NBEK-000-XXX

EW N 16 16 April 2008 Radiometrix Hartcran House, 231 Kenton Lane, Harrow, HA3 8RP, England Tel: +44 (0) 20 8909 9595, Fax: +44 (0) 20 8909 2233 NBEK-000NBEK-000-xxx NBEK NBEK Controller As 1200 Baud Modem The Narrow band Evaluation Kit (NBEK) IC can be used as 1200baud half-duplex serial modem suitable for narrow band receivers, transmitters and transceivers (or any RF modules with >5kbps data rate). It takes care of preamble, synchronisation, bit balancing and error checking and enables a transparent radio data link to be established between radio devices This is a half duplex unit, so collisions between transmitted and received packets must be dealt with by the user. Provided no two devices attempt to transmit simultaneously no further restrictions on data Figure 1: NBEK-000-DIL transmission need be made, as all transmit timing, valid data identification and data stream buffering is conducted by the unit. Synchronisation and framing words in the packet prevent the receiver outputting garbage in the absence of wanted RF signal or presence of interference. Supports 1200 baud asynchronous data: 1 start bit, 8 data bits, 1 stop bit. With typical microcontrollers and UARTs, direct connection is usable as shown on figures 2 & 3. To connect to a true RS232 device, inverting level shifters must be used (MAX232 type are ideal, but simple NPN/PNP transistor switches often suffice as used in the application circuits figures 4 & 5). Features ! ! ! ! ! ! ! ! ! Operating voltage (temperature): 5V for standard version (-40°C to +85°C) Maximum usage of the range capability of an RF module Adequate preamble to settle data slicer in the receiver Extra wake up preamble to allow for transmitter power up time requirements Differential Manchester encoding of address, data and checksum Synchronisation codes and checksum to reduce false triggering on noise Suitable to be used with Narrow Band FM radio modules Serial modem baud rate at 1200bps (half-duplex) Addressable point-to-point Applications ! ! ! ! ! ! PDAs, organisers & laptops Handheld / portable terminals EPOS equipment, barcode scanners In-building environmental monitoring and control Remote data acquisition system, data logging Fleet management, vehicle data acquisition Radiometrix Ltd Page 1 1200buad Modem IC User Interface User Interface NC STATUS TXE RESET Vss (0V) D0 TXD RXD OSC1 OSC2 Vdd M3 M2 M1 D3 M0 serial data I/O Remote control Data bits RSTXD/D1 mode select bits Figure 2: package type, 18-Lead Plastic Dual In-line (PDIP - 300mil wide body) Pin description: Pin 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 Name NC STATUS TXE RESET 0V D0 D1/RSTXD D2/RSRXD D3 M0 M1 M2 M3 Vcc OSC2 OSC1 RXD TXD I/O out out in in/out in/out in/out in/out Function No Connection High indicates data received or in rx FIFO buffer Active low enable transmitter A 10kΩ pullup to VCC must be provided Supply ground Data bit 0 value during Control44 encoder / decoder mode Data bit 1 value during Control44 encoder / decoder mode Inverted RS232 datastream in, 1200 baud Data bit 2 value during Control44 encoder / decoder mode Inverted RS232 datastream out, 1200 baud Data bit 3 value during Control44 encoder / decoder mode Mode select LSB Mode select Mode select Mode select MSB 5V (regulated power supply); Decouple with 0.01uF close to IC connect to 3.58MHz crystal connect to 3.58MHz crystal Baseband input from receiver data output Baseband output to transmitter data input out in in out Notes: 1. No connections at all may be made to 'nc' pin 2. TXD, RXD, RSRXD, RSTXD and STATUS are 5V CMOS logic level 3. Some Radiometrix transmitters require 3V logic levels on their transit data inputs: a divider (4.7kΩ series, 10kΩ to ground) on the TXD pin is needed 4. In RX operation, RXD becomes a high impedance 5. After pulling TXE low (active), the coder allows about 50mS for TX to power up and settle 6. RSTXD (7) has no pullup. If the device is only used for receive, then tie this pin to VCC 7. Vcc must be a 5v regulated supply (4.75 - 5.25V). At this oscillator speed the PIC will not operate reliably at 3V 8. Pin 3 has no pullup. It is used to enter 'setup' mode (see below) 9. Without external loads the chip draws less than 5mA from 5v 10. STATUS goes high when valid data is present in the receive buffer. 11. OSC1, 2 require a 3.58MHz fundamental mode crystal, a series 100Ω resistor from OSC2, and a pair of 15pF caps : from the crystal pins to 0V Radiometrix Ltd Page 2 1200buad Modem IC Mode selection The mode select bits M0-M3 put NBEK IC in to one of 16 operating modes, including modem mode. MODE 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 (Modem) 15 H=5V, L=0V HHHH HHHL HHLH HHLL HLHH HLHL HLLH HLLL LHHH LHHL LHLH LHLL LLHH LLHL LLLH LLLL Receive mode Un-modulated Transmission for testing carrier frequency, power, spurii 250Hz (500bps) square wave Modulated Transmission 1250Hz (2.5kbps) square wave Modulated Transmission Pseudorandom NRZ stream modulated Transmission Transmitter and Receiver turned ON and OFF periodically at 100ms interval RESERVED for future use RESERVED for future use Continuous Control44 Transmission of Address=0 and Data=D3, D2, D1, D0 Control44 Transmission of Address=0 and Data=D3, D2, D1, D0 If either Data is changed or RESET (Trigger) switch is pressed. Control44 Reception with Momentary Output. (paired with Mode 8) Control44 Reception with Latched Output. (paired with Mode 9) Transmits CTR44 Test Packet, Receive Echoed Packet (Radar Mode – Master) Receive CTR44 Test Packet, Re-transmit it back to Sender (Echo Mode – Slave) I1200 type 1200 baud Dumb Modem for bit balanced serial data transmission RESERVED for future use Notes: 1. Mode 12 and 13 require Transceiver 2. In Mode 12, a test packet is transmitted, then the unit switches to Receive mode for 100ms before repeating. 3. Data sequence of 8 (D3=L, D2=H, D1=H, D0=H), 4, 2, 1 (D3=H, D2=H, D1=H, D0=L) is cycled through with each transmission. 4. In Mode 13, the unit idles in Receive mode. When a valid CTR44 burst is received the unit keys up the Transmitter and re-transmits this CTR44 burst back to sender in Mode 12. Radiometrix Ltd Page 3 1200buad Modem IC Operating principle of modem This device is a simplex link handling a 1200 baud asynchronous datastream (1 start, 8data, 1stop). Buffering in the transmit end handles TX startup timing requirements, while the presence of sync codes in the transmitted bursts prevents the receiver from outputting garbage in the presence of noise. No error correction or retransmission of lost packets is supported. To operate with proper +/-12V RS232 levels an external buffer (such as a MAX232) will be needed Operation: Serial interface Both transmit and receive modems implement a 32 byte software FIFO. At the transmit end this is used to allow for the transmitter start up time (about 32mS), while on receive it buffers arriving packets to the constant output data rate. All timing and data formatting tasks are handled by the software. The user need not worry about keying the transmitter before sending data: the link is entirely transparent. For transmission across the link data is formatted into packets, each comprising 3 bytes of data and a sync code. If less than 3 bytes are in the transmit end FIFO then a packet is still sent, but idle state replaces the unused bytes. When the transmit end FIFO is completely emptied, then the transmitter is keyed off . Operation: Radio interface Raw data is not fed to the radios. A coding operation in the transmit mode, and decoding in the receive mode, isolate the AC coupled, potentially noisy baseband radio environment from the datastream. The radio link is fed a continuous tone by the modem. As in biphase codes, information is coded by varying the duration consecutive half-cycles of this tone. In our case half cycles of 500µs (a long, or L) and 250µs (a short, or S) are used. In idle (or 'preamble') state, a sequence of Ls is sent (resembling a 1kHz tone). A packet comprises the Synchronising (or address) part : LSSSSSSSSSSSSL followed by the Data part, made up of twelve Groups (of four half cycles duration). Each Group encodes 2 data bits, so one byte is encoded by 4 Groups. Although there are 16 possible states for a four half cycle group (from SSSS to LLLL), only four of the possible states are used for valid data: All other possible group combinations (except LLLL) are void, and result in the entire packet being rejected by the receiver software as a noise artifact. Idle state tone (LLLL) is decoded as null data, but does not void the packet, as a packet containing less than 3 bytes still needs to be decoded. The advantage of using the above coding technique: 1.Ease of decoding: 2. Inherent error detection: Unlike biphase, where a bit is coded as either a long half cycle or a short cycle, here all half cycles are detected separately. Although only 14 sync/address 'bits' (halfcycles) are used, the following 48 'bits' (halfcycles) only code 24 real data bits, leading to enhanced noise/error discrimination (the equivalent of 5 more sync bits). For a maximum transmitted baseband frequency of 2kHz, a 3 byte packet is sent in 22ms. An equivalent biphase coded packet (comprising 19 sync + 24 data + 3 null flags) at 2kbits/sec takes 23ms 3. Comparable spectral efficiency: Radiometrix Ltd Page 4 1200buad Modem IC Application Circuits 5V supply 10k 10k 10k 10k NC 1k STATUS TXD RXD OSC1 OSC2 VDD M3 M2 M1 M0 100nF 3.58MHz 3k2 2k2 EN TXD Vcc GND RF Transmitter NBEK-000-DIL TXE RESET VSS NC TXD µC UART RSTXD RSRXD NC Figure 2: NBEK IC interfaced to a Transmitter (e.g. TX1) Note: Note Note 1. Transmit keyed when valid serial data is present at the RSTXD input, so no separate TX control needed 2. OSC1,2 require a 3.58MHz ceramic resonator with internal capacitors like Murata CSTLA3M58G55-B). If a 2 pin resonator or crystal is used, then two 15pF caps are needed: one from OSC1 to 0V; one from OSC2 to 0V 5V supply RF Receiver 10k NC 1k STATUS TXD RXD OSC1 OSC2 VDD M3 M2 M1 M0 100nF 3.58MHz RXD Vcc GND NBEK-000-DIL TXE RESET VSS NC RSTXD RXD µC UART RSRXD NC Figure 3: NBEK IC interfaced to a Receiver (e.g. NRX1) Radiometrix Ltd Page 5 1200buad Modem IC 5V supply 10k 10k 10k 10k 10k NC 1k STATUS TXD RXD OSC1 OSC2 VDD M3 M2 M1 M0 100nF 3.58MHz 3k2 2k2 EN TXD Vcc GND RF Transmitter NBEK-000-DIL TXE RS232 Port 1 RESET VSS NC RSTXD TXD 10k 10k RSRXD NC 9 5 Figure 4: RF Transmitter (e.g. TX1) + NBEK IC interface for RS232 data transmission 5Vsupply RF Receiver 10k NC 1k STATUS TXD RXD OSC1 OSC2 VDD M3 M2 M1 M0 100nF 3.58MHz RXD Vcc GND NBEK-000-DIL TXE RESET VSS RS232 Port 1 NC RSTXD 10k RSRXD NC 10k RXD 9 5 Figure 5: RF Receiver (e.g. NRX1) + NBEK IC interface for RS232 data reception Ordering Information: The NBEK controller IC can be ordered separately with equal number of radio modules. NBEK-000-SS - Shrink Small Outline NBEK-000-SO - Small Outline NBEK-000-DIL - Plastic Dual In Package Radiometrix Ltd Page 6 1200buad Modem IC Radiometrix Ltd Hartcran House 231 Kenton Lane Harrow, Middlesex HA3 8RP ENGLAND Tel: +44 (0) 20 8909 9595 Fax: +44 (0) 20 8909 2233 sales@radiometrix.com 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/ 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 information.requests@ofcom.org.uk European Radiocommunications Office (ERO) Peblingehus Nansensgade 19 DK 1366 Copenhagen Tel. +45 33896300 Fax +45 33896330 ero@ero.dk www.ero.dk