered. Use the „F4(Stop)“
button to stop the timer. Then, you can use the „3D button“ to scroll
through the stored lap times.
Free-Running The timer starts counting when the chosen
switch is triggered. Once started, this type of timer can only be
stopped using the „F4(Stop)“ button.
Use the „F5(Clr)“ button from the desktop to reset the timers.
e. Report type
You can use this item to select the type of audio alarm for the timer.
Some of the choices will create an audible warning which sounds
just before the target value is reached.
f. Switch
This item is used to assign the switch or button to start the timer.
See chapter 9.7: „Select input control“.
g. Reset type
The „F5(Clr)“ button is used to reset the timers.
If you select „Short reset“, the timer is reset by a short press of the
„F5(Clr)“ button.
If you select „Long reset“, the timer is reset by a long press of the
„F5(Clr)“ button.
h. Flight modes active
This item allows you to select which flight mode(s) for which the
timer is active.
While you are in the Timer Detail“ menu, the timer initial value is
displayed in the first function key position (bottom, left).
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9.4.2 Alarms
If you use the JETI telemetry system, in this menu you can set your
alarm thresholds and choose which sound is played in the alarm
condition. The transmitter supports both first generation Duplex
and Duplex EX alarms.
First Generation Alarms
First generation Duplex (non-EX) sensors generate their alarms as
Morse Code. If you are using first generation Duplex sensors, then
you must select „Enable Morse Code Alarms“ using the „3D
button“. When this option is selected, a table appears. In this table,
the first column shows the Morse Code alphabet. The second
column shows the .wav sound files associated with each letter. Use
the „3D Button“ to change the .wav file association as needed. The
third column shows whether the selected .wav file for each letter is
enabled. Use the „3D button“ to enable or disable the alarm sound
as needed. This configuration must be set for each model and is
saved for each model independently. 1. Creating an Alarm
Use the „F2(Add)“ button to add an alarm. Then, in the „Sensor“
item, select the sensor whose alarm limit you want to set.
4. 4.
EX Alarms
Duplex EX sensors generate their alarms directly to the transmitter.
The corresponding Duplex EX sensor must first be connected to a
Duplex EX receiver and the receiver must be bound to the
transmitter. It may take several minutes for the transmitter to initially
communicate the sensors. The list of connected sensors is found in:
„Main Menu >Timers/Sensors >Sensors/Logging Setup“.
For this operation, both the transmitter and all receivers and sensors
must be connected and powered.
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2. Enable an Alarm
Using the „3D button“, select „Enabled“ and press to enable the
alarm and display the alarm parameters.
3. Parameter Values
„Condition“ defines the condition which must be met in order to
trigger the alarm. The value „X“ will vary with the sensor being used.
4. File
This item allows you to select the audio file that is played when the
alarm occurs. Press „F1“ to play the selected audio file. Press „F2“ to
stop playing the selected audio file.
5. Activation Switch
If the switch is assigned, the alarm is enabled or disabled according
to the switch status.
6. Repeat
If the alarm condition occurrence is longer than the selected audio
file, you can use this item to repeat the audio file. If a check mark is
displayed then the audio file will repeat. If an „x“ is displayed then
the audio file will play only once.
7. Announce current value by voice
EX Alarms provide the ability to tell you the actual value of a given
sensors variable. If you want the alarm value to be announced, then
check this option.
8. Set Throttle Idle
With this item activated, you models throttle will go to idle when the
alarm condition occurrs.
4. 4.
9.4.3 Vario (* depending on equipment)
Located in: „Menu->Timers/Sensors/Vario. There are two types of
acoustic signalling. The first one is controlled directly by the sensor's
alarm. This is mainly useful if a non-EX MVARIO is installed inside the
model. It is possible to assign a switch that enables or disables the
sound. The slider at the bottom shows the actual value of climb/sink
rate.
The second mode of the Vario is dedicated to EX sensors. The
acoustic signalling varies directly depending on the actual
numerical values sent by the sensor. It is also possible to assign a
switch that enables the acoustic signal.
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Other parameters displayed in this menu are:
EX Parameter. Here you can select your sensor and its
parameter which will act as a source for the Vario system. The Climb
Rate is predefined by default (if the MVARIO EX is detected) but you
are free to choose one of the other sensors and their parameters (for
example: an RPM probe to indicate high revolutions).
Dead Zone (negative and positive). This field sets an area
around the centre of the range with no acoustic signal. Values are
relative to the center.
Range (minimum, center and maximum). Here you can define
the full range of the sensor which will be indicated by the Vario
system.
The actual value of the sensor and its appropriate Vario output are
indicated at the bottom of the screen.
Centre of range Negative dead zone Positive dead zone
Silence Permanent sound Beeping...
Minimum Maximum
9.4.4 Voice Output (* depending on equipment)
This powerful function makes it easier for all modellers who need to
know their actual telemetry values often but they don't want to (or
cannot) look at the display because it may be inconvenient or
dangerous.
Voice output for a timer
The first menu row represents settings for the voice output of a timer.
The actual status of a single timer can be expressed by a synthesized
voice. If you select the desired timer and a switch, every time the
switch is activated the actual time is stated aloud.
If the timer type equals “Laps” type, another menu row equipped
with checkbox appears below. In this row, “Report previous lap
allows you to determine whether you want to hear the time of a
current lap which is already running or hear the time of the previous
lap which has ended recently.
Voice output for telemetry
There are two independent queues dedicated to output telemetry
values. The first queue repeats its message every x seconds (number
of seconds elapsed is displayed over the F(1) button). You can also
assign a switch to enable or disable the repeating of the countdown.
Every time this switch is activated, the appropriate variables are
reported by voice and then the countdown starts a new round until a
timeout is reached.
The second voice queue specifies which variables are reported only
once, after a single press of a switch. You can select a Trigger switch
and a list of variables that are reported when the switch is activated.
4. 4.
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4. 4.
By selecting the pushing the “Sensors & Variables” option using the
3D rotary button, you are able to choose which variables will be
expressed by a synthesized voice. The first column represents the
name of the sensor or variable. The Repeat option provides an easy
way to add a variable to the Repeat queue or to remove a variable
from the Repeat queue. By selecting the Trigger option, the specified
variable is added into the Trigger queue, so that every time the
Trigger switch is activated, the items in the Trigger queue are
expressed by synthesized voice.
You may change the priority of any variable. This will also change the
order of the reported items. Possible choices for priority are: Low,
Medium and High. The order, top to bottom, is from High priority to
Low priority.
9.4.5 Sensors/Logging Setup
This menu lists all of the Duplex EX sensors and their values which
are operating in your model. When you connect a sensor to a Duplex
EX receiver, it may take several minutes for the sensor to be
recognized by the transmitter and added to the list.
In this menu you can edit the telemetry parameters of each sensor.
It is possible to store service information of the transmitter, alarms,
and position of up to 4 controls (as markers) on your SD card. Then
the data is a part of logged flight telemetry. In the menu
Timers/sensors -> Sensors/Logging setup go to the item
Transmitter status info and push the 3D button. In the menu it is
possible to select whether the text information about the alarms and
other general data about the transmitter state will be stored (by
default it is disabled). Note that some PC programs for the evaluation
of telemetry data can recognize the text information as an error in
the data file. To view the information, you should use the built-in
Data analysis application or update the PC program.
In this menu you can also select up to four controls whose position
will be recorded in a file on the SD card. It is possible to select
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4. 4.
between recording of proportional or two-state values (0% 100%).
The control positions are recorded with a fixed period of 0.2s. The
data is a part of the standard telemetry record and can be displayed
as the other parameters.
This application can easily be used as a marker to highlight
interesting situations during the flight.
Conversion of Units
1. The voice synthesized telemetry units can be expressed in either
metric or US units. It is also possible to display the telemetry units on
the main screen in either format as well. The temperature is
automatically converted according to the option selected in the
Configuration menu. Conversion of the other units is accessible
through the Sensors/Logging menu. You can choose from the
following units:
Distance:
Metres (m), kilometres (km), feet (ft.), yards (yd.), miles (mi.).
Speed:
Metres per second (m/s), kilometres per hour (km/h), feet per second
(ft/s), miles per hour (mph) and knots (kt.).
Deleting a sensor
Above the F3 function button the transmitter shows the number
of detected telemetry parameters from sensors and it is possible to
reset any unnecessary entry using the F4 button. However, if the
button whose parameter has been deleted is still connected, the
parameter will later be re-loaded. The transmitters can detect up to
32 telemetry items.
9.4.6 Displayed Telemetry
This menu lists all of the user information blocks which are displayed
on the desktop. You can use this menu to manually add, delete,
rename and resize the user information blocks displayed on the
desktop.
User Block Overview:
"Flight mode" - Name of the current flight mode
Voltage Rx“ - Receiver Voltage
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4. 4.
Tx Battery“ - Transmitter Battery Status
"Antenna" - Information about the signal strength of each
antenna. The percentage success of bidirectional communication,
which is in the range of 0-100%, is shown in the box as well.
Charge/Discharge current rate
Actual Tx battery voltage
Consumed capacity of Tx battery This value increases when the
transmitter is in use and decreases when the battery is charging.
„User Name“ - User name.
„JETIbox“ - JETIBOX emulation screen
Timer“ - Timer
Press the ESC button to see and
operate standard JETIbox controls.
The JETIbox emulator can also
show data from both Tx modules
and receivers. You can set a specific
JETIbox window by selecting one of
JB 1 or JB 2.
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4. 4.
Telemetry“ - Displays selected, connected telemetry sensor
information.
The user blocks can be either standard or double size. Double sized
blocks obviously use up more of the desktop. In return, some of
them display more data while others display the same data in a
larger font.
Custom blocks can be linked to flight modes. This means that you
can set up different groups of blocks for each flight mode creating a
completely different desktop appearance from one flight mode to
another.
Trim - Displays the position of the digital trims.
Note: When the trims are displayed on the main screen, the special
Trim Screen no longer appears when any trim button is pressed.
1. Creating a new user block
In the “Displayed Telemetry” menu, press the “F3(Add)” button to
add a blank user block to the list. Using the “3D button” change the
first item of the new block’s line to the type of block you want to
create. Next, in the second line item, select whether you want the
new block to be double size (yes) or not (no).
2. Change the User Block order
Using the „3D button“ highlight your selected user block in the list.
Use the „F1“ and „F2“ buttons to move your selected block up or
down the list.
3. Deleting a User Block
Use the „F4(Del)“ button to delete the selected user block from the
list.
4. How the User Blocks are Displayed
The right end of the first line in the „Displayed Telemetry“ menu
displays a symbol to indicate if the list of user blocks is displayed for
all flight modes or just the current flight mode. If the „G (Global
symbol)“ is displayed then the all of the listed user blocks are
displayed in all of the flight modes. This means that when you
change flight modes, your desktop display will not change. If the „S
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4. 4.
(Separate symbol)“ symbol is displayed then the current list of user
blocks are only displayed in the current flight mode. This means that
when you change your flight modes, the desktop display will also
change. When using separates you must create a user block list for
each flight mode. You can change from Global to Separate by
highlighting the first line and pressing the „3D button“.
9.4.7 Main Screen
This page displays additional desktop options.
Switches can be used to flip pages on the main screen. You can
assign two separate switches – the first one will always flip to
previous page, the second switch will jump to the following page.
You can also use any of the integrated accelerometer gestures (DS-
14/16 only) to scroll through various telemetry screens.
Telemetry displayed at clock panel
Here is where you can select one telemetry parameter, which will
appear at location of the digital clock on the top bar of the screen.
This way you can select eg. displaying the instant current draw from
the batteries, which is very helpful when balancing different servo
travels.
Setting the display of the telemetry data on the top menu
bar of the screen is saved as a part of the model
configuration and it is displayed again when the
transmitter is switched on. It is possible to select any
simple numerical telemetry value, except GPS
coordinates.
Note:
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9.5 Applications
This menu displays some of the special applications within the
DC/DS. (*depends on equipment)
9.5.1 Data Analyzer (* depending on equipment)
This function allows you to view telemetry log files after each flight.
You don’t have to take your PC to the airfield and download the data
anymore. The analyzer is able to display up to three variables
simultaneously in a graph with one variable displayed. The variables
will alternate each time you press the F(5) 1/2/3 button while the
graph is displayed.
To view any logged telemetry
data, open the Data Analyzer
main window which is located
under Applications menu item
(see picture ). Highlight a row a)
beneath Select LOG file and press
the rotar y button. Browse
through the contents of the SD
card and locate the desired file
(pictures and ). All files are in b)c)
order by date and time, so it is
easy to find the latest record. After
the appropriate file has been
selected, you will be redirected
back to the screen a). There you
can select up to three variables
that will be alternately displayed
in the graph.
By pressing the F3 Del." button
while browsing the log directory
you are able to delete any log file
and even directory.
After pressing the button F4",
resulting graph is displayed. The X
axis presents time domain,
starting always at zero seconds.
The Y axis shows the values of the measured parameter from its
calculated minimum to maximum. The Y axis has a dynamic range
according to the actual values.
For convenience here is the list of available controls:
You can scroll through the timespan of the log file quickly using
the and buttons. F1" F2"
You can also view the timeline at an increased speed on
demand - just turn the rotary button to the left or to the right to
move the timeline. After pressing the Menu button (or the rotary
button itself), the timeline will begin moving with larger steps.
4. 4.
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F3 “Zoom In” F4“Zoom Out” and decreases or increases the
timespan of the whole graph.
"F5" 1/2/3 button toggles between the variables that have
been selected on the .screen a)
You cannot display a log file which is currently being written to. To
view the most recent file, you should stop logging and clear the
flight using F(5) Clr button on the main screen. After that you can
open the file in Data Analyzer.
Note:
9.5.2 Audio Player (* depending on equipment)
This menu lists all of the audio data stored on your transmitter’s
internal memory.
The available audio files are stored in the Audio folder. Use the „3D
control“ to access and scroll through the Audio folder contents. The
function keys provide playback control: „F1 (Esc)“, „F2 (Play)“, „F3
(Stop)“, „F4 (Vol -)“ and „F5 (Vol+)“.
Audio files are supported in *.wav format.
9.5.3 JETIBOX
For maximum compatibility with 1st generation JETI DUPLEX, the
DC/DS are equipped with a JETIBOX emulation function. This
emulation shows its information in the legacy two-line display
format. Use the function keys to navigate the JETIBOX menu in order
to view or change the individual parameters. You can use also
wirelessly access a bound receiver’s menu and/or any connected
telemetry sensors connected to the receiver.
4. 4.
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9.5.4 Games
Here you can find several simple games for fun and relaxation.
- Snake
- Tetris
- Gomoku
- Chess
9.6 System
- Use this menu to configure the system functions of your
transmitter. All of the settings in this menu are global and do not
9.6.1 Configuration
Basic transmitter settings
1
2
3
4
5
6
8
9
10
7
11
12
4. 4.
13
14
change when you
switch between
models.
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Language Setting1.
Use this menu to select the transmitter’s language setting.
All of the transmitter’s text and sounds will be changed based upon
your selection.
4. 4.
After changing the transmitter’s language you need to
turn the transmitter off and back on for the change to
take effect.
Warning:
2. User Name
Enter the user name that you want to appear in the User block on the
desktop.
3. Stick Mode
The transmitter supports Modes 1-4. To change the stick mode you
can either use the „3D button“ to highlight and select the line item
or simply press the „F3“ button. Either will take you into the Stick
Mode menu. Use the „F1-F4“ buttons to make your selection and
then press the „F5(Ok)“ button to confirm. The mode change will
only be effective for new models. All of your stored models will retain
their existing stick modes.
4. Sound Profile
This item allows you to select the sound profile for your transmitter.
This determines how your transmitter will audibly communicate
with you. You can select: quiet (mute), beep only, beep and voice
(sound file) or voice (sound file) only.
5. Date and Time
Here is where you set the current date and time. The DC/DS will
automatically observe the time change for Daylight Saving Time.
The time and date information is used when creating new models
and for telemetry.
6. Distance units
This menu item allows you to select the distance units for your
telemetry display. All telemetry data is automatically converted to
your selected units for display.
7. Temperature units
This menu item allows you to select whether your temperature data
is displayed in Farenheit or Celcius.
8. Transmit frequency
Says how often the stick positions will be refreshed. Please check the
settings of your receivers prior setting this option to 100Hz. The
Output Period should be set to "Auto" and maximum of 3 servo
groups (A, B, C) should be used. In other cases, the refresh rate will be
applied according to receiver settings.
9. Disable Startup Question
This menu item disables the question/confirmation during startup.
(see Chapter 6)
10. Reverse Menu navigation
This menu item allows you to reverse the direction that the „3D
control“ scrolls through the menus.
11. Rolling Menu (up&down)
If this option is set to No, the ability to scroll from the last item in the
Use only digital servos that can handle 100Hz refresh
rate.
Warning:
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menu directly to the first one will be disabled (and vice versa from
the first row to the last).
12. Screenshot Capture Switch
This feature gives you the ability to create your own screenshots.
After you activate the switch, a bitmap is created in the root folder of
the SD card. You can create up to 1000 screenshots.
13. PPM connector settings
This option presents the possibility to configure the internal
connector labeled as PPM Output (please refer to the chapter 3.7
PPM Output Connector):
- Off the connector output (pin No. 4) will not generate any kind of
signal.
- PPM Positive the connector output (pin No. 4) will generate
standard eight-channel PPM signal with positive pulses.
- PPM Negative the connector output (pin No. 4) will generate
inverted eight-channel PPM signal with negative pulses (0V level).
- EX Data Stream – the connector output (pin No. 4) will generate a
digital data stream containing EX telemetry. The format of
transmitted sensor/receiver data is described in the document JETI
Telemetry Communication Protocol. The communication is
unidirectional and cannot be used to configure the transmitter or
any linked device. If you connect the RCDroidBox device to the
transmitter, you will need to set this option.
14. Check signal before flight
It is possible to check the signal strength immediately after the
model is turned on and connected to the transmitter. If you set Yes
for this option, a warning message is generated for antenna signal
levels less than 8. To make this function work correctly, you should be
4. 4.
located a distance of up to several meters from the model at the
moment of switching it on. If the message is still present, please
perform a range test and check the installation of the on-board
electronic equipment.
9.6.2 Servo & Range Test
This menu allows you to perform a range test and servo tests.
During the servo test it is possible to send the test output to all of the
channels which are active in the current model setup. The servo
speed item allows you to adjust the travel time for the servos during
the servo test. During the test, the servos will only be driven to their
programmed maximum throws. You can select which servos will be
included in the test.
1
2
34
5
6
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4. 4.
1. Servo speed
This menu item allows you to adjust the servo travel speed for the
servo test.
The time shown is the time that it will take for the servo to move from
one travel extreme to the other.
Note: A servo will only move to it’s programmed maximum throw.
2. Servo Number
Use the “3D Control” to select which servos will be included (check
mark) or not included (X) in the servo test.
3. Starting the Servo Test
Press the “F3 (Start)” button to start the test for your selected servo
outputs.
Once started, the servo test will continue to run even if you exit the
menu.
You must stop the servo test before you can change any of the test
settings (speed, output channel).
4. Stopping the Servo Test
Press the „F4 (Stop)“ button to stop the servo test.
5. Display Receiver Outputs
Press the „F2 (Servo Monitor)“ button to see the outputs being sent
to your selected receiver channel.
6. Range Test
This menu line allows you to set the transmitter output to its range
test mode.
See the receiver instructions for how to set the receiver to its range
test mode.
9.6.3 View Inputs
This menu allows you to view input from the transmitter sticks,
switches and knobs as detected by the transmitter software. This
menu also contains a wizard to guide you through calibrating your
transmitters proportional controls.
It is recommended to calibrate your proportional controls when:
You change from modes 1-2 to modes 3-4
The proportional controllers do not move to the extremes of the
graphic display
1. Calibration of Proportional Controls
Press the „F1 (Calib)“ button. You will be asked if you really want to
perform the calibration. Press the „F5 (Yes)“ button to confirm.
Follow the onscreen directions: Move all of the proportional controls
slowly to their maximums a few times and return them to their
centered positions. Press the „F1 (Calib)“ button again to finish
calibration. You will be taken back to the View Inputs (1/2)“ screen.
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4. 4.
2. Proportional Input Display
The „Display Inputs (1/2)“ screen displays the currently detected
position of each proportional control.
3. Switch Status Display
Press the „F3“ button to show the View Inputs (2/2)“ screen.
This screen shows the type and currently detected position of the
transmitter’s switches. Use the „3D control“ to select and edit any
of the displayed switches. The „Sk“ and „Sl“ switch positions are
reserved for the switches that can be mounted into the ends of your
transmitter sticks.
9.6.4 Receiver Output (Servo Monitor)
This menu displays the receiver output channels being generated by
the transmitter. You can press the „F3“ button to see your
programmed receiver output function names and their current
output as a percentage. If you have modified the „Channel Set“ or
„Pin-Out Setting“ of your Duplex receiver then the displayed receiver
output channel numbers may not be accurate. If, however, your
Duplex receiver still has its default channel settings then this list will
be accurate.
9.6.5 System Sound
This menu allows you to assign any available sound file to the system
events.
-Start-Up - associated file is played when the transmitter is turned
on.
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-Receiver Bound - Assigned file is played after the receiver is turned
on and communication with the transmitter is established.
-Low TX Voltage - optional file with a warning at low transmitter
voltage. You can also set an adjustable voltage level which says when
the alarm will be activated.
-Low Signal - an optional file with a warning at low signal level. The
file is played when the signal level of both antennas falls below a
number specified in the parameter "Value".
-Signal Loss - the associated file is played after signal from the
receiver is lost.
-Range Test - the associated file is played repeatedly in the "Range
Test" mode.
-Autotrim Active - the associated file is played repeatedly when the
Autotrim function is active.
9.6.6 Sound Volume
Here you may select volumes for each part of the audio system
individually. You are also free to assign any proportional control
(stick or knob) for adjustment. The first row represents a master
volume for the transmitter. Other volumes are then derived relative
to this value.
Beep Volume controls volume of beeping and trimming.
Vario Volume intensity of vario tone signalising.
Playback Volume – volume of played WAV files (Alarms, Audio
Player and Sound on Event).
Stop Playback Switch – after activating the assigned switch (in
the picture Sj), all currently played WAV files are being stopped. This
doesn’t influence any further playback.
9.6.7 Installed Modules
This summary table is used to quickly view
all the modules available in the transmitter.
It is possible to determine whether the
feature is enabled or disabled (indicated by
tick, respectively crossing). You'll also find
the number of elements useful for active
modules and maximum values that are
available for purchase as expansion packs.
The DC-16 and DS-16 transmitters in their
basic version have all the modules
activated on maximum possible values.
With the DS-14 transmitter it is possible to
take advantage of the system that enables
purchasing of the extended functions on
swshop.jetimodel.com.
4. 4.
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4. 4.
9.6.9 USB
This menu allows you to establish communication between your
DC/DS and a PC once you have connected the two with a USB cable.
How to connect your DC/DS to a PC:
1. Manually enter the menu: „Menu, >System, >USB“
2. When prompted, connect your transmitter and the PC with a
USB cable.
Leaving the menu disables the connection.
Note:
9.6.10 Info
This menu displays information about your DC/DS such as: product
name, firmware version, available memory, etc. Press the „F5 (Ok)“
button to exit this menu.
9.6.8 Limitations in copying models between transmitters
When copying models from one transmitter to another one, it is
necessary to bear in mind that the transmitters may not have the
same software equipment. Thus it is possible that the configuration
of the activated modules may not correspond. In this case it is
necessary to check individual features of the model. Loading the
model memory to a different transmitter with different activated
modules can be carried out, but according to the use of individual
modules the transmitter can display warnings or does not allow
loading the model. The table (9.6.8) shows the conditions under
which a warning message will be displayed indicating that the
model will be loaded in a limited form, or will not load at all.
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Module
Warning message
Possibility of
loading with
module not
activated
Accelerometer
-
YES
Double Path
If the Double Path mode is activated (menu Advanced Properties -
>Wireless Modes/Trainer)
NO
Data analysis
-
YES
Audio player
-
YES
Voice output
If any control starting the voice output is assigned (Timers/Sensors -
>Voice Output)
YES
Servobalancer
If any check point of the servobalancer has a non-zero position on the Y
axis (menu Model->Servo setup)
NO
Function curves
If a different curve type than „Standard“ is selected in the menu Fine
tuning ->Function Curves
NO
Throttle limiter
If a control is assigned in the menu Fine tuning ->Throttle Limiter
NO
Vario
If the vario indication mode (Timers / Sensors->Vario) is not in the Off
state.
YES
Number of channels
If an output of any function in the menu Model->Servo Assignment is
assigned to the transmitter channel that is not activated.
NO
Flight modes
If the number of flight modes of the model is higher than the number of
flight modes in the transmitter.
NO
Free mixes
If the number of free mixes used in the model is higher than the number
of free mixes available in the transmitter.
NO
Logic switches
If the logic switch is activated in the position that is not available in the
transmitter.
NO
Device explorer:
Number of remote
commands
If the number of registered commands in the model is higher than the
number of commands available in the transmitter.
YES
Sequencer
If the trigger switch is assigned to a sequencer that is unavailable in the
transmitter.
NO
Timers
If the number of timers in the model is higher than the number of timers
available in the transmitter.
YES
Values on display
If the number of values on display in the model configuration is higher
than the number of values available in the transmitter.
YES
Event sounds
If the number of event sounds in the model is higher than the number of
event sounds available in the transmitter.
YES
Alarms
If the number of active alarms in the model is higher than the number of
alarms available in the transmitter.
YES
Gyro settings
If the number of active gyro functions in the model is higher than the
number of functions available in the transmitter.
NO
Functions
If the number of model features in the model configuration is higher than
the number of features available in the transmitter (menu Model-
>Functions Assignment)
NO
Telemetry controls
If the telemetry control is activated on the position that is not available in
the transmitter (menu Advanced Properties->Telemetry Controls)
NO
The table 9.6.8 - Limitations in copying models between transmitters
4. 4.
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4. 4.
9.7 Throttle Lock
Throttle lock is an important safety feature incorportated in your
DC/DS transmitter. This feature effectively "locks" the throttle
channel output leaving it at the last output value so that if your
motor is stopped, it cannot start accidentally. To activate/deactivate
the throttle lock go to the „Main Menu“ and then press the „F1
(lock/unlock)“ button. You will see the small padlock icon change
to indicate the lock/unlocked condition. Additionally, when the
throttle is locked, you will see a padlock icon appear in the center of
the top bar of the desktop.
Use the throttle lock whenever you are handling a model
whose power system is active to eliminate the chance of
accidental activating the throttle and unexpected starting
of the motor.
Hint:
This menu allows you to select your desired input control device
(switch, knob, stick or logical switch) for a given function. This menu
will appear any time you edit an input control device seletion. In this
menu you can also assign/edit how a control device functions. You
can set the control device to have two types of proportional output
or just a simple ON/OFF function. From this menu you can also
reverse the control devices functional direction.
9.8 Select Input control
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1. Switch Assignment
When the menu appears, you can either press the „F1 (Log)“ button
to select/edit a logical switch for your function or you can simply
move the stick, switch or knob that you want to use to control the
function. When you move the chosen control device it will be
recogized and assigned to your function. The control device name
and current status is displayed. Once the control is activated you can
use the function buttons to configure the control device.
Think about what position/direction that you want the
control to work and move the stick, switch or knob into
position before you enter the assignment menu.
Hint:
2. Proportional Settings
Press the „F2 (Prop)“ button to make the selected device control
have either proportional or non-proportional control input. This
setting will not be available for all control devices.
For example, you have selected a 3-positon switch for your airbrakes.
If you select:
Non-proportional The brake can have only two positions.
Proportional The brake can have up to three positions.
3. Reversing
Press the „F3 (Rev)“ button to change the control device activation
direction.
This will not reverse the output direction of your function. It will
simply reverse the direction of the control device (stick,
switch,knob).
4. Removing the Switch Assignment
Press the „F4 (Clr)“ button to clear (remove) the selected control
device from your function. You can then select another control
device if you wish or press the „F5 (Ok)“ button to return to your
function’s menu without assigning any control device.
Once you are happy with your control device seletion and
configuration, press the „F5 (Ok)“ button or the „3D control“ to
confirm.
5. Selecting other sources
You can take advantage of several control types that are available in
the dialogue for selecting the control input (press F1 F4 buttons to
browse through different types of inputs):
P1 P8 Physical proportional sticks and proportional
controls.
4. 4.
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4. 4.
Sa Sl Physical configurable and replaceable switches. 1)
L1 L16 Logical switches. 2)
MAX Logical maximum, can be configured as a switch
that is always in an on-state.
GX, GY, GZ Individual, independent axis of the built-in
accelerometers (not available for DC-16). 2)
G/L, G/R Virtual controls switched on at the moment the
transmitter is shifted to the left, or respectively to
the right (not available for DC-16). 2)
GXL, GXR Virtual controls switched on at the transmitter tilt to
the left, or resp. to the right
(not available for DC-16). 2)
Q1 Q6 Individual sequencers. 2)
Tr1 Tr6 Digital trims as individual controls.
CH1 CH8 Channel inputs of the PPM signal lead that is
attached to the internal connector.
MX1 MX8 Telemetry control inputs. 2)
1) Configuration of the switches depends on the type of transmitter and also on which
switches they are installed.
2)Controls are available depending on the equipment of the transmitter.
Preview of the individual screens of the dialogue for
selecting control input c)
d)
a)
b)
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4. 4.
PPM input
The transmitter can handle up to 8 channels of the PPM input signal
(please refer to the chapter 3.7 PPM Input/Output Connector). The
signal should be present on the pin No. 1. To prevent any damage,
you need to use the 3V logic level and protective elements on the
input.Throughout the model settings you can assign any of the PPM
channels to any function of the transmitter. The PPM input is not
linked with the trainer system in any way and works separately. It is
possible to use the PPM input in cooperation with head-tracking
systems etc.
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This menu displays the current trim settings. You can access this
menu from the desktop by either pushing the „3D control“ or by
simply pushing one of the trim buttons. In this menu, you can press
the „F1 (Back)“ button to exit or push the „F5 (Auto)“ button to
activate the Automatic Trim feature.
9.9 Trim Menu
When the Automatic Trim is activated, the trim is automatically set
based upon your flight stick positions. The farther the stick
defection, the faster the trim value is set in that direction. During
the auto-trim process you still have normal control of your model.
4. 4.
This chart displays how the transmitter
output functions are processed and at
what point the various configuration
choices affect the output function.
9.10 How Transmitter Output Functions
are Processed
When you move a control device (top
block), the output function will move
according to its programmed function
curve „Menu, >Fine Tuning, >Function
C u r v e s “. A t t he s a me tim e a ny
programmed delay is also applied.
Fo llowing this, any prog rammed
exponential is applied and then any dual
rate limits are also applied. The next step
applies any mixes and/or programmed
flight modes to the output function. Now,
any servo setup configuration items (end
point, subtrim, reversing, etc.) are
implemented and then any trims or flight
mode trims are applied to the channel’s
output function.
Control Device
Flight Function Curves
Dual Rate – Exponential
Mixes
Servo Setup
Channels
Dual Rate – Throw
Trims
Flight
Mode
Trims
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10 Transmitter to PC Connection
The JETI Duplex line of transmitters are equipped with a mini USB
port. The Transmitters also come with a standard USB to mini USB
cable which is used to connect your transmitter to a PC. The JETI
Duplex system is fully compatible with Microsoft Windows XP and
higher versions of Windows OS. After connection and confirmation
your transmitter will be identified by the PC as another memory
drive. While it is connected to a PC your transmitter‘s battery is also
being charged via the USB port.
After your transmitter has been connected to a PC it will behave like
standard external hard drive. Your transmitter’s file directory is
displayed on the PC screen. Pay close attention to moving, deleting
or adding files to any open file directory, any changes performed
here have a direct effect on your transmitter‘s internal data
File Directory
Audio sounds, music, and acoustic warnings
Config software configuration
Lang language configuration
Log telemetry data, all files use date stamp year/month/day
Manual instruction manual
Model programming files of individual models
Update directory used for software updates
Voice audio samples for speech synthesis
Devices device definitions used for communication with
intelligent devices based on EX Bus protocol
The JETI Duplex line of transmitters fully support future software
updates. We recommend that you check the distributors and/or
manufacturer‘s web sites frequently for the most current update.
How to update your transmitter’s firmware:
1. Connect your transmitter to a PC via USB port
2. Confirm the connection
3. On the PC screen, open the partition of the transmitter and
extract the contents of the update file (*. Zip) to the root folder.
Confirm "overwrite existing files" if prompted.
4. After the successful data transfer, disconnect your transmiter
from the PC USB port and turn OFF the transmitter. The next
time that you turn your transmitter ON, the software will be
updated.
With any new firmware update no model setups or configuration
settings will be lost. For safety, after performing a new update, we
highly recommend that you check all functions, assignments,
configurations, and model mixes. A list of new features is always
released with the firmware update.
At this time, the JETI firmware supports *.wav sound files. Any
sound file can be assigned to any function, switch, flight mode,
telemetry alarm, or music routine. Your applications are limited only
by your imagination. All sounds must be copied to the Audio” file.
10.1 Memory & System Files
10.2 Update firmware
10.3 Sounds, Alarms & Acoustic Updates
5. 5.
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10.6 Telemetry Data Logging
10.4 System Backup
Data backup is as easy as the standard backup you can perform on
your PC. You can save all your data onto a PC hard drive or CD. The
saved data will, of course, reflect your last transmitter configuration
and model settings. The data recovery is as easy as copying your
backed up files back to the transmitter.
DC/DS transmitters can be very simply used as a joystick interface for
your PC. Connect your transmitter to a PC with the USB cable. Your
operating system will identify the transmitter as an HID (Human
Interface Device) gaming device.
All telemetry data is stored on the internal SD card in the “Log”
directory file. Telemetry data files are easily identifiable as .log files.
The data files use date stamps with the “year/month/day
configuration. Flight logs can be viewed on the PC using the JETI
“Flight Monitor software.
10.5 PC Joystick
5. 5.
10.7 Copying models between the transmitters
Configuration of all models in the transmitter are stored on the
internal SD card in the directory /Model/. When you copy the
selected model from one transmitter to another, simply copy the
*. jsn file again to the /Model/ directory of the second transmitter.
It is important to bear in mind that the two transmitters
may not have the same software equipment, so it is
possible that the configuration of the activated modules
will not match each other. In this case it is necessary to
check the individual functions of the model, since an
attempt to load the model by another transmitter may end
up with error message.
Note:
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11 Battery Safety Handling Rules
11.1 Transmitter Battery Pack
1. The Installed battery pack must be charged from an AC voltage
source using only the included wall battery charger. The included
adapters work with local utility services, each country might be
supplied with a different type of charger.
EU: SYS1428-2412-W2E
UK: SYS1428-2412-W3U
US: SYS1428-2412-W2
Do not use any battery other than the manufacturer approved
Power Ion 3200 DC battery pack.
2. Always verify the correct polarity while connecting a
transmitter battery pack. The red lead is positive “+” and the black
lead is negative “-“ polarity.
3. Never test a battery pack by shorting the wire leads. Do not
allow the battery to overheat at any time.
4. Never leave your transmitter unattended at any time while it is
being charged.
5. Never charge an overheated battery pack, or in an
environment warmer than 158 F (70C).
6. During cold months always check the battery‘s capacity, do not
rely on your radio’s low battery warning system.
7. Always check your transmitter and receiver batteries prior each
flight. Do not rely on your radios low battery warning system.
8. Do not allow radio battery pack to come in contact with open
flame, other heat source or moisture at any time.
2. For any of the upgrades which require removing the radio back
cover you MUST disconnect the transmitter battery pack before
attempting any work.
3. It is imperative to store your radio in a controlled environment.
Any extreme temperatures can cause damage to the sensitive
electronics. A sudden change in temperature or humidity can create
condensation which can permanently damage your radio.
4. Do not use radio during poor weather conditions. Any water or
condensation can cause corrosion and could permanently disable
your radio. If you suspect that moisture has entered your transmitter,
turn it OFF, remove the back cover and let dry it out.
5. Avoid use in dusty environments.
6. The manufacturer is not responsible for any unauthorized
modifications. Changes or modifications not expressly approved by
the party responsible for compliance will void the users authority to
operate the equipment.
7. This is a sophisticated hobby product and not a toy. It must be
operated with caution and common sense, always avoid any
mechanical damage.
8. Always avoid operating close to devices that might cause
harmful electromagnetic interferences.
9. Keep all moving parts clean and free of dust or fine debris that
might damage the mechanical parts of the radio.
1. Any repair, installation, or upgrade must be
performed with caution and common sense. These will
require some basic mechanical skills.
11.2 General Safety Rules
5. 5.
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10. Do not point the transmitter antenna directly towards your
model or a human body. The radiation pattern from the antenna will
be shielded and provide poor connection to your model.
11. Never repair, re-install, or exchange the internal memory SD
card for other type.
12. Avoid extreme temperatures as they can cause damage to the
sensitive internal SD card.
13. Always perform a ground range check prior to your initial flight.
11.3 Flight Safety Check
1. Always verify the correct position of the switches, and the
gimbals, prior turning ON your transmitter. Turn on the transmitter
first, then receiver. JETI transmitters use "Model Checking". This
safety is designed so that the model memory stores the unique serial
number of the receiver that has already been assigned to model.
When the transmitter establishes communication with the receiver
and the serial number does not match the number stored in the
current model’s setup, the transmitter displays a warning. You will
then be able to accept the change or reject the change. If you accept
the change, the transmitter stores the new receiver number into the
model’s setup and begins transmitting. If you reject the change, the
transmitter will not communicate with the receiver and you will be
allowed to select another model.
2. Perform a ground range check before each days flying session.
3. Check the battery voltage on both the transmitter and the
receiver battery packs.
4. Check all channel assignments, trim, mixes, and the correct
5. 5.
This product may be used for model airplane or surface (boat, car,
robot) use only. It is not intended for use in any other application
than control of the models for hobby, sport and recreational
purposes.
11.4 Application
direction of movement for your flight surfaces.
5. Set motor/engine kill switch and test the power train.
This equipment has been tested and found to comply with the limits
for a Class B digital device, pursuant to Part 15 of the FCC Rules.
These limits are designed to provide reasonable protection against
harmful interference in a residential installation. This equipment
generates, uses, and can radiate radio frequency energy and, if not
installed and used in accordance with the instructions, may cause
harmful interference to radio communications. However, there is no
guarantee that interference will not occur in a particular installation.
If this equipment does cause harmful interference to radio or
television reception, which can be determined by turning the
equipment off and on, the user is encouraged to try to correct the
interference by one or more of the following measures:
Reorient or relocate the receiving antenna.
Increase the separation between the equipment and receiver.
Connect the equipment into an outlet on a circuit different from
that to which the receiver is connected.
Consult the dealer or an experienced radio/TV technician for help.
11.5 FCC /IC information
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5. 5.
THIS DEVICE COMPLIES WITH PART 15 OF THE FCC RULES.
OPERATION IS SUBJECT TO THE FOLLOWING TWO CONDITIONS(1)
THIS DEVICE MAY NOT CAUSE HARMFUL INTERFERENCE, AND (2)
THIS DEVICE MUST ACCEPT ANY INTERFERENCE RECEIVED,
INCLUDING INTERFERENCE THAT MAY CAUSE UNDESIRED
OPERATION.
Warning: Changes or modifications to this device not expressly
approved by Esprit Model/JETI USA could void the users authority
to operate the equipment. “This equipment complies with FCC
radiation exposure limits set forth for an uncontrolled
environment. This equipment is in direct contact with the body of
the user under normal operating conditions. This transmitter
must not be co-located or operating in conjunction with any other
antenna or transmitter.
Under Industry Canada regulations, this radio transmitter may only
operate using an antenna of a type and maximum (or lesser) gain
approved for the transmitter by Industry Canada. To reduce
potential radio interference to other users, the antenna type and its
gain should be so chosen that the equivalent isotropically radiated
power (e.i.r.p.) is not more than that necessary for successful
communication.
Conformément à la réglementation d'Industrie Canada, le présent
émetteur radio peut fonctionner avec une antenne d'un type et d'un
gain maximal (ou inférieur) approuvé pour l'émetteur par Industrie
Canada. Dans le but de duire les risques de brouillage
radioélectrique à l'intention des autres utilisateurs, il faut choisir le
type d'antenne et son gain de sorte que la puissance isotrope
rayonnée équivalente (p.i.r.e.) ne dépasse pas l'intensité nécessaire
à l'établissement d'une communication satisfaisante.
This device complies with the Industry Canada license-exempt RSS
standard(s). Operation is subject to the following two conditions: (1)
this device may not cause interference, and (2) this device must
accept any interference, including interference that may cause
undesired operation of the device.
Le présent appareil est conforme aux CNR d'Industrie Canada
applicables aux appareils radio exempts de licence. L'exploitation
est autorisée aux deux conditions suivantes :
(1) l'appareil ne doit pas produire de brouillage, et (2) l'utilisateur
de l'appareil doit accepter tout brouillage radioélectrique subi,
même si le brouillage est susceptible d'en compromettre le
fonctionnement.
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5. 5.
12 Model Menu – Airplane/Sailplane
Butterfly/Crow mixing is available with wing configurations of 2
aileron servos or more.
You can find the Butterfly menu in “Fine Tuning, >Butterfly”.
12.1 Butterfly Mix (Crow Mix)
a. Switch assignment for butterfly mix function
b. Delay of deployment or retraction function
c. Flight mode setting configuration
d. Aileron/flap travel settings
e. Elevator settings
f. Butterfly tuning
Programming can be set according to specific wing and tail type
configurations. For example if your model has “Wing Type: 2
Ailerons” and standard tail configuration, the Butterfly function can
be setup to raise the ailerons (spoilers) and also to raise the elevator
(compensation).
Aileron Differential is available with wing configurations of 2 ailerons
servos or more.
You can find the Aileron Differential menu in “Fine Tuning, >Aileron
Differential”.
12.2 Aileron Differential
a. Flight mode setting configuration
b. Aileron „Up“ travel setting
c. Aileron „Down“ travel setting
The aileron differential function reduces the downward travel of the
aileron(s) to help eleminate any adverse yaw tendencies in rolling
maneuvers. Semi-Symmetrical airfoils with an aileron in the down
position induce higher drag than when the aileron is in the up
position.
ab
d
f
e
cc
b
a
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The ailevator function uses two servos for the elevator channel. Both
sides can be programmed to be controlled independently.
If you have this selected as your model’s tail type, you can find the
Ailevator menu in “Fine Tuning, >Ailevator”.
12.3 Ailevator
a. Flight mode setting configuration
b. Elevator travel setting
c. Aileron travel setting
Your model’s roll sensitivity is significantly greater with this mix.
To disable the mix, set your „Aileron“ throw to zero. This will cause
both elevator surfaces to move only when the elevator stick is
moved.
The V-Tail mix function uses two tail servos to control both the
elevator function and the rudder function. See chapter 9.2.8
If you have this selected as your model’s tail type, you can find the V-
Tail menu in “Fine Tuning” -> V-Tail”
12.4 V-Tail Mix
a. Flight mode setting configuration
b. Elevator travel setting
c. Rudder travel setting
5. 5.
c
b
a
c
b
a
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The Delta/Elevon Mix uses two servos for the control of both the
elevator and aileron functions. This mix is most commonly used for
Delta type aircraft.
If you have this selected as your model’s tail type, you can find the
Delta/Elevon menu in „Fine Tuning, >Delta/Elevon“.
12.5 Delta/Elevon Mix
a. Flight mode setting configuration
b. Elevator travel setting
c. Aileron travel setting
For models equipped with spoilers, the elevator is often used to
compensate for any pitching tendencies generated when the
spoilers are deployed. You can use one of the free mixers to set up
this compensation.
12.6 Spoilers to Elevator Mix
1. From inside the „Fine Tuning>Free
mixes“ menu, press the „F2 (Add)“ button
to create a new mix.
2. In the „From“ menu line, select the
“Spoiler” input function as the master
function and in the To“ line select the
“Elevator” for your slave function. The
“Master Value” represents the percentage
of elevator travel as it relates to the spoiler
travel. Press “F5 (Next)” to save the mix.
3. To edit the mix simply highlight the mix
and press the “F4 (Edit)” button to go into
the selected mixs advanced menu.
5. 5.
a
c
b
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4. When you press the “F4 (Curve)” button
you go directly to curve function menu
screen.
5. From the curve type options select
thex>0 type. Adjust the curve, if
necessary, so that the middle point is at the
50% output point (in the middle).
a. Flight mode setting configuration
b. Curve type icon
c. Switch assignment for the spoiler mix function
d. Delay for the mix function deployment or retraction
One of the most commonly used mixes for sailplanes, this mix
function will allow you to mix rudder function with your ailerons to
help your model have more coordinated turns. You can use one of
the free mixers to set up this mixing function.
12.7 Ailerons to Rudder Mix
1. From inside the „Fine Tuning, >Free
mixes“ menu, press the „F2 (Add)“ button
to create a new mix.
2. In the „From“ menu line, select the
Ailerons” input function as the master
function and in the To“ line select the
“Rudder” for your slave function. The
“Master Value” represents the percentage
of elevator travel as it relates to the spoiler
travel. Press “F5 (Next)” to save the mix.
3. To edit the mix simply highlight the mix
and press the “F4 (Edit)” button to go into
the selected mixs advanced menu.
5. 5.
a
b
c
d
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computer radio control system EN
a. Flight mode setting configuration
b. Curve type icon
c. Switch assignment for the spoiler mix function
d. Delay for the mix function deployment or retraction
One of the most commonly used mixes for 3D planes, this mix helps
to improve your control in knife-edge flight and while performing
other 3D aerobatics. You can use one of the free mixers to set up this
mixing function.
12.8 Rudder to Ailerons Mix
1. From inside the „Fine Tuning, >Free
mixes“ menu, press the „F2 (Add)“ button
to create a new mix.
2. In the „From“ menu line, select the
“Rudder” input function as the master
function and in the To“ line select the
Ailerons” for your slave function. The
“Master Value” represents the percentage
of elevator travel as it relates to the spoiler
travel. Press “F5 (Next)” to save the mix.
5. 5.
a
b
c
d
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3. To edit the mix simply highlight the mix
and press the “F4 (Edit)” button to go into
the selected mixs advanced menu.
a. Flight mode setting configuration
b. Curve type icon
c. Switch assignment for the spoiler mix function
d. Delay for the mix function deployment or retraction
The basic configuration of the butterfly mix (also known as crow) is
created by using ailerons, flaps, and elevator flying surfaces. The
Butterfly/Crow mix is helpful for maintaining speed during fast
descents and for creating controlled drag for spot landings.
Typically, this mix is set up so that the ailerons travel up, the flaps
travel down and the elevator is set to control any pitch changes.
You can find the Butterfly menu in „Fine Tuning, >Butterfly“.
12.9 Butterfly (Crow) Mix
5. 5.
ab
d
f
e
c
a
b
c
d
a. Switch assignment for butterfly mix function
b. Delay for the mix function deployment or retraction
c. Flight mode setting configuration
d. Aileron /flap travel settings
e. Elevator servo travel setting
f. Butterfly Tuning
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Another one of the most commonly used mixes for 3D planes, this
mix helps to improve your control in knife-edge flight particularly to
help with any coupling issues. You can use one of the free mixes to
set up this mixing function.
12.10 Rudder to Elevator Mix
1. From inside the „Fine Tuning, >Free
mixes“ menu, press the „F2 (Add)“ button
to create a new mix.
2. In the „From“ menu line, select the
“Rudder” input function as the master
function and in the To“ line select the
“Elevator” for your slave function. The
“Master Value” represents the percentage
of elevator travel as it relates to the spoiler
travel. Press “F5 (Next)” to save the mix.
3. To edit the mix simply highlight the mix
and press the “F4 (Edit)” button to go into
the selected mixs advanced menu.
a. Flight mode setting configuration
b. Curve type icon
c. Switch assignment for the spoiler mix function
d. Delay for the mix function deployment or retraction
5. 5.
a
b
c
d
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computer radio control system EN
This is also one of the more commonly used mixes for sailplanes.
Mixing flaps with your ailerons will increase you model’s aileron
response. You can use one of the free mixes to set up this mixing
function.
12.11 Aileron to Flap Mix
1. From inside the „Fine Tuning, >Free
mixes“ menu, press the „F2 (Add)“ button
to create a new mix.
2. In the „From“ menu line, select the
“Flaps” input function as the master
function and in the To“ line select the
Ailerons” for your slave function. The
“Master Value” represents the percentage
of elevator travel as it relates to the spoiler
travel. Press “F5 (Next)” to save the mix.
3. To edit the mix simply highlight the mix
and press the “F4 (Edit)” button to go into
the selected mixs advanced menu.
a. Flight mode setting configuration
b. Curve type icon
c. Switch assignment for the spoiler mix function
d. Delay for the mix function deployment or retraction
e. Output travel settings for the individual servos
5. 5.
e
a
b
c
d
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computer radio control system EN
This mix variation is used if your model is equipped with 4 flaps and
you want only the inner flaps (the set closest to the fuselage) to move
with the ailerons while leaving the outer flaps to be used only for
braking.
Except for the last step below, you will create this mix exactly as
described above. (See 12.11)
12.12 Aileron to Flap Mix (Brake Variation)
Set the „Mix Output“ for columns „S1“ and „S4“ to 0%. This
setting will not allow the „S1“ or „S4“ flaps to move with the aileron
mix function.
If your model is equipped with flaps you might want consider mixing
the flaps to the elevator. In some model designs this mix can improve
the elevator response. You can use one of the free mixers to set up
this mixing function.
12.13 Elevator to Flap Mix
1. From inside the „Fine Tuning, >Free
mixes“ menu, press the „F2 (Add)“ button
to create a new mix.
2. In the „From“ menu line, select the
“Elevator” input function as the master
function and in the To“ line select the
“Flaps” for your slave function. The
“Master Value” represents the percentage
of elevator travel as it relates to the spoiler
travel. Press “F5 (Next)” to save the mix.
5. 5.
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computer radio control system EN
3. To edit the mix simply highlight the mix
and press the “F4 (Edit)” button to go into
the selected mixs advanced menu.
a. Flight mode setting configuration
b. Curve type icon
c. Switch assignment for the spoiler mix function
d. Delay for the mix function deployment or retraction
e. Output travel settings for the individual servos
If your wing configuration has 4 flap surfaces and you only want the
outer flaps (the set furthest from the fuselage) to move with the
elevator with this mix then set the „Mix Output“ for columns „S2“
and „S3“ to 0%. This setting will not allow the „S2“ or „S3“ flaps to
move with the elevator mix function.
This is another popular sailplane mix. This mix allows you to
effectively change the airfoil of your model‘s wing by combining the
flaps and ailerons to lower the trailing edge (under camber) of the
wing. This helps to lower your flight speeds during landings or while
soaring. „Under camber“ is added to the wings when the flaps and
ailerons are deflected a little bit downward. Adding under-camber
means that the bottom surface of the wing becomes more concave.
To use this mix your wing configuration must be „2Ail“ or higher.
You can either use free mixer to set up this mix or you can use the
Butterfly mix. You can find the Butterfly menu in „Fine Tuning,
>Butterfly“.
12.14 Flaps Mix – Camber Control
a. Aileron servo travel settings
b. Flight mode setting indicator
c. Aileron differential adjustment
d. Flap servo travel settings
5. 5.
e
a
b
c
d
a
c
d
b
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computer radio control system EN
This safety feature is mainly for models using glow or gasoline
engines as their main source of power. Electric models can also
highly benefit from this safety feature. The Throttle Cut function can
be activated using any assigned switch, knob or stick. By editing the
“Output Value” item, the throttle output will move to the user
defined (completely off) throttle position once the assigned switch
is activated. When the Throttle Cut is active, your throttle stick has no
effect on the throttle output.
You can find the Throttle Cut menu in: Advanced Properties,
>Other Model Options, >Throttle Cut“.
12.15 Throttle Cut (Kill Switch)
This feature is used to set the idle position for your throttle and will
prevent your engine from shutting-off when you move throttle stick
to its low position. The minimum throttle setting is defined by
editing the “Throttle-Idle Offset value. When this function has
been activated, the minimum throttle setting (idle point) is defined
by the offset value as a percentage. Standard throttle function is not
affected by the idle offset setting. You can find the Throttle Cut menu
in: Advanced Properties, >Other Model Options, >Throttle Idle“.
12.16 Throttle Idle
5. 5.
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computer radio control system EN
13.1 Tray for DC/DS
13 Accessories for Transmitters
DC-Blue DC-Black
DC-Carbon Design
(PCD-3)
BracketBracket
Holder for transmitterHolder for transmitter
DC/DSDC/DS
Bracket
Holder for transmitter
DC/DS
Hand PadsHand Pads
for Pult PCD-2, PCD-3for Pult PCD-2, PCD-3
Hand Pads
for Pult PCD-2, PCD-3
13.2 Stick Ends for DC/DS
2 position switch3 position switch Button switch
Potentiometer Spare stick ends
13.3 Replacement switches
5. 5.
Switch nut spanner
DS-Blue
DS-Black
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13.4 Straps for DC/DS
Strap for DS
Strap for DC-16
Cross strap for DC-16
13.5 Charging
Car Charger
DC/DS
Charger
DC/DS
UK
US
EU
13.6 Other
Aluminum Case
Spare Battery
for for DC/DS
Blind Plug DC-16
USB-miniUSB cable
USB adapter
to update receivers
and other products
5. 5.
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computer radio control system EN
DS-14
DS-16
DC-16
New possibilities
charged
free of charge
free of charge
Channels
8 (up to 14)
16
16
Accelerometer
m
l
Secondary RF module in function:
teacher, double p.
m
l
l
Flight modes
3 (up to 6)
10
10
Free mixes
5 (up to 12)
20
20
Graphs
m
l
l
Audio player
m
l
l
Logic switches
0 (up to 10)
16
16
Number of remote commands
0 (up to 8)
16
16
Sequencer
0 (up to 3)
6
6
Timer
3 (up to 6)
10
10
Values on display
10 (up to 20)
40
40
Event sounds
5 (up to 10)
20
20
Alarms
10 (up to 20)
40
40
Voice output
m
l
l
Gyro settings
1 (up to 3)
3
3
Servo balancer
m
l
l
Function curves
m
l
l
Throttle limiter
m
l
l
Vario
m
l
l
Telemetry Controls
0
5
l
Number of control inputs
14 (up to 18)
16 (up to 18)
16 (up to 20)
Material of sticks
Polyamid
Aluminium
Aluminium
Resolution of sticks
4096
4096
4096
Hall sensors
l
l
l
Internal memory , SD card
4 GB
4 GB
4 GB
RF modules
2
2
2
Number of antennas
4
4
2
LCD backlight
3,8" 320x240 pixels
3,8" 320x240 pixels
3,8" 320x240 pixels
Weight [kg]
1,2
1,25
1,5
Dimensions [mm]
194x233x40
194x233x40
230x270x40
Transmitter Battery Pack [mAh]
Power Ion
1S2P 3200
Power Ion
1S2P 3200
Power Ion
1S2P 3200
Battery Charger
l
l
l
Receiver included
R9 EX BUS
Straps
l
13.7 Overview of the DS-14 expansion modules (transmitter equipment comparison)
5. 5.
m - The module is not included in the basic version
l - This function is available after purchasing the module
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computer radio control system EN
5. 5.
159
computer radio control system EN
5. 5.
160
computer radio control system EN
5. 5.
161
computer radio control system EN
5. 5.
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computer radio control system EN
JETI model s.r.o.
Lomená 1530, 742 58 Příbor
®
www.jetimodel.com

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