Futaba TMSS1-24G Radio Control Transmitter User Manual

Futaba Corporation Radio Control Transmitter

User Manual

6EX-2.4GHz
INSTRUCTION MUNUAL
for Futaba 6EX-2.4GHz
6-channel, FASST
Radio control system
for Airplane/helicopter
1M23N12014
Futaba Corporation
Technical updates available at: http://www.futaba-rc.com
Entire Contents © Copyright 2007
2
TABLE OF CONTENTS
Introduction ..........................................................................3
Service ..................................................................................3
Usage Precautions ...............................................................3
Contents and specifications ...............................................4
Glossary ................................................................................4
Introduction to the 6EX-2.4GHz system ............................5
Transmitter controls and descriptions ..............................5
Radio installation .................................................................7
Receiver and servo connections .....................................10
Charging the Ni-Cd batteries ............................................11
LCD and Programming controls ......................................12
Programming the T6EX-2.4GHz radio ..............................14
MODL Model select function ........................................14
MODL Model select function ..................................14
REST Data reset function .......................................14
ACRO/HELI Model type select function ................15
TRNR Trainer function ............................................15
Model name settings ...............................................16
REVR Servo reversing .................................................16
D/R Dual Rate and Exponential settings .................. 16
D/R Dual Rate settings ...........................................16
EXPO Exponentials ................................................17
EPA End Point Adjustments .........................................17
TRIM Trim Settings ......................................................18
FS Fail safe (Throttle channel only) .............................30
(ACRO functions)
PMX1 Programmable Mixer #1 ....................................19
PMX2 Programmable Mixer #2 ...................................19
FLPR Flaperon mixing .................................................20
FLTR Flap trim..............................................................20
V-TL V-tail mixing .........................................................21
ELVN Elevon mixing .....................................................22
(HELI functions)
N-TH Normal Throttle Curve ........................................24
N-PI Normal Pitch Curve ..............................................24
I-TH Idle-Up Throttle Curve function ............................24
I-PI Idle-Up Pitch Curve function .................................25
HOLD Throttle hold function ........................................25
REVO Pitch - rudder mixing function ...........................26
GYRO Gyro mixing function .........................................26
SW-T Swash to throttle mixing .....................................28
SWSH Swashplate types selection & Swash AFR ......28
Flow chart (ACRO) .............................................................31
Flow chart (HELI) ................................................................32
OtherT6EX-2.4GHz functions............................................33
Trainer function .............................................................33
Throttle cut function ......................................................33
Adjustable-length control sticks ...................................34
Changing the stick mode ..............................................34
Flying safety guidelines ....................................................34
Flight preparation ..............................................................35
Model Data Recording Sheets (ACRO) ............................36
Model Data Recording Sheets (HELI) ..............................37
3
INTRODUCTION
Thank you for purchasing the Futaba 6EX-2.4GHz FASST*1 digital proportional R/C airplane/helicopter system. If this is your
first “computer radio, rest assured that it is designed to make initial setup and field-tuning of your airplane/helicopter easier
and more accurate than would be if using a “non-computer” radio. Although this is a beginner or sport system with the
requirements of those flyers in mind, in order to make the best use of your Futaba 6EX-2.4GHz and to operate it safely, you
must carefully read all of the instructions.
*1FASST: Futaba Advanced Spread Spectrum Technology
Suggestion: If, while reading the instructions, you are unclear of some of the procedures or functions and become “stuck,
continue to read on anyway. Often, the function or procedure will be explained again later in a different way providing another
perspective from which to understand it. Another suggestion is to connect the battery, switch and servos to the receiver and
actually operate the radio on your workbench as you make programming changes. Then, you’ll be able to see the effects of
your programming inputs.
SERVICE
(in USA)
If any difficulties are encountered while setting up or operating your system, please consult the instruction manual first.
For further assistance you may also refer to your hobby dealer, or contact the Futaba Service Center at the web site, fax
number or telephone number below:
www.futaba-rc.com
Fax: (217) 398-7721
Telephone (8:00 am to 5:00 pm Central time Monday through Friday): (217) 398-8970, extension 2
If unable to resolve the problem, pack the system in its original container with a note enclosed and a thorough, accurate
description of the problem(s). Include the following in your note:
• Symptoms. Any unusual mounting conditions.
• An inventory of items enclosed. The items that require repair.
Your name, address, and telephone number. • Include the warranty card if warranty service is requested.
Send your system to the authorized Futaba R/C Service Center at the address below:
Futaba Service Center
3002 N Apollo Drive Suite 1
Champaign, IL 61822
This product is to be used for sport and recreational flying of radio-control models only. Futaba is not
responsible for the results of use of this product by the customer or for any alteration of this product,
including modification or incorporation into other devices by third parties. Modification will void any
warranty and is done at the owner’s risk.
(USA only)
Protect the environment by disposing of rechargeable batteries responsibly. Throwing rechargeable
batteries into the trash or municipal waste system is illegal in some areas. Call 1-800-8-BATTERY for
information about Ni-Cd battery recycling in your area.
USAGE PRECAUTIONS
1. Special attention must be paid before turning on the transmitter while other models are running or flying because the
2.4GHz system may affect them.
2. If there is a special regulation for using 2.4GHz radio systems at your flying site, please obey all regulations to enjoy safe
flying with your 2.4GHz system.
3. 2.4GHz is very different than the frequencies we currently use. Please keep the model in sight at all times as large
objects can block the RF signal. Please keep in mind that objects such as wire fences and wire mesh will also cause loss of
signal.
4. NEVER grip the transmitter antenna when flying as this degrades RF quality and cause loss of control.
4
Transmitter: T6EX-2.4G
T6EX-2.4GHz Transmitter of FASST system.
Transmitting on 2.4GHz band.
Operating system: 2-stick, 6-channel system
Power supply: 9.6V NT8F600B Ni-Cd battery
Current drain: 170mA
Receiver: R606FS
6 channel receiver of FASST system.
Receiving on 2.4GHz band.
Power requirement: 4.8V or 6V (shared with servo)
Current drain: 80mA (at no signal)
Size: 1.64x1.08x0.36” (41.6x27.5x9.2mm)
Weight: 0.34oz. (9.8g)
CONTENTS AND SPECIFICATIONS
Other components:
Switch harness
Instruction manual
*Specifications and ratings are subject to change without notice.
GLOSSARY
It will be helpful to understand the following terms before reading the rest of the manual. The terms are not in alphabetical
order, but are in a logical order that prepares the reader for understanding the next term.
Reversing (servo reversing) - A function that allows the user to determine the direction of response of each servo. If, after
hooking up the servos, a control on the model responds in the wrong direction, the user may change the servo's direction so
the control responds correctly.
Throw - When speaking of a control surface (such as an elevator or aileron), the throw is the
distance the surface moves. Control surface throw is usually measured at the trailing edge of
the surface and is expressed in inches or millimeters. The model in the diagram has 1/2" [13mm]
of up elevator throw. Throw can also refer to the distance a servo arm (or wheel) travels.
Dual rate (D/R) - On the 6EX-2.4GHz the dual rate switch allows you to instantly switch, in
flight, between two different control throws for the aileron, elevator and rudder. Often, different
control throws are required for different types of flying. (“Low” throws may be required for flying
at high speeds where the models response becomes more sensitive, and “high” throws may
be required for aggressive aerobatic maneuvers or landing or flying at lower speeds where the
model's response becomes less sensitive.)
End point adjustment (E.P.A.) - Sets the overall, maximum distance the servo rotates in either direction. (No matter where
the dual rates are set, the servo will never travel beyond the limit set by the end point adjustment.)
Exponential - Normally, servos respond proportionally to control stick input from the transmitter (e.g., if the stick is moved
halfway, the servo will move halfway). However, with “exponential, the servo can be made to move more or less than initial
stick movement (less servo movement is more common). Exponentials are commonly used to “soften, or decrease initial
servo travel for the ailerons, elevators and rudder. This way, initial control stick inputs from the pilot result in small servo
movement for a smoother flying airplane.
(Dual rates adjust the amount of servo travel. Exponentials determine where most of the travel will occur.)
Mixing - Two (or more) servos can be made to operate together either by mechanically joining the wires (with a Y-connector)
or by electronically “joining” them through programming functions in the transmitter. When servos are electronically joined via
programming, they are said to be “mixed. Unlike joining servos with a Y-connector, when servos are mixed electronically they
can be made to move in opposition. Additionally, each servo’s end points can be independently set.
5
INTRODUCTION TO THE 6EX-2.4GHz SYSTEM
IMPORTANT!: Always turn on the transmitter first, then the receiver. When turning off the system, always turn off the receiver
first. The object is never to have the receiver on by itself. Otherwise, the servos or control surfaces could be damaged, or in the
case of electric-powered models, the motor may unexpectedly turn on causing severe injury.
Transmitter
ACRO mode: External switches operate dual rates (D/R), landing gear, and trainer cord or “buddy-box” capabilities.
Programming features include servo reversing and E.P.A on all channels, dual rates, exponentials and programmable mixing.
Additionally, any one of four, factory-set, preprogrammed “wing-type” mixers including flaperon, V-tail, elevon mixing may be
selected.
HELI mode: Dual rate (D/R), Idle up, Throttle hold, and Gyro sense can be operates by switch. Two different gyro senses can
be set with Futaba GY401/502/611 Gyro on gyro function of this transmitter. Programming features include servo reversing
and E.P.A on all channels, dual rates, exponentials, throttle curve, pitch curve, throttle hold, and pit to rudder mixing(REVO).
Additionally, any one of three, factory-set, preprogrammed “swashplate type” mixers including three servo type 3-S/3-E may
be selected.
Transmitter controls
The diagram and explanations briefly describe the functions of the Futaba T6EX-2.4GHz transmitter. Full instructions on how
to operate the controls are provided beginning on page 14.
NOTE: The diagram shows a Mode 2 system as supplied. (More on flight modes on page 34).
Aileron, Elevator & Rudder
dual rate switch
Antenna
A:Gear switch/CH.5
H:Gyro switch/CH.5
A:Flap switch/CH.6
H:Throttle hold switch
Carrying handle
Liquid-crystal display
screen (LCD)
Throttle/rudder
control stick
(Mode 2)
MODE key
SELECT key
A:Trainer switch
H:Idle-up switch Neck strap hook
Charging jack
On-off switch
Rudder trim
lever
Throttle trim
lever (Mode 2)
DATA INPUT lever
Aileron trim lever
Elevator trim lever
(Mode 2)
Aileron/elevator
control stick
(Mode 2)
Throttle cut
button
DESCRIPTIONS:
Aileron, Elevator and Rudder dual rate switch -
Use this switch to “flip between two aileron, elevator and rudder control throw settings. The throws can be set up however you
prefer, but generally, when the switch is “up” the throws are greater (“high rate”) and when the switch is “down” the throws are
less (“low rate”). This switch also flips between exponential rates (if used).
A:Flap switch/Channel 6 - This switch operates the servo connected to channel 6 in the receiver if your model has flaps this
is the control used to operate them.
H:Throttle hold switch - This switch operates to hold the engine in the idling position and disengaged it from the Throttle
Stick. It is commonly use to practice auto-rotation.
Neck strap hook - Mounting point for optional neck strap.
Aileron/elevator control stick - Operates the servos connected to channel 1 (aileron) and channel 2 (elevator) in the
receiver.
6
Trim levers (all) - Used to shift the neutral or center position of each servo as labeled in the diagram. Once either trim lever
is operated, the trim position is displayed on the LCD screen. Also once either edit key is operated, all trim positions are
displayed sequentially on the LCD screen.
NOTE: The throttle trim lever is intended for fine tuning the throttle servo when the engine is at idle. Throttle trim does not
affect the throttle servo when the throttle control stick is all the way up (so idle r.p.m. can be adjusted without affecting
throttle settings through the rest of the stick movement).
Charging jack - Port for charging the transmitter batteries with the included battery charger.
On/off switch
DATA INPUT lever - Used to change the values of the various functions displayed on the LCD screen
Liquid – crystal display screen (LCD) - Displays programming modes and values entered.
MODE key - Used to scroll through and display the “11-14” different functions.
SELECT key - Used to display the values for the current function.
Throttle – cut button - To use the throttle-cut function, lower the throttle stick all the way, then push the throttle-cut button to
fully close the carburetor and shut of the engine.
Throttle/rudder control stick - Operates the servos connected to channel 3 (throttle) and channel 4 (rudder) in the receiver.
A:Trainer switch - Operates the trainer functions. To operate as a trainer switch the transmitter must be connected to another
transmitter via. a trainer cord (available separately).
H:Idle up switch - This switch operates to change the fight condition which is set the throttle curve and pitch curve of mid
air maneuvers (rolls, loops, stall turns) and 3D flight.
A:Retractable landing gear switch/Channel 5 - Switch operates the servo connected to channel 5 in the receiver if your
model has retractable landing gear this is the control used to extend and retract the gear.
H:Gyro switch/Channel 5 - You can connect the sense adjust connector to the channel 5 of the receiver to operate the gyro
which has two different sense. Also if you use Futaba GY401/502/611 Gyro, two different gyro senses setting on gyro function
in this transmitter can be call by this switch.
Antenna - Radiates signals to the receiver. NEVER point at the model when flying! See page__ for detail.
7
RADIO INSTALLATION
Follow these guidelines to properly mount the servos, receiver and battery.
Make certain the alignment tab on the battery, switch and servo connectors is oriented correctly and “keys” into the
corresponding notch in the receiver or connectors before plugging them in. When unplugging connectors, never pull on the
wires. Always pull on the plastic connector instead.
If any servo wires are not long enough to reach the receiver, servo extension wires (available separately) may be used.
Servo Rubber
grommet Servo Rubber
grommet
Always mount the servos with the supplied rubber grommets. Do not over
tighten the screws. No part of the servo casing should contact the mounting
rails, servo tray or any other part of the airplane/helicopter structure. Otherwise,
vibration will be transmitted to the servo causing premature wear and/or servo
failure.
• Note the small numbers (1, 2, 3, 4) molded into each arm on the Futaba 4-arm servo arms. The numbers
indicate how many degrees each arm is “offfrom 90 degrees to correct for minute manufacturing
deviations from servo to servo.
To center the servos, connect them to the receiver and turn on the transmitter
and receiver. Center the trims on the transmitter, then find the arm that will be
perpendicular to the pushrod when placed on the servo.
After the servos are installed, operate each servo over its full travel and check that the pushrods and servo arms do not
bind or contact each other. Also make sure the controls do not require excess force to operate. If there is an objectionable
buzzing sound coming from a servo, there is probably too much resistance in the control. Find and correct the problem.
Even if there is no servo damage, excess battery drain will result.
Use the mounting plate from the receiver on/off switch as a template for the cutout and screw holes. Mount the switch on
the side of the fuselage opposite the engine exhaust, and where it won’t be inadvertently turned on or off during handling or
storage. Be certain the switch moves without restriction and “snaps” from ON to OFF, and that the cutout allows full motion
of the switch in both directions.
• When you install the switch harness to the helicopter, please use switch cover. Generally sandwich the frame by switch and
switch cover and securely tighten the screws. It might be different installations on model by model. In that case, please
follow the model instruction manual.
Fasten about 5-10cm
from the servo outlet
so that the lead wire
is neat.
Margin in the lead wire.
• To prevent the servo lead wires from being broken by vibration during flight,
provide a margin so that the wire sticks out slightly and fasten it at suitable
points. In addition, periodically check the wire during daily maintenance.
8
IMPORTANT: Since the 2.4GHz have different characteristics than that of the conventional frequencies of 27MHz to
72MHz, please read this section carefully and enjoy your safety flight with the 2.4GHz system.
Receiver's Antenna Installation:
Antenna
*Must be kept as straight as possible.
Coaxial cable
R606FS Receiver
The R606FS has two antennas. These antennas have a diversity
function to decrease the chance of a receiving error.
Since the wave length of the 2.4GHz is much shorter than that
of the conventional frequencies 27MHz and 72MHz, it is very
susceptible to loss of signal which results in a receiving error.
In order to avoid this phenomenon, the R606FS adopted a
diversity antenna system.
To obtain the best results of the diversity function, please refer to the following instructions;
1. The two antennas must be kept as straight as possible otherwise it will
reduce the effective range.
2. The two antennas should be placed at 90 degrees to each other.
This is not a critical figure, but the most important thing is to keep the antennas
away from each other as much as possible.
Larger models can have large metal objects that can attenuate the RF signal.
In this case the antennas should be placed at both sides of the model then the
best RF signal condition is obtained at any flying attitude.
3. The antennas must be kept away from conductive materials, such as metal and carbon by at least a half inch. The coaxial
part of the antennas does not need to follow these guidelines, but do not bend it in a small radius.
4. Keep the antennas away from the motor, ESC, and other noise sources as much as possible.
*The two antennas should be placed at 90 degrees to each other.
*The main purpose of the photo demonstrates how the antenna should be placed.
For actual installation the receiver must be wrapped with a sponge or placed with
floating material to protect from vibration.
Antenna Antenna
The receiver contains precision electronic parts. It is the most delicate radio component on-board the model and should
be protected from vibration, shock and temperature extremes. To protect the receiver, wrap it in R/C foam rubber or other
vibration-absorbing material. If appropriate, waterproof the receiver by placing it in a plastic bag and closing the open end
with a rubber band before wrapping it in foam. If moisture enters the receiver, intermittent operation or a failure may result.
Wrapping the receiver in a plastic bag also protects it from fuel and exhaust residue which, in some models, can work its
way into the fuselage.
9
Transmitter Antenna
1. The transmitter antenna is adjustable so please make sure that the antenna is never
pointed directly at the model when flying as this creates a weak signal for the receiver.
2. Keep the antenna perpendicular to the transmitter's face to create a better RF condition
for the receiver. Of course this depends on how you hold the transmitter, but in most
cases by adjusting the transmitter antenna so that it is perpendicular to the face will give
the best results. Please adjust the transmitter antenna to the way you hold the transmitter.
3. NEVER grip the antenna when flying as this degrades RF quality.
Range Check the Radio
A range check must be performed before the first flight of a new model. It is not necessary to do a range check before every
flight (but is not a bad idea to perform a range check before the first flight of each day). A range check is the final opportunity
to reveal any radio malfunctions, and to be certain the system has adequate operational range.
1. We have installed a special "Power Down Mode" for doing a ground range check. To activate
the "Power Down Mode" please hold down the Mode key and then turn the transmitter switch
on. During this mode, the RF power is reduced so the range test can be performed. When this
mode is active the red LED on the back of the transmitter starts blinking and the green LED
is solid. In addition, when the mode is activated the transmitter gives users a warning with a
beep sound every 3 seconds, and visual indication.
2. Walk away from the model while simultaneously operating the controls. Have an assistant
stand by the model and signal what the controls are doing to confirm that they operate
correctly. You should be able to walk approximately 30 - 50 paces from the model without
losing control.
3. If everything operates correctly, return to the model. Set the transmitter in a safe, yet accessible location so it will be within
reach after starting the engine. Be certain the throttle stick is all the way down, then start the engine. Perform another
range check with your assistant holding the plane and the engine running at various speeds. If the servos jitter or move
inadvertently, there may be a problem. Do not fly the plane! Look for loose servo connections or binding pushrods. Also be
certain that the battery has been fully charged.
4. The "Power Down Mode" continues for 60 seconds and after that the power will go back to the normal level.
To exit the "Power Down Mode" before the 60 seconds, press the "MODE" key again. This mode is available 1 time only so
if you need to re-use this function the transmitter power must be cycled.
5. NEVER start flying when the "Power Down Mode" is active.
Link Procedure
Each transmitter has an individually assigned, unique ID code. In order to start operation, the receiver must be linked with
the ID code of the transmitter with which it is being paired. Once the link is made, the ID code is stored in the receiver and no
further linking is necessary unless the receiver is to be used with another transmitter. (For T/R set, the link is already done at
factory. When you purchased another R606FS, this procedure is necessary; otherwise the receiver will not work.
1. Place the transmitter and the receiver close to each other within one (1) meter
2. Turn on the transmitter.
3. Check the LED that is placed on the back side of the transmitter to see if the RF signal is active. When the green LED is ON
solid, the RF signal is being sent.
4. Turn on the receiver.
5. Press down the "ID SET" switch for more than one second, and release the switch. The receiver starts the linking operation.
6. When the linking is complete, the LED in the receiver will change to solid green. Please confirm that the servos will now
operate by your transmitter. Please refer to the table below for the LED status of the receiver's condition.
No signal reception Red : On
Receiving signals Green: On
Receiving signals, but ID is unmatched. Green: Blink
Unrecoverable failure (EEPROM, etc.) Red and Green turn
on alternatively.
10
RECEIVER AND SERVO CONNECTIONS
Connect the servos to the receiver to perform the functions indicated:
Receiver
output
channel
Function
Aircraft (ACRO) Helicopter (HELI)
1Aileron -or-right flaperon -or-right elevon (for tail-
less models) Aileron
2Elevator -or-left ruddervator (for V-tail models)
-or-left elevon (for tailless models) Elevator
3Throttle Throttle
4Rudder -or-right ruddervator (for V-tail models) Rudder
5Retractable landing gear Gyro sensitivity
6Flap -or-left flaperon Pitch
BReceiver on/off switch (the plug colored red
goes into the receiver)
Receiver on/off switch (the plug colored red
goes into the receiver)
Switch
Harness
To Battery
Charging
Jack
(Black)
Aileron Servo
(CH1)
Optional
Gyro
System
Elevator Servo
(CH2)
Throttle Servo
(CH3)
Rudder Servo
Rudder (CH4)
Pitch Servo
(CH6)
The diagram shown is for helicopter models only. It is necessary to buy an additional gyro separately.
Gyro sensitivity (CH5)
Receiver
Switch
Harness
To Battery
Charging
Jack
(Black)
Aileron Servo
(CH1)
Elevator Servo
(CH2)
Throttle Servo
(CH3)
Rudder Servo
(CH4)
Gear Servo
(CH5)
Flap Servo
(CH6)
The diagram shown is for aircraft models only. Additional servos may have to be purchased separately.
(CH1)
(CH6)
(CH1)
(CH2)
(CH4)
(CH2)
(CH4)
Flaperon Mode (Dual Aileron
Servo, CH1 & 6)
Independent Aileron & Flap
(CH6)
(Red)
(Red)
Receiver
11
CHARGING THE Ni-Cd BATTERIES
The transmitter batteries included with your 6EX-2.4GHz system are rechargeable, Ni-Cd (nickel-cadmium, pronounced ni-
kad) batteries. Ni-Cd batteries require special care and charging. Read the charging instructions carefully.
NOTE: The batteries are supplied partially charged, but will require a full, overnight charge before the model may be flown.
1. Connect the transmitter charging cord coming from the A/C wall charger to the charge jack in the right side of the
transmitter case. The receiver charging cord may be connected to the batteries two different ways: The charge cord may be
connected directly to the battery pack, or to the vacant charge connector (black) coming from the on/off switch in the model.
Charging “through the switch is preferred as there will be no need to disconnect the battery.
2. Plug the A/C wall charger into a wall outlet. Note: If the wall outlet can be turned off by a switch in the room, be certain the
switch remains on after leaving the room. Otherwise, the batteries will not be charged!
3. The LEDs (light-emitting diodes) should light red, indicating that current is flowing and the batteries are being charged.
Discharged batteries will take about 15 hours to fully charge. If using an aftermarket fast charger, be certain to follow
the manufacturer’s instructions provided with the charger so you do not overcharge the batteries. NEVER charge
the batteries at a rate higher than 1,000mAh. The batteries should also be discharged periodically to prevent a condition
called “memory. If, for example, only two flights are made each time you go flying, the batteries will not have “reached”
very far down into their full capacity. After doing this several times the batteries will “remember and eventually “think” they
can supply only enough power for two flights. After two flights the batteries may not provide enough power to operate the
system, thus causing a crash. To erase any potential memory, cycle the batteries by discharging, then charging them with a
commercial battery cycler, or leave the system on and exercise the servos by moving the transmitter sticks until the servos
are moving very slowly, indicating that the battery is discharged. Cycling should be done every one to two months, even
during the winter or periods of long storage. If using a cycler with a readout, note the capacity after the batteries have been
cycled. If there is a noticeable drop in capacity the batteries should be replaced.
Note: Charging your batteries with the included Futaba A/C battery charger is always safe. However, fast-charging with
an aftermarket charger is acceptable as long as you know how to properly operate the charger. NEVER charge at a rate
higher than 1,000 mAh (1 Amp). If not done correctly, fast-charging can damage the batteries.
12
LIQUID CHIP DISPLAY (LCD) & PROGRAMMING CONTROLS
To open
programming menu;
Press both keys
simultaneously and
hold for one second
MODE key - use to select desired
function while programming
Throttle-cut button -
To use the throttle-cut
function,
SELECT key - use to select items within
function to be set or changed in the screen
DATA INPUT lever - use this lever to input
numbers or settings
LCD display screen
Current model
memory name
Transmitter
battery voltage
Current model
type
When the transmitter is initially turned on, the model type, model
memory name, modulation type and transmitter battery voltage are
displayed on the LCD screen. When prompted by the user, the functions
and settings stored in the memory can also be read on the screen. The
user accesses the different functions using the MODE and SELECT
keys and changes the values and settings using the DATA INPUT lever.
(This is called programming!)
Note: Feel free to explore by scrolling through the programs and viewing the displays using the MODE and SELECT keys.
The MODE and SELECT keys only determine what will be displayed on the screen and will not change any of the settings.
Only when using the DATA INPUT lever will you be able to change any of the settings.
Model name
The Futaba T6EX-2.4GHz stores model memories for six models. This means all the data (control throws, trims, end points,
etc.) for up to six different models can be stored in the transmitter and activated at any time (depending upon which model you
choose to fly that day). This eliminates the requirement for reconfiguring the transmitter each time you decide to fly a different
model with it! When the transmitter is turned on the model type, model name, modulation and the transmitter voltage will
be indicated on the LCD screen. Before every flight BE CERTAIN that the correct model name for the model you intend to fly
appears on the screen. If the transmitter is not operating the correct model, some (or all) of the controls could be reversed and
the travels and trims will be wrong.
Flying a model with the wrong program will result in a crash, so always be certain the model name in the transmitter is
correct. One way to ensure this is to write the corresponding model name directly on the airplane or helicopter, or attach a
list to the bottom or back of the transmitter.
13
Transmitter battery voltage
“Battery” icon
In addition to the model type, the LCD screen also displays the transmitter battery voltage.
When the voltage goes below approximately 8.5 Volts the “battery” icon will flash and the low-
battery alarm will continuously beep until the transmitter is turned off. When the low-battery
alarm sounds you will have approximately four minutes (or less) to land your model before
losing control. You should never allow the transmitter voltage to become this low while flying,
but if it does, land immediately.
Note: When the transmitter voltage reads 8.9 Volts you will
still have approximately ten minutes (or less) before losing
operational range, so this is the recommended absolute
minimum voltage. If the transmitter ever reaches 8.9 Volts,
land as soon as safely possible. A more reasonable margin
of safety would be to quit flying for the day (or recharge the
batteries) when the transmitter battery.
SUGGESTED GUIDELINES
9.4 Volts - No more flying until recharge.
8.9 Volts - Land as soon as safely possible.
8.5 Volts - Emergency- Land immediately!
Mixer alert warning
The Mixer alert warning is displayed to alert you whenever you turn on the transmitter with
any of the mixing switches active. This warning will disappear when the offending switch or
control is deactivated. Switches for which warnings will be issued at power-up and model
selection are Throttle hold switch or Idle-up switch.
Backup error
The Backup error warning occurs when the transmitter memory is lost for any reason. If this
occurs, all of the data will be reset when the power is turn on again.
When the Backup error occurs, initialization starts from model number 6 to 1.
The model number on the left of the screen changes from 6 to 5, to 4, to 3, to 2, to 1, and
finally the number disappears. The disappearance of the model number indicates that the
initialization has been completed. Now you can turn off the power of the transmitter. Please
do NOT turn off the power during the initialization; otherwise initialization will restart when you
turn on the power.
Do not fly when this message is displayed: all programming has been erased and is not
available. Return your transmitter to Futaba service.
14
PROGRAMMING THE 6EX-2.4GHz RADIO
Anytime you wish to view or change any of the current settings in the transmitter, the programming mode must first be
entered by, of course, turning on the power, then by pressing the “MODE” and “SELECT” keys simultaneously and holding
them down for one second. Once in the program the MODE key will be used to scroll through each of the functions (Model
type ACRO: model select/ data reset/ model type select/ modulation select/ trainer/ model name, reversing, dual rates/
exponentials, end point adjustments, trim, programmable mix 1, programmable mix 2, flaperon mixing, flap trim, v-tail mixing,
elevon mixing, and failsafe Model type HELI: model select/ data reset/ model type select/ modulation select/ model name,
reversing, dual rates/ exponentials, end point adjustments, trim, normal throttle curve, normal pitch curve, idle-up throttle
curve, idle-up pitch curve, throttle hold, revolution mixing, gyro sensitivity, swash-throttle mixing/ swashplate types, and
failsafe) and the SELECT key will be used to view the settings within the function. When a data change is actually required the
“DATA INPUT” lever will be used to increase or decrease the value of the item displayed, thus making the change.
You can return to the home screen (where the model name and battery voltage is displayed) by pressing the MODE and
SELECT keys simultaneously and holding them down for one second.
Note: The functions are listed and described in the order that they appear in the transmitter. Read all the way through the
programming instructions before setting up your model (if you won’t be using any of the mixing functions for a while you
can read those instructions when ready). Refer to the FLOW CHART on page 31(ACRO) or page 32(HELI) as well.
Model Select / Data Reset / Model Type Select / Modulation Select / Trainer / Model Name
MODL Model select function
To select model memory:
1. Access the Model Select function in the programming mode (by pressing the MODE and
SELECT keys simultaneously and holding them down for one second). The number for the
current, active model will be blinking.
2. To activate a different model memory press the DATA INPUT lever and hold it down for 0.5
seconds until the desired model number appears.
3. Now the model has been selected. All programming inputs from this point forward will affect
only the model number on the screen (until another model number is selected).
REST Data reset function
All the data for any model memory can be reset to the original factory defaults. Often this function is done to get a “fresh start”
and clear the memory before inputting new model settings.
To reset data:
1. Access the Model Select function in the programming mode (by pressing the MODE and
SELECT keys simultaneously and holding them down for one second). To select the model
memory you wish to reset press the DATA INPUT lever and hold it down for 0.5 seconds
until the desired model number appears.
2. Once the desired model number is displayed on the screen, press the SELECT key. A
“REST” will appear on the screen.
3. Push DATA INPUT upward or downward for about 2 seconds to clear and reset the memory.
“CLR” blinks first, and then it stops blinking with a sound. Now the model data is reset to the
initial setting that is the default value set at the factory.
The existing modulation and swashplate type settings are not reset. If the power switch is turned off while reset is underway,
the data may not be reset.
CAUTION: Resetting the current model memory will permanently erase ALL programming information for that model. The
data cannot be recovered (unless you recorded it on a Model Data Recording Sheet in the back of this manual). Do not reset
the model unless you are certain you want to clear-out that memory and start from scratch.
When actually setting up a model you should have the model in front of you with the power on so you can actually see the
effects of your programming inputs and measure the control throws.
15
ACRO/HELI Model type select function
The Model type select function is used to select the ACRO or HELI mode of model type.
ACRO: Powered aircraft memory type (with multiple wing and tail configurations. See Wing mixing type selection for further
information, p20.)
HELI: Helicopter memory type (with three helicopter swashplate type. See Swashplate types selection for further information,
p28.)
CAUTION: Before doing anything else to set up your aircraft, first you must decide Model type (include wing mixing type or
swashplate type) best fits this particular aircraft.
To select model type:
1. Access the Model Select function in the programming mode (by pressing the MODE and
SELECT keys simultaneously and holding them down for one second). To select the model
memory you wish to select model type press the DATA INPUT lever and hold it down for 0.5
seconds until the desired model number appears.
2. Push SELECT key twice after seeing on the screen the model memory where you want to
select model type, then you will see “ACRO” or “HELI” on the screen.
3. To change model type, push the DATA INPUT lever and hold it down for about two seconds.
“HLand “AC” blinks first, and then it stops blinking with a sound. The current model type
“ACRO” or “HELI” is displayed.
TRNR Trainer function (ACRO only)
The Trainer function is used to activate the trainer switch each model memory as the
instructors’ transmitter. See Trainer switch for further information, p33.
To activate trainer function:
1. Access the Model Select function in the programming mode (by pressing the MODE and
SELECT keys simultaneously and holding them down for one second). To select the model
memory you wish to activate trainer function press the DATA INPUT lever and hold it down
for 0.5 seconds until the desired model number appears.
2. Push SELECT key four times after seeing on the screen the model memory where you want
to activate trainer function, then you will see “TRNR” on the screen.
3. To activate the function, push the DATA INPUT lever up for 0.5 seconds. The “ON” is
displayed. To inhibit the function, push the DATA INPUT lever down for 0.5 seconds. The
“INH” is displayed.
16
Model name function
Assign a name to the model memory. By giving each model a name that is immediately recognizable, you can quickly select
the correct model, and minimize the chance of flying wrong model memory that could lead crash.
To assign a name
1. Access the Model Select function in the programming mode (by pressing the MODE and
SELECT keys simultaneously and holding them down for one second). To select the model
number you wish to change press the DATA INPUT lever and hold it down for 0.5 seconds
until the desired model number appears..
2. Push SELECT key five times after seeing on the screen the model memory where you want
to set the model name, then you will see the model name on the screen.
3. Choose a character for the first digit by using DATA INPUT lever. Then move to the next digit
by pressing the SELECT key and choose a character in the same way. Continue choosing
characters for the third and fourth digits. You can use up to four characters for the name.
REVR Servo Reversing
The servo reversing function is used to change the direction that a servo responds to a control input from the transmitter
(stick or switch). After using the reversing function, check all the controls on the model to be certain they are operating in the
correct direction and that you did not inadvertently reverse a servo other than the one intended. Reversing the wrong servo (and
not checking the response of the controls before each flight) may be the most common cause of a crash!
To reverse a servo:
1. Enter the programming mode and use the MODE key to access the REVR function.
2. Use the SELECT key to select the channel you wish to reverse.
3. Push the DATA INPUT lever downward for 0.5 seconds to reverse the servo (REV), or push
the lever upward for 0.5 seconds to make the servo operate normally (NOR). The arrow will
indicate the condition of the servo (normal or reversed).
4. Use the SELECT key to display other channels to be reversed.
Dual Rates / Exponential Settings
The aileron, elevator and rudder dual rates on the 6EXHP are simultaneously activated by the dual rate switch. The amount of
travel decrease for each control may be set between 0% and 100% of the values set for the end points (explained in End Point
Adjustment on page 17).
Note: It is possible to set a dual rate value to zero, thus causing no response from that channel. If the dual rates are
inadvertently set to zero, a crash could result.
Note: When performing initial model setup, the E.P.A.s should be set prior to setting the dual rates. When setting the E.P.A.s
for the first time on a new model, the dual rates should be set to 100%.
D/R Dual Rate Settings
To set the dual rates:
1. Enter the programming mode. Access the “D/R” screen with the MODE key.
2. Select the channel to be adjusted (1-aileron, 2-elevator, 4-rudder) by pressing the SELECT
key until the desired channel number the left side on the screen. Note: If a “EXPO” will
appear on the screen, you have pressed the SELECT key too many times and displayed
the values for the exponentials (explained later). Press the SELECT key to return to the dual
rate values.
3. Place the dual rate switch in the desired position for the value you wish to change. (Generally,
pilots prefer to have the switch in the “up” position for the high rate, and in the “down”
position for the low rate.)
4. Change the dual rate value using the DATA INPUT lever until the desired control throw is achieved. If you wish to change
the control throw when the switch is in the other position as well, flip the switch, then use the DATA INPUT lever to change
17
the throw.
5. Repeat the procedure for the other dual rate (channel 2-elevator, 4-rudder).
EXPO Exponential Settings
The “exponentials” are in the same function as the dual rates. (Pressing the MODE key will take you to the next function which
is End Point Adjustments). The same as dual rates, “expos” can be set for both switch positions. Negative exponential (-)
decreases initial servo movement. Positive exponential (+) increases initial servo movement. The exponential “curve” may be
set anywhere between -100% and +100%.
To set the exponentials:
1. Enter the programming mode. Access the “D/R” screen with the MODE key.
2. Access the “EXPO” screen with the SELECT key.
3. Select the channel (1-aileron, 2-elevator, 4-rudder) you wish to set by pressing the SELECT
key. The active channel number will be displayed on the screen Note: If a “D/R” will appear
on the screen, you have pressed the SELECT key too many times and displayed the values
for the D/R (dual rate values). Press the SELECT key to return to the exponentials.
4. Position the dual rate switch where desired for the value you wish to change.
5. Enter the amount of exponential with the DATA INPUT lever. (As stated above, an exponential value with a “-” in front of it
makes the initial servo movement less, or “softer. ”)
6. Flip the switch to the other position to enter the exponential value for that switch position.
7. Repeat for the settings on the other channel.
EPA End Point Adjustment
Note: Since changing theend points will also change the dual rates, the end points should be set prior to setting the dual
rates. If you set the dual rates first, and then go back and change the end points, the dual rate throws will also change.
The EPA function is designed to “fine tune” the servo throws in cases where changing the
pushrod hookup will not achieve the correct throw. The pushrods should first be connected
to the servo arms and control horns so that the correct, or near correct control surface throw
will be achieved. THEN the EPAs may be used to make small changes in the servo throw
until the desired control throw is achieved. The control throws should be set up so that the
“end points” are as near to 100% as possible. If the EPA values must be set below 70% or
above 120% to get the desired throw, you should strongly consider changing the pushrod
connections so the values can be set closer to 100%. (When the EPA is set to 100% the
maximum servo throw for channels 1, 2, 3 & 4 is approximately 40° and approximately 55°
for channels 5 & 6.)
To set the end points:
1. Enter the programming mode and use the MODE key to access the “EPA” screen. The
channel number being adjusted will the left side on the screen and the “%” symbol will be
flashing.
2. To change the RIGHT aileron throw move the aileron stick to the right, then push the DATA
INPUT lever up or down to change the value and the throw.
3. Move the stick to the left and use the DATA INPUT lever to change the LEFT aileron throw.
4. Use the SELECT key to display the other channels and set the other end points. Notice that
moving the stick (or switch or dial) from one end to the other changes the value displayed
and the position of the arrow for that “end” of the control input.
18
TRIM Trim Settings
There are four trim levers (“trims”) on the front of the transmitter. Three of the trims are for adjusting the neutral position of the
aileron, elevator and rudder servos. The fourth trim is for setting the idle r.p.m. of the engine when the throttle stick is all the
way down. The intended use of the trims is to make small servo adjustments, in flight, to get the model properlytrimmed (so
it will fly straight-and-level). Because the trims are intended to be used while the model is in flight, you do not have to “enter
the program” to adjust the trims. Simply push or pull on the trim levers while flying and the neutral position of the servos will
shift. Keep in mind that you should start out with the control surfaces centered when the servos are centered and the trims are
“zeroed (or near zero). THEN you can adjust the trims once airborne.
Center the servos:
1. Turn on the transmitter and receiver. Operate the controls to make sure the servos respond in the correct direction. Use the
reversing function to reverse any servos necessary.
2. Center the throttle control stick.
3. Place the servo arms on the servos so they are perpendicular to the pushrods (see page 8). It is okay to cut off any unused
servo arms.
4. Connect the pushrods to the control surfaces. Adjust the length of the pushrods until the control surfaces are centered when
the servos are centered.
Note: The throttle trim affects the throttle servo only when the throttle stick is below “1/2 stick. This way, the final closing of
the carburetor can be adjusted without affecting the servo throughout the rest of the range.
To adjust the trim settings:
Once the servos and control surfaces have been connected and the control throws have been set using the end points and
dual rates, get the model airborne. Adjust the trims as necessary to get the model to fly straight-and-level. If much trim is
required on any one control it is a good idea to readjust the pushrods so the trims can be returned to neutral (zero). Adjusting
the trims with the trim levers changes the servo’s position in increments of “4.If finer adjustments are required, land the
model, then enter the program as described below to adjust the trims in increments of “1.
1. Enter the programming mode and use the MODE key to activate the TRIM menu.
2. Press the SELECT key to display the channel to be adjusted (the figure shows trim
adjustment for CH1).
3. Adjust the trim using the DATA INPUT lever. Note that initially, the values change in
increments of “1,”but if the DATA INPUT lever is held long enough the values will change
more rapidly.
4. Repeat the steps for other channels that require trim adjustments.
19
PMIX1/2 Programmable Mixer 1/2 (ACRO only)
Unlike the “wing mixing” function (explained later) where the channels to be mixed are factory-set, the T6EX-2.4GHz also
contains two programmable mix where the you, the pilot determine the channels to be mixed. This could be used to correct
unwanted flight tendencies (by mixing rudder to aileron, or aileron to rudder for example).
To set up a programmable mix:
1. Enter the programming mode. Access the “PMIX screen with the MODE key.
2. Push the DATA INPUT lever upward for 0.5 seconds. This will cause the flashing INH
display to change to a flashing ON display.
3. Push SELECT key to call the screen for selecting channels to control MAS(Master)
mixing. Then select the channel by pushing DATA INPUT lever . Channel 1 (aileron) in this
figure is assigned to the master.
4. Push SELECT key to call the screen for selecting channels to control SLV (Slave) mixing.
Then select the channel by pushing DATA INPUT lever. Channel 4 (rudder) in this figure is
assigned to the slave.
5. Press the SELECT key twice to display the flashing % sign. Use the DATA INPUT lever
to set the percentage of mixing from -100% to +100% (depending on the direction and
distance you wish the slave servo to move).
6. Push SELECT key to call the screen for selecting the on/off switch. Then select the switch
by pushing DATA INPUT lever. CH5, D/R, or FLP switch (include the on direction) is
selectable. The “ON” is “always on”.
7. Observe how the controls on the model respond to be certain you have achieved the correct
mix and that the throws are as desired.
20
Wing Mixing Type Selection (ACRO only)
With the programmable mix (previously described) the user determines the two channels to be mixed. The wing mixing
function is another mix that may be used, but the channels mixed are predetermined. There are three different wing mixing
functions to select from:
*If necessary, use the Servo Reversing
function to achieve the correct direction of
servo throws.
FLPR Flaperon mixing (ACRO only)
This function allows the ailerons to be used both as ailerons and as flaps. The flap
control dial (CH 6) operates the flap function. To use flaperon mixing both ailerons
must be operated by separate servos.
To activate flaperon mixing:
1. Connect the aileron servo in the right wing to channel 1 (aileron) in the receiver and connect
the aileron servo in the left wing to channel 6 (flaps) in the receiver.
2. Enter the programming mode. Access the “FLPR screen with the MODE key.
You cannot set Flaperon mixing when “Elevon” mixing has already been set. In order to
enable Flaperon mixing, you first need to cancel “Elevon” mixing. However, it is allowed to
use “Flaperon” and “V-Tail” mixing simultaneously.
3. Push the DATA INPUT lever upward for 0.5 seconds. This will cause the flashing INH
display to change to a flashing ON display. Now the mixing is on.
4. If needed to set ailerons differential. Press the SELECT key to display the flashing “%” sign.
Use the DATA INPUT lever to set the percentage of ailerons differential from -100% to
+100% (The - direction indicates decreasing amount of movement toward the upward from
the aileron surface, while + direction indicates decreasing amount of movement toward the
downward from the aileron surface.)
5. Once this mix has been activated, move the servos to their full extremes to make certain
they are not overdriving the controls. If necessary, adjust the linkages to achieve the correct
control throws.
FLTR Flap trim (ACRO only)
The Flap Trim function is used to specify the amount of flap travel produced moving the flap switch. As normal flap switch will
be inhibited to use if the flaperon function is activated, the Flap Trim function should be activated if you need to control flap by
Flap switch.
21
To activate flap trim:
1. Enter the programming mode. Access the “FLTR screen with the MODE key.
2. If INHis blinking, push DATA INPUT lever upward for 0.5 seconds. Then you will see that
the blinking INH” changes to ON”. Your flap trim is now turned on.
3. Set the travel of the flap switch at between -100% and +100% by using DATA INPUT lever.
Two rates (upward and downward of flap switch) are adjustable.
V-TL V-tail mixing (ACRO only)
*If necessary, use the Servo Reversing
function to achieve the correct direction of
servo throws.
Intended for V-tail aircraft (such as a Beechcraft Bonanza), V -tail mixing allows
the ruddervators to operate both as rudders and elevators. The same as the other
mixes, V -tail mixing requires that each ruddervator be operated by a separate
servo.
To activate V-tail mixing:
1. Connect the left ruddervator servo to channel 2 (elevator) in the receiver and connect the
right ruddervator servo to channel 4 (rudder) in the receiver.
2. Enter the programming mode. Access the “V-TL screen with the MODE key.
You cannot set “V-tail mixing when “Elevon mixing has already been set. In order to enable
V-tail mixing, you first need to cancel Elevon mixing. However, it is allowed to use “V-Tail”
and “Flaperon” mixing simultaneously.
3. Push the DATA INPUT lever upward for 0.5 seconds. This will cause the flashing INH
display to change to a flashing ON display. Now the mixing is on.
22
4. Next you may the elevator setting. Press the SELECT key to display the “CH2” and flashing
“%” sign. Use the DATA INPUT lever to set the percentage of elevator travel rate from -100%
to +100%
5. Next you may the rudder setting. Press the SELECT key to display the “CH4 and flashing “%”
sign. Use the DATA INPUT lever to set the percentage of rudder travel rate from -100% to
+100%
6. Once this mix has been activated, move the servos to their full extremes to make certain
they are not overdriving the controls. If necessary, adjust the linkages to achieve the correct
control throws.
ELVN Elevon mixing (ACRO only)
CH1 CH2
*If necessary, use the Servo Reversing
function to achieve the correct direction of
servo throws.
Intended for tailless, “flying wing” models such as delta wings and flying wings,
elevon mixing mixes channel 1 (aileron) to channel 2 (elevator) allowing the
elevons to operate in unison (as elevators) or in opposition (as ailerons). This
function requires that each elevon be operated by a separate servo.
To activate elevon mixing:
1. Connect the servo in the right wing to channel 2 (elevator) in the receiver and
connect the servo in the left wing to channel 1 (aileron) in the receiver.
2. Enter the programming mode. Access the “ELVN” screen with the MODE key.
You cannot set Elevon mixing when Flaperon or V-TL mixing has already been set. In
order to enable Elevon mixing, you first need to cancel both “Flaperon” and “V-tail” mixing.
23
3. Push the DATA INPUT lever upward for 0.5 seconds. This will cause the flashing INH
display to change to a flashing ON display. Now the mixing is on.
4. Next you set the left wing to channel 1 (aileron) setting. Press the SELECT key to display
the “CH1” and flashing “%” sign. Use the DATA INPUT lever to set the percentage of elevator
travel rate from -100% to +100%
5. Next you set the right wing to channel 2 (elevator) setting. Press the SELECT key to display
the “CH2” and flashing “%” sign. Use the DATA INPUT lever to set the percentage of rudder
travel rate from -100% to +100%
6. Once this mix has been activated, move the servos to their full extremes to make certain
they are not overdriving the controls. If necessary, adjust the linkages to achieve the correct
control throws.
24
N-TH Normal throttle curve function (HELI only)
Used to set throttle curve for normal flight. 5-point throttle curve is utilized to best match the blade collective pitch to the engine
RPM for consistent load on the engine. Throttle curve can be adjust from 0-100% each point.
This normal throttle curve create basic curve for around hovering. Use this function together with the normal pitch curve (see
Normal pitch curve) so that up/down control has a constant engine speed.
To set the normal throttle curve:
1. Enter the programming mode and use the MODE key to access the “N-TH” function.
Throttle stick position number will appears on left side of display and “%” symbol will be
flashing.
2. Use SELECT key to select the desire curve point. Point 1 is shown initially which is throttle
stick all the way downward (slow) position. Point 5 is throttle stick all the way upward (hi)
position.
3. Push up or down DATA INPUT lever to set the servo position.
4. Use SELECT key to set other points with same manner.
N-PI Normal pitch curve function (HELI only)
Used to set pitch curve for normal flight. 5-point pitch curve is utilized to best match the blade collective pitch to the engine
RPM for consistent load on the engine. Pitch curve can be adjust from 0-100% each point.
This normal pitch curve create basic curve for around hovering. Use this function together with the normal throttle curve so
that up/down control has a constant engine speed.
To set the normal pitch curve:
1. Enter the programming mode and use the MODE key to access the “N-PI” function. Throttle
stick position number will appears on left side of display and “%” symbol will be flashing.
2. Use SELECT key to select the desire curve point. Point 1 is shown initially which is throttle
stick all the way downward (slow) position. Point 5 is throttle stick all the way upward (hi)
position.
3. Push up or down DATA INPUT lever to set the servo position.
4. Use SELECT key to set other points with same manner.
I-TH Idle-up throttle curve function (HELI only)
Used to set throttle curve for idle up flight. 5-point throttle curve is utilized to best match the blade collective pitch to the engine
RPM for consistent load on the engine when idle up function is on. Throttle curve can be adjust from 0-100% each point.
This idle up throttle curve is to set for consistent engine RPM and can be activated at any time when mid air maneuvers are
executed, such as loops, rolls, and 3D flight even when reduced the blade collective pitch.
To set the idle-up throttle curve:
1. Enter the programming mode and use the MODE key to access the “I-TH” function.
2. Push the DATA INPUT lever upward for 0.5 seconds. This will cause the flashing “INH”
display to change to a flashing “ON” display. Now the I-TH function is on. Push the SELECT
key, throttle stick position number will appears on left side of display and “%” is blinks.
25
3. Use SELECT key to select the desire curve point. Point 1 is shown initially which is throttles
stick all the way downward (slow) position. Point 5 is throttles stick all the way upward (hi)
position.
4. Push up or down DATA INPUT lever to set the servo position.
5. Use SELECT key to set other points with same manner.
I-PI Idle-up pitch curve function: (HELI only)
Used to set pitch curve for idle up flight. 5-point pitch curve is utilized to best match the blade collective pitch to the consistent
engine RPM when idle up is used. Pitch curve can be adjust from 0-100% each point.
The high side pitch curve should be set to not to over load the engine and keep consistent engine RPM. Generally set less
pitch than normal maximum pitch. The low side pitch curve is to set for desired maneuver such as loops, rolls, and 3D flight.
To set the idle-up pitch curve:
1. Enter the programming mode and use the MODE key to access the “I-PI” function.
2. This function cannot be used when “I-TH” function is not activated. When you set “I-PI”
function, you must activates “I-TH” function.
3. Use SELECT key to select the desire curve point. Point 1 is shown initially which is throttles
stick all the way downward (slow) position. Point 5 is throttles stick all the way upward (hi)
position.
4. Push up or down DATA INPUT lever to set the servo position.
5. Use SELECT key to set other points with same manner.
HOLD Throttle hold function (HELI only)
Throttle hold function is to be used for autorotations where only pitch control is used to make
a descent and landing. Just flip the hold switch on to set the engine in the idling or cut position
and disengaged it from the Throttle Stick. It can be set from (-)50 to (+)50% from throttle trim
position.
To set the throttle hold:
1. Enter the programming mode and use the MODE key to access the “HOLD” function.
2. Push the DATA INPUT lever upward for 0.5 seconds. This will cause the flashing “INH”
display to change to a flashing “ON” display. Now the “HOLD” function is on.
3. Push SELECT key once. This will cause the flashing “%” symbol on the display. Pull the hold
switch fowards you. Push up or down DATA INPUT lever to set the throttle servo position of
throttle hold.
26
REVO Pitch-rudder mixing function (HELI only)
This mix adds rudder in conjunction with pitch. This helps compensate for rotation of the helicopter caused by the increased
engine torque. (Never use revo. mixing with a heading-hold/AVCS gyro which is in heading hold/AVCS mode. However, revo.
mixing is still used when a heading-hold/AVCS gyro is in normal mode.)
To set the REVO mixing:
1. Enter the programming mode and use the MODE key to access the “REVO” function.
2. Push the DATA INPUT lever upward for 0.5 seconds. This will cause the flashing “INH”
display to change to a flashing “ON” display. Now the “REVO” function is on.
3. Push the SELECT key once. This will cause the flashing “%” symbol on the display. It can
be set mixing amount on throttle stick hi side and low side separately. When you move the
throttle stick to the low side from neutral, the arrow indicates down direction and than push
up or down DATA INPUT lever to set the mixing amount of the low side. When you move the
throttle stick to the high side from neutral, the arrow indicates up direction and than push up
or down DATA INPUT lever to set the mixing amount of the low side.
5SEDWITHRUDDER
YAWAXIS
GYRO Gyro mixing function (HELI only)
GYROS : Using electronics to take some of the complexity out of setups and flight.
What is a gyro? A gyroscope is an electronic unit that senses motion and
corrects for it. For example, if the wind blows your helicopters tail to the left, a
gyro will sense that motion (and confirm that no input was given) and will correct
for it.
How does it help in helicopter setup? A good gyro will totally eliminate the need
for revo. mixing. The gyro will sense and correct the unwanted motion for you, so
you don’ t have to spend time to get a complex curve operating properly.
Gyro sensor kinds: There are many different kinds of gyros. Early gyros were mechanical, with a spinning drum similar to a
child’s gyroscope toy. The next generation utilized a special type of crystal, called piezoelectric, which sensed the motion and
provided an electrical pulse. The finest gyros at the time of this writing are SMM technology. These silicone micro machines,
or computer chips, sense the motion. SMM is far more accurate and less susceptible to inaccuracies caused by temperature
changes, etc.
Choosing the right gyro for your skills, your helicopter, and your budget:
Mechanical: some are still available. They are very challenging to set up and not as reliable as piezo or SMM.
Non-Heading-Hold Piezo: these are now inexpensive gyros that are reliable and easy to set up. Some have dual rates and
remote gain control to adjust sensitivity in flight. Lack heading-hold capabilities for precision flying.
Heading-Hold Piezo: Until recently, the cream of the crop. Expensive, and more complex to set up. Adds GPS-like heading
recognition. Exhibits minor difficulties with temperature drift (position setting varying with unit’s temperature).
Heading-Hold SMM: 21st Century gyro technology. Computer chip technology. Expensive, easier set up, higher durability.
Significant decrease in temperature sensitivity. Many include frame rate settings to allow faster response when using
specialized digital servos. Examples:
27
• GY401: Simpler set up. Ideal for learning aerobatics through 3D.
• GY502: Better centering than 401 for more advanced aerobatics. Ideal through Class III competition.
• GY611: Exceptional center. Extremely fast response time. Requires specialized servo.
Gyro mixing function is use for adjusting the gain of the gyro and selecting the gain from two different gain settings by switch
on the transmitter with the gyro that can set two different gains witch placed on the model.
To set the GYRO mixing:
1. Plug the gyro’s sensitivity adjustment to channel 5 of the receiver. (not assignable)
2. EPA of channel 5 (see page 12-13) to set 100% both UP and DOWN.
3. Enter the programming mode and use the MODE key to access the “GYRO” function.
4. Push the DATA INPUT lever upward for 0.5 seconds. This will cause the flashing “INH”
display to change to a flashing “ON” display. Now the mixing is on.
5. Push the SELECT key once. This will show the gyro gain setting and flashing “%” symbol on
the display.
Flip the gyro (CH5) switch up and down. This will cause the arrow points up and down on the display simultaneously with
switching operation and show the position of the switch. Push up or down DATA INPUT lever to set the gyro gains both switch
up and down position. Gyro gain can be adjust from -100% to +100%.
(Up position)
(Down position)
Relationship
between transmitter set value
and gyro sensitivity
+100%
Transmitter
set value
Gyro
sensitivity
50%
0%
-50%
-100%
100%
50%
0%
50%
100%
AVCS side
Normal side
Normal mode
60%
AVCS mode
80%
Sensitivity
switch
(CH5)
Example of sensitivity setting with GY401
28
SW-T Swash to throttle mixing (HELI only)
This function corrects slowing of engine speed caused by swashplate operation at aileron or elevator operation.
To activate swash to throttle mixing:
1. Enter the programming mode. Access the “SW-T screen with the MODE key.
2. Push the DATA INPUT lever upward for 0.5 seconds. This will cause the flashing INH
display to change to a flashing ON display. Now the mixing is on.
3. Press the SELECT key to display the CHA”. Use the DATA INPUT lever to set the
percentage of aileron to throttle mixing rate from 0% to 50%.
4. Press the SELECT key to display the CHE”. Use the DATA INPUT lever to set the
percentage of elevator to throttle mixing rate from 0% to 50%.
SWSH Swashplate types selection & Swash AFR (HELI only)
This function can chose from three swashplate types. Swash AFR can be set, if you chose 3-S or 3-E type
1-S: Independent aileron, pitch and elevator servos linked to the swashplate. Most kits are 1-S type.
&RONT
%LEVATOR
0ITCH
!ILERON
!ILERON
0ITCH
34YPE
3-S: With Aileron inputs, the aileron and pitch servos tilt the swashplate left and
right; with Elevator inputs, the three servos tilt the swashplate fore and aft; with Pitch
inputs, all three servos raise the swashplate up and down.
Front
Elevator
Pitch
(Aileron)
Aileron
(Pitch)
3-E Type
3-E: With Aileron inputs, the aileron and pitch servos tilt the swashplate left and right;
with Elevator inputs, the servo tilt the swashplate fore and aft; with Pitch inputs, all
three servos raise the swashplate up and down.
29
To select the swashplate types:
1. Enter the programming mode and use the MODE key to access the “SWSH” function.
2. To select swashplate type press the DATA INPUT lever upward or downward for about two
seconds. When you are changing swashplate type to 1-S, 3-S or 3-E, the 1-S, 3-S or 3-E on
the display flashes slow to change rapid and then returns slow flashing with conformation
sound.
3. Now it set the swashplate type.
To set the swash AFR:
This function only can set when you selected the 3-S or 3-E swashplate type. There is no swash AFR setting with 1-S type.
This swash AFR function is to use for change the direction and amount of servo movement on aileron, elevator, and pitch.
At first, linkage and set the servo horn length on aileron, elevator, and pitch servos follow by instruction manual comes with
the model. Basically “EPA” (see page17) is set near 100% with these three servos. To set the servo “reveres” function (see
page16) so that swashplate keeps horizontally and moves correct direction up and down by operating pitch control (up and
down throttle stick).
1.Enter the programming mode and use the MODE key to access the “SWSH” function.
2. Swashplate types, Confirm 3-S or 3-E type is selected. If 3-S or 3-E type is not selected,
please see “To select the swashplate types” and set.
3. Use SELECT key to select the channel you wanted to set. Aileron channel “CHA” is
displayed at first and “%” is flashing.
Move the aileron stick left and right to set the direction and amount of movement on the
aileron servo by push up or down DATA INPUT lever. Aileron movement can be adjust from
-100% to +100% .
4. Other channel (elevator and pitch) select by SELECT key to set the direction of movement
and movement amount of servo with same manner of aileron channel setting.
“CHE” is elevator and “CHP” is pitch channel on the Display.
30
F/S Fail Safe (Throttle channel <ch 3> only)
The Fail Safe function is recommended to use for safety reason in the event radio interference is received. In this menu, you
may select from one of two options of operation. The “NOR”(normal) setting holds the servo in its last commanded position,
while the “F/S”(Fail Safe) function moves the servo to a predetermined position.
The setting is set to “F/S” as a default.
The use of the failsafe function is recommended from the standpoint of safety. You may wish to set the throttle channel so that
the throttle is moved to idle when theres interference. This may give enough warning to allow you to fly towards yourself and
recover from the radio interference. If you choose to specify a failsafe setting, the failsafe data are automatically transmitted to
the receiver many times during the flight.
Battery Failsafe
Your system provides a second safety function called Battery Failsafe. When the airborne battery voltage drops below
approximately 3.8V, the battery fail safe function moves the throttle to a predetermined position or fast idle, if you haven’t set it.
If this happens, you should immediately land! If you need to increase throttle for your landing approach, you may temporarily
reset the failsafe function by moving the throttle stick to idle, after which you’ll have about 30 seconds of throttle control before
the battery function reactivates.
To set the Fail Safe Function:
1. Enter the programming mode. Access the “F/S” screen with the MODE key.
2. Press DATA Input lever downward when you need to set Fail Safe. The arrow moves to
“F/S” side. This means that the F/S function is activated. Then move the throttle stick to the
position where you want the servo to move when “F/S” function works and press DATA
INPUT lever downward for about two seconds. A figure in percentage will be shown with
a beeping sound. Press DATA INPUT lever upward if you want to set “NOR”. The arrow
moves to “NOR” side and then the “NOR” function is selected.
The F/S value is set to 20% of the full throttle for “F/S” function as a default.
3. Verify if the F/S function has been correctly set. Turn off the transmitter, then check if the
throttle servo move to the position that you set.
31
MODE key
MODE key
SELECT key
DATA INPUT
lever
[CH 2-5]
[CH 2-5]
[CH 2-3]
[Model 2-5]
(press MODE and SELECT keys for one second)
*1. Press the DATA INPUT lever
for 0.5 seconds
*1
*1
*1
*1
*1
*1
*1
Stick Mode
FLOW CHART ACRO MODE FUNCTIONS
(Screen at Startup)
To enter or leave Programming Mode,
press MODE and SELECT keys
simultaneously for one second.
To change the Stick Mode, turn on
the transmitter holding MODE and
SELECT keys down simultaneously.
Use the DATA INPUT lever to display
the desired stick mode.
Simultaneously Press the “MODE” and “SELECT” keys and hold them down for one second to enter the programming
mode. Press the keys again (or turn off the transmitter) to exit the programming mode.
32
Stick Mode
MODE
key
MODE key
SELECT key
DATA INPUT
lever
[CH 2-5]
[CH 2-5]
[CH 2-3]
[2-4]
[2-4]
[2-4]
[2-4]
[Model 2-5]
(press MODE and SELECT keys for one second)
*1. Press the DATA INPUT lever
for 0.5 seconds
*2. Press the DATA INPUT lever
for about two seconds
*1
*1
*1
*1
*1
*1
*2
FLOW CHART HELI MODE FUNCTIONS
(Screen at Startup)
To enter or leave Programming Mode,
press MODE and SELECT keys
simultaneously for one second.
To change the Stick Mode, turn on
the transmitter holding MODE and
SELECT keys down simultaneously.
Use the DATA INPUT lever to display
the desired stick mode.
Simultaneously Press the “MODE” and “SELECT” keys and hold them down for one second to enter the programming
mode. Press the keys again (or turn off the transmitter) to exit the programming mode.
33
OTHER 6EX-2.4GHz FUNCTIONS
Trainer switch (ACRO mode)
To utilize the trainer function, the appropriate trainer cord (available separately) and a second Futaba transmitter (usually
provided by your flight instructor or R/C club) will be required. When two radios are connected with the trainer cord, they are
both capable of operating the model, but it's usually best for the instructor to hold the radio that has been setup for the plane
to be flown (as it is already programmed to fly the model). When the instructor holds the trainer switch on his radio, the student
will have control. When the instructor wishes to regain control he simply releases the switch. Then he will have immediate, full
control.
If connecting the 6EX-2.4GHz to another 6EX-2.4GHz with the small, square “micro” trainer jack, use the “Micro to Micro
(MM-TC) trainer cord (FUTM4415). Never connect the T6EX-2.4GHz trainer system with Futaba radios that have the
large round "DIN" connector type as it will cause malfunction to your T6EX-2.4GHz. The T6EX-2.4GHz transmitter may be
connected to another T6EX-2.4GHz, or any T4EX, T6EXA, T7C, T9C, T12Z, T14MZ, FX-40 series transmitter.
To use the trainer function:
1.
It is best for the instructor to use the transmitter that is already set up for the model to be flown.
2. If the student's radio has PCM/PPM capability, set it to PPM.
3. If the student's radio has a plug-in RF module, remove the module.
4. Collapse the student's antenna when the student’s transmitter is conventional type.
(29-72MHz)
5.
With the transmitters off, connect the trainer cord to both radios. (On the 6EX-2.4GHz the trainer jack is in the center of the
rear of the case.) Do not force the plug into the transmitter and note that the plug is “keyed” so it can go in only one way.
6. Turn on the instructor's transmitter. DO NOT turn on the students transmitter it will automatically “power up, but will not
transmit a signal. Set the servo reversing and trims of the student's radio to match that of the instructor's. If both the
instructor and the student use T6EX2.4G, the F/S function's set-up must be the same in both transmitters.
7. Turn on the receiver switch in the model. Depress the trainer switch on the instructor's radio. Use the student’s radio to
operate the controls (ailerons, elevator, rudder, etc.) and observe how they respond. Make any adjustments necessary to
the student's transmitter to get the controls to respond correctly.
8. Check to see that the trims are in “sync” by toggling the trainer switch back and forth a few times. The controls on the
model should remain stationary. If the controls do not remain stationary, this indicates that the trim settings on the
student's radio do not match those on the instructor's radio. Adjust the student's trims as necessary.
Note: When the instructor initially depresses the trainer switch on his transmitter, there will be a one-second delay before the
student takes control. In most situations this momentary delay will go unnoticed.
Trainer function (HELI mode, student only)
The T6EX-2.4GHz (HELI mode) trainer function lets you practice flying as student by connecting the T6EX-2.4GHz to the
instructors Futaba transmitter.
Throttle-cut function
The throttle-cut function is intended to be used for shutting off the engine. The engine can be conveniently shut off by pressing
the “THR Cut button. The throttle-cut feature prevents inadvertently shutting off of the engine when lowering the throttle stick
all the way (such as when coming in for a landing). Throttle-cut works only when the throttle stick is down. To set up throttle-
cut, turn on the transmitter and receiver. Actuate the throttle-cut function by rapidly depressing, then releasing the switch twice.
Observe the momentary position of the carburetor barrel on the engine. It should be fully closed (thus shutting off the engine).
If necessary, use the throttle E.P.A. (channel 3) to fully close the carburetor barrel when the throttle-cut is activated. Now use
the throttle trim to open the carburetor barrel so the engine will idle at the desired R.P.M. when the throttle stick is all the way
down.
34
Adjustable-length control sticks
The control stick length is adjustable to make the transmitter more comfortable to
hold and operate. To adjust the length, hold the locking piece (B) and turn the
stick tip (A) counterclockwise. Turn the locking piece B up or down to lengthen
or shorten the stick. When the length is suitable, lock the stick in position by
turning locking piece B counterclockwise.
Changing the 6EX-2.4GHz stick mode
The transmitter may be operated in four different stick “modes” (1, 2, 3 & 4). The modes
determine the functions that will be operated by control sticks. Currently, the transmitter is in
“mode 2” and should be left in mode 2 unless you are an experienced flyer and have learned
to fly in a different mode. In mode 2, the right control stick operates the aileron and elevator
and the left stick operates the rudder and throttle. This is how 99% of Americans fly their
models.
To change the mode, simultaneously depress the MODE and SELECT keys, then turn on the power. The current mode will
appear on the LCD screen. Push the DATA INPUT lever up or down to change the mode. If a mode is selected that moves the
throttle control to the right stick, the throttle detent mechanism will have to be moved as well. This can be done by the
Futaba Service Center. (See page 3)
FLYING SAFETY GUIDELINES
Find a suitable flying site (for USA)
If you are a beginning modeler and not yet a member of an R/C club, joining a club and flying at a site specifically intended for
R/C model aircraft is highly recommended. In addition to joining a club, we strongly recommend joining the AMA (Academy
of Model Aeronautics). AMA membership is required to fly at AMA clubs. There are over 2,500 AMA-chartered clubs across
the country. Among other benefits, the AMA provides insurance to its members who fly at sanctioned sites and events.
Additionally, training programs and instructors are available at AMA club sites to help you get started the right way. Contact the
AMA at the address or toll-free phone number below:
cademy of Model Aeronautics
5151 East Memorial Drive
Muncie, IN 47302-9252
Tele. (800) 435-9262
Fax (765) 741-0057
Or via the Internet at: http://www.modelaircraft.org
IMPORTANT:
If you do insist on flying on your own, you must be aware of your proximity to R/C club sites. If there is an R/C site within six
miles of where you are flying, and if you are operating your model on the same frequency as somebody else, there is a strong
possibility that one or both models will crash due to radio interference. There is great potential for an out-of-control model to
cause property damage and/or severe personal injury. We strongly urge you to fly at an R/C club site where frequency control
is in effect so you can be confident you will be the only one flying on your channel.
Charge the batteries
Second to the pilot’s flight skills, one of the most important factors that can determine a model’s longevity is the state-of-
charge of the batteries - especially the on-board receiver pack. Inadequate charging and failing to monitor a battery’s voltage
may lead to low battery power, causing loss of control and a crash. To avoid this, always charge the batteries the night before
you go flying. If ever uncertain how much “charge” is left in a battery, it is wiser to err on the side of caution, rather than trying
to get in one last flight! Due to the number of factors that determine receiver battery power consumption (such as the number
and type of servos in your model, the type of flying you do, how much resistance is built into the controls, the size of the
model, etc.), it is not possible to recommend how many flights one can get on a charge. The best way to monitor battery power
and calculate how much flight time you have left is to use a volt meter to check the batteries after each flight. This can be done
through the battery charging plug coming from the switch. There are many small, hand-held volt meters available specially
intended for R/C use. The Hobbico® Digital Voltmeter MKIII(HCAP0356) is one such unit. An on-board volt meter mounted
directly on the model (HCAP0330) can also be used.
35
FLIGHT PREPARATION
Flight preparation is to be done at the flying field.
If you are an inexperienced pilot, be certain your flight instructor performs these following checks with you.
Check the controls
1. Get the frequency clip from the frequency control board at your flying site if the site have a clip for 2.4GHz.
2. Mount the wing to the fuselage. Turn on the transmitter, then the receiver (remember to do this in reverse order when turning
off the system). Be certain the correct model memory matching the model you will be flying is the one on the LCD screen.
3. Operate and observe the controls. Look for inadvertent movement and listen for abnormal servo sounds. If problems are
noted, correct them before flying. Look for binding pushrods or servo arms or pushrods that interfere with each other.
4. One at a time, operate each control on the airplane using the sticks on the transmitter to make certain each control
is responding correctly. This must be done before every flight. (There are several types of malfunctions that can be
discovered by performing this elementary task, thus saving your model!)
Range check the radio
A range check must be performed before the first flight of a new model. It is not necessary to do a range check before every
flight (but is not a bad idea to perform a range check before the first flight of each day). A range check is the final opportunity
to reveal any radio malfunctions, and to be certain the system has adequate operational range.
1. We have installed a special "Power Down Mode" for doing a ground range check. To activate the "Power Down Mode"
please hold down the “Mode” key and then turn the transmitter switch on. During this mode, the RF power is reduced so the
range test can be performed. When this mode is active the red LED on the back of the transmitter starts blinking and the
green LED is solid. In addition, when the mode is activated the transmitter gives users a warning with a beep sound every 3
seconds, and visual indication.
2. Walk away from the model while simultaneously operating the controls. Have an assistant stand by the model and signal
what the controls are doing to confirm that they operate correctly. You should be able to walk approximately 30 - 50 paces
from the model without losing control.
3. If everything operates correctly, return to the model. Set the transmitter in a safe, yet accessible location so it will be within
reach after starting the engine. Be certain the throttle stick is all the way down, then start the engine. Perform another
range check with your assistant holding the plane and the engine running at various speeds. If the servos jitter or move
inadvertently, there may be a problem. Do not fly the plane! Look for loose servo connections or binding pushrods. Also be
certain that the battery has been fully charged.
4. The "Power Down Mode" continues for 60 seconds and after that the power will go back to the normal level.
To exit the "Power Down Mode" before the 60 seconds, press the "MODE" key again. This mode is available 1 time only so
if you need to re-use this function the transmitter power must be cycled.
5. NEVER start flying when the "Power Down Mode" is active.
Do not fly in the rain!
Moisture may enter the transmitter through the antenna or stick openings and cause erratic operation or loss of control. If you
must fly in wet weather during a contest, be sure to cover the transmitter with a plastic bag or other waterproof cover.
MODEL DATA RECORDING SHEET
After finalizing the programming for each model, fill out the values and settings in the Model Data Recording Sheets in the
back of the manual. The data sheets will serve as a backup in case a program is ever lost or inadvertently reset, or in case you
have to intentionally reset a program to make room for another model. Make additional copies before filling out the sheets.
MENU FUNCTION
REVR Servo Reverse
D/R Dual Rate setting
EPA End Point Adjust
TRIM Trims
EXPO Exponential setting
F/S Failsafe
CH 1 CH 2 CH 3 CH 4 CH 5 CH 6
N R
%
% % %
N R
%
N R N R
%
%
% % %
% %
N R N R
%%%%%%
%%%%%%
%
MIXING SETTING
PMX1 Programmable Mixer 1
Flaperon
V-Tail
Elevon
INH ON
FLPR INH ON
V-TL INH ON
ELVN INH ON
Master Ch
Ailerons differential rate %
Slave Ch Rate- %Sw
CH 2 (Elevator) rate- %CH 4 (Rudder) rate- %
CH 1 (Aileron) rate- %CH 2 (Elevator) rate- %
PMX2 Programmable Mixer 2 INH ON Master Ch Slave Ch Rate- %Sw
FLAP TRIM SETTING
FLTR Flap Trim INH ON
TRAINER SETTING
TRNR Trainer Function INH ON
Flap trim rate % %
MODEL DATA RECORDING SHEET (ACRO)
(Make copies before using)
Model name:
Model No. 1• 2 • 3 • 4 • 5 • 6
Model Type: ACRO
MODEL DATA RECORDING SHEET (HELI)
(Make copies before using)
Model name:
Model No. 1• 2 • 3 • 4 • 5 • 6
Model Type: HELI
MENU FUNCTION
REVR Servo Reverse
D/R Dual Rate setting
EPA End Point Adjust
TRIM Trims
EXPO Exponential setting
F/S Failsafe
CH 1 CH 2 CH 3 CH 4 CH 5 CH 6
N R
%
% % %
N R
%
N R N R
%
%
% % %
% %
N R N R
% % % % % %
% % % % % %
%
MIXING SETTING
N-TH Normal Throttle Curves
Normal Pitch Curves
Idle-UP Throttle Curves
Idle-UP Pitch Curves
N-PI
I-TH INH ON
I-PI
Throttle Hold HOLD
Pitch- Rudder Mixing REVO
Gyro Mixing GYRO
Swashplate TypesSWSH
INH ON
INH ON
INH ON
INH ON
1-S 3-S 3-E
P-1 % P-2 % P-3 % P-4 % P-5 %
P-1 % P-2 % P-3 % P-4 % P-5 %
P-1 % P-2 % P-3 % P-4 % P-5 %
P-1 % P-2 % P-3 % P-4 % P-5 %
Throttle hold position
CH A(Aileron) % %
CH E(Elevator)
CH A(Aileron) % %
CH E(Elevator)
%
CH P (Pitch)
%
% %
% %
Swash-Throttle MixingSW-T INH ON
38
FUTABA CORPORATION
Makuhari Techno Garden Bldg., B6F 1-3 Nakase, Mihama-ku, Chiba 261-8555, Japan
Phone: (043) 296-5119 Facsimile: (043) 296-5124
©FUTABA CORPORATION 2007, 01 (1)
INSTRUCTIONS MANUAL
FEDERAL COMMUNICATIONS COMMISSION
INTERFERENCE STATEMENT
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 according to 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 it found 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 other than the receiver’s
-- Consult the dealer or an experienced radio/TV technician for assistance.
CAUTION:
To assure continued FCC compliance:
(1) Any changes or modifications not expressly approved by the grantee of this device
could void the user's authority to operate the equipment.
FCC Label Compliance Statement:
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.
Exposure to Radio Frequency Radiation
To comply with FCC RF exposure compliance requirements, a separation distance of at
least 20cm must be maintained between the antenna of this device and all persons. This
device must not be co-located or operating in conjunction with any other antenna or
transmitter.

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