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| This
Evaluation Kit can be used to evaluate single frequency
Radiometrix VHF/UHF transmitter, receiver and transceiver
modules. LED indicators are provided to show system status
and to facilitate range testing and site surveys. The
board is controlled by the Eval-RPC chip and incorporates
several useful diagnostics & debug modes. Link-selectable
9.6kbps or 64kbps data rate. |
Universal Evaluation Board |
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Features
- Range Testing
- Target Environment Testing
- Noise and Interference Identification
- Antenna Evaluation
- TX1(H)/HX1/RX1, NTX2/NRX2, TX2(A)/TX2H/RX2(A),
TX3A/RX3A, BiM1T/ BiM1R, CVR1, BiM/1/2/3A and NiM2 hardware
test
- Transient Analysis
- Communication Eye Diagrm
- Analogue and digital data transmission
- Received Signal Strength Indicator (RSSI)
meter
- Linking external hardware directly or
via on board Eval RPC
- Responses up to 9.6kbps (A) or
64kbps (F)
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| The Eval-RPC is based upon
a modified RPC-000-DIL design and provides management of all
the necessary data and control lines. The user can define both
operational mode and data bit rate simply by selecting the required
positions on the provided DEBUG switch and the various jumpers.
Indication of unit status is provided by means of LEDs for Power,
Transmit, Receive, Carrier Detect, Signal and OK (link success)
functions. |
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| Check List
The Universal Evaluation Kit should include
the following components and documentation:
- 2 Analogue input/output boards
- 2 Parallel port interface adaptor
- 2 9V battery (PP3)
- 2 1/4 wavelength whip for 418/433MHz,
869/914MHz and helical antennas for 173MHz
- 2 10.24MHz crystals
for 40kbps operation
- 2 FRPC-000-DIL (optional)
- 2 20.48MHz crystals for 160kbps operation
(optional)
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In addition to the above a 2-channel (or
even better, a 4-channel) digital storage oscilloscope is
highly recommended as a means of monitoring system operation.
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| Visual Facilities
The following status LEDs will be activated
depending on which mode is selected:
| LED |
Indication |
| TX (Red) |
Transmitter enabled |
| RX (Green) |
Receiver enabled |
| CD (Orange) |
Carrier
/ Interference detected |
| SIGNAL (bright Red): |
Preamble detected |
| OK (bright Yellow) |
Valid packet received
/ Test passed |
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| The Received Signal Strength Indicator (RSSI)
meter on the analogue I/O board provides an indication of the
received RF signal power level, useful in range testing and
when checking for interference. |
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Diagnostic Modes
| Mode |
Name |
Function |
| 0 |
RX-ON |
preamble detector on
(SIGNAL LED lit = preamble detected) |
| 1 |
RX-PULSE
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7ms on: 10ms off, preamble
detector on SIGNAL LED |
| 2 |
TX-ON-PRE |
Preamble modulation -
send continuous preamble on TX |
| 3 |
TX-ON-SQ |
100Hz square wave modulation,
for TX testing using spectrum analyser, etc |
| 4 |
TX-ON-255 |
256 bit pseudo-random
data for eye diagram tests, sync on RXR |
| 5 |
TX-PULSE |
8ms on / 8ms off, preamble
bursts for Rx lock-in tests |
| 6 |
ECHO |
Transponder
mode, unit re-transmits any valid packets received |
| 7 |
RADAR |
Send ASCII test packet
"Universal Eval Kit XX" and listen for echo |
| 8 |
Self-test |
Local loop test, TX à
RX (OK on RXR) |
| 9 to E |
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For
future updates on additional Modes, check the Radiometrix
web site |
| F |
Normal RPC |
Normal Eval RPC mode allows
external host microcontroller or PC interface |
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Jumper Links
| Jumper Links |
Function |
| LK1 |
Short TXR to 0V pin to
enter diagnostic modes |
| LK2 |
Select the data rate according
to module requirements
Across left & middle pins (A position) for 9.6kbps,
Across middle & right pins (F position) for 64kbps |
| LK3 |
Remove to disconnect Eval-RPC
data from the module TXD line when using external analogue
/ digital data or to transmit unmodulated carrier. |
| LK4 |
Insert to reduce Eval-RPC
drive amplitude to module TXD from 0-5V to 0-3V. e.g.
TX1(H), NTX2, TX3A, BiM1 and BiM3A. LK5 should also be
removed |
| LK5 |
Insert to operate with
standard 0-5V Eval-RPC drive amplitude. LK4 should also
be removed |
| LK6 |
Insert to enable Carrier
Detect LED (For RX2, BiM/BiM2 only). |
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LK1
Eval RPC has two modes of operation:
1) Normal mode (Jumper removed)
2) Diagnostic mode (Jumper inserted)
In normal mode, the Eval-RPC behaves similarly to a Radio
Packet Controller (RPC). The board can be used in conjunction
with a host microcontroller or PC to transmit & receive
packetised data.
Diagnostic mode can be used to evaluate system performance
in the intended environment.
LK2
This link connects the appropriate crystal to the Eval-RPC
oscillator circuit for data bit rate selection.
Crystal Frequency
All timings within the Eval RPC (except sleep) are determined
by the clock frequency. The standard frequencies are 2.4576MHz
and 16.384MHz.
 
Figure 1: Jumper selection for data
rate |
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When the Jumper is placed as shown on the above left diagram,
2.4576MHz, the Eval RPC will transmit data at 9.6kbps.
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| TX2/RX2 and BiM module performance at 40kbps
can be evaluated by replacing one of the standard crystals with
the 10.24MHz unit supplied. |
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LK3
The module TXD line is normally driven directly with data
from the Eval-RPC chip. However, it can also be driven from
an external digital or analogue source if required. In this
case, removing LK3 allows the TXD line to be disconnected
from the internal Eval-RPC data for correct operation.
LK4
The TX2, HX1, BiM and BiM2 operate on 5V supply and hence
their TXD input can be in 0-5V range. However, TX1, NTX2,
TX3A, BiM1 and BiM3A operate internally on 3V supply and their
data input should be in 0-3V range.
This LK4 jumper link grounds the R4, making a parallel connection
to the TXD input.
Very high input impedance of TXD with R4 resistor in parallel
combination will give effective impedance equivalent to R4
(3.3k) resistor. R3 (2.2k) and R4 (3.3k) will form a potential
divider reducing the logic level from 0-5V to 0-3V range.
LK5 jumper should be removed while LK4 jumper link is inserted
LK5
Removing the LK4 jumper and linking the LK5 returns the Eval-RPC
drive amplitude of module TXD back to 0-5V
LK6
The RX2 and BiM/BiM2 modules have Carrier Detect (CD) output
instead of RSSI output featured on RX1, RX2A, NRX2, RX3A,
BiM1 and BiM3A modules. Inserting the LK6 will enable the
CD LED to work with RX2 and BiM/BiM2 modules. It should be
removed when evaluating modules with RSSI output and CD LED
output should also be ignored.
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Diagnostic Modes
To enter the DEBUG mode, Jumper Link (LK1) (below the 9V
battery) should be connected across TXR and 0V pin. The RESET
button should be pressed while the Jumper Link is connected
across TXR and 0V.
Note: All the Oscilloscope
screen capture and Spectrum Analyser screen capture given
on the manual are instantaneous and they will vary with time.
Mode 0 -
Preamble Detector
Applies to Evaluation Kit with Receiver:
Insert Receiver module in one of the Evaluation Kit and Transmitter
module on another.
Transmitting and Receiving unit should operate at same data
rate. i.e. LK2 position on both evaluation kit should be same
position on both evaluation kits.
If the jumper LK2 is at position A, the preamble will be a
4.8kHz or 9.6kbps square wave signal.
In this mode, receiver is continuously powered up (RX LED
on) and if preamble, 32kHz or 64kbps square wave signal, with
jumper LK2 at position F, is detected the SIGNAL line is pulled
low lighting the SIGNAL LED. RXR will also be pulled low lighting
the OK LED to indicate that valid preamble was received.
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Figure 2: Transmitted and received preamble (64kbps square
wave signal) |
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| In the above screen capture of a 4-channel
oscilloscope:
An Evaluation Kit with Transmitter is powered on (TX LED
on) continuously (Mode 2) to transmit preamble. The TX line
is held low (blue TX waveform) by the Eval-RPC and it feeds
32kHz square wave signal into TXD pin (green TXD waveform)
of the Transmitter. Oscilloscope is triggered on TXD.
Other Evaluation Kit with receiver is also powered on (green
RX LED on) continuously (Mode 0). AF output (red AF waveform)
and RXD output (brown RXD waveform) are monitored.
The AF output is at 1.16V DC with about 240mV AC sine wave,
which is digitised by the Adaptive Data Slicer in the Receiver
to re-produce the received preamble. (Ground level of AF is
at the bottom of the screen)
Note: LK3 should be removed
when connecting analogue I/O board.
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Mode 1 - Pulsed Receiver
Applies to Evaluation Kit with Receiver:
Receiver is switched on for about 7ms and Eval RPC checks
for preamble. If preamble is detected the SIGNAL line is pulled
low. This will light up the SIGNAL LED. If not, the Receiver
is turned off for about 10ms and the process is repeated.
OK LED will also light up if a valid Preamble is detected.
Figure 3: receiver power up to valid data timing measurement
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| This mode can be used to test the power
up time and settling time of the receiver module. |
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2 - Transmit Preamble Modulation
Applies to Evaluation Kit with Transmitter:
Transmitter is turned on continuously and preamble
is transmitted. This complement mode can be used with Mode
0 as a pair.
Figure 4: Transmitter spectrum with 32kHz (64kbps) square
wave modulation
The above frequency spectrum shows a Carrier
Frequency in the middle and FM side bands on both sides. Each
side band is spaced 32kHz apart. This mode can also be used
to measure modulation bandwidth at maximum data rate.
Note: Mode 2, with LK3 removed,
can be also be used as TX On mode to switch on the transmitter,
when feeding analogue signal or external data. LK3 should
also be removed when analogue I/O board is connected.
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Mode 3 - Transmit 100Hz (200bps) square
wave modulation
Applies to Evaluation Kit with Transmitter:
Transmitter is turned on and the carrier
is modulated by 100Hz or 200bps square wave signal. This mode
can be used to test the Transmitter on a Spectrum Analyser.
It can be used to measure RF power output, Peak FM deviation
and frequency offset.
Figure 5: TX2-433-40 spectrum with 100Hz square wave modulation
The RF output power on the above
spectrum is the maximum peak value of about +10dBm. The above
spectrum shows 2 prominent peaks. The peak to peak spacing
is twice the peak FM deviation value. Left peak will be at
same position as unmodulated carrier when TXD is at 0V. Right
peak will be at the same position as unmodulated carrier when
TXD is at 5V.
Note: Universal
Eval Kit uses a common 50W microstrip
track between transmitter, receiver, transceiver and the antenna
connector, instead of an RF switch. Therefore, actual measured
RF output power will appear to be few dB lower.
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Figure 6: Transmitted and received 100Hz (200bps) square wave
signal |
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RF Carrier will not be modulated by the data from Eval RPC
if the LK3 is removed. The spectrum of unmodulated carrier
with TXD held at 0V is given below
Figure 7: Unmodulated transmitter spectrum when TXD is at
0V
It can be used to check the phase noise of the transmitter.
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Mode 4 - Transmit Random Code
Applies to Evaluation Kit with Transmitter:
Transmitter is turned on and the carrier is modulated by
a 8 bit maximal length (255) pseudo-random code at 15.6ms
per bit (at 64kbps). On the receiving end, the data output
RXD line can be connected to an Oscilloscope to obtain an
eye diagram.
Figure 8: Transmitted and received pseudo-random code
Eye Diagram:
An eye diagram is an oscilloscope display in which a pseudo-random
digital data signal from AF output of a receiver is repetitively
sampled and applied to the vertical input, while the data
rate (RXR) on the transmitting unit is used to trigger the
horizontal sweep. The picture one obtains is a superposition
of ones and zeros output.
Figure 9: eye diagram of receiver
System performance information can be derived by analyzing
the display. The horizontal width of the lines gives the jitter
(phase noise) and the rise and fall times of the data pulses
can be measured from the "crossings". An open eye
pattern corresponds to minimal signal distortion. Distortion
of the signal waveform due to intersymbol interference and
noise appears as closure of the eye pattern.
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Figure 10: spectrum of BiM2-433-64 when transmitting pseudo-random |
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5 - Pulsed Preamble Transmitter
Applies to Evaluation Kit with Transmitter:
The transmitter is turned on for about 8ms and normal preamble
(length used for normal data transmission) is sent. Then transmitter
is turned off and waits for equal amount of time before another
cycle.
Figure 11: TX spectrum when transmitter is pulsed to transmit
preamble
Figure 12: pulsed preamble transmission and received preamble
This mode can be used to test the power up time of transmitter
and settling time of the receiver module when receiver is
already powered up.
Mode 6 - Echo
Applies to Evaluation Kit with Receiver (and Transmitter):
Receiver is turned on. Checks for preamble and if it finds
a preamble, then it locks on to the data and receives the
data packet. SIGNAL LED will be turned on if the preamble
is detected.
Then error check is carried out on the received data and if
it passes, the OK LED is turned on and waits for a Transmit
to Receive Change Over Delay period. Then it retransmits (echoes
back) the packet to the transmitter.
Figure 13: Receiver unit echoing back to transmitting unit
on every valid packet
The above oscilloscope screen capture shows RXR line pulled
Low every time valid packet is received. Same RXR line activates
the OK LED.
In the oscilloscope screen capture below, the receiving (mode
6) unit's echo did not reach the transmitting (mode 7) unit.
Therefore, transmitting moves onto transmitting next packet
after waiting for the time required to detect preamble of
the echo packet.
Note: This may also happen
if the Transmitter is removed from the receiving (mode 6)
unit.
Figure 14: Transmitting unit moves to next transmission because
echo was not received
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Mode 7 - Radar
Applies to Evaluation Kit with Transmitter (and receiver):
Transmitter is turned on and sends a packet with Universal
Eval Kit XX as data where XX will be a Packet Counter
from 00 to 63. Then transmitter is turned off and receiver
is turned on for 8ms. Checks for preamble and if it finds
a preamble, then it locks on to the data and receives the
packet. Then error check is carried out and if it passes,
OK LED will be lit.
Nevertheless, it will continue the above process but the
packet counter value will be increased with each transmission.
This mode can be used along with Mode 6 (Echo Mode) to function
as a 'Pin-Pong' system. This provides a very effective method
for Range Testing and Antenna Type Evaluation.
If one eval kit is set to Mode 6, then other eval kit can
be set to Mode 7. By walking around the site where the final
product based on the Radiometrix Modules are going to be used,
the range and antenna type requirements, interference, etc
could identified well in advance. The OK LED will be ON as
long as the 'Ping-Pong' the units are within the radio range
and the wireless link is error free.
OK LED will start to flicker on the Eval Kit set to mode
7, if some of the echoed packets are received with bit errors.
Note: Operating range of the
modules will apper to be shorter due to the RF power loss
in the common 50W microstrip.
Figure 15: Receiver unit sampling (RXD output) received data
bit but echo was received
Figure 16: TX spectrum when transmitting radar mode ASCII
data packet
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Mode 8 - Local Loop Test
Applies to Evaluation Kit with both Transmitter and Receiver:
This Eval RPC puts the transceiver or transmitter & receiver
pair on same Eval kit into a local loop back (both TX &
RX on), a test code is continuously sent and recovered. The
SIGNAL LED will light to indicate a pass.
Figure 17: TX spectrum when transmitting unbalanced test code
Figure 18: Transmitted and received unbalanced test code
Figure 19: expanded view of the unbalanced
test code
The above waveform shows the test pattern used to evaluate
receiver and its Adaptive Data Slicer.
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F - Normal RPC Mode
Jumper Link (LK1) (below the 9V battery) should be removed
and the RESET button should be depressed.
This will effectively put the Eval RPC into normal (non-diagnostic)
mode. Therefore, any interface cable with Host Microcontroller
or Parallel Port of a PC can be interfaced with the Eval Kit.
Figure 20: Transmitted and received 27-byte (full length)
data packet
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The trace below is a close up of the transition
from preamble to Data to 12-bit encoded data bytes with 7 bit
Barker sequence in the middle used to identify the start of
the encoded data bits.
Figure 21: Expanded view of the preamble to encoded data bit
transition |
| More details on the above data packet format
is given on pages 17-19 of the
SP2 data sheet. |
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PC Interface
Parallel Port Interface Adaptor can be used to interface
the Universal Evaluation Kit to Parallel port using standard
D25 parallel port extension cable (One to One connection with
D25 plug connector on one end and D25 socket on other end)
RPC Development Kit software can be used to view/modify the
RPC EEPROM values. Data transmission can also be monitored
using the same software.
This feature will help debug the host software routines in
the design & development stage of a product.
Figure 22: RPC Dev-Kit software showing the default EEPROM
values of Eval RPC
Note: RPC development kit
software runs on the MS-DOS operating system or Windows 95/98/98SE/ME.
It will not run under NT4.0/XP/2000
Figure 23: Eval RPC to Parallel port interface
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| Analogue
Signal
Even though the Radiometrix modules are specifically designed
for data transmission, they can also be used for analogue
transmission excluding signals which contain DC level or very
low frequency components.
Analogue I/O board should be connected to the 10-pin header
(J12) on top right hand corner of the Evaluation Kit. Jumper
link on LK3 should also be removed to disconnect the TXD line
from Eval RPC's data pin.
Analogue I/O contains:
1) Analogue transmit signal amplifier
2) Buffered audio output for stereo headphone/speaker.
DC component in the analogue signal is removed via capacitor.
A simple common emitter amplifier with negative feedback is
used to amplify the small AC signal from few mV to few Volts.
Signal level on TXD pin should be large enough to cause enough
FM deviation on the RF carrier of the transmitter. Otherwise,
the small demodulated AF output, under poor signal to noise
ratio (S/N) conditions, will be indistinguishable or submerged
in the noise. The AC signal is also biased at 1.25V, so that
it is at half the transmit data voltage swing of 0-3V.
User can feed a function/waveform generator output through
the Analogue In and receive the analogue output on the other
kit to evaluate the performance of the module under various
signal frequencies and amplitudes.
Note: a large signal on the
Analogue input will saturate the amplifier and clipping may
occur on the amplified signal.
Audio Frequency (AF) output can be monitored with an headphone
or speaker to identify any noise or interference source in
the environment. It can also be connected to Line In of a
PC. User can walk around the building or field with the receiving
kit while constantly listening to the Analogue Out. A crackling
sound can be heard whenever user passes through a null spot
or poor reception area. Any interference source can be clearly
distinguished from expected analogue sound.
Warning: Headphone
should be worn after switching on the transmitting kit and
it should only be worn while the transmitter is on. It should
be removed before switching off the transmitter. The output
on the headphone will be too loud if the transmitter is switched
off.
AF output will contain noise if the RF signal level drops.
The unmuted noise level on the AF output has significantly
higher amplitude compared to data signal level.
Figure 24: Analogue I/O board circuit diagram
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R17 value can be increased to raise
the audio volume.
R25 Value can be increased to prevent clipping if larger analogue
signal is going to be applied on the inpu |
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Figure 25: Evaluation of TX2 & RX2 using Universal Evaluation
Kit
Figure 26: Evaluation of TX3A & RX3A using Universal Evaluation
Kit
Figure 27: Evaluation of BiM or BiM2 using Universal Evaluation
Kit
Figure 28: Evaluation of BiM1 & BiM3A using Universal
Evaluation Kit
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Limitation of liability
The information furnished by Radiometrix
Ltd is believed to be accurate and reliable. Radiometrix Ltd
reserves the right to make changes or improvements in the
design, specification or manufacture of its subassembly products
without notice. Radiometrix Ltd does not assume any liability
arising from the application or use of any product or circuit
described herein, nor for any infringements of patents or
other rights of third parties which may result from the use
of its products. This data sheet neither states nor implies
warranty of any kind, including fitness for any particular
application. These radio devices may be subject to radio interference
and may not function as intended if interference is present.
We do NOT recommend their use for life critical applications.
The Intrastat commodity code for all our modules is: 8542
6000.
R&TTE Directive
After 7 April 2001 the manufacturer can
only place finished product on the market under the provisions
of the R&TTE Directive. Equipment within the scope of
the R&TTE Directive may demonstrate compliance to the
essential requirements specified in Article 3 of the Directive,
as appropriate to the particular equipment.
Further details are available on The Office of Communications
(Ofcom) web site:
Licensing
policy manual
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