CMX969E2 - CML Microcircuits (USA) Inc.

CMX969

RD-LAP/MDC4800

Motient/ARDIS

 2001 Consumer Microcircuits Limited

D/969/5 April 2001 Provisional Information

Features Applications

•• Autonomous Frame Sync Detection

for SFR operation •• DataTAC*, Motient/ARDIS*, Dual

Mode RD-LAP* and MDC 4800

•• Full Packet Data Framing •• Two-Way Paging Equipment

•• Low Power, 3.0 to 5.5V operation •• Mobile Data Systems

•• Powersave Option •• Wireless Telemetry

•• DataTAC* Terminals

*Radio Data-Link Access Procedure (RD-LAP) is a data communications air interface protocol developed by Motorola Inc.

*Motient is a registered service mark of the Motient Company operating the Motient Network. (Formerly known as American Mobile

operating the ARDIS Network).

*DataTAC is a registered trademark of Motorola Inc.

1.1 Brief Description

The CMX969 is a CMOS integrated circuit that contains all of the baseband signal processing and Medium

Access Control (MAC) protocol functions required for a high performance DataTAC dual mode (RD-LAP

19200 bps and MDC 4800 bps) FSK Wireless Packet Data Modem suitable for use with the Motient/ARDIS

network. It interfaces with the modem host processor and the radio modulation/demodulation circuits to

deliver reliable two-way transfer of the application data over the wireless link.

The CMX969 assembles application data received from the host processor, adds forward error correction

(FEC) and error detection (CRC) information and interleaves the result for burst-error protection. After adding

symbol and frame synchronisation codewords and channel status symbols, it converts the packet into a

filtered analogue baseband signal for modulating the radio transmitter.

In receive mode, the CMX969 performs the reverse function using the analogue baseband signals from the

receiver frequency discriminator. After error correction and removal of the packet overhead, the recovered

application data is supplied to the host processor. Any residual uncorrected errors in the data will be flagged.

A readout of the received signal quality is also provided.

An optional Autonomous Frame Sync Detection function is provided for use in Motient/ARDIS systems

employing Single Frequency Re-use operation.

The CMX969 uses signal filtering, data block formats and FEC/CRC algorithms compatible with the MDC and

RD-LAP over-air standards. The device is programmable to operate from a wide choice of Xtal frequencies

and is available in 24 pin DIP, SSOP and TSSOP packages.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 2 D/969/5

CONTENTS

Section Page

1.0 Features and Applications.......................................................................1

1.1 Brief Description .......................................................................................1

1.2 Block Diagram ...........................................................................................3

1.3 Signal List...................................................................................................4

1.4 External Components...............................................................................5

1.5 General Description..................................................................................6

1.5.1 Description of Blocks..................................................................6

1.5.2 Modem - µC Interaction...............................................................8

1.5.3 Binary to RD-LAP 4-Level Symbol Translation .......................9

1.5.4 Frame Structure .........................................................................10

1.5.4.1 MDC Mode...................................................................................10

1.5.4.2 RD-LAP Mode.............................................................................11

1.5.5 The Programmer's View............................................................12

1.5.5.1 Data Block Buffer.......................................................................12

1.5.5.2 Control Register.........................................................................12

1.5.5.3 Mode Register ............................................................................13

1.5.5.4 Command Register....................................................................15

1.5.5.5 Status Register...........................................................................26

1.5.5.6 Data Quality Register ................................................................28

1.6 Application Notes....................................................................................29

1.6.1 Autonomous Frame Sync Detect Function............................29

1.6.2 Rx Control Procedure................................................................30

1.7 Performance Specification.....................................................................32

1.7.1 Electrical Performance..............................................................32

1.7.1.1 Absolute Maximum Ratings .....................................................32

1.7.1.2 Operating Limits.........................................................................32

1.7.1.3 Operating Characteristics ........................................................33

1.7.2 Packaging....................................................................................36

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 3 D/969/5

1.2 Block Diagram

Figure 1 Block Diagram

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 4 D/969/5

1.3 Signal List

Package

P4/E2/D5 Signal Description

Pin No. Name Type

1 IRQN O/P A 'wire-ORable' output for connection to the host µC's Interrupt

Request input. This output has a low impedance pull down to VSS

when active and is high impedance when inactive. An external pull

up resistor of about 100k ohm to VDD is required.

2 D7 BI )

3 D6 BI )

4 D5 BI )

5 D4 BI ) 8-bit bidirectional 3-state µC interface data

6 D3 BI ) lines.

7 D2 BI )

8 D1 BI )

9 D0 BI )

10 RDN I/P Read. An active low logic level input used to control the reading of

data from the modem into the host µC.

11 WRN I/P Write. An active low logic level input used to control the writing of

data into the modem from the host µC.

12 Vss Power The negative supply rail (ground).

13 CSN I/P Chip Select. An active low logic level input to the modem, used to

enable a data read or write operation.

14 A0 I/P ) Two logic level modem register select

15 A1 I/P ) inputs.

16 XTALN O/P The output of the on-chip oscillator.

17 XTAL I/P The input to the on-chip oscillator, for external Xtal circuit or clock.

18,19 NC No connection should be made to these pins (reserved for possible

future use)

20 TXOP O/P The Tx signal output from the modem.

21 VBIAS O/P A bias line for the internal circuitry, held at ½ VDD. This pin must be

decoupled to VSS by a capacitor mounted close to the device pins.

22 RXIN I/P The input to the Rx input amplifier.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 5 D/969/5

Package

P4/E2/D5 Signal Description

Pin No. Name Type

23 RXFB O/P The output of the Rx input amplifier .

24 VDD Power The positive supply rail. Levels and voltages are dependent upon

this supply. This pin should be decoupled to VSS by a capacitor.

Notes: I/P = Input O/P = Output BI = Bidirectional NC = No connection

Internal protection diodes are connected from each signal pin to VDD and VSS.

1.4 External Components

Figure 2 Recommended External Components

R1 See Section 1.5.1 C1 0.1 µF ± 20% C4 ± 20%, see Note 1

R2 100k ohm ± 5% C2 0.1 µF ± 20% C5 100pF ± 5%

R3 1M ohm ± 20% C3 ± 20%, see Note 1 C6 100pF ± 5%

R4 100k ohm ± 5%

X1 4.9152, 7.3728 or 9.8304 MHz ±100ppm. See Section 1.5.5.2

Note 1: The values used for C3 and C4 should be suitable for the frequency of the crystal X1. As a

guide, values (including stray capacitances) of 33pF at 1MHz falling to 18pF at 10MHz will generally

prove suitable.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 6 D/969/5

1.5 General Description

1.5.1 Description of Blocks

Refer to Figure 1.

Data Bus Buffers

Eight bidirectional 3-state logic level buffers between the modem's internal registers and the host µC's data

bus lines.

Address and R/W Decode

This block controls the transfer of data bytes between the µC and the modem's internal registers, according to

the state of the Write and Read Enable inputs (WRN and RDN), the Chip Select input (CSN) and the Register

Address inputs A0 and A1.

The Data Bus Buffers, Address and R/W Decode blocks provide a byte-wide parallel µC interface, which can

be memory-mapped, as shown in Figure 3.

Figure 3 Typical Modem µC Connections

Status and Data Quality Registers

Two 8-bit registers which the µC can read to determine the status of the modem and the received data quality.

Command, Mode and Control Registers

The values written by the µC to these 8-bit registers control the operation of the modem.

Data Buffer

A 12-byte buffer used to hold receive or transmit data to or from the µC.

CRC Generator/Checker

A circuit which generates (in transmit mode) or checks (in receive mode) the Cyclic Redundancy Checksum

bits, which are included in transmitted data blocks so that the receive modem can detect transmission errors.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 7 D/969/5

FEC Encoder/Decoder

In transmit mode, this circuit adds Forward Error Correction information to the transmitted data. In RD-LAP

mode it also converts the binary data to 4-level symbols. In receive mode, this block translates received

symbols to binary data, using the FEC information to correct a large proportion of transmission errors.

Interleave/De-interleave Buffer

This circuit interleaves data symbols within a block before transmission and de-interleaves the received data

so that the FEC system is best able to handle short noise bursts or fades.

Auto Frame Sync Detect, Rx Level & Timing Extraction, Rx Data Symbol Extraction

This block, which is only active in receive mode, is used to look for the Frame Synchronisation pattern which

is transmitted to mark the start of every frame and to extract the received symbols from the received signal

using extracted signal level and timing information.

Rx Input Amp

This amplifier allows the received signal input to the modem to be set to the optimum level by suitable

selection of the external components R1 and R2. The dc level of the received signal should be adjusted so

that the signal at the modem's RXFB pin is centred around VBIAS (½ VDD). See section 1.7.1.3 for details of

the optimum levels.

Low Pass Filter

This filter, which is used in both transmit and receive modes, is a linear-phase lowpass filter having a

frequency response automatically switched to suit RD-LAP or MDC operation.

In transmit mode, the data symbols are passed through this filter to eliminate the high frequency components

which would otherwise cause interference into adjacent radio channels.

Figure 4 Generation of Filtered Tx Baseband Signal

In receive mode, the filter is used to reject HF noise and to equalise the received signal to a form suitable for

extracting the received data.

Tx Output Buffer

This is a unity gain amplifier used in transmit mode to buffer the output of the Tx low pass filter. In receive

mode, the input of this buffer is connected to VBIAS unless the RXEYE bit of the Control Register is '1', when it

is connected to the received signal. When changing from Rx to Tx mode the input to this buffer will be

connected to VBIAS for 8 symbol times in RD-LAP mode, 2 symbol times in MDC mode while the low pass filter

settles.

Note: The RC low pass filter formed by the external components R4 and C5 between the TXOP pin and the

input to the radio's frequency modulator forms an important part of the transmit out of band spurious signal

filtering. These components may form part of any dc level-shifting and gain adjustment circuitry. C5 should be

positioned to give maximum attenuation of high frequency noise into the modulator.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 8 D/969/5

Clock Oscillator and Dividers

These circuits derive the transmit symbol rate (and the nominal receive symbol rate) by frequency division of

a reference frequency which may be generated by the on-chip Xtal oscillator or applied from an external

source.

Note: If the on-chip xtal oscillator is to be used, then the external components X1, C3, C4 and R3 are

required. If an external clock source is to be used, then it should be connected to the XTAL input pin, the

XTALN pin should be left unconnected, and X1, C3, C4 and R3 not fitted.

1.5.2 Modem - µC Interaction

In general, data is transmitted over-air in the form of messages, or 'Frames', consisting of a 'Frame Preamble'

followed by one or more formatted data blocks. The Frame Preamble includes a Frame Synchronisation

pattern designed to allow the receiving modem to identify the start of a frame. The following data blocks are

constructed from the 'raw' data using a combination of CRC (cyclic redundancy checksum) generation,

Forward Error Correction coding and Interleaving. Details of the message formats handled by the modem are

given in Section 1.5.4 and Figures 5a and 5b.

To reduce the processing load on the associated µC, the CMX969 modem has been designed to perform as

much as possible of the computationally intensive work involved in Frame formatting and de-formatting and -

when in receive mode - in searching for and synchronising onto the Frame Preamble. In normal operation the

modem will only require servicing by the µC once per received or transmitted block.

Thus, to transmit a block, the controlling µC has only to load the - unformatted - 'raw' binary data into the

modem's Data Block Buffer then instruct the modem to format and transmit that data. The modem will then

calculate and add the CRC bits as required, encode the result as 2 or 4-level symbols (with Forward Error

Correction coding) and interleave the symbols before transmission.

In receive mode, the modem can be instructed to assemble a block's worth of received symbols, de-interleave

the symbols, translate them to binary - using the FEC coding to correct as many errors as possible - and

check the resulting CRC before placing the received binary data into the Data Block Buffer for the µC to read.

The modem can also transmit and receive un-formatted data using the T4S, T24S, R4S, T8B, T40B and R8B

tasks described in section 1.5.5.4 These are normally used for the transmission of Symbol and Frame

Synchronisation sequences. They may also be used for the transmission and reception of special test

patterns.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 9 D/969/5

1.5.3 Binary to RD-LAP 4-Level Symbol Translation

Although the over-air signal, and hence the signals at the modem TXOP and RXIN pins, consists of 4-level

symbols in RD-LAP mode, the raw data passing between the modem and the µC is in binary form.

Translation between binary data and the 4-level symbols is done in one of two ways, depending on the task

being performed.

Direct: the simplest form, which converts between 2 binary bits and a single symbol, such as the 'S' Channel

Status symbol.

symbol ms bit ls bit

+3 1 1

+1 1 0

-1 0 0

-3 0 1

This is expanded so that an 8-bit byte translates to four symbols for the T4S, T24S and R4S tasks described

in Section 1.5.5.2.

msb lsb

Bits: 7 6 5 4 3 2 1 0

Symbols: a b c d

sent first sent last

With FEC: This is more complicated, but essentially translates groups of 3 binary bits to pairs of 4-level

symbols using a Forward Error Correcting coding scheme for the block oriented tasks THB, TIB, TLB, TSID,

RHB, RILB and RSID described in Section 1.5.5.4.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 10 D/969/5

1.5.4 Frame Structure

In both RD-LAP and MDC modes the CMX969 performs all of the block formatting and de-formatting, the

binary data transferred between the modem and its µC being that enclosed by the thick dashed rectangles

near the top of Figures 5a and 5b.

1.5.4.1 MDC Mode

The CMX969 Frame Structure in MDC mode is illustrated in Figure 5a, and consists of a Frame

Synchronisation pattern followed by one or more 'Header’ blocks, one or more 'Intermediate’ blocks and a

'Last’ block. Channel Status bits are included at regular intervals. The first Frame of any transmission is

preceded by a Bit Synchronisation pattern.

Figure 5a MDC Over Air Signal Format

The MDC bit synchronisation pattern consists of alternating 1’s and 0’s. The normal MDC Frame

Synchronisation (SYNC1) pattern is 07092A446F Hex (msb transmitted first). SYNC2 is the 1’s complement

of SYNC1.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 11 D/969/5

1.5.4.2 RD-LAP Mode

The CMX969 Frame Structure in RD-LAP mode is illustrated in Figure 5b, and consists of a Frame Preamble

(comprising a 24-symbol Frame Synchronisation pattern and Station ID block) followed by one or more

'Header’ blocks, one or more 'Intermediate’ blocks and a 'Last’ block. Channel Status (S) symbols are

included at regular intervals. The first Frame of any transmission is preceded by a Symbol Synchronisation

pattern.

Figure 5b RD-LAP Over Air Signal Format

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 12 D/969/5

1.5.5 The Programmer's View

The modem appears to the programmer as 4 write only 8-bit registers shadowed by 3 read only registers,

individual registers being selected by the A0 and A1 chip inputs: Note that there is a minimum allowable time

between accesses of the modem's registers, see Section 1.7.1 for details.

A1 A0 Write to Modem Read from Modem

0 0 Data Buffer Data Buffer

0 1 Command Register Status Register

1 0 Control Register Data Quality Register

1 1 Mode Register Reserved for other uses.

1.5.5.1 Data Block Buffer

This is a 12-byte read/write buffer which is used to transfer data (as opposed to command, status, mode, data

quality or control information) between the modem and the host µC. It appears to the µC as a single 8-bit

locations within the buffer.

The µC should only access this buffer when the Status Register BFREE (Buffer Free) bit is '1'.

The buffer should only be written to while in Tx mode and read from while in Rx mode. Note that in receive

mode the modem will function correctly even if the µC does not read the received data from the Data Buffer.

1.5.5.2 Control Register

This 8-bit write-only register controls the modem's operating mode (RD-LAP or MDC), symbol rate and the

response times of the receive clock extraction and signal level measurement circuits.

Control Register B7, B6: CKDIV - Clock Division Ratio

These bits control a frequency divider driven from the clock signal present at the XTALN pin, and hence

determine the nominal symbol and bit rates. The following table shows the settings of B7 and B6 needed for

19200bps RD-LAP and 4800bps MDC4800 operation.

Division ratio:

B7 B6 Xtal Frequency Xtal frequency / RD-LAP

Symbol Rate Xtal frequency /

MDC4800 Symbol Rate

0 0 4.9152 MHz 512 1024

0 1 7.3728 MHz 768 1536

1 0 9.8304 MHz 1024 2048

1 1 See note 1536 3072

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 13 D/969/5

Note: The setting B7 = 1 and B6 = 1 cannot be used with 19200bps RD-LAP / 4800bps MDC4800 as this

would require a Xtal frequency above the oscillator operating range.

The CMX969 may also be used with a 9600bps RD-LAP system if the Xtal frequency is 4.9152 or 7.3728MHz

and Control register bits 7-6 set to ‘1 0’ or ‘1 1’

Control Register B5: Reserved for future use.

This bit should always be set to ‘0’.

Control Register B4: ALTCRC - Alternative CRC

This bit should always be set to ‘0’ for standard RD-LAP and MDC systems. Setting it to ‘1’ in RD-LAP mode

selects an alternative CRC generation/checking algorithm.

Control Register B3: ALTFILT - Alternative Filtering

This bit should always be set to ‘0’ for standard RD-LAP and MDC systems. Setting it to ‘1’ in RD-LAP mode

selects slightly different transmit and receive lowpass filter characteristics more suitable for some non-

standard systems.

Control Register B2: MDC - MDC Mode

If this bit is ‘0’ the CMX969 operates in RD-LAP mode, setting this bit to ‘1’ selects MDC mode. Changing

between RD-LAP and MDC modes will cancel any current task.

Control Register B1: FSTOL - Frame Sync Detect Tolerance

In RD-LAP mode this bit affects the number of errors tolerated by the Frame Sync detector when running SFS

or SFP tasks or AFSD. Approximately 3 bit errors are allowed when FSTOL = 0, 7 when FSTOL = 1.

In MDC mode this bit has no effect and the Frame Sync detector will accept up to 5 incorrect bits in a received

Frame Sync pattern when running the SFS task or AFSD.

Control Register B0: HOLD - Freeze Rx Level and Timing Corrections

Setting this bit to 1 disables the receive level and symbol timing error correction circuits.

1.5.5.3 Mode Register

The contents of this 8-bit write only register control the basic operating modes of the modem:

Mode Register B7: IRQNEN - IRQN Output Enable

When this bit is set to '1', the IRQN chip output pin is pulled low (to Vss) whenever the IRQ bit of the Status

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 14 D/969/5

Mode Register B6: INVSYM - Invert Symbols

This bit controls the polarity of the transmitted and received symbol voltages.

B6 Symbol Signal at TXOP Signal at RXFB

0 '+3 or +1' Above VBIAS Below VBIAS

'-3 or -1' Below VBIAS Above VBIAS

1 '+3 or +1' Below VBIAS Above VBIAS

'-3 or -1' Above VBIAS Below VBIAS

Mode Register B5: TXRXN - Tx/Rx Mode

Setting this bit to '1' puts the modem into Transmit mode, clearing it to '0' puts the modem into Receive mode.

Note that changing between receive and transmit modes will cancel any current task.

Mode Register B4: ZP - Zero Power

Setting this bit to ‘1’ removes power from all of the CMX969’s circuitry, including the Xtal oscillator, the Vbias

supply and the Tx o/p buffer. The µC interface will continue to operate except for the Command Register

which will not recognise or execute commands when ZP is ‘1’ as it relies on a clock source for correct

operation.

To obtain the lowest power consumption in Zero Power mode, the Mode Register TXRXN bit (B5) should be

set to 0 when the ZP bit (B4) is set to 1.

Mode Register B3: PSAVE - Powersave

When this bit is a '1', the modem will be in a 'powersave' mode in which the internal filters, the Rx Symbol and

Clock extraction circuits and the Tx o/p buffer will be disabled, and the TxOp pin will be connected to Vbias

through a high value resistance. The Xtal Clock oscillator, Rx i/p amplifier and the µC interface logic will

continue to operate.

Setting the PSAVE bit to '0' when the ZP bit is ‘0’ restores power to all of the chip circuitry. Note that the

internal filters - and hence the TxOp pin in transmit mode - will take about 20 symbol-times to settle after the

PSAVE bit is taken from '1' to '0'.

Mode Register B2: SSIEN - 'S' Symbol IRQ Enable

In receive mode, setting this bit to '1' causes the IRQ bit of the status register to be set to '1' whenever a new

channel status 'S' symbol has been received. (The SRDY bit of the Status Register will also be set to '1' at the

same time, and the SVAL bits updated to reflect the received 'S' symbol.)

In transmit mode, setting this bit to '1' causes the IRQ bit of the Status Register to be set to '1' whenever a 'S'

symbol or channel status bit has been transmitted. (The SRDY bit of the Status Register will also be set to '1'

at the same time.)

In MDC mode no interrupt is generated for the unused ‘94th bit’ in each block.

Mode Register B1, 0: SSYM - 'S' Symbol To Be Transmitted

In transmit mode these two bits define the next 'S' symbol or channel status bit to be transmitted. These bits

have no effect in receive mode.

B1 B0 RD-LAP MDC

1 1 ‘+3’ ‘+1’

1 0 ‘+1’ ‘+1’

0 0 ‘-1’ ‘-1’

0 1 ‘-3’ ‘-1’

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 15 D/969/5

1.5.5.4 Command Register

Writing to this register tells the modem to perform a specific action or actions, depending on the setting of the

AFSD and TASK bits, and controls the RxEye function.

Note that the Command Register uses internal clocks derived from the XTAL input to decode and carry out

any task written to it, so it is advisable to postpone writing to the Command Register until about 20 msec after

power is applied to the CMX969 or the Mode Register ZP bit is changed from ‘1’ to ‘0’, to allow time for the

Xtal oscillator to start up.

When it has no action to perform, the modem will be in an 'idle' state. If the modem is in transmit mode the

input to the Tx filter will be connected to VBIAS. In receive mode the modem will continue to measure the

received data quality and extract symbols from the received signal, supplying them to the de-interleave buffer,

but will otherwise ignore the received data.

Command Register B7: AFSD - Autonomous Frame Sync Detect

Setting this bit to ‘1’ in receive mode enables the Autonomous Frame Sync Detect function. It has no effect in

transmit mode.

Command Register B6: RXEYE - Show Rx Eye

This bit should normally be set to '0'.

Setting it to '1' when the modem is in receive mode connects the input of the Tx o/p buffer to the Rx filter

output (see Figure 1). This allows the filtered and equalised receive signal monitored with an oscilloscope (at

the TXOP pin itself), to assess the quality of the complete radio channel including the Tx and Rx modem

filters, the Tx modulator and the Rx IF filters and FM demodulator. In transmit mode this bit has no effect.

In RD-LAP mode the resulting eye diagram (for reasonably random data) should ideally be as shown in

Figure 6a, with 4 'crisp' and equally spaced crossing points.

Figure 6a Ideal 'RXEYE' Signal: RD-LAP Mode

In MDC mode the eye diagram should be as Figure 6b

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 16 D/969/5

Figure 6b Ideal 'RXEYE' Signal: MDC Mode

Command Register B5-3

These bits are reserved for future use and should always be set to ‘0’.

Command Register B2, B1, B0: TASK

Operations such as transmitting or receiving a data block are treated by the modem as 'tasks' and are initiated

when the µC writes a byte to the Command Register with the TASK bits set to anything other than the 'NULL'

code.

The µC should not write a task (other than NULL or RESET) to the Command Register or write to or read from

the Data Buffer when the BFREE (Buffer Free) bit of the Status Register is '0'.

Different tasks apply in RD-LAP and MDC receive and transmit modes.

CMX969 Modem Tasks, Transmit Mode:

B2 B1 B0 RD-LAP MDC

0 0 0 NULL NULL

0 0 1 T24S Transmit 24 symbols T40B Transmit 40 bits

0 1 0 THB Transmit Header Block THB Transmit Header Block

0 1 1 TIB Transmit Intermediate Block TIB Transmit Intermediate Block

1 0 0 TLB Transmit Last Block TLB Transmit Last Block

1 0 1 T4S Transmit 4 symbols T8B Transmit 8 bits

1 1 0 TSID Transmit Station ID - Unused

1 1 1 RESET Cancel any current action RESET Cancel any current action

When the modem is in transmit mode, all tasks other than NULL or RESET instruct the modem to transmit

data from the Data Buffer, formatting it as required. The µC should therefore wait until the BFREE (Buffer

Free) bit of the Status Register is '1', before writing the data to the Data Block Buffer, then it should write the

desired task to the Command Register. If more than 1 byte needs to be written to the Data Block Buffer, byte

number 0 of the block should be written first.

Once the byte containing the desired task has been written to the Command Register, the modem will:

Set the BFREE (Buffer Free) bit of the Status Register to '0'.

Take the data from the Data Block Buffer as quickly as it can - transferring it to the Interleave Buffer

for eventual transmission. This operation will start immediately if the modem is 'idle' (i.e. not

transmitting data from a previous task), otherwise it will be delayed until there is sufficient room in the

Interleave Buffer.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 17 D/969/5

Once all of the data has been transferred from the Data Block Buffer the modem will set the BFREE

and IRQ bits of the Status Register to '1', (causing the chip IRQN output to go low if the IRQNEN bit of

the Mode Register has been set to '1') to tell the µC that it may write new data and the next task to the

modem.

This lets the µC write a task and the associated data to the modem while the modem is still transmitting the

data from the previous task.

Figure 7 Transmit Task Overlapping

T24S: Transmit 24 Symbols (RD-LAP only)

This task, which is intended to facilitate the transmission of Symbol and Frame Sync patterns as well as

special test sequences, takes 6 bytes of data from the Data Block Buffer and transmits them as 24 4-level

symbols without any CRC, FEC, interleaving or adding any 'S' symbols.

Byte 0 of the Data Block Buffer is sent first, byte 5 last.

Once the modem has read the data bytes from the Data Block Buffer, the BFREE and IRQ bits of the Status

the modem.

The following tables show what data has to be written to the Data Block Buffer to transmit the CMX969

Symbol and Frame Sync sequences:

'Symbol Sync' Values written to Data Block Buffer

Symbols Binary Hex

+3 +3 -3 -3 Byte 0: 11110101 F5

+3 +3 -3 -3 Byte 1: 11110101 F5

+3 +3 -3 -3 Byte 2: 11110101 F5

+3 +3 -3 -3 Byte 3: 11110101 F5

+3 +3 -3 -3 Byte 4: 11110101 F5

-3 -3 +3 +3 Byte 5 : 01011111 5F

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 18 D/969/5

'Frame Sync' Values written to Data Block Buffer

Symbols Binary Hex

-1 +1 -1 +1 Byte 0: 00100010 22

-1 +3 -3 +3 Byte 1: 00110111 37

-3 -1 +1 -3 Byte 2: 01001001 49

+3 +3 -1 +1 Byte 3: 11110010 F2

-3 -3 +1 +3 Byte 4: 01011011 5B

-1 -3 +1 +3 Byte 5: 00011011 1B

NULL:

This ‘task’ has no effect in transmit mode.

T40B: Transmit 40 Bits (MDC only)

This task is similar to the RD-LAP mode T24S task, but transmits 40 bits taken from the first 5 bytes in the

Data Block Buffer. Data block buffer byte 0 is transmitted first, byte 4 last, within each byte the msb is

transmitted first, lsb last.

THB: Transmit Header Block (RD-LAP and MDC)

In RD-LAP mode this task takes 10 bytes of data from the Data Block Buffer, calculates and appends the 2-

byte CRC1 checksum, translates the result to 4-level symbols (with FEC), interleaves the symbols and

transmits the result as a formatted 'Header' Block , inserting 'S' symbols at 22-symbol intervals.

In MDC mode this task takes 4 bytes of data from the Data Block Buffer, calculates and appends the 2-byte

checksum, adds FEC bits, interleaves the result, inserts channel status bits and transmits the result as a

formatted 'Header' Block..

Once the modem has read the data bytes from the Data Block Buffer, the BFREE and IRQ bits of the Status

TIB: Transmit Intermediate Block (RD-LAP and MDC)

In RD-LAP mode this task takes 12 bytes of data from the Data Block Buffer, updates the 4-byte CRC2

checksum for inclusion in the 'Last' block, translates the 12 data bytes to 4-level symbols (with FEC),

interleaves the symbols and transmits the result as a formatted 'Intermediate' Block , inserting 'S' symbols at

22-symbol intervals.

In MDC mode this task takes 6 bytes of data from the Data Block Buffer, updates the 2-byte CRC checksum

for inclusion in the 'Last' block, adds FEC bits, interleaves the result, inserts channel status bits and transmits

the result as a formatted ‘Intermediate’ Block.

Once the modem has read the data bytes from the Data Block Buffer, the BFREE and IRQ bits of the Status

TLB: Transmit Last Block (RD-LAP and MDC)

In RD-LAP mode this task takes 8 bytes of data from the Data Block Buffer, updates and appends the 4-byte

CRC2 checksum, translates the resulting 12 bytes to 4-level symbols (with FEC), interleaves the symbols

and transmits the result as a formatted 'Last' Block , inserting 'S' symbols at 22-symbol intervals.

In MDC mode this task takes 4 bytes of data from the Data Block Buffer, updates and appends the 2-byte

checksum, adds FEC bits, interleaves the result, inserts channel status bits and transmits the result as a

formatted ‘Last’ Block.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 19 D/969/5

Once the modem has read the data bytes from the Data Block Buffer, the BFREE and IRQ bits of the Status

T4S: Transmit 4 Symbols (RD-LAP only)

This task is similar to T24S but takes only one byte from the Data Block Buffer, transmitting it as four 4-level

symbols most significant bit first.

T8B: Transmit 8 Bits (MDC only)

This task is similar to T40B but takes only one byte from the Data Block Buffer, transmitting it as 8 bits.

TSID: Transmit Station ID (RD-LAP only)

This task takes 3 ID bytes from the Data Block Buffer, calculates and appends the 6-bit CRC0 checksum,

translates the result to 4-level symbols (with FEC) and transmits the resulting 22 symbols preceded and

followed by 'S' symbols.

Once the modem has read the data bytes from the Data Block Buffer, the BFREE and IRQ bits of the Status

RESET: Stop any current action

This 'task' takes effect immediately, and terminates any current task the modem may be performing and sets

the BFREE bit of the Status Register to '1', without setting the IRQ bit. It should be used (after a delay to allow

the Xtal oscillator to start up) when VDD is applied or the ZP bit of the Mode Register changed from ‘1’ to ‘0’ to

set the modem into a known state.

Note that due to delays in the transmit low pass filter, it will take several symbol times for any change to

appear at the TXOP pin.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 20 D/969/5

CMX969 Modem Tasks, Receive Mode:

B2 B1 B0 RD-LAP MDC

0 0 0 NULL NULL

0 0 1 SFP Search for Frame Preamble - Unused

0 1 0 RHB Read Header Block RHB Read Header Block

0 1 1 RILB Read Intermediate or Last

Block RILB Read Intermediate or Last

Block

1 0 0 SFS Search for Frame Sync SFS Search for Frame Sync

1 0 1 R4S Read 4 symbols R8B Read 8 bits

1 1 0 RSID Read Station ID - Unused

1 1 1 RESET Cancel any current action RESET Cancel any current action

When the modem is in receive mode, the µC should wait until the BFREE bit of the Status Register is '1', then

write the desired task to the Command Register.

Once the byte containing the desired task has been written to the Command Register, the modem will:

Set the BFREE bit of the Status Register to '0'.

Wait until enough received symbols are in the De-interleave Buffer.

Decode them as needed, and transfer the resulting binary data to the Data Block Buffer

Then the modem will set the BFREE and IRQ bits of the Status Register to '1', (causing the IRQN

output to go low if the IRQNEN bit of the Mode Register has been set to '1') to tell the µC that it may

read from the Data Block Buffer and write the next task to the modem. If more than 1 byte is

contained in the buffer, byte number 0 of the data will be read out first.

In this way the µC can read data and write a new task to the modem while the received symbols needed for

this new task are being received and stored in the De-interleave Buffer.

Figure 8 Receive Task Overlapping

Detailed timings for the various tasks are given in Figures 10 and 11.

NULL:

This ‘task’ allows the AFSD or RXEYE bits to be changed without any other effect.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 21 D/969/5

SFP: Search for Frame Preamble (RD-LAP only)

This task causes the modem to search the received signal for a valid Frame Preamble, consisting of a 24-

symbol Frame Sync sequence followed by Station ID data which has a correct CRC0 checksum.

The task continues until a valid Frame Preamble has been found.

The search consists of four stages:

First of all the modem will attempt to match the incoming symbols against the Frame Synchronisation

pattern

Once a match has been found, the modem will read in the following 'S' symbol, place it in the SVAL

bits of the Status Register then set the SRDY bit to '1'. (The IRQ bit of the Status Register will also be

set to '1' at this time if the SSIEN bit of the Mode Register is '1').

The modem will then read the next 22 symbols as station ID data. They will be decoded and the

CRC0 checked. If this is incorrect, the modem will resume the search, looking for a fresh Frame Sync

pattern.

If the received CRC0 is correct, the following 'S' symbol will be read into the SVAL bits of the Status

decoded Station ID bytes placed into the Data Block Buffer.

On detecting that the BFREE bit of the Status Register has gone to '1', the µC should read the 3 Station ID

bytes from the Data Block Buffer then write the next task to the modem's Command Register.

RHB: Read Header Block (RD-LAP and MDC)

In RD-LAP mode this task causes the modem to read the next 69 symbols as a 'Header' Block. It will strip out

the 'S' symbols then de-interleave and decode the remaining 66 symbols, placing the resulting 10 data bytes

and the 2 received CRC1 bytes into the Data Block Buffer, and setting the BFREE and IRQ bits of the Status

and write the next task to the modem's Command Register.

In MDC mode this task causes the modem to read the next 112 bits as a 'Header' Block. It will strip out the

channel status bits then de-interleave and decode the remaining bits, placing the resulting 4 data bytes and

the 2 received CRC bytes into the Data Block Buffer, and setting the BFREE and IRQ bits of the Status

and write the next task to the modem's Command Register.

In both cases the CRCERR bit of the Status Register will be set to '1' or '0' depending on the validity of the

received CRC checksum bytes.

As each of the 'S' symbols or channel status bits of a block is received, the SVAL bits of the Status Register

will be updated and the SRDY bit set to '1'. (If the SSIEN bit of the Mode Register is '1', then the Status

SRDY bit will be set to '1' coincidentally with the BFREE bit also being set to '1'.

RILB: Read 'Intermediate' or 'Last' Block (RD-LAP and MDC)

This task causes the modem to read the next 69 symbols (RD-LAP) or 112 bits (MDC) as an 'Intermediate' or

'Last' block (the µC can tell from the 'Header' block how many blocks are in the frame, and hence when to

expect the 'Last' block).

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 22 D/969/5

In each case, it will strip out the 'S' symbols or channel status bits, de-interleave and decode the remaining

symbols and place the resulting 12 (RD-LAP) or 6 (MDC) bytes into the Data Block Buffer, setting the BFREE

and IRQ bits of the Status Register to '1' when the task is complete.

If an 'Intermediate' block is received then the µC should read out all 12 or 6 bytes from the Data Block Buffer

and ignore the CRCERR bit of the Status Register, for a 'Last' block the µC need only read the first 8 or 4

bytes from the Data Block Buffer, and the CRCERR bit in the Status Register will reflect the validity of the

received checksum.

As each of the 'S' symbols or channel status bits of the block is received, the SVAL bits of the Status Register

will be updated and the SRDY bit set to '1'. (If the SSIEN bit of the Mode Register is '1', then the Status

SRDY bit will be set to '1' coincidentally with the BFREE bit also being set to '1'.

SFS: Search for Frame Sync (RD-LAP and MDC)

This task causes the modem to search the received signal for a 24-symbol (RD-LAP) or 40-bit (MDC)

sequence which matches the required Frame Synchronisation pattern(s) allowing 5 bits in error for MDC

mode. In RD-LAP mode the allowable errors are approximately 3 bits when FSTOL = 0, 7 bits when FSTOL =

In RD-LAP mode when a match is found the modem will read in the following 'S' symbol, then set the BFREE,

IRQ and SRDY bits of the Status Register to '1' and update the SVAL bits. The µC may then write the next

task to the Command Register.

In MDC mode when a match is found the modem will set the BFREE, IRQ bits of the Status Register to ‘1’ and

set the FSTYPE bit according to the type of Frame Synchronisation pattern received. The µC may then write

the next task to the Command Register.

R4S: Read 4 Symbols (RD-LAP only)

This task causes the modem to read the next 4 symbols and translate them directly (without de-interleaving or

FEC) to an 8-bit byte which is placed into the Data Block Buffer. The BFREE and IRQ bits of the Status

write the next task to the Command Register.

This task is intended for special tests and channel monitoring - perhaps preceded by SFS task.

Note that although it is possible to construct message formats which do not rely on the block formatting of the

THB, TIB and TLB tasks by using T4S or T24S tasks to transmit and R4S to receive the user’s data, anyone

attempting this should be aware that the receive level and timing measurement circuits need to see a

reasonably ‘random’ distribution of all four possible symbols in the received signal to operate correctly, and

should therefore ‘scramble’ the binary data before transmission.

R8B: Read 8 Bits (MDC only)

This task reads the next 8 received bits and places the resulting 8-bit byte directly (without any attempt to de-

interleave, remove channel status bits or apply FEC) into the Data Block Buffer. The BFREE and IRQ bits of

the Status Register will then be set to '1' to indicate that the µC may read the data byte from the Data Block

Buffer and write the next task to the Command Register.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 23 D/969/5

RSID: Read Station ID (RD-LAP only)

This task causes the modem to read in and decode the following 23 symbols as Station ID data followed by an

'S' symbol. It is similar to the last two parts of a SFP task except that it will not re-start if the received CRC0 is

incorrect. It would normally follow a SFS task.

The 3 decoded bytes will be placed into the Data Block Buffer, and the CRCERR bit of the Status Register set

to '1' if the received CRC0 was incorrect, otherwise it will be cleared to '0'. The SVAL bits of the Status

received bytes from the Data Block Buffer and write the next task to the modem's Command Register.

RESET: Stop any current action.

This ‘task’ is similar to the Transmit mode RESET task. It takes effect immediately, and terminates any

current task the modem may be performing and sets the BFREE bit of the Status Register to ‘1’, without

setting the IRQ bit. Writing a RESET task to the CMX969 also resets an internal received signal buffer

memory used by AFSD function, so that if a RESET task is written while the CMX969 is receiving a Frame

Sync pattern then that pattern will not be recognised by the AFSD function.

Task Timings

Figure 9 Transmit Task Timing Diagram

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 24 D/969/5

RD-LAP Transmit Task Timings

Task Time

(symbol times)

t1 Modem in idle state. Time from writing first

task to application of first transmit bit to Tx

filter

Any

1 to 2

t2 Time from application of first symbol of the T24S 5

task to the Tx filter until BFREE goes TSID 6

to a logic '1' (high). THB/TIB/TLB 16

T4S 0

t3 Time to transmit all symbols of the task T24S/TSID 24

THB/TIB/TLB 69

T4S 4

t4 Max time allowed from BFREE going to a T24S 18

logic '1' (high) for next task (and data) to TSID 17

be written to modem THB/TIB/TLB 52

T4S 3

MDC Transmit Task Timings

Task Time

(bit times)

t1 Modem in idle state. Time from writing first

task to application of first transmit bit to Tx

filter

Any

0 to 1

t2 Time from application of first symbol of the T40B 0.5

task to the Tx filter until BFREE goes THB/TIB/TLB 0.5

to a logic '1' (high). T8B 0.5

t3 Time to transmit all symbols of the task T40B 40

THB/TIB/TLB 112

T8B 8

t4 Max time allowed from BFREE going to a T40B 38

logic '1' (high) for next task (and data) to THB/TIB/TLB 110

be written to modem T8B 6

Figure 10 Receive Task Timing Diagram

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 25 D/969/5

RD-LAP Receive Task Timings

Task Time

(symbol times)

t3 Time to receive all symbols of block or SFS/AFSD 25

Frame Sync pattern SFP 48

RSID 23

RHB/RILB 69

R4S 4

t6 Maximum time between first symbol of the SFS 21

Block or Frrame Sync pattern entering the SFP 21

de-interleave circuit and the task or AFSD RSID 15

being written to the modem’s Command RHB/RILB 51

t7 Maximum time from the last bit of the block Any 1

or Frame Sync pattern entering the de-

interleave circuit to BFREE or AFSDET

going to logic ‘1’ (high)

MDC Receive Task Timings

Task Time

(symbol times)

t3 Time to receive all symbols of block or SFS/AFSD 40

Frame Sync pattern RHB/RILB 112

R8B 8

t6 Maximum time between first symbol of the SFS/AFSD 38

Block or Frame Sync pattern entering the

de- RHB/RILB 13

interleave circuit and the task or AFSD being R8B 7

written to the modem’s Command Register

t7 Maximum time from the last bit of the block SFS/AFSD 2

or Frame Sync pattern entering the de- RHB/RILB 3

Interleave circuit to BFREE or AFSDET R8B 2

Going to a logic ‘1’ (high).

Lowpass Filter Delay

The previous task timing figures are based on the signal at the input to the low pass filter (in transmit mode) or

the input to the de-interleave buffer (in receive mode). In RD-LAP mode there is an additional delay of about 8

symbol times through to the RRC filter in both transmit and receive modes, as illustrated below: The

corresponding delay in MDC mode is about 3 symbol times.

Symbol-times

Tx Symbol to RRC Filter

Rx Symbol to De-interleave Buffer

Tx Symbol at Txop pin / Rx Symbol from FM discriminator

Figure 11 RRC Low Pass Filter Delay (RD-LAP mode)

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 26 D/969/5

1.5.5.5 Status Register

This register may be read by the µC to determine the current state of the modem.

Status Register B7: IRQ - Interrupt Request

This bit is set to '1' by:

The Status Register BFREE bit going from '0' to '1', unless this is caused by a RESET task or by a

change to the Mode Register TXRXN, ZP or PSAVE bits.

or The Status Register IBEMPTY/AFSDET bit going from '0' to '1', unless this is caused by a RESET

task or by changing the Mode Register TXRXN, ZP or PSAVE bits.

or The Status Register DIBOVF bit going from '0' to '1'.

or The Status Register SRDY bit being set to '1' (due to a 'S' symbol or channel status bit being

received or transmitted) if the Mode Register SSIEN bit is '1'.

The IRQ bit is cleared to '0' immediately after a read of the Status Register.

If the IRQNEN bit of the Mode Register is '1', then the chip IRQN output will be pulled low (to VSS) whenever

the IRQ bit is set to '1', and will go high impedance when the Status Register is read.

Status Register B6: BFREE - Data Block Buffer Free

This bit reflects the availability of the Data Block Buffer and is cleared to '0' whenever a task other than NULL

or RESET is written to the Command Register.

In transmit mode, the BFREE bit will be set to '1' (also setting the Status Register IRQ bit to '1') by the modem

when the modem is ready for the µC to write new data to the Data Block Buffer and the next task to the

Command Register.

In receive mode, the BFREE bit is set to '1' (also setting the Status Register IRQ bit to '1') by the modem when

it has completed a task and any data associated with that task has been placed into the Data Block Buffer.

The µC may then read that data and write the next task to the Command Register.

The BFREE bit is also set to '1' - but without setting the IRQ bit - by a RESET task or when the Mode Register

TXRXN, ZP or PSAVE bits are changed.

Status Register B5: IBEMPTY - Interleave Buffer Empty / AFSDET - Autonomous Frame Sync Detect

In transmit mode, this bit signals ‘Interleave Buffer Empty’ and will be set to '1' - also setting the IRQ bit - when

less than two symbols remain in the Interleave Buffer. Any transmit task written to the modem after this bit

goes to '1' will be too late to avoid a gap in the transmit output signal.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 27 D/969/5

In transmit mode this bit is also set to '1' by a RESET task or by a change of the Mode Register TXRXN, ZP or

PSAVE bits, but in these cases the IRQ bit will not be set.

In transmit mode this bit is cleared to '0' within one symbol time after a task other than NULL or RESET is

written to the Command Register.

Note: When the modem is in transmit mode and the Interleave Buffer is empty, a mid level (half-way between

'+1' and '-1') signal will be sent to the low pass filter.

In receive mode this bit is set to ‘1’ - also setting the IRQ bit - when the Autonomous Frame Sync circuit is

enabled (by setting b7 of the Command Register) and a received Frame Sync pattern is detected. The bit is

cleared to ‘0’ immediately after reading the Status Register. To avoid confusion this bit is not set when Frame

Sync is detected as part of a RD-LAP SFP task.

In receive mode this bit is also cleared to '0' by a RESET task or by a change of the Mode Register TXRXN,

ZP or PSAVE bits.

Status Register B4: DIBOVF - De-Interleave Buffer Overflow

In receive mode this bit will be set to '1' - also setting the IRQ bit - when a RHB, RILB, RSID, R8B or R4S task

is written to the Command Register too late to allow continuous reception.

The bit is cleared to '0' immediately after reading the Status Register, by writing a RESET task to the

Command Register or by changing the TXRXN, ZP or PSAVE bits of the Mode Register.

In transmit mode this bit is '0'.

Status Register B3: CRCERR - CRC Checksum Error

In receive mode this bit will be updated at the end of a SFP, RHB, RILB or RSID task (when BFREE goes

high) to reflect the result of the receive CRC check. '0' indicates that the CRC was received correctly, '1'

indicates an error. In transmit mode this bit will be '0'.

Note that this bit should be ignored when an 'Intermediate' block (which does not have an integral CRC) is

received.

The bit is cleared to '0' by a RESET task, or by changing the TXRXN, ZP or PSAVE bits of the Mode Register.

Status Register B2: SRDY - 'S' Symbol Ready

In receive mode this bit is set to '1' whenever an 'S' symbol or channel status bit (other than the 94th bit) has

been received. In RD-LAP mode the µC may then read the value of the symbol from the SVAL field of the

Status Register. In MDC mode the value of the received channel status bit will be in bit 0 of the Status

In transmit mode this bit is set to '1' whenever an 'S' symbol or channel status bit (other than the 94th bit) has

been transmitted.

The bit is cleared to '0' immediately after a read of the Status Register, by a RESET task or by changing the

TXRXN, ZP or PSAVE bits of the Mode Register.

Status Register B1, B0: RD-LAP Mode: SVAL - Received 'S' Symbol Value

In receive RD-LAP mode these two bits reflect the value of the latest received 'S' symbol. In transmit mode,

these two bits will be '0'.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 28 D/969/5

Status Register B1: MDC Mode: Received Frame Sync Type

In receive MDC mode this bit reflects the type of Frame Synchronisation pattern received:

‘0’ indicates Frame Sync SYNC1 ($07092A446F, msb first)

‘1’ indicates Frame Sync SYNC2 (logical inverse of SYNC1)

Status Register B0: MDC Mode: SBIT - Received Channel Status Bit

In receive MDC mode this bit reflect the value of the latest received channel status bit. In transmit mode, this

bit will be '0'.

1.5.5.6 Data Quality Register

In receive mode, the CMX969 continually measures the 'quality' of the received signal, by comparing the

actual received waveform against an internally generated 'ideal' 2 or 4-level FSK baseband signal.

The result is placed into bits 3-7 of the Data Quality Register for the µC to read at any time, bits 0-2 being

always set to '0'. Figure 12 shows how the value (0-255) read from the Data Quality Register varies with

received raw (uncorrected) bit error rate:

1.E-06

1.E-05

1.E-04

1.E-03

1.E-02

1.E-01

050 100 150 200 250

Average DQ Reading

BER

Figure 12 Typical Data Quality Reading vs BER (uncorrected)

The Data Quality readings are only valid when the modem has successfully acquired signal level and timing

lock for at least 64 symbol times. A low reading will be obtained if the received signal waveform is distorted in

any significant way.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 29 D/969/5

1.6 Application Notes

1.6.1 Autonomous Frame Sync Detect Function

In receive mode the CMX969 needs to know the received signal levels and symbol timing in order to

successfully extract the received data from the incoming signal. This can be done by using the AFSD function

to establish the levels and timing from the Frame Sync pattern at the start of a received message.

The AFSD function is enabled whenever bit 7 of the Command Register is 1 and operates in parallel with any

other receive task that may be running. It monitors the received signal for the presence of a Frame Sync

pattern without regard for any preconceived idea of the symbol timing or levels. When a Frame Sync pattern is

found the AFSD function then uses it to establish the optimum timing and levels for extracting the following

data.

This contrasts with the SFS and SFP (Search for Frame Sync and Search for Frame Preamble) tasks that rely

on previously established timing and level information and - when a Frame Sync pattern is detected - do not

change these timing and level settings.

On detecting a Frame Sync pattern the AFSD function sets the AFSDET and IRQ bits of the Status Register

and terminates any other current task.

AFSD should be enabled to look for a Frame Sync pattern whenever the CMX969 is switched to receive mode

or the radio is switched to a new receive channel or when the transmitter may have been switched off - in fact

in any circumstance where the correct levels and timing need to be re-established.

Once Frame Sync has been detected the AFSD function may be switched off if it is known that the transmitter

is sending continuous concatenated frames, in which case SFS or SFP tasks should be used to find

subsequent Frame Sync patterns. Alternatively, the AFSD function may be used instead of SFS to find all

received Frame Sync patterns.

If the system is operating in SFR (Single Frequency Re-use) mode and so has to be able to detect the start of

a new (stronger) transmission then AFSD should be left running so that it can detect the new transmitter and

automatically abort any current task and adjust the timing and level settings to suit the new signal.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 30 D/969/5

1.6.2 Rx Control Procedure

The following procedure illustrates how the CMX969 can be controlled to receive one or more messages in

MDC mode. RD-LAP mode is similar except that the first block of each message will be a Station ID block.

Step Action Notes

0 Switch radio onto receive channel.

CMX969 Mode Register IRQNEN, INVSYM

and SSIEN bits should be set as required,

other bits 0.

Control Register should have CKDIV bits set

as required, MDC bit = 1, all other bits 0.

1 Write RESET + AFSD (87h) to Command

Frame Sync pattern using AFSD.

AFSD should always be used instead of SFS to

look for the fist Frame Sync when switching into

Rx mode or when the Rx channel is changed.

2 Wait for Status Register AFSDET bit to go to

1 AFSDET will go to 1 when Frame Sync is

detected.

3 Write RHB + AFSD (82h) to Command

Header block.

Keep AFSD function running in case a false

Frame Sync had been detected or in case a

new transmitter starts up on this radio channel.

4 Wait for Status Register AFSDET or BFREE

bits to go to 1.

If AFSDET bit = 1 then a new Frame Sync

has been detected so go to step 3.

If AFSDET = 0 and BFREE = 1 the previous

Rx task (RHB or RILB) has completed.

Read Rx data from Data Buffer.

Check the Status Register CRCERR bit if it

was a Header block or the ‘last’ Data block.

Wait for the CMX969 to finish the current task

or for the AFSD function to recognise a new

Frame Sync.

If a new Frame Sync has been detected then it

is the start of a new message to abandon the

‘old’ one and start to receive and decode the

‘new’ one.

CMX969 has received and decoded a Header

Intermediate or Last block. Read the data and

check the CRC if the block contained one.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 31 D/969/5

To receive and decode the next block from

this Rx message write AFSD + RHB or RILB

(82h or 83h) to the Command Register and

go to step 4.

If we have received all of the blocks in the

message or wish to ignore any following

blocks in this message then write AFSD

(80h) to the Command Register and go to

step 2.

If we want to continue receiving the rest of this

Rx message then tell the CMX969 to receive

and decode the next block. Keep the AFSD

function running in case a new transmitter

starts up on this channel (SFR).

AFSD will detect the next Fram Sync pattern.

See note.

Note: Once a Frame Sync pattern has been detected with AFSD then if the radio is receiving concatenated

messages and if the system does not employ Single Frequency Reuse techniques subsequent Frame Sync

patterns may be detected by using a SFS task (04h) instead of AFSD. Using SFS will reduce the, very small,

chance of a false Frame Sync detection. Note that the SFS task signals that it has found a Frame Sync

pattern by setting the Status Register BFREE bit to 1, whereas AFSD sets the AFSDET bit.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 32 D/969/5

1.7 Performance Specification

1.7.1 Electrical Performance

1.7.1.1 Absolute Maximum Ratings

Exceeding these maximum ratings can result in damage to the device.

Min. Max. Units

Supply (VDD - VSS) -0.3 7.0 V

Voltage on any pin to VSS -0.3 VDD + 0.3 V

Current into or out of VDD and VSS pins -30 +30 mA

Current into or out of any other pin -20 +20 mA

P4 Package Min. Max. Units

Total Allowable Power Dissipation at Tamb = 25°C 800 mW

... Derating 13 mW/°C

Storage Temperature -55 +125 °C

Operating Temperature -40 +85 °C

E2 Package Min. Max. Units

Total Allowable Power Dissipation at Tamb = 25°C 400 mW

... Derating 5.3 mW/°C

Storage Temperature -55 +125 °C

Operating Temperature -40 +85 °C

D5 Package Min. Max. Units

Total Allowable Power Dissipation at Tamb = 25°C 550 mW

... Derating 9 mW/°C

Storage Temperature -55 +125 °C

Operating Temperature -40 +85 °C

1.7.1.2 Operating Limits

Correct operation of the device outside these limits is not implied.

Correct operation for supply voltages less than 3.0V is subject to a restricted temperature range.

Notes Min. Max. Units

Supply (VDD - VSS) 2.7 5.5 V

Operating Temperature -40 +85 °C

Symbol Rate 2000 9700 Symbols/sec

Xtal Frequency 1.0 10.0 MHz

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 33 D/969/5

1.7.1.3 Operating Characteristics

For the following conditions unless otherwise specified:

Xtal Frequency = 4.9152MHz.

Symbol Rate = RD-LAP mode 9600 symbols/sec, MDC mode 4800 symbols/sec.

VDD = 3.0V to 5.5V, Tamb = - 40°C to +85°C.

Notes Min. Typ. Max. Units

DC Parameters

IDD (VDD = 5.0V) 1 4.0 9.0 mA

IDD (VDD = 3.0V) 1 2.5 5.0 mA

IDD (Powersave Mode, VDD = 5.0V) 1 1.5 mA

IDD (Powersave Mode, VDD = 3.3V) 1 0.8 mA

IDD (Zero Power Mode, VDD = 5.0V) 1, 1a 10.0 µA

AC Parameters

Tx Output

TXOP Impedance 2 1.0 2.5 kΩ

Signal Level RD-LAP 3 1.6 2.0 2.4 V p-p

Signal Level MDC 3 0.71 0.89 1.07 V p-p

Output DC Offset wrt VDD/2 4 -0.25 +0.25 V

Rx Input

RXIN Impedance (at 100Hz) 10.0 MΩ

RXIN Amp Voltage Gain (I/P = 1mVrms at 100Hz) 300 V/V

Input Signal Level RD-LAP 5 1.0 2.5 V p-p

Input Signal Level MDC 5 0.5 1.2 V p-p

Input DC Offset wrt VDD/2 5 -1.0 +1.0 V

Xtal Input

'High' Pulse Width 6 40.0 ns

'Low' Pulse Width 6 40.0 ns

Input Impedance (at 100Hz) 10.0 MΩ

Inverter Gain (I/P = 1mVrms at 100Hz) 20.0 dB

µC Interface

Input Logic "1" Level 7, 8 70% VDD

Input Logic "0" Level 7, 8 30% VDD

Input Leakage Current (Vin = 0 to VDD) 7, 8 -5.0 +5.0 µA

Input Capacitance 7, 8 10.0 pF

Output Logic "1" Level (lOH = 120µA) 8 92% VDD

Output Logic "0" Level (lOL = 360µA) 8, 9 8% VDD

'Off' State Leakage Current (Vout = VDD)

9 10.0 µA

Notes: 1. At 25°C. Not including any current drawn from the modem pins

by external circuitry other than the Xtal oscillator.

1a Mode Register TXRXN bit set to 0.

2. Small signal impedance, at VDD = 5.0V and Tamb = 25°C.

3. For a "+3 +3 -3 -3...." symbol sequence in RD-LAP mode, “+1 -1 ..” in MDC mode, at VDD =

5.0V and Tamb = 25°C (Tx output level is proportional to VDD).

4. Measured at the TXOP pin with the modem in Rx or Tx idle mode.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 34 D/969/5

5. For optimum performance, measured at RXFB pin, for a "...+3 +3 -3 -3..." symbol sequence

in RD-LAP mode, “+1 -1 “ in MDC mode, at VDD = 5.0V and Tamb = 25°C. The optimum input

level and DC offset values are proportional to VDD. Signal peaks should not go outside the

range of (VSS + 0.25V) to (VDD – 0.25V).

6. Timing for an external input to the XTAL pin.

7. WRN, RDN, CSN, A0 and A1 pins.

8. D0 - D7 pins.

9. IRQN pin.

1E-6

1E-5

1E-4

1E-3

1E-2

1E-1

8 9 10 11 12 13 14 15 16

S/N dB (Noise in 2 x Symbol Rate Bandwidth)

BER

BER with FEC

BER without

FEC

Figure 13a Typical Bit Error Rate With and Without FEC: RD-LAP Mode

1E-6

1E-5

1E-4

1E-3

1E-2

1E-1

0 1 2 3 4 5 6 7 8 9 10 11 12

S/N dB (Noise in Bit Rate Bandwidth)

BER

BER with FEC

BER without

FEC

Figure 13b Typical Bit Error Rate With and Without FEC: MDC Mode

Note: BER vs. S/N measured under nominal working conditions, after a Frame Sync has been detected using

AFSD, with pseudo-random data.

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 35 D/969/5

Notes Min. Typ. Max. Units

µµC Parallel Interface Timings (ref. Figure 14)

tACSL Address valid to CSN low time 0 ns

tAH Address hold time 0 ns

tCSH CSN hold time 0 ns

tCSHI CSN high time 10 6.0 clock cycles

tCSRWL CSN to WRN or RDN low time 0 ns

tDHR Read data hold time 0 ns

tDHW Write data hold time 0 ns

tDSW Write data setup time 90.0 ns

tRHCSL RDN high to CSN low time (write) 0 ns

tRACL Read access time from CSN low 11 175 ns

tRARL Read access time from RDN low 11 145 ns

tRL RDN low time 200 ns

tRX RDN high to D0-D7 3-state time 50.0 ns

tWHCSL WRN high to CSN low time (read) 0 ns

tWL WRN low time 200 ns

Notes: 10. Xtal clock cycles at the XTAL pin.

11. With 30pF max to VSS on D0 - D7 pins.

Figure 14 µC Parallel Interface Timings

RD-LAP/MDC4800 Motient/ARDIS CMX969

 2001 Consumer Microcircuits Limited 36 D/969/5

1.7.2 Packaging

Figure 15 E2 Mechanical Outline: Order as part no. CMX969E2

Figure 16 P4 Mechanical Outline: Order as part no. CMX969P4

RD-LAP/MDC4800 Motient/ARDIS Modem CMX969

Handling precautions: This product includes input protection, however, precautions should be taken to prevent device damage from

electro-static discharge. CML does not assume any responsibility for the use of any circuitry described. No IPR or circuit patent

licences are implied. CML reserves the right at any time without notice to change the said circuitry and this product specification.

CML has a policy of testing every product shipped using calibrated test equipment to ensure compliance with this product

specification. Specific testing of all circuit parameters is not necessarily performed.

Oval Park - LANGFORD

MALDON - ESSEX

CM9 6WG - ENGLAND

Telephone: +44 (0)1621 875500

Telefax: +44 (0)1621 875600

e-mail: sales@cmlmicro.co.uk

http://www.cmlmicro.co.uk

Figure 17 D5 Mechanical Outline: Order as part no. CMX969D5

CML Product Data

In the process of creating a more global image, the three standard product semiconductor

companies of CML Microsystems Plc (Consumer Microcircuits Limited (UK), MX-COM, Inc

(USA) and CML Microcircuits (Singapore) Pte Ltd) have undergone name changes and, whilst

maintaining their separate new names (CML Microcircuits (UK) Ltd, CML Microcircuits (USA)

Inc and CML Microcircuits (Singapore) Pte Ltd), now operate under the single title CML Micro-

circuits.

These companies are all 100% owned operating companies of the CML Microsystems Plc

Group and these changes are purely changes of name and do not change any underlying legal

entities and hence will have no effect on any agreements or contacts currently in force.

CML Microcircuits Product Prefix Codes

Until the latter part of 1996, the differentiator between products manufactured and sold from

MXCOM, Inc. and Consumer Microcircuits Limited were denoted by the prefixes MX and FX

respectively. These products use the same silicon etc. and today still carry the same prefixes.

In the latter part of 1996, both companies adopted the common prefix: CMX.

This notification is relevant product information to which it is attached.

Company contact information is as below:

CML Microcircuits

(UK)Ltd

COMMUNICATION SEMICONDUCTORS

CML Microcircuits

COMMUNICATION SEMICONDUCTORS

CML Microcircuits

(Singapore)PteLtd

COMMUNICATION SEMICONDUCTORS

CML Microcircuits

(USA) Inc.

COMMUNICATION SEMICONDUCTORS

Oval Park, Langford, Maldon,

Essex, CM9 6WG, England

Tel: +44 (0)1621 875500

Fax: +44 (0)1621 875600

uk.sales@cmlmicro.com

www.cmlmicro.com

4800 Bethania Station Road,

Winston-Salem, NC 27105, USA

Tel: +1 336 744 5050,

0800 638 5577

Fax: +1 336 744 5054

us.sales@cmlmicro.com

www.cmlmicro.com

No 2 Kallang Pudding Road, 09-05/

06 Mactech Industrial Building,

Singapore 349307

Tel: +65 7450426

Fax: +65 7452917

sg.sales@cmlmicro.com

www.cmlmicro.com

D/CML (D)/1 February 2002