Linx Technologies OTX-XXX-LRHSA Long-Range Handheld Transmitter User Manual OTX xxx HH LR8 HS Data Guide 3 30 07

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Document Description	Users Manual
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Date Submitted	2007-04-12 00:00:00
Date Available	2007-04-12 00:00:00
Creation Date	2007-04-04 15:39:49
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Document Lastmod	2007-04-04 15:39:49
Document Title	OTX-xxx-HH-LR8-HS Data Guide 3-30-07.qxd
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Document Author:	justinho

WIRELESS MADE SIMPLE ®
HS LONG-RANGE HANDHELD TRANSMITTER DATA GUIDE
DESCRIPTION
TM
The Linx OTX-***-HH-LR8-HS Long-Range
Handheld Transmitter is ideal for generalpurpose remote control and command
applications which require high security and
long transmission distances. This unit has been
pre-certified for FCC Part 15, Industry Canada,
and European CE (433MHz only) compliance,
reducing costs and time to market. Available in
315, 418 (standard), or 433.92MHz, this small
remote has a transmission range of up to 1,000
feet when combined with an LR Series receiver.
The transmitter unit can be configured with 1 to
8 buttons and the keypad and labeling can be
modified to meet specific OEM customer
requirements.
Security
is
dramatically
enhanced by the on-board HS Series encoder,
which uses Cipherlinx™ technology, a highsecurity encryption algorithm and wireless
protocol. When paired with an HS Series
decoder, transmitter identity can be determined
and button permissions established. The unit
uses a single 3V CR2032 lithium button cell.
FCC, Canada, and CE pre-certified
Highly secure, encrypted transmission
1 to 8 buttons
Customizable keypad
APPLICATIONS INCLUDE
„
„
„
„
„
„
„
Secure Remote Control
Keyless Entry
Garage / Gate Openers
Lighting Control
Call Systems
Home / Industrial Automation
Wire Elimination
1.375"
R 0.2"
2.00"
2.81"
1.35"
1.62"
0.20"
0.60"
Figure 1: Package Dimensions
OFF
ON
ON
OFF
OFF
ON
Ligh
ts O
Poo
ON
FEATURES
„
„
„
„
CipherLinx
Technology
Spa
ON
ON
FASCO
OEM Configurations
With a one-time NRE and
minimum order, Linx can configure
the keypad and label areas to
meet your specific requirements.
Contact Linx for details.
ORDERING INFORMATION
PART #
DESCRIPTION
OTX-***-HH-LR8-HS-xxx HS Long-Range Transmitter
MDEV-***-HH-LR8-HS
HH-LR8 Master Development System
*** = 315, 418 (Standard), 433.92MHz
xxx = Reserved for custom colors. Leave blank for standard black
Revised 3/30/07
ELECTRICAL SPECIFICATIONS
Parameter
Designation
Min.
POWER SUPPLY
Operating Voltage
VCC
Supply Current
ICC
Power-Down Current
TRANSMITTER SECTION
Transmit Frequency Range:
IPDN
SECURITY OVERVIEW
Typical
Max.
Units
Notes
2.1
3.0
3.6
VDC
–
–
3.4
–
mA
–
–
5.0
–
nA
OTX-315-HH-LR8-HS
–
315
–
MHz
–
OTX-418-HH-LR8-HS
–
418
–
MHz
–
OTX-433-HH-LR8-HS
–
433.92
–
MHz
–
FC
Center Frequency Accuracy
–
-50
–
+50
kHz
–
ENVIRONMENTAL
Operating Temperature Range
–
-40
–
+85
°C
Notes
1. Characterized, but not tested
THEORY OF OPERATION
The OTX-***-HH-LR8-HS Long-Range Handheld Transmitter combines an LR
Series transmitter and an antenna with an on-board HS Series encoder to form
a highly reliable and secure RF remote-control transmitter. The LR Series
transmitter is a low-cost, high-performance synthesized OOK transmitter. It’s
synthesized architecture delivers outstanding stability and frequency accuracy,
while minimizing the effects of antenna port loading and mismatching. This
reduces or eliminates frequency pulling, bit contraction, and other negative
effects that are common to SAW-based transmitter architectures, providing a
significantly higher level of performance and reliability.
When a button is pressed on the transmitter, power is applied to the internal
circuitry and the encoder is enabled. The encoder then detects the logic states
of the button data lines. These states are formatted into an encrypted message
that is output to the transmitter module. This cycle continues until the button is
released. The encoder data is used to modulate the transmitter, which conveys
the data into free space through the antenna. Once data is received, a decoder
IC is used to decrypt the transmitter’s commands. If decryption is successful, the
decoder’s outputs are set to replicate the transmitter’s button states. These
outputs can then be used to activate whatever external circuitry is required by the
application.
The transmitter is compatible with several Linx receiver products. For
applications where range is critical, the LR Series receiver is the best choice due
to its outstanding sensitivity. When the transmitter is combined with an LR Series
receiver and an HS Series decoder, ranges of up to 1,000 feet are possible.
Applications operating over shorter distances will also benefit from the increased
link reliability and superior noise immunity provided by the LR Series receiver.
Page 2
The HS Long-Range Handheld transmitter uses the HS Series encoder, which is
based on Cipherlinx™ technology. CipherLinx™ is a high-security encryption
algorithm and wireless protocol designed for remote control and remote keyless
entry applications. It provides a much greater level of security and many more
features than older technologies on the market, such as fixed address or “rolling
code” systems. Additionally, the CipherLinx™ protocol is much more advanced
than the simple PWM method employed by many systems. By utilizing an
advanced serial protocol, CipherLinx™ is able to offer superior noise immunity,
greater range, and greater link reliability, all of which are key factors in a wireless
system.
CipherLinx™ never sends or accepts the same data twice, never loses sync, and
changes codes with every packet, not just every button press. The encryption
that is used in CipherLinx™ is based on the Skipjack cipher developed by the
U.S. National Security Agency (NSA), and is widely considered one of the most
secure ciphers available. The CipherLinx™ algorithm has been evaluated by
Independent Security Evaluators (ISE), a company that has testified before
Congress as experts on electronic security. They concluded that “In short, the
CipherLinx™ protocol in the HS Series is well-designed and is an excellent
choice for applications requiring a secure unidirectional link.”
In addition to this high level of security, CipherLinx™ also offers a number of
features that are unique among remote control products. These include a large
number of data lines, internal key generation, “button level” control permissions,
an optional encoder PIN, as well as the ability for the decoder to identify the
originating encoder.
CipherLinx™ is based on the NSA-designed cipher Skipjack. Skipjack is a block
cipher that has 80-bit keys and 64-bit data blocks. Since each packet is longer
that 64 bits, Skipjack must be employed in an encryption mode. The particular
encryption mode chosen for CipherLinx™ is based on the CMC encryption
mode, so that the resulting cipher is a special kind of function known as a “strong
PRP” (sPRP). The encryption mode uses several invocations of Skipjack to
encrypt the 128 bits in each message. The definition of these terms is quite
involved, but more details can be found in ISE’s evaluation report at
www.cipherlinx.com.
The HS Series uses a 40-bit counter to change the appearance of each
message. This large counter value and the timing associated with the protocol
ensure that the same message is never sent twice and prevents the encoder
from ever losing sync with the decoder.
The user generates the key with the decoder through multiple button presses.
This is ensures that the key is random and chosen from among all 280 possible
keys. Since all of the keys are created by the user and are internal to the part,
there is no list of numbers anywhere that could be accessed to compromise the
system.
The user or manufacturer may also set “button level” Control Permissions.
Control Permissions determine how the decoder will respond to the reception of
a valid command, either allowing the activation of an individual data line or not.
The decoder is programmed with the permission settings during set-up, and
those permissions are retained in the decoder’s non-volatile memory.
Page 3
TYPICAL SYSTEM SETUP
USING THE OPTIONAL KEYPAD PIN
The HS Series Long-Range Handheld Transmitter is intended to make user
setup straightforward while ensuring the highest possible security. This inherent
ease of use can be illustrated by a typical user setup. The Typical Applications
section of the HS Series Decoder Data Guide shows the circuit schematics on
which the receiver examples are based.
1. Create and exchange a key from a decoder to the handheld transmitter
The handheld transmitter includes an onboard infrared receiver designed to
optically receive the decoder’s key
transmission. Sending the key in this
manner preserves security while avoiding
the need for a hardwire connection.
Creation of a keypad PIN
GET_KEY Button
MODE_IND
The high security key is created and
Window
exchanged by placing the decoder in the
Create Key Mode. The decoder’s
MODE_IND LED will light to indicate that
CREATE_PIN
the decoder has entered Create Key
Button
Mode. The decoder’s CREATE_KEY Figure 2: Button Access Holes
button is then pressed ten times to create
the key. After the tenth press, the MODE_IND LED will turn off and the decoder
will output the key via a 900nm infrared diode on the KEY_OUT line. A paper clip
is used to press the GET_KEY button on the back of the transmitter. Hold the
back of the transmitter near the decoder’s infrared diode within twenty seconds.
Once the key has been transferred, the MODE_IND LEDs on the transmitter and
decoder illuminate to indicate success.
2. Establish Control Permissions
Next, the user defines which buttons on the transmitter will be acknowledged by
the decoder. The HS Series Control Permissions allow each transmitter in a
system to activate different data lines. This is especially useful in applications
where differing user access or activation capabilities are desired.
Consider this practical example: a three-door garage houses Dad’s Corvette,
Mom’s Mercedes, and Son’s Yugo. With most competitive products, any user’s
keyfob could open any garage door as long as the addresses match. In an HSbased system, the keyfobs could easily be configured to open only certain doors
(guess which one Son gets to open!).
Setting the control permissions is intuitive. The user presses the decoder’s
LEARN button. The decoder’s MODE_IND LED will start flashing and the user
simply presses the handheld transmitter buttons that will be recognized. Control
Permissions are stored when the LEARN button is pressed again or
automatically after seventeen seconds.
There are other powerful options, such as programming a user PIN or copying a
decoder, but these two steps are all that is required for a typical setup.
Page 4
For higher security applications, the HS Series encoder has the option to set a
Personal Identification Number (PIN) to control access to the encoder. This PIN
is a four-button combination of the eight buttons which must be entered before
the transmitter will send any commands. It will need to be re-entered after fifteen
minutes of inactivity. If no PIN is created, then the transmitter will activate as
soon as a button is pressed.
1. Use a paper clip to press the CREATE_KEY button on the back of the
transmitter. The MODE_IND LED will begin flashing until either a PIN is
successfully entered or fifteen seconds has passed.
2. To enter the PIN, press a sequence of any four buttons. The MODE_IND will
stop flashing and the PIN will be created.
3. To cancel Create PIN Mode prior to the fourth entry, either wait for the fifteen
second timeout to pass or press the CREATE_KEY button. The MODE_IND
LED will stop flashing and no PIN will be created.
4. If a new KEY is created, the PIN will be automatically erased.
Using the PIN
1. The PIN is entered by pressing each button until all four entries have been
made. There is a maximum two-second time limit between entries, after which
the PIN must be re-entered in its entirety.
2. Once the PIN is successfully entered, the transmitter will be operational unless
it is inactive for fifteen minutes, in which case the PIN must be re-entered.
CONTENTION CONSIDERATIONS
It is important to understand that only one transmitter at a time can be activated
within a reception area. While the transmitted signal consists of encoded digital
data, only one carrier of any particular frequency can occupy airspace without
contention at any given time. If two transmitters are activated in the same area
at the same time, then the signals will interfere with each other and the decoder
will not see a valid transmission, so it will not take any action.
BATTERY REPLACEMENT
The transmitter uses a standard CR2032 lithium
button cell. In normal use, it will provide 1 to 2 years
of operation. To replace the battery, remove the
access cover by pressing firmly on the label area and
sliding it off. Once the unit is open, remove the
battery by sliding it from beneath the holder. There
may be the risk of explosion if the battery is replaced
by the wrong type. Replace it with the same type of
battery while observing the polarity shown in the
adjacent figure.
Battery Access
Figure 3: Battery Access
Page 5
OTX-***-HH-LR8-HS BUTTON ASSIGNMENTS
This diagram illustrates the relationship between the button locations and
encoder data lines.
COMPLIANCE REQUIREMENTS
The OTX-***-HH-LR8-HS has been pre-certified by Linx Technologies for FCC
Part 15 and Industry Canada RSP-100 compliance. The 433.92MHz version has
also been tested for CE compliance for use in the European Union. The 315MHz
and 418MHz versions are not legal for use in Europe.
LABELING / INSTRUCTION REQUIREMENTS
The OTX-***-HH-LR8-HS Long-Range Handheld Transmitter has already been
labeled in accordance with FCC, Industry Canada, and CE regulations in effect
as of the date of this document. No further labeling of the unit is needed;
however, it is necessary to include the following statement in the end product’s
instruction manual or insert card for FCC compliance. Industry Canada only
requires the shaded portion. The EU does not require a statement.
D6
D7
D4
D5
D2
D3
INSTRUCTION TO THE USER
D0
D1
This device complies with Part 15 of the FCC Rules.
Operation of this device 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.
Figure 4: OTX-***-HH-LR8-HS Button Assignments
ASSEMBLY DIAGRAM
418MHz
FCC ID: OJM-OTX-XXX-LRMSA
IC: 5840A-LRMSXXXA
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.
This equipment has been certified to comply with the limits for a Class B
computing device, pursuant to FCC Rules. In order to maintain compliance with
FCC regulations, shielded cables must be used with this equipment. Operation
with non-approved equipment or unshielded cables is likely to result in
interference to radio and TV reception. The user is cautioned that changes and
modifications made to the equipment without the approval of manufacturer
could void the user’s authority to operate this equipment.
Figure 5: OTX-***-HH-LR8-HS Assembly
Place the above statement in the instruction manual or insert card.
Page 6
Page 7
TYPICAL APPLICATIONS
100K
100K
GND
R10
R9
100K
100K
R8
R7
100K
100K
100K
R6
R5
R4
R2
U5
DPAK-X2
DPAK-X2
GND
VCC
GND
VCC
C1
4.7uF
TLV2302
GND
GND
R16
9.1M
C4
4.7uF
GND
GND
SW-PB
S2
R14
5.1M
R17
9.1M
VCC
R15
9.1M
U6
AOUT
AINAIN+
GND
VCC
COUT
CINCIN+
GND
GND
B1
BAT-LINX2032
GND
GND
VCC
GND
R3
200
C5
0.01uF
R20
51k
IR1
PS1102
R22
100k
LICAL-DEC-HS001
The TX_ID line will output a
number associated with the
Figure 6: LR Receiver and HS Decoder Schematic
handheld transmitter from
which the signal originated. Linx Application Note AN-00156 shows how to use
this feature.
Data guides for the LR Series receiver, the HS encoder, and the HS decoder can
be found on the Linx Technologies website at www.linxtechnologies.com.
GND
LICAL-ENC-MSHS
D1
LED
R18
9.1M
R21
100k
GND
C3
4.7uF
GND
GND
GND
220
VCC
VCC
220
GND
20
19
18
17
16
15
14
13
12
11
R19
10k
From Copy Input Port
100k
D5
D4
D3
D2
VCC
VCC
D1
D0
DATA_IN
LEARN
100k
100k
D6
D7
SEL_BAUD
SEND_COPY
GND
GND
COPY_IN
CREATE_KEY
KEY_OUT
MODE_IND
GND
GND
VCC
10
10pF
VCC
U4
R1
100k
S1
Learn
U3
DPAK-X2
DPAK-X2
VCC
VCC
VCC
U1
Set for FCC
Compliance
D5
D6
D4
D7
D3
SEL_BAUD
SEL_BAUD1/HS_GND
D2
GND
VCC
GND
VCC
KEY_IN/MS_GND
D1
TX_CNTL
D0
DATA_OUT
SEND
MODE_IND
CREATE_ADDR
LADJ/VCC
TXM-***-LR
RF OUT
GND
GND
GND
RXM-***-LR
R13
DATA IN
GND
TX1
GND
16
15
14
13
12
11
10
ANT
GND
NC
NC
NC
NC
NC
NC
VCC
PDN
GND
NC
NC
NC
GND
VCC
PDN
RSSI
DATA
GND
VCC
C2
As the name suggests, “Send
Copy” allows the users and
associated Control Permissions
of one HS Series decoder to be
transferred to another. This is
useful if the same users and
permissions are desired at
multiple locations, such as the
front door and back door of a
building. Please see the HS
Series Decoder Data Guide for
more information on this
feature.
The decoder has several
unique features, such as Send
Copy, and TX_ID.
GND
The adjacent figure shows a schematic for a typical receiver application. The
handheld transmitter is set to 4,800bps, so the decoder’s SEL_BAUD line will
need to be tied low.
U2
ANT1
ANTENNA
LICAL-DEC-HS001
The transmitter and decoder must be synchronized
before they can work together. This is done by creating
a new encryption key in the decoder, then transferring it
to the transmitter as previously described.
100K
RXM-***-LR
When a button is pressed on the transmitter, a
corresponding line on the decoder will go high. This can
then be connected to external circuitry to perform
whatever function is required by the application.
100K
VCC
R11
SM1
COM
SW8
SW7
SW6
SW5
SW4
SW3
SW2
SW1
The signal sent by the HS Long-Range Transmitter can
be received by an LR Series receiver module. The
outstanding sensitivity of the LR Series receiver offers
the best range when used with a Linx OEM transmitter.
The receiver module is then connected directly to an HS
Series decoder, which will decrypt the transmitted signal.
Figure 7: OTX-***-HH-LR8-HS Schematic
Page 8
Page 9
MASTER DEVELOPMENT SYSTEM
The Master Development System is intended to give a designer all the tools
necessary to incorporate the Long-Range Handheld transmitter, LR Series
receiver, and HS Series decoder into a product. The Master Development
System serves several important functions. It allows the performance and
features of the transmitter, LR Series, and HS Series to be quickly evaluated. It
shows how to design with the receiver and decoder and how to interface with
other components. It also demonstrates the overall system function, making it
easy to develop the initial system design. It allows for additional circuitry to be
placed directly on the board so that it can act as the first prototype of the product.
All of the signals are available on a wire-wrap header for easy connection to
external circuitry.
ONLINE RESOURCES
®
www.linxtechnologies.com
•
•
•
•
•
Latest News
Data Guides
Application Notes
Knowledgebase
Software Updates
If you have questions regarding any Linx product and have Internet access,
make www.linxtechnologies.com your first stop. Our website is organized in an
intuitive format to immediately give you the answers you need. Day or night, the
Linx website gives you instant access to the latest information regarding the
products and services of Linx. It’s all here: manual and software updates,
application notes, a comprehensive knowledgebase, FCC information, and much
more. Be sure to visit often!
Figure 8: OTX-***-HH-LR8-HS Master Development System
www.antennafactor.com
When the decoder board is plugged into a USB port on a PC, the kit can be used
to activate the features in the included software. When a data line goes high on
the decoder, a microcontroller sends a command to the computer via a Linx USB
interface module to control functions in the software. Please see the
documentation included with the Development System for details.
The Antenna Factor division of Linx offers
a diverse array of antenna styles, many of
which are optimized for use with our RF
modules. From innovative embeddable
antennas to low-cost whips, domes to
Yagis, and even GPS, Antenna Factor
likely has an antenna for you, or can
design one to meet your requirements.
www.connectorcity.com
Through its Connector City division, Linx offers a wide
selection of high-quality RF connectors, including FCCcompliant types such as RP-SMAs that are an ideal
match for our modules and antennas. Connector City
focuses on high-volume OEM requirements, which
allows standard and custom RF connectors to be offered
at a remarkably low cost.
Figure 9: The HS Series Master Development Software
Page 10
Page 11
WIRELESS MADE SIMPLE ®
U.S. CORPORATE HEADQUARTERS
LINX TECHNOLOGIES, INC.
159 ORT LANE
MERLIN, OR 97532
PHONE: (541) 471-6256
FAX: (541) 471-6251
www.linxtechnologies.com
Disclaimer
Linx Technologies is continually striving to improve the quality and function of its products. For
this reason, we reserve the right to make changes without notice. The information contained in
this Data Guide is believed to be accurate as of the time of publication. Specifications are based
on representative lot samples. Values may vary from lot to lot and are not guaranteed. Linx
Technologies makes no guarantee, warranty, or representation regarding the suitability or
legality of any product for use in a specific application. None of these devices is intended for use
in applications of a critical nature where the safety of life or property is at risk. The user assumes
full liability for the use of product in such applications. Under no conditions will Linx Technologies
be responsible for losses arising from the use or failure of the device in any application, other
than the repair, replacement, or refund limited to the original product purchase price.
© 2007 by Linx Technologies, Inc. The stylized Linx logo,
Linx, “Wireless Made Simple”, CipherLinx and the stylized
CL logo are trademarks of Linx Technologies, Inc.
Printed in U.S.A.

---

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