LC Series
Basic Evaluation Kit
User's Guide
customers
may("RF")
wantproducts
Linx radiomay
frequency
(“RF”)
Linx radio
frequency
be
! Warning: Some
products
to
control
machinery
or
devices
remotely,
including
machinery
used to control machinery or devices remotely, including machinery
or
or devices
devices that
that can
can cause
cause death,
death, bodily
bodily injuries,
injuries, and/or
and/or property
property
damage
if
improperly
or
inadvertently
triggered,
particularly
damage if improperly or inadvertently triggered, particularly in
in industrial
industrial
settings
or
other
applications
implicating
life-safety
concerns
and
settings or other applications implicating life-safety concerns.(“Life
No Linx
Property Safety Situations”).
Technologies product is intended for use in any application without
redundancies where the safety of life or property is at risk.
NO OEM LINX REMOTE CONTROL OR FUNCTION MODULE
SHOULD EVER BE USED IN LIFE AND PROPERTY SAFETY
The customers No
andOEM
usersLinx
of devices
machinery
controlled
with
SITUATIONS.
Remoteand
Control
or Function
Module
RF products
must understand
must Safety
use all Situations.
appropriate Such
safety
should
be modified
for Life andand
Property
procedures incannot
connection
with
the devices,
without
limitation,
modification
provide
sufficient
safetyincluding
and will void
the product’s
using appropriate
safety
procedures
regulatory
certification
and
warranty. to prevent inadvertent triggering by
the user of the device and using appropriate security codes to prevent
Customers
use our controlled
(non-Function)
Modules,
Antenna
and of other
triggering ofmay
the remote
machine
or device
by users
Connectors
as
part
of
other
systems
in
Life
Safety
Situations,
but
remote controllers.
only with necessary and industry appropriate redundancies and
in
with
safety standards,
without
Docompliance
not use this
or applicable
any Linx product
to triggerincluding
an action
directly
limitation, ANSI and NFPA standards. It is solely the responsibility
from the data line or RSSI lines without a protocol or encoder/
of any Linx customer who uses one or more of these products to
decoder to validate the data. Without validation, any signal from
incorporate appropriate redundancies and safety standards for the Life
another
unrelated
transmitter
the environment received by the
and
Property
Safety
Situation in
application.
module could inadvertently trigger the action. This module does not
havenot
data
builtLinx
in. product to trigger an action directly
Do
usevalidation
this or any
from the data line or RSSI lines without a protocol or encoder/
All RF products
are susceptible
to RFvalidation,
interference
can
prevent
decoder
to validate
the data. Without
any that
signal
from
another
unrelated RF
transmitter
the environment
the module
communication.
productsinwithout
frequencyreceived
agility orby
hopping
could
inadvertently
trigger
the action.
implemented
are more
subject
to interference. This module does not
have frequency agility built in.
All RF products are susceptible to RF interference that can prevent
communication.
RF products
or hopping
Do not use any Linx
product without
over thefrequency
limits in agility
this data
guide.
implemented are more subject to interference. This module does have
Excessive voltage or extended operation at the maximum voltage could
a frequency hopping protocol built in, but the developer should still be
cause product failure. Exceeding the reflow temperature profile could
aware of the risk of interference.
cause product failure which is not immediately evident.
Do not use any Linx product over the limits in this data guide.
Do not make
any or
physical
or operation
electrical at
modifications
any Linx
Excessive
voltage
extended
the maximumtovoltage
could
product.
This will
voidExceeding
the warranty
regulatory
and UL
certifications
cause
product
failure.
theand
reflow
temperature
profile
could
and may
causefailure
product
failure
which
is not immediately
cause
product
which
is not
immediately
evident. evident.
Do not make any physical or electrical modifications to any Linx
product. This will void the warranty and regulatory and UL certifications
and may cause product failure which is not immediately evident.
Table of Contents
1^
2^
2^
3^
4^
4^
5^
6^
7^
8^
8^
9^
10^
11^
Introduction
Ordering Information
LC Transmitter Evaluation Board
LR Receiver Evaluation Board
Theory of Operation
Using the Kit
Development Using the Prototyping Area
Range Testing
Using the Boards as a Design Reference
About Antennas
In Closing
Online Resources
LR Receiver Evaluation Board Schematic
LC Transmitter Evaluation Board Schematic
LC Series Basic Evaluation Kit
User's Guide
Figure 1: LC Series Basic Evaluation Kit
Introduction
Linx LC Series RF modules offer a simple, efficient, and cost-effective
method of adding wireless communication capabilities to any product. The
Basic Evaluation Kit gives a designer all the tools necessary to correctly
and legally incorporate the LC Series modules into an end product. The
development boards themselves serve several important functions:
• Rapid Module Evaluation: The boards allow the performance of the LC
Series modules to be evaluated quickly in a user’s environment.
• Range Testing: Using the on-board encoders and decoders to generate
a simplex transmission, a pair of evaluation boards can be used to
evaluate the range performance of the modules.
• Design Benchmark: The boards provide a known benchmark against
which the performance of a custom design may be judged.
• Application Development: An onboard prototyping area allows for the
development of custon circuits directly on the evaluation board. All
signal lines are available on a header for easy access.
The kit includes 2 LC Series transmitters*, 2 LR Series receivers*, 2 extra
PCB-mount RP-SMA connectors, 2 evaluation boards, 2 CW Series
antennas, 1 CR2032 battery, 2 AAA batteries and full documentation.
* One part is soldered to each board. One extra is for use on your first prototype boards.
– 1–
Revised 3/19/14
Ordering Information
LR Receiver Evaluation Board
Ordering Information
2
Part Number
Description
EVAL-***-LC
LC Series Basic Evaluation Kit
7
5
*** = 315, 418 (Standard), 433MHz
1
Figure 2: Ordering Information
4
3
LC Transmitter Evaluation Board
6
9
7
8
3
8
1
4
5
6
9
2
Figure 4: LR Receiver Evaluation Board
1. Battery – 3VDC (use 2 AAA
style batteries only)
2. Power Switch
3. Prototyping Area
4. Breakout Header
5. LR Series Receiver Module
6. MS Series Decoder
7. Reverse-Polarity SMA Antenna
Connector
8. LED - D1
9. Buzzer - D0
Figure 3: LC Transmitter Evaluation Board
1. Battery - 3VDC (use a
CR2032-style battery only)
2. Power Switch
3. Continuous ON Switches
4. Momentary Pushbuttons
5. Prototyping Area
6. Breakout Header
7. Reverse-Polarity SMA Antenna
Connector
8. LC Series Transmitter Module
9. MS Series Encoder
– 2–
– 3–
Theory of Operation
Development Using the Prototyping Area
Transmitter Evaluation Board
The transmitter board is powered by an on-board 3V CR2032 lithium
battery. It has eight SPST pushbutton switches, the state of which is
encoded into a data stream using a Linx MS Series encoder. If a switch
is closed, the transmitter is enabled while the encoder captures the
pushbutton states for encoding and transmission. The encoder powers
down the transmitter when the button is released. All of the data lines have
been wired out to the header to the right of the prototyping area and can
be accessed for use with other switches, contacts or microcontrollers.
In addition to their evaluation functions, the boards may also be used for
product development. They feature a prototyping area to facilitate the
addition of application-specific circuitry. This area has a connection to
VCC at the top and ground at the bottom that can be used to power any
circuitry that is added.
Receiver Evaluation Board
The receiver board is powered by two AAA batteries. The LR Series
receiver exhibits a sensitivity of greater than –112dBm, so under optimum
line-of-sight conditions, the transmitter / receiver link can operate over
distances of up to 3,000 feet (1,000m). The data recovered by the LR
Series receiver is decoded by a MS Series decoder, and the data lines
are updated to match the state of the data lines (or pushbuttons) on the
transmitter board. To demonstrate this, one data line is used to drive a
LED while another is used to activate a buzzer. This board also has a
prototyping area with all of the receiver and decoder lines brought out to a
header.
The holes are plated and set at 0.1" on center with a 0.04" diameter,
making it easy to add most industry-standard SIP and DIP packages to the
board.
Note: The CR2032-style battery on the transmitter board has very low
current capacity with, only about 3mA available for external circuitry. If
added circuitry requires a higher current, the battery must be removed
and the board powered from an external source.
On the transmitter board, the data lines from the encoder have been wired
out to a row of plated holes on the right side of the prototyping area. On
the receiver board, the data lines from the decoder plus the RSSI, PDN,
and DATA lines from the receiver have been wired out. This allows for easy
access to connect external circuitry to the modules, the encoder, and the
decoder. Data line D0 is connected to the buzzer and D1 is connected to
the LED.
Using the Kit
Using the kit is straightforward. Simply attach the antennas, turn on the
power and press buttons on the transmitter board. When S0 is pressed,
the buzzer sounds; when S1 is pressed, the LED turns on. When any
button (S0–S7) is pressed on the transmitter board, the corresponding
decoder output (D0–D7) is active high (VCC) on the prototyping header.
– 4–
– 5–
Range Testing
Several complex mathematical models exist for determining path loss in
many environments. These models vary as the transmitter and receiver are
moved from indoor operation to outdoor operation. Although these models
can provide an estimation of range performance in the field, the most
reliable method is to simply perform range tests using the transmitter and
receiver in the intended operational environment.
Basic range testing can be performed with the ransmitter and receiver
evaluation boards. To prepare the board for range testing, turn it on
by switching the power switch to the ON position. Pressing S0 on the
transmitter activates the buzzer on the receiver board, while S1 activates
the LED. Switches SW0 and SW1 have been provided to jumper the
buttons and continuously transmit. This allows the designer to turn on the
transmitter and walk with the receiver.
As the maximum range of the link in an area is approached, it is not
uncommon for the signal to cut in and out as the transmitter moves. This
is normal and can result from other interfering sources or fluctuating signal
levels due to multipath. Multipath results in cancellation of the transmitted
signal as direct and reflected signals arrive at the receiver at differing times
and phases. The areas in which this occurs are commonly called “nulls”
and simply walking a little further usually restores the signal. If this does not
restore the signal, then the maximum effective range of the link has been
reached.
the battery, switch positions, and antenna connection. Next, measure
the receiver’s RSSI voltage with the transmitter turned off to determine
if ambient interference is present. If this fails to resolve the issue, please
contact Linx technical support.
Using the Boards as a Design Reference
The basic evaluation boards included in this kit are very simple, yet they
illustrate some important techniques that should be incorporated into the
board layout. The module’s mounting pads extend slightly past the edge of
the part. This eases hand assembly and allows for better heat conduction
under the part if rework is necessary. A full ground plane fill is placed on the
bottom of the board. This ground plane serves three important purposes:
First, since a quarter-wave antenna is employed, the ground plane is
critical to serve as a counterpoise (please see Application Note AN-00500
“Antennas: Design, Application, and Performance” for details on how a
ground plane affects antenna function).
Second, a ground plane suppresses the transfer of noise between stages
of a product as well as unintentional radiation of noise into free space.
Third, a ground plane allows for the implementation of a microstrip feed
between the module and the antenna. The term microstrip refers to a PCB
trace running over a ground plane that is designed to serve as a 50-ohm
transmission line. See the LC Series data guide or the calculator available
on our website for details on microstrip calculations.
Since the evaluation boards are intended for use by design engineers,
they are not FCC certified. The transmitter has been set to approximate
legal limits by resistor R9 so that the range test results will approximate the
results from a well-designed, certified product. For applications where Part
15 limits are not applicable or output levels can be legally raised due to
protocol duty cycle, R9 can be changed according to the Output Power vs.
LADJ Resistance graph in the LC Series Transmitter Module Data Guide.
To achieve maximum range, keep objects such as your hand away from
the antenna and ensure that the antenna on the transmitting board has a
clear and unobstructed line-of-sight path to the receiving board. Range
performance is determined by many interdependent factors. If the range
you are able to achieve is significantly less than specified by Linx for the
products you are testing, then there is likely a problem with either the board
or the ambient RF environment in which the board is operating. First, check
– 6–
– 7–
About Antennas
Online Resources
The choice of antennas is one of the most critical and often overlooked
design considerations. The range, performance, and legality of an RF link
are critically dependent upon the type of antenna employed. Linx offers
a variety of antenna styles that can be considered for a design. Included
with your kit are HD Series (315MHz) or CW Series (418MHz and 433MHz)
connectorized whip antennas that should be connected prior to using the
kit. Despite the fact that the antenna is not centered on the board’s ground
plane, it exhibits a VSWR of