RADIOMETRIX TLC2

W
E
N
Radiometrix
Hartcran House, 231 Kenton Lane, Harrow, HA3 8RP, England
Issue 4, 27 July 2005
Tel: +44 (0) 20 8909 9595, Fax: +44 (0) 20 8909 2233
TLC2/RLC2
UHF Narrow Band FM Low Cost multi
multi channel radio modules
The TLC2 transmitter RLC2 receiver
modules offer a low power, reliable data
link in an industry-standard pin out
and
footprint.
This
makes
the
TLC2/RLC2 pair ideally suited to those
low power applications where existing
wideband modules have insufficient
range, or where low cost multi-channel
operation
is
needed
without
compromising on RF specification or
regulatory requirement.
Figure 1: RLC2 receiver, TLC2 transmitter
Features
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433MHz version conforms to EN 300 220-3 and EN 301 489-3
High performance double superhet. PLL synthesizer with TCXO
SAW front-end filter
Data rates up to 5 kbps for standard module
Usable range over 500m
Fully screened. Low profile
Feature-rich interface (RSSI, analogue and digital baseband)
Re-programmable via RS232 interface
Low power requirements
Applications
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Handheld terminals
EPOS equipment, barcode scanners
Data loggers
Industrial telemetry and telecommand
In-building environmental monitoring and control
High-end security and fire alarms
DGPS systems
Vehicle data up/download
Heavy vehicle/machinery controls
Technical Summary
•
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•
Operating frequency: 433.875-434.650MHz
Any custom frequency on 433MHz – 435MHz
32 channels in 433MHz band
Transmit power: +10dBm (10mW)
Supply range: 4.0 - 15V (TLC2), 1.8 - 10V (TLC2LV)
3.7 - 15V (RLC2)
Current consumption: 32mA (TX), 18mA (RX)
Data bit rate: 5kbps max. (standard module)
Receiver sensitivity: -120dBm (for 12 dB SINAD)
Serial configuration by inverted RS232 at 3V CMOS level
Radiometrix Ltd
TLC2/RLC2 Data Sheet
page 1
Figure 2: TLC2 block diagram
Radiometrix Ltd
TLC2/RLC2 Data Sheet
page 2
Figure 3: TLC2 footpint (top view)
Pin description – TLC2
Pin
1
2
3
Name
Vcc
No pin
TXD
4
5
P0/PGM
No pin
0V
Parallel channel
select, bit 0
Parallel channel
select, bit 1
Parallel channel
select, bit 2
Parallel channel
select, bit 3
Parallel channel
select, bit 4 (MSB)
P1
P2
P3
Jumper
P4
Function
power supply : 4 – 15V (TLC2) and 1.8 – 10V (TLC2LV)
Not present
TLC2: DC coupled input for 3V CMOS logic. Rin=100kΩ
TLC2LV: DC coupled input for CMOS logic5. Rin=47kΩ
Not present
Ground
True logic (0V = low). Weak pullup to 3V;
Serial frequency programming / configuration1
True logic (0V = low). Weak pullup to 3V
True logic (0V = low). Weak pullup to 3V
True logic (0V = low). Weak pullup to 3V
Jumper soldered, P4=0 (Channel 00 – Channel 15 at 50kHz step)
Jumper clear, P4=1 (Channel 16 – Channel 31 at 50kHz step)
1. Serial programming is by an inverted 2400 baud RS232 at 3V CMOS level command into the PGM.
If connection to a true RS232 port is desired, then a suitable inverting level shifter / buffer
(MAX232 or NPN switch transistor) is needed.
2. Parallel channel selection is by a true logic (0V=0, 3V=1), 4-pin parallel input (MSB selected by
jumper).
3. Channel select inputs have 10kΩ weak internal pull-up to 3V internal rail. Do not exceed 3V logic
levels on this port.
4. TLC2LV will shutdown if Vcc falls below 1.6V
5. TXD (TLC2LV): logic low < 1.3V, logic high > 1.7V. TXD maximum voltage = 10V
Radiometrix Ltd
TLC2/RLC2 Data Sheet
page 3
Figure 4: RLC2 block diagram
Radiometrix Ltd
TLC2/RLC2 Data Sheet
page 4
Figure 5: RLC2 footpint (top view)
Pin description – RLC2
Pin
1
2
3
4
5
P0/PGM
P1
P2
P3
Jumper
P4
Name
Vcc
RSSI
0V
RXD
AF
Parallel channel
select, bit 0
Parallel channel
select, bit 1
Parallel channel
select, bit 2
Parallel channel
select, bit 3
Parallel channel
select, bit 4
Function
DC supply (3.7V to 15V, at 18mA).
0.5V-2.5V DC level. 60dB dynamic range. 40kΩ output impedance
Ground
Open collector digital data output with internal 47kΩ pull-up to Vcc
600mV pk-pk audio. DC coupled, approx 0.8V bias.
True logic (0V = low). Weak pullup to 3.5V
Serial frequency programming / configuration1
True logic (0V = low). Weak pullup to 3.5V
True logic (0V = low). Weak pullup to 3.5V
True logic (0V = low). Weak pullup to 3.5V
Jumper soldered, P4=0 (Channel 00 – Channel 15 at 50kHz step)
Jumper clear, P4=1 (Channel 16 – Channel 31 at 50kHz step)
NOTES:
1. Serial programming is by a 2400 baud inverted 'RS232' (3V CMOS levels) datastream applied
to the P0 pin. If connection to a true RS232 port is desired, then a suitable inverting level
shifter / buffer (MAX232 or NPN switch transistor) is needed.
2. Parallel channel select is by a 4 pin parallel input (MSB selected by jumper). 3V CMOS levels
should be used.
3. As supplied the frequency table is thus:
ch 0-15 433.875 – 434.625 MHz (50KHz steps)
ch 16-31 433.9 - 434.65 MHz (50KHz steps)
Radiometrix Ltd
TLC2/RLC2 Data Sheet
page 5
Serial interface commands
2400 baud RS232. 8 bit data, no parity, 1 start bit, 1 or 2 stop bits.
Serial data is sent to the unit on one of the parallel channel select pins (P0). It is very important that
the unit does not ‘decode’ switch bounce in ordinary operation as a command string, or spurious rewriting of the EEPROM will result. For this reason the user must send the 16 character string
ENABLESERIALMODE to fully enable the serial command mode before sending any of the command
strings listed below. Command mode is disabled on power down, or on reception of a # character.
GOCHAN xx
LOAD aa nnnnn
SETPAR
SETSER
RVALUE rrrr
SINGLE nnnnn
Serially select of channel xx, where xx is 0 to 31
Set value of N register for channel aa, where aa is Channels 0 to 31
Channel selected by 5 bit parallel inputs (4pins + jumper)
Channel selected by most recent GOCHAN operation
Set value for R register
Set value of N for single channel operation.
N value NOT stored in EEPROM
Process entry
Clear all buffers
Disable command mode
<cr>
/
#
xx = a channel number from 00 to 31
aa = a two digit channel number from 00 to 31
nnnnn = synthesizer N register value (up to 65535)
rrrr = synthesizer R register value (up to 16383)
N TX =
N RX =
f RF
f Channelspacing
=
433.875MHz
= 17355
25kHz
R=
f TCXO
f channelspacing
=
13MHz
, So R=520
25kHz
f RF − 21.4MHz 433.875MHz − 21.4
=
= 16499
f Channelspacing
25kHz
Note: A pause of at least 25ms must be allowed between command strings (EEPROM
programming time).
SINGLE mode does not store the N value in EEPROM. Therefore the unit is inoperative
after a power down until either another valid SINGLE command is received, or mode is
changed by a GOCHAN, SETPAR or SETSER command. SINGLE mode is intended for
frequency agile applications.
Radiometrix Ltd
TLC2/RLC2 Data Sheet
page 6
TLC2, RLC2 channels are spaced at 50kHz interval into two frequency groups. 50kHz spacing between
sequential channels minimises adjacent channel interference. P4 jumper link determines which
frequency group is selected.
Channel
(P4 soldered)
0
Frequency
(MHz)
433.875
1
433.925
2
433.975
3
434.025
4
5
6
Radiometrix Ltd
433.900
17
433.950
18
434.000
19
434.050
20
434.100
21
434.150
22
434.200
23
434.250
24
434.300
25
434.350
26
434.400
27
434.450
28
434.500
29
434.550
30
434.600
31
434.650
434.175
8
434.275
9
434.325
10
434.375
13
16
434.125
434.225
12
Frequency
(MHz)
434.075
7
11
Channel
(P4 clear)
434.425
434.475
434.525
14
434.575
15
434.625
TLC2/RLC2 Data Sheet
page 7
Condensed specifications
Frequency
Peak deviation
Frequency stability
Channel spacing
Number of channels
433.875-434.675MHz (custom variants on 433MHz – 435MHz)
±3kHz
±1.5kHz
25kHz (12.5kHz by special order)
32 channels selected via RS232 interface
or 2 x 16 groups by parallel port
Operating temperature
Spurious radiations
-10 ºC to +60 ºC (Storage -30 ºC to +70 ºC)
Compliant with ETSI EN 300 220-3 and EN 301 489-3
Transmitter
Output power
TX on switching time
Modulation type
TX modulation bandwidth
Adjacent channel TX power
TX spurious
Supply
Voltage
Current
Inputs
Size
Interface
User
Channel
RF
Recommended PCB hole size
Receiver
Sensitivity
S/N ratio
AF bandwidth (-3dB)
image / spurious / adjacent channel
Blocking
LO re-radiation
Supply
Voltage
Current
Outputs
Size
Interface
User
Channel
RF
Recommended PCB hole size
Power on to valid audio
Power on to stable data out
(50:50 mark / space)
+10dBm (10mW) ±1dB (1mW or 5mW by special order)
50ms from power up
FSK (F3D)
DC – 5kHz (3V CMOS compatible)
<-37dBm
<-50dBm (<-60dBm in standby)
TLC2: 4.0V – 15V
TLC2LV: 1.8V – 10V (do not exceed 10V)
TLC2:
32mA nominal
TLC2LV: 27mA nominal at 5V
66mA at 2V
45mA at 3V
20mA at 7V
17mA at 9V
analogue, data (CMOS/TTL compatible)
37 x 27 x 8mm
3pin 0.2" pitch molex
4pin 0.1" pitch molex
2pin 3mm pitch
1.2mm
-112dBm for 1 part per 1000 BER
-120dBm for 12 dB SINAD
35dB (min), 40dB (typ) on AF output
4kHz
<-60dB
<-85dB
<-60dBm
3.7V – 15V
18mA
RSSI, audio, data
50 x 30 x 10mm
5pin 0.1" pitch molex
4pin 0.1" pitch molex
2pin 0.1" pitch molex
1.2mm
28ms
50ms
Notes:
1. The data slicer cannot be depended upon for data waveform frequencies below 250Hz
2. When RX is on and a transmitter keys up, again a 50ms period is required to stabilise data
output mark/space. i.e. allow at least 50ms of preamble
Radiometrix Ltd
TLC2/RLC2 Data Sheet
page 8
RX Received Signal Strength Indicator (RSSI)
The RLC2 has wide range RSSI that measures the strength of an incoming signal over a range of 60dB
or more. This allows assessment of link quality and available margin and is useful when performing
range tests.
The output on pin 2 of the module has a standing DC bias of up to 0.4V with no signal, rising to 2.5V at
maximum indication (RF input levels of -40dBm and above). ∆Vmin-max is typically 2V and is largely
independent of standing bias variations. Output impedance is 40kΩ. Pin 2 can drive a 100mA meter
directly, for simple monitoring.
Figure 6: RSSI level with respect to received RF level at RLC2 antenna pin
Low Cost TLC2 transmitter differs from standard BMT2 transmitter in the following key features.
Footprint
Frequency band
Channels
Channel select switches
Parallel channel select
Serial Frequency programming
Transmit Enable
Modem
Supply
BMT2
Industry standard (extra 2 pins)
400-480MHz (any 5MHz band)
32 parallel or 256 serial
5 bit optional
4 pins (and 1 jumper link)
Pin 2
Pin 4
1200 baud modem
2.4V-15, 40mA
TLC2
Industry standard
433.875 - 434.650Hz (only)
32 parallel/serial
Not available
4 pins (and 1 jumper link)
Via S0/PGM pin
not present on TLC2
Not available
4V-15, 32mA
Low Cost RLC2 receiver differs from standard BMR2 receiver in the following key features.
Footprint
Frequency band
Channels
Channel select switches
Parallel channel select
SAW front end filter
Serial Frequency programming
Modem
Supply
Spurii
Sensitivity
Radiometrix Ltd
BMR2
Industry standard
400-480MHz (any 5MHz band)
32 parallel or 256 serial
5 bit internal
4 pins (and 1 jumper link)
Via RSSI/PGM pin
1200 baud modem
3.7V-15, 18mA
65dB-70dB
-118dBm
TLC2/RLC2 Data Sheet
RLC2
Industry standard
433 – 435 MHz
32 parallel/serial
Not available
4 pins (and 1 jumper link)
Yes
via S0/PGM pin
Not available
3.7V-15, 20mA
<-60dB
-120dBm
page 9
Antenna requirements
Three types of integral antenna are recommended and approved for use with the module:
A) Whip
This is a wire, rod ,PCB track or combination connected directly to RF pin of the module.
Optimum total length is 16.4cm (1/4 wave @ 433MHz). Keep the open circuit (hot) end
well away from metal components to prevent serious de-tuning. Whips are ground plane
sensitive and will benefit from internal 1/4 wave earthed radial(s) if the product is small
and plastic cased
B) Helical
Wire coil, connected directly to RF pin, open circuit at other end. This antenna is very
efficient given it’s small size (20mm x 4mm dia.). The helical is a high Q antenna, trim
the wire length or expand the coil for optimum results. The helical de-tunes badly with
proximity to other conductive objects.
C) Loop
A loop of PCB track tuned by a fixed or variable capacitor to ground at the 'hot' end and
fed from RF pin at a point 20% from the ground end. Loops have high immunity to
proximity de-tuning.
A
whip
***
***
*
*
500m
Ultimate performance
Easy of design set-up
Size
Immunity proximity effects
Range open ground to similar antenna
B
helical
**
**
***
**
200
C
loop
*
*
**
***
100
The antenna choice and position directly controls the system range. Keep it clear of other metal in the
system, particularly the 'hot' end. The best position by far, is sticking out the top of the product. This is
often not desirable for practical/ergonomic reasons thus a compromise may need to be reached. If an
internal antenna must be used, try to keep it away from other metal components, particularly large
ones like transformers, batteries and PCB tracks/earth plane. The space around the antenna is as
important as the antenna itself.
0.5 mm enameled copper wire
close wound on 3.2 mm diameter former
RF
433 MHz = 24 turns
A. Helical antenna
Feed point 15% to 25% of total loop length
RF-GND
track width = 1mm
2
C2
C3
C4
C1
4 to 10 cm inside area
RF
B. Loop antenna
16.4cm
C. Whip antenna
wire, rod, PCB-track or a combination
of these three
RF
433 MHz = 16.4 cm total from RF pin.
Figure 7: Antenna types
Radiometrix Ltd
TLC2/RLC2 Data Sheet
page 10
Radiometrix Ltd
Hartcran House
231 Kenton Lane
Harrow, Middlesex
HA3 8RP
ENGLAND
Tel: +44 (0) 20 8909 9595
Fax: +44 (0) 20 8909 2233
[email protected]
www.radiometrix.com
Copyright notice
This product data sheet is the original work and copyrighted property of Radiometrix Ltd. Reproduction in whole or
in part must give clear acknowledgement to the copyright owner.
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:
http://www.ofcom.org.uk/radiocomms/ifi/licensing/licensing_policy_manual/
Information Requests
Ofcom
Riverside House
2a Southwark Bridge Road
London SE1 9HA
Tel: +44 (0)845 456 3000 or 020 7981 3040
Fax: +44 (0)20 7783 4033
[email protected]
European Radiocommunications Office (ERO)
Peblingehus
Nansensgade 19
DK 1366 Copenhagen
Tel. +45 33896300
Fax +45 33896330
[email protected]
www.ero.dk