DATA BULLETIN
CMX589A
1998 MX-COM, Inc. www.mxcom.com Tele: 800 638 5577 336 744 5050 Fax: 336 744 5054 Doc. # 20480183.002
4800 Bethania Station Road, Winston-Salem, NC 27105-1201 USA All trademarks and service marks are held by their respective companies.
HIGH-SPEED
GMSK MODEM
PRELIMINARY INFORMATION
Features Applications
Data Rates from 4kbps to 200kbps
Full or Half Duplex Gaussian Filter & Data Recovery
for Minimum Shift Keying (GMSK) Designs
Selectable BT: (0.3 or 0.5)
Low Power
3.0V, 20kbps, 1.5mA typ.
5.0V, 64kbps, 4.0mA typ.
Low Current Non-DSP Solution
Small TSSOP size fits PCMCIA / PC CARDs
Portable Wireless Data Applications
Cellular Digital Packet Data (CDPD)
Mobitex Mobile Data System
Spread Spectrum Data Links
GPS/Differential GPS Wireless Links
Point of Sale Terminals
Low Power Wireless Data Link for PCs,
Laptops, and Printers
TX PS
RX PS
BT
TX DATA
ClkDIVA
PLLacq
RXDCacq
RX SIGNAL IN
RX FEEDBACK
CLOCK
DIVIDER
XTAL/CLOCK
TX ENABLE
XTAL
V
DD
V
BIAS
V
BIAS
V
BIAS
V
SS
RXHold
RX CLK
TX CLK
TX OUT
RX DATA
RX S/N
DOC1 DOC2
ClkDIVB
RX CIRCUIT
CONTROL
RX
FILTER
DATA RETIME &
LEVEL SHIFT TX
FILTER
RX S/N
DETECTION
RX CLOCK
RX DC LEVEL
MEASURE
+
-
V
BIAS
RX DATA
DETECTION
The CMX589A is a single-chip synchronous data pump/modem designed for Wireless Data Applications.
Employing Gaussian filtering for Minimum shift Keying (GMSK) baseband modulation applications, the
CMX589A features a wide range of available data rates from 4k to 200kbps. Data Rates and the choice of BT
(0.3 or 0.5) are pin programmable to provide for different system requirements.
The Tx and Rx digital data interfaces are bit serial, synchronized to generated Tx and Rx data clocks.
Separate Tx and Rx Powersave inputs allow full or half-duplex operation. Rx input levels can be set by
suitable AC and DC level adjusting circuitry built with external components around an on-chip Rx Input
Amplifier.
Acquisition, Lock, and Hold of Rx data signals are made easier and faster by the use of Rx Control Inputs to
clamp, detect, and /or hold input data levels and can be set by the Processor as required. The Rx S/N
output provides an indication of the quality of the received signal.
The CMX589A may be used with a 3.0V to 5.5V power supply and is available in the following packages:
24-pin TSSOP (CMX589AE2), 24-pin SSOP (CMX589AD5), 24-pin SOIC (CMX589AD2), and 24-pin PDIP
(CMX589AP4).
High Speed GMSK Modem 2 CMX589A PRELIMINARY INFORMATION
1998 MX-COM, Inc. www.mxcom.com Tele: 800 638 5577 336 744 5050 Fax: 336 744 5054 Doc. # 20480183.002
4800 Bethania Station Road, Winston-Salem, NC 27105-1201 USA All trademarks and service marks are held by their respective companies.
Contents
Section Page
1 Block Diagram................................................................................................................3
2 Signal List.......................................................................................................................4
3 External Components....................................................................................................6
4 General Description.......................................................................................................8
4.1 Clock Oscillator Divider ....................................................................................................... 8
4.2 Receive................................................................................................................................ 8
4.2.1 Rx Signal Path Description.....................................................................................................8
4.2.2 Rx Circuit Control Modes .......................................................................................................9
4.2.3 Rx Clock Extraction..............................................................................................................10
4.2.4 Rx Data Extraction ...............................................................................................................10
4.2.5 Rx S/N Detection..................................................................................................................11
4.2.6 Rx Signal Quality..................................................................................................................12
4.3 Transmit............................................................................................................................. 12
4.3.1 TX Signal Path Description ..................................................................................................12
4.4 Data Formats..................................................................................................................... 14
4.5 Acquisition and Hold Modes.............................................................................................. 14
5 Application ...................................................................................................................15
5.1 Radio Channel Requirements ........................................................................................... 15
5.1.1 Bit Rate, BT, and Bandwidth................................................................................................15
5.1.2 FM Modulator, Demodulator and IF .....................................................................................15
5.1.3 Two-Point Modulation...........................................................................................................16
5.2 AC Coupling of Tx and Rx Signals.................................................................................... 17
6 Performance Specifications........................................................................................18
6.1 Electrical Specifications..................................................................................................... 18
6.1.1 Absolute Maximum Limits ....................................................................................................18
6.1.2 Operating Limits...................................................................................................................18
6.1.3 Operating Characteristics.....................................................................................................19
6.2 Packages........................................................................................................................... 20
MXCOM, Inc. reserves the right to change specifications at any time without notice.
High Speed GMSK Modem 3 CMX589A PRELIMINARY INFORMATION
1998 MX-COM, Inc. www.mxcom.com Tele: 800 638 5577 336 744 5050 Fax: 336 744 5054 Doc. # 20480183.002
4800 Bethania Station Road, Winston-Salem, NC 27105-1201 USA All trademarks and service marks are held by their respective companies.
1 Block Diagram
TX PS
RX PS
BT
TX DATA
ClkDIVA
PLLacq
RXDCacq
RX SIGNAL IN
RX FEEDBACK
CLOCK
DIVIDER
XTAL/CLOCK
TX ENABLE
XTAL
V
DD
V
BIAS
V
BIAS
V
BIAS
V
SS
RXHold
RX CLK
TX CLK
TX OUT
RX DATA
RX S/N
DOC1 DOC2
ClkDIVB
RX CIRCUIT
CONTROL
RX
FILTER
DATA RETIME &
LEVEL SHIFT TX
FILTER
RX S/N
DETECTION
RX CLOCK
RX DC LEVEL
MEASURE
+
-
V
BIAS
RX DATA
DETECTION
Figure 1: Block Diagram
RX Frequency
Discriminator Frequency
Modulator
Signal and
DC Level
Adjustment
DC Level
Adjust
RX Sig In
RX Feedback
RX circuits
TX circuits
RXD
RXC
TXD
TXC
uController
or UART
RX Data
RX Clock
TX Data
TX Clock
CMX589A
GMSK MODEM
TX Out
TX Out
Filter
RX Filter
and Gain
Figure 2: System Block Diagram
High Speed GMSK Modem 4 CMX589A PRELIMINARY INFORMATION
1998 MX-COM, Inc. www.mxcom.com Tele: 800 638 5577 336 744 5050 Fax: 336 744 5054 Doc. # 20480183.002
4800 Bethania Station Road, Winston-Salem, NC 27105-1201 USA All trademarks and service marks are held by their respective companies.
2 Signal List
Pin No.
E2/D5/
D2/P4
Signal Type Description
1XTAL output The output of the on-chip clock oscillator.
2 XTAL/CLOCK input The input to the on-chip Xtal oscillator. A Xtal, or externally derived
clock (fXTAL) pulse input should be connected here. If an externally
generated clock is to be used, it should be connected to this pin and the
XTALpin left unconnected. Note: Operation without a suitable Xtal or
clock input may cause device damage.
3 ClkDivA input Logic level inputs control the internal clock divider and therefore the
transmit and receive data rate. See Table 4.
4 ClkDivB input Logic level inputs control the internal clock divider and therefore the
transmit and receive data rate. See Table 4.
5HOLDRx input A logic 0 applied to this input will freeze the Clock Extraction and Level
Measurement circuits unless they are in ‘Acquire’ mode.
6 RxDCacq input A logic 1 applied to this input will set the RX Level Measurement circuitry
to the Acquire mode.
7 PLLacq input A logic 1 applied to this input will set the RX Clock Extraction circuitry to
the ‘Acquire’ mode. See Table 6.
8 Rx PSAVE input A logic 1 applied to this input will powersave all receive circuits except
for RX CLK output (which will continue at the set bit-rate) and cause the
RX Data and RX S/N outputs to go to a logic 0.
9VBIAS The internal circuitry bias line, held at VDD/2. This pin must be bypassed
to VSS by a capacitor mounted close to the pin.
10 Rx FB Output of the RX Input Amplifier.
11 Rx Signal In input Input to RX input amplifier.
12 VSS power Negative supply (GND).
13 DOC1 Connections to the RX Level Measurement Circuitry. A capacitor should
be connected from each pin to VSS.
14 DOC2 Connections to the RX Level Measurement Circuitry. A capacitor should
be connected from each pin to VSS.
15 BT A logic level to select the modem BT (the ratio of the TX Filter's -3dB
frequency to the Bit-Rate). A logic 1 = BT of 0.5 and a logic 0 = BT of
0.3.
16 Tx Out output Gaussian filtered TX output signal. In powersave mode the Tx Out pin is
a high impedance open.
17 Tx Enable input A logic 1 applied to this input, enables the transmit data path, through
the TX Filter to the TX Out pin. A logic 0 will place the TX Out pin to
VBIAS via a high impedance.
18 Tx PSAVE input A logic 1 applied to this input will powersave all transmit circuits except
for the TX Clock.
19 Tx Data input The logic level input for the data to be transmitted. This data should be
synchronous with TX CLK.
20 Rx Data output A logic level output carrying the received data, synchronous with
RX CLK.
21 Rx CLK output A logic level clock output at the received data bit-rate.
22 Tx CLK output A logic level clock output at the transmit-data rate.
High Speed GMSK Modem 5 CMX589A PRELIMINARY INFORMATION
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4800 Bethania Station Road, Winston-Salem, NC 27105-1201 USA All trademarks and service marks are held by their respective companies.
Pin No.
E2/D5/
D2/P4
Signal Type Description
23 Rx S/N output A logic level output which may be used as an indication of the quality of
the received signal.
24 VDD power Positive supply. Levels and voltages within the device are dependent
upon this supply. This pin should be bypassed to VSS by a capacitor
mounted close to the pin.
Table 1: Signal List
High Speed GMSK Modem 6 CMX589A PRELIMINARY INFORMATION
1998 MX-COM, Inc. www.mxcom.com Tele: 800 638 5577 336 744 5050 Fax: 336 744 5054 Doc. # 20480183.002
4800 Bethania Station Road, Winston-Salem, NC 27105-1201 USA All trademarks and service marks are held by their respective companies.
3 External Components
ClkDivA
ClkDivB
RX HOLD
RXDCacq
PLLacq
RX PSAVE
V
BIAS
RX FB
RX SIGNAL IN
V
SS
V
DD
RX S/N
TXCLK
RXCLK
RXDATA
TXDATA
TXPSAVE
TXENABLE
TXOUT
BT
DOC2
DOC1
1
2
3
4
5
6
7
8
9
10
11
12
24
23
22
21
20
19
18
17
16
15
14
13
CMX589A
E2/D5/D2/P4
C6
R4
R3
C7 C8
C4
R1
C1
V
DD
XTAL/CLOCK
XTAL
C5
Suggested Clock Circuits
XTAL
XTAL/CLOCK
1
2
C3
C2 X1 R2
Crystal Circuit
XTAL
XTAL/CLOCK
1
2
C9 R2
EXT CLK
External Clk > 10.24MHz Circuit
XTAL
1
2
EXT CLK XTAL/CLOCK
External Clk 10.24MHz Circuit
Figure 3: Recommended External Components
Component Notes Value Tolerance Component Notes Value Tolerance
R1 1 ±5% C4 0.1µF ±20%
R2 1.0M±10% C5 1.0µF ±20%
R3 2 ±10% C6 5 ±20%
R4 3 ±10% C7 6
C1 1 ±10% C8 6
C2 4 C9 7 100pF
C3 4 X1 8
Table 2: Recommended External Components
Recommended External Component Notes:
1. The RC network formed by R1 and C1 is required between the TX Out pin and the input to the modulator.
This network, which can form part of any DC level shifting and gain adjustment circuitry, forms an
important part of the transmit signal filtering. The ground connection to the capacitor C1 should be
positioned to give maximum attenuation of high-frequency noise into the modulator.
The component values should be chosen so that the product of the resistance and the capacitance is:
For a BT of 0.3 R1C1 = 0.34/bit rate (bps)
For a BT of 0.5 R1C1 = 0.22/bit rate (bps)
High Speed GMSK Modem 7 CMX589A PRELIMINARY INFORMATION
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4800 Bethania Station Road, Winston-Salem, NC 27105-1201 USA All trademarks and service marks are held by their respective companies.
BT = 0.3 BT = 0.5
Data Rates
(kbps) R1 C1 R1 C1
4120k680pF 120k470pF
4.8 100k680pF 100k470pF
891k470pF 120k220pF
9.6 91k390pF 47k470pF
16 47k470pF 91k150pF
19.2 100k180pF 91k120pF
32 47k220pF 47k150pF
38.4 * 47k180pF 47k120pF
64 * 56k100pF 51k68pF
80 * 39k68pF
128 * 82k22pF
144 * 68k22pF
160 * 62k22pF
176 * 56k22pF
192 * 51k22pF
* VDD 4.5V, external clock
Table 3: Data Rate vs. BT and Selected External Component Values
Note: In all cases, the value of R1 should not be less than 20.0k, and that the calculated value of C1
includes calculated parasitic capacitance.
2. R3, R4 and C6 form the gain components for the RX Input signal. R3 should be chosen as required by
the signal input level.
3. For bit rate 64kbps, R4 = 100k. For bit rate > 64kbps, R4 = 10k.
4. The values chosen for C2 and C3 (including stray capacitance) should be suitable for the applied VDD
and the frequency of X1.
As a guide: C2 = C3 = 33pF at 1.0MHz falling to 18pF at the maximum frequency.
At 3.0V, C2 = C3 = 33pF falling to 18pF at 5.0MHz the equivalent series resistance of X1 should be less
than 2.0K falling to 150 at the maximum frequency. Stray capacitance on the Xtal/Clock circuit pins
must be minimized.
5. For bit rate 64kbps, C6 = 22pF. For bit rate > 64kbps, C6 = 10k 2 rate bit 3 1 e.g. for 128kbps,
C6 = 41.1pF.
6. C7 and C8 should both be .015F for a data rate of 8kbps, and inversely proportional to the data rate for
other data rates, e.g. 0.030F at 4kbps, 1800pF at 64kbps, 680pF at 192kbps.
7. The tolerance of C9 is not very critical because it primarily serves as a DC blocking capacitor.
8. The CMX589A can operate correctly with the Xtal/Clock frequencies between 1.0MHz and 8.2MHz
(VDD = 5.0V) and 1.0MHz to 5.0MHz (VDD = 3.0V). External clock frequencies up to 25.6MHz
(VDD 4.5V) are also supported. (See Table 4 for examples.) For best results, a crystal oscillator design
should drive the clock inverter input with signal levels of at least 40% of VDD, peak to peak. Tuning fork
crystals generally cannot meet this requirement. To obtain crystal oscillator design assistance, consult
your crystal manufacturer. Operation of this device without a Xtal or Clock input may cause device
damage.
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4800 Bethania Station Road, Winston-Salem, NC 27105-1201 USA All trademarks and service marks are held by their respective companies.
4 General Description
4.1 Clock Oscillator Divider
The TX and (nominal) RX data rates are determined by division of the frequency present at the Xtalpin as
generated by the on-chip Xtal oscillator, with external components, or supplied from an external source.
The division ratio is controlled by the logic level inputs on ClkDivA and ClkDivB pins as shown in Table 4,
together with an indication of how various standard data rates may be derived from common µP Xtal
frequencies.
A/B)(ClkDiv Ratio Division Frequency Xtal/Clk
Rate Data
Xtal/Clock Frequency (MHz)
24.576* 8.192 4.9152 4.096 2.4576 2.048
Inputs 12.288/3 12.288/5 6.144/3
ClkDivA ClkDivB Rate Data Freq Xtal/Clk
Data Rate (kbps)
0 0 128 192* 64* 38.4* 32 19.2 16
0 1 256 96* 32 19.2 16 9.6 8
1 0 512 48* 16 9.6 8 4.8 4
1 1 1024 24* 8 4.8 4
* VDD 4.5V
Table 4: Example Clock/Data Rates
Note: The device operation is not guaranteed above 200kbps or below 4kbps at the relevant supply voltage.
Tx Enable
ClkDIVA
ClkDIVB
BT
RxHOLD
Rx S/N
Tx PS
Rx PS
XTAL/CLOCK
XTAL
Rx DATA
Rx CLOCK
Tx DATA
Tx ClOCK
PLLacq
RxDCacq
RxD
RxC
TxD
TxC
SERIAL
I/O PORT
µCONTROLLER
SETTINGS: D/RATE 4800 bps -BT 0.5 - Rx and Tx Enabled
CMX589A
GMSK MODEM
V
DD
4.9152MHz
Figure 4: Minimum Controller System Connections
4.2 Receive
4.2.1 Rx Signal Path Description
The function of the RX circuitry is to:
1. Set the incoming signal to a usable level.
2. Clean the signal by filtering.
3. Provide DC level thresholds for clock and data extraction.
4. Provide clock timing information for data extraction and external circuits.
5. Provide RX data in a binary form.
6. Assess signal quality and provide Signal-to-Noise information.
High Speed GMSK Modem 9 CMX589A PRELIMINARY INFORMATION
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4800 Bethania Station Road, Winston-Salem, NC 27105-1201 USA All trademarks and service marks are held by their respective companies.
The output of the radio receiver's Frequency Discriminator should be fed to the CMX589A's RX Filter by a
suitable gain and DC level adjusting circuit. This circuit can be built with external components around the on-
chip RX Input Amplifier. The gain should be set so that the signal level at the RX Feedback pin is nominally
1V peak to peak (for VDD=5.0V) centered around VBIAS when receiving a continuous 1111000011110000..
data pattern.
Positive going signal excursions at RX Feedback pin will produce a logic 0 at the RX Data Output. Negative
going excursions will produce a logic 1.
The received signal is fed through the lowpass RX Filter, which has a -3dB corner frequency of 0.56 times the
data bit-rate, before being applied to the Level Measure and Clock and Data extraction blocks.
The Level Measuring block consists of two voltage detectors, one of which measures the amplitude of the
positive parts of the received signal. The other measures the amplitude of the negative portions. (Positive
refers to signal levels higher than VDD/2, and negative to levels lower than VDD/2.) External capacitors are
used by these detectors, via the Doc1 & Doc2 pins, to form voltage ‘hold’ or ‘integrator’ circuits. These two
levels are then used to establish the optimum DC level decision-thresholds for the Clock and Data extraction,
depending upon the RX signal amplitude and any DC offset.
4.2.2 Rx Circuit Control Modes
The operating characteristics of the Rx Level Measurement and Clock Extraction circuits are controlled, as
shown in Table 6, by logic level inputs applied to the PLLacq, HOLDRx , and RxDCacq pins to suit a
particular application, or to cope with changing reception conditions, reference Figure 5.
In general, a data transmission will begin with a preamble, for example, 1100110011001100, to allow the
receive modem to establish timing and level-lock as quickly as possible. After the Rx carrier has been
detected, and during the time that the preamble is expected, the RxDCacq and PLLacq Inputs should be
switched from a logic 0 to a logic 1 so that the Level Measuring and Clock Extraction modes are operated and
sequenced as shown.
The HOLDRx input should normally be held at a logic 1 while data is being received, but may be driven to a
logic 0 to freeze the Level Measuring Clock Extraction circuits during a fade. If a fade lasts for less than 200
bit periods, normal operation can be resumed by returning the HOLDRx input to a logic 1 at the end of the
fade. For longer fades, it may be better to reset the Level Measuring circuits by placing the RxDCacq to a
logic 1 for 10 to 20 bit periods.
HOLDRx has no effect on the Level Measuring circuits while RxDCacq is at a logic 1, and has no effect on
the PLL while PLLacq is at a logic 1.
A logic 0 on HOLDRx does not disable the Rx Clock output, and the Rx Data Extraction and S/N Detector
circuits will continue to operate.
Rx Signal Input
Rx CARRIER DET
(RSSI) Input
RxDCacq
Rx LEVEL MEASURE
MODE
PLLacq
CLOCK EXTRACTION
CCT MODE
FAST PEAK
DETECT
30 BITS
MEDIUM
BANDWIDTH NARROW
BANDWIDTH
AVERAG ING PEAK
DETECT
ACQUIRE
CLAMP
PREAMBLE DATA
Figure 5: Rx Mode Control Diagram
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PLLacq RxHOLD PLL Action
1 1 Acquire Sets the PLL bandwidth wide enough to allow a lock to the
received signal in less than 8 zero crossings. This mode will
operate as long as PLLacq is a logic “1”.
1 to 0 1 Medium
Bandwidth The correction applied to the extracted clock is limited to a
maximum of ±1/16th bit-period for every two received zero-
crossings. The PLL operates in this mode for a period of
about 30 bits immediately following a 1 to 0 transition of the
PLLacq input, provided that the HOLDRx input is a logic 1.
0 1 Narrow
Bandwidth The correction applied to the extracted clock is limited to a
maximum of ±1/64th bit-period for every two received zero-
crossings. The PLL operates in this mode whenever the
HOLDRx Input is a logic 1 and PLLacq has been a logic 0
for at least 30 bit periods (after Medium Bandwidth operation
for instance).
0 0 Hold The PLL feedback loop is broken, allowing the RX Clock to
freewheel during signal fade periods.
Table 5: PLL Action Measurement Operational Modes
RxDCacq RxHOLD Rx Level Measure Action
0 to 1 X Clamp Operates for one bit-time after a 0 to 1 transition of the
RXDCacq input. The external capacitors are rapidly charged
towards a voltage mid-way between the received signal input
level and VBIAS, with the charge time-constant being of the
order of 0.5 bit-time.
1 X Fast Peak Detect The voltage detectors act as peak-detectors, one capacitor is
used to capture the positive-going signal peaks of the RX
Filter output signal and the other capturing the negative-
going peaks. The detectors operate in this mode whenever
the RXDCacq input is at a logic 1, except for the initial 1-bit
Clamp-mode time.
01
Averaging Peak
Detect Provides a slower but more accurate measurement of the
signal peak amplitudes.
0 0 Hold The capacitor charging circuits are disabled so that the
outputs of the voltage detectors remain substantially at the
last readings (discharging very slowly [time-constant approx.
2,000 bits] towards VBIAS).
X = Do not care
Table 6: Rx Level Measurement Operational Modes
4.2.3 Rx Clock Extraction
Synchronized by a PLL circuit to zero-crossings of the incoming data, the Rx Clock Extraction circuitry
controls the Rx Clock output. The Rx Clock is also used internally by the Data Extraction circuitry. The PLL
parameters can be varied by the Rx Circuit Control inputs PLLacq and HOLDRx to operate in one of four
PLL modes as described in Table 5 and Table 6.
4.2.4 Rx Data Extraction
The RX Data Extraction circuit decides whether each received bit is a 1 or 0 by sampling the received signal,
after filtering, and comparing the sample values to an adaptive threshold derived from the Level Measuring
circuit. This threshold is adapted from bit to bit to compensate for intersymbol interference caused by the
bandlimiting of the overall transmission path and the Gaussian premodulation filter. Extracted data is output
from the RX Data pin, and should be sampled externally on the rising edge of the RX CLK.
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4.2.5 Rx S/N Detection
The RX S/N Detector system classifies the incoming zero-crossings as GOOD or BAD depending upon the
time when each crossing actually occurs with respect to its expected time as determined by the Clock
Extraction PLL. This information is then processed to provide a logic level output at the RX S/N pin. A high
level indicates a series of GOOD crossings; a low level indicates a BAD crossing.
By averaging this output, it is possible to derive a measure of the Signal-to-Noise-Ratio and hence the
Bit-Error-Rate of the received signal.
10
-6
10
-5
10
-4
10
-3
10
-2
10
-1
5678910
11 12 13 14 15 16 17 18 19 20
S/N (dB) [Noise Bandwidth = Bit Rate]
BER
CMX589A BT = 0.3
CMX589A BT = 0.5
BT = 1.0 (Theoretical)
Figure 6: Typical Bit-Error-Rate Performance
Note: Figure 6 indicates typical performance, independent of bit rate (although the applied noise bandwidth is
considered to match the bit rate used), radio performance (e.g. IF filter distortion), supply voltage (higher bit
rates require VDD 4.5V), and other ‘real world’ factors.”
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4800 Bethania Station Road, Winston-Salem, NC 27105-1201 USA All trademarks and service marks are held by their respective companies.
4.2.6 Rx Signal Quality
The effect of input Rx Signal quality on the Rx S/N output is shown in Figure 7.
0
10
20
30
40
50
60
70
80
90
100
678910
11 12 13
S/N (dB)
% High Time
5
BT=0.5
BT = 0.3
Figure 7: Typical Rx S/N Output High time (%) vs. Input S/N
4.3 Transmit
4.3.1 TX Signal Path Description
The binary data applied to the TX Data input is retimed within the chip on each rising edge of the TX Clock
and then converted to a 1-volt peak-to-peak binary signal centered at VBIAS (for VDD= 5.0V)
If the TX Enable input is high, then this internal binary signal will be connected to the input of the lowpass TX
Filter, and the output of the filter connected to the TX Out pin.
Tx Enable Tx Filter Input Tx Out Pin
1Data @ 5
VDD VP-P
e.g. 1VP-P for VDD=5V
Filtered ‘Tx Filter Input’
0VBIAS VBIAS via 500k
A ‘low’ input to the TX Enable will connect the input of the TX Filter to VBIAS, and disconnect the TX Out pin
from the filter, connecting it instead to VBIAS through a high resistance (nominally 500k).
The TX Filter has a lowpass frequency response, which is approximately gaussian in shape as shown in
Figure 9, to minimize amplitude and phase distortion of the binary signal while providing sufficient attenuation
of the high frequency-components which would otherwise cause interference into adjacent radio channels.
The actual filter bandwidth to be used in any particular application will be determined by the overall system
requirements. The attenuation-vs.-frequency response of the transmit filtering provided by the CMX589A has
been designed to meet the specifications for most GMSK modem systems that are -3dB bandwidth
switchable between 0.3 and 0.5 times the data bit-rate (BT).
Note: An external RC network is required between the TX Out pin and the input to the Frequency Modulator
(see Figure 2 and Figure 3). This network, which can form part of any DC level shifting and gain adjustment
circuitry, forms an important part of the transmit signal filtering. The ground connection to capacitor C1
should be positioned to give maximum attenuation of high-frequency noise into the modulator.
The signal at Tx Out is centered around VBIAS, going positive for logic 1 (high) level inputs to the Tx Data
input and negative for logic 0 (low) inputs.
When the transmit circuits are put into a powersave mode (by a logic 1 to the Tx PS pin) the output voltage of
the Tx Filter will go to high impedance. When power is subsequently restored to the Tx filter, its output will
take several bit-times to settle. The Tx Enable input can be used to prevent these abnormal voltages from
appearing at the Tx Out pin.
High Speed GMSK Modem 13 CMX589A PRELIMINARY INFORMATION
1998 MX-COM, Inc. www.mxcom.com Tele: 800 638 5577 336 744 5050 Fax: 336 744 5054 Doc. # 20480183.002
4800 Bethania Station Road, Winston-Salem, NC 27105-1201 USA All trademarks and service marks are held by their respective companies.
1 BIT PERIOD
1.0 s Min.µ
TX DATA SAMPLED BY
THE CMX589A AT THESE
INSTANCES
TX Data
RX Data
RX CLK
TX CLK
DON'T CARE
DATA INVALID DATA VALID
DATA MUST
BE VALID
EXTERNAL CIRCUITS SHOULD
SAMPLE RX DATA AT THIS TIME
TX CLOCK AND RX CLOCK OUTPUTS
(MARK/SPACE) DUTY CYCLE NOMINALLY 50%.
1.0 s Max.µ1.0 s Max.µ
1.0 s Min.µ
Figure 8: Rx and Tx Clock Data Timings
..
BT = 0.3 BT = 0.5
0
-10
-20
-30
-40
-50
-60
-70 0.1 10
1
0.01 Frequency/Bitrate
Gain (dB)
Figure 9: Tx Filter Response
High Speed GMSK Modem 14 CMX589A PRELIMINARY INFORMATION
1998 MX-COM, Inc. www.mxcom.com Tele: 800 638 5577 336 744 5050 Fax: 336 744 5054 Doc. # 20480183.002
4800 Bethania Station Road, Winston-Salem, NC 27105-1201 USA All trademarks and service marks are held by their respective companies.
BT = 0.3 BT = 0.5
Figure 10: Typical Transmit Eye Patterns
-70
-60
-50
-40
-30
-20
-10
0
01.0
2.0
Gain (dB)
Frequency/Bitrate
BT = 0.3 BT=0.5
Figure 11: Tx Output Spectrum (Random Data)
4.4 Data Formats
The receive section of the CMX589A works best with data which has a reasonably random structure --the
data should contain approximately the same number of ‘ones’ as ‘zeroes’ with no long sequences (>100 bits)
of consecutive ones or zeroes. Also, long sequences (>100 bits) of 10101010 ... patterns should be avoided.
For this reason, it is recommended that data be made random in some manner before transmission, for
example by exclusive-ORing it with the output of a binary pseudo-random pattern generator.
Where data is transmitted in bursts, each burst should be preceded by a preamble designed to allow the
receive modem to establish timing and level lock as quickly as possible. This preamble for BT=0.3 should be
at least 16 bits long, and should preferably consist of alternating pairs of ones and zeros i.e.
110011001100....; the eye of pattern 10101010 .... has the most gradual slope and will yield poor peak levels
for the RX circuits. For BT=0.5 the eye pattern of 10101010... has reduced intersymbol interference and may
be used as the preamble (DC Acq pin should be held high during preamble). See Fig. 6.
4.5 Acquisition and Hold Modes
The RXDCacq and PLLacq inputs must be pulsed High for about 16 bits at the start of reception to ensure
that the DC measurement and timing extraction circuits lock-on to the received signal correctly. Once lock
has been achieved, the above inputs should be taken Low again.
In most applications, there will be a DC step in the output voltage from the receiver FM discriminator due to
carrier frequency offsets as channels are changed or when the remote transmitter is turned on.
The CMX589A can tolerate DC offsets in the received signal of at least ±0.5V with respect to VBIAS,
(measured at the RX Feedback pin). However, to ensure that the DC offset compensation circuit operates
correctly and with minimum delay, the Low to High transition of the RXDCacq and PLLacq inputs should
occur after the mean input voltage to the CMX589A has settled to within about 0.1V of its final value.
Note: This can place restrictions on the value of any series signal coupling capacitor.
High Speed GMSK Modem 15 CMX589A PRELIMINARY INFORMATION
1998 MX-COM, Inc. www.mxcom.com Tele: 800 638 5577 336 744 5050 Fax: 336 744 5054 Doc. # 20480183.002
4800 Bethania Station Road, Winston-Salem, NC 27105-1201 USA All trademarks and service marks are held by their respective companies.
As well as using the RX Hold input to freeze the Level Measuring and Clock Extraction circuits during a signal
fade, it may also be used in systems which use a continuously transmitting control channel to freeze the RX
circuitry during transmission of a data packet, allowing reception to resume afterwards without losing bit
synchronization. To achieve this, the CMX589A Xtal clock needs to be accurate enough that the derived
RXClock output does not drift by more than about 0.1 bit time from the actual received data-rate during the
time that the RXHold input is ‘Low’.
However; the RXDCacq input may need to be pulsed High for 2 bit durations to re-establish the level
measurements if the RXHold input is Low for more that a few hundred bit-times (exact number depends on
system crystal tolerances).
The voltages on the Doc1 and Doc2 pins reflect the average peak positive and negative excursions of the
(filtered) receive signal, and could therefore be used to derive a measure of the data signal amplitude.
Note: These pins are driven from very high-impedance circuits, so that the DC load presented by any
external circuitry should exceed 10M to VBIAS.
5 Application
5.1 Radio Channel Requirements
To achieve legal adjacent channel performance at high bit-rates, a radio with an accurate carrier frequency
and an accurate modulation index is required. For optimum channel utilization, (e.g. low BER and high data-
rates) attention must be paid to the phase and frequency response of both the IF and baseband circuitry.
5.1.1 Bit Rate, BT, and Bandwidth
The maximum data rate that can be transmitted over a radio channel depends on the following:
Channel spacing
Allowable adjacent channel interference
TX filter bandwidth
Peak carrier deviation (Modulation Index)
TX and RX carrier frequency accuracies
Modulator and Demodulator linearity
RX IF filter frequency and phase characteristics
Use of error correction techniques
Acceptable error-rate
As a guide to MOBITEX operation, a raw data-rate of 8kbps at 12.5kHz channel spacing may be achievable -
depending on local regulatory requirements- using a ±2kHz maximum deviation, a BT of 0.3, and no more
than 1.5kHz discrepancy between Tx & Rx carrier frequencies. Forward error correction (FEC) could then be
used with interleaving to reduce the effect of burst errors.
Reducing the data-rate to 4.8kbps would allow the BT to be increased to 0.5, improving the error-rate
performance.
5.1.2 FM Modulator, Demodulator and IF
For optimum performance, the eye pattern of the received signal (when receiving random data) applied to the
CMX589A should be as close as possible to the Transmit eye pattern examples shown in Figure 10.
Of particular importance are general symmetry, cleanliness of the zero-crossings, and for a BT of 0.3, the
relative amplitude of the inner eye opening.
To achieve this, attention must be paid to:
Linearity and frequency/phase response of the Tx frequency modulator. Unless the transmit data is
especially encoded to remove low frequency components, the modulator frequency response should
extend down to a few hertz. This is because two-point modulation is necessary for synthesized
radios.
Bandwidth & phase response of the RX IF filters.
Accuracy of the Tx and Rx carrier frequencies -any difference will shift the received signal towards
one of the skirts of the IF filter response.
High Speed GMSK Modem 16 CMX589A PRELIMINARY INFORMATION
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4800 Bethania Station Road, Winston-Salem, NC 27105-1201 USA All trademarks and service marks are held by their respective companies.
Ideally, the Rx demodulator should be DC coupled to the CMX589A RX Signal In pin (with a DC bias added to
center the signal at the RX Feedback pin at VDD/2 [VBIAS]). However, AC coupling can be used provided that:
The 3dB cut-off frequency is 20Hz or below (i.e. a 0.1F capacitor in series with 100k).
The data does not contain long sequences of consecutive ones or zeroes.
Sufficient time is allowed after a step change at the discriminator output (resulting from channel
changing or the appearance of a RF carrier) for the voltage into the CMX589A to settle before the
RXDCacq line is strobed.
5.1.3 Two-Point Modulation
When designing the CMX589A into a radio that uses a frequency synthesizer, a two-point modulation
technique is recommended. This is both to prevent the radio's PLL circuitry from counteracting the
modulation process, and to provide a clean flat modulation response down to DC.
Figure 12 shows a suggested basic configuration to provide a two-point modulation drive from the CMX589A
TX Output using MX-COM's MX019 Digitally Controlled Quad Amplifier Array. The MX019 elements provide
individual set-up, calibration and dynamic control of modulation levels. Level setting control of the
amplifiers/attenuators of the MX019 is via an 8-bit data word. Note that the MX019 frequency response
supports data rates as high as 8kbps.
With reference to Figure 12:
The buffer amplifier is required to prevent loading of the CMX589A external RC circuit.
Stage B, with R1/R2, provides suitable signal and DC levels for the VCO varactor; C1 is RF
decoupling. The drive level should be adjusted (digitally) to provide the desired deviation.
Stage C, with R3/R4, provides the Reference Oscillator drive (application dependent). This
parameter is set by adjusting for minimum AC signal on the PLL control voltage with a low-frequency
modulating signal (inside the PLL bandwidth) applied.
Stage D could be used with the components shown if a negative reference drive is required.
Stage A provides buffering and overall level control.
CMX589A
TX OUT +14dB to -14dB
Buffer
+3dB to -3dB
CONTROL
+3dB to -3dB
+3dB to -3dB
A
B
C
D
TX VCO
To TX
REF Osc (+)
To TX
REF Osc (-)
V
SS
V (-)
REF
R5
External RC
See Fig.3
R6
V
VCO
C1
R1
R2
V(+)
REF
R3
R4
With reference to the MX019 Data Sheet
Stage A = MX019 Channel 4
Stage B = MX019 Channel 1
Stage C = MX019 Channel 2
Stage D = MX019 Channel 3
Note:
1. All stages of the MX019 are 'inverting' stages.
2. Components R1-R6 should produce the proper output
signal levels f or interface into the modulator.
Figure 12: An Example of Two-Point Modulation Drive with Individual Adjustment Using the MX019
High Speed GMSK Modem 17 CMX589A PRELIMINARY INFORMATION
1998 MX-COM, Inc. www.mxcom.com Tele: 800 638 5577 336 744 5050 Fax: 336 744 5054 Doc. # 20480183.002
4800 Bethania Station Road, Winston-Salem, NC 27105-1201 USA All trademarks and service marks are held by their respective companies.
5.2 AC Coupling of Tx and Rx Signals
In practical applications, it is possible to arrange AC coupling between the CMX589A Tx Output and the
frequency modulator to cut-off at a very low frequency, such as 5.0Hz. AC coupling between the receive
discriminator and the input of the CMX589A may need a shorter time-constant to avoid problems from voltage
steps at the output of the discriminator when changing channels or when the distant transmitter turns on.
For these reasons, as well as to maintain reasonable BER, the optimum –3dB cut-off frequencies are around
5.0Hz in the Tx path and 20.0Hz in the Rx path.
Figure 13 shows the typical static Bit-Error-Rate performance of the CMX589A operating under nominal
conditions for various degrees of AC coupling at the Rx input and the Tx output.
Data Rate = 8kbps VDD = 5.0V TAMB = 25C Tx BT = 0.3
S/N (dB) (noise in 8kHz bandwidth)
10
-5
10
-4
10
-3
10
-2
10
-1
45678910111213
BER
TX and RX DC coupled
TX 5Hz, RX DC coupled
TX 5Hz, RX 10Hz
TX 5Hz, RX 30Hz
TX 5Hz, RX 100Hz
Figure 13: Effect of AC Coupling on Typical Bit-Error Rate
Any AC Coupling at the receive input will transform any step in the voltage at the discriminator output to a
slowly decaying pulse which can confuse the modem’s level measuring circuits. As illustrated in Figure 14,
the time for this step to decay to 37% of its original value is ‘RC’ where:
network) RC the offrequency cutoff 3dB (the21
RC
which is 32ms, or 256 bit times at 8kbps, for a 5Hz network.
Figure 14: Decay time-AC Coupling
High Speed GMSK Modem 18 CMX589A PRELIMINARY INFORMATION
1998 MX-COM, Inc. www.mxcom.com Tele: 800 638 5577 336 744 5050 Fax: 336 744 5054 Doc. # 20480183.002
4800 Bethania Station Road, Winston-Salem, NC 27105-1201 USA All trademarks and service marks are held by their respective companies.
6 Performance Specifications
6.1 Electrical Specifications
6.1.1 Absolute Maximum Limits
Exceeding these maximum ratings can result in damage to the device.
General Notes Min. Typ. Max. Units
Supply (VDD-VSS)-0.3 7.0 V
Voltage on any pin to VSS -0.3 VDD + 0.3 V
Current
VDD -30 30 mA
VSS -30 30 mA
Any other pin -20 20 mA
D2 / P4 Packages
Total allowable Power dissipation
at TAMB = 25C800 mW
Derating above 25C13 mW/C above 25C
Operating Temperature -40 85 C
Storage Temperature -55 125 C
D5 / E2 Packages
Total allowable Power dissipation
at TAMB = 25C550 mW
Derating above 25C9mW/C above 25C
Operating Temperature -40 85 C
Storage Temperature -55 125 C
Table 7: Absolute Maximum Ratings
6.1.2 Operating Limits
Correct Operation of the device outside these limits is not implied.
Notes Min. Typ. Max. Units
Supply (VDD-VSS)3.0 3.3/5.0 5.5 V
Operating Temperature -40 85 C
Rx and Tx Data Rate
VDD 3.0V 4 32 kbps
VDD 4.5V 4 200 kbps
Xtal Frequency
VDD 3.0V 1.0 5.0 MHz
VDD 4.5V 1.0 25.6 MHz
High Pulse Width 1 15 ns
Low Pulse Width 1 15 ns
Table 8: Operating Limits
Operating Limits Notes
1. Timing for an external clock input to the Xtal/Clock pin.
High Speed GMSK Modem 19 CMX589A PRELIMINARY INFORMATION
1998 MX-COM, Inc. www.mxcom.com Tele: 800 638 5577 336 744 5050 Fax: 336 744 5054 Doc. # 20480183.002
4800 Bethania Station Road, Winston-Salem, NC 27105-1201 USA All trademarks and service marks are held by their respective companies.
6.1.3 Operating Characteristics
For the following conditions unless otherwise specified.
VDD = 5.0V @ TAMB = 25C
Xtal/Clock Frequency = 4.096MHz, Data Rate = 8kbps, Noise Bandwidth = Bit Rate
Static Values Notes Min. Typ. Max. Units
Supply Current Tx PS Rx PS 1
IDD (VDD = 3.0V) 11 0.5 mA
01 1.0 mA
10 1.0 mA
00 1.5 mA
IDD (VDD = 5.0V) 11 1.0 mA
01 2.0 mA
10 3.0 mA
00 4.0 mA
Input Logic Level
Logic 1 Input Level 3.5 V
Logic 0 Input Level 1.5 V
Logic Input Current 2 -5.0 5.0 A
Output Logic Level
Logic 1 Output Level (IOH = 120A) 4.6 V
Logic 0 Output Level (IOL = -120A) 0.4 V
Transmit Parameters
Tx OUT pin DC bias shift caused by change from
Tx Enable = 0 to Tx Enable = 1 while
Tx PSAVE = 0 at 25C
-85 85 mV
Tx OUT, Output Impedance 3 1.0 k
Tx Out, Level 4, 10 0.8 1.0 1.2 VP-P
Output DC Offset 12 -0.125 0.125 V
Tx Data Delay
BT = 0.3 5 2.0 2.5 bit-
periods
BT = 0.5 5 1.5 2.0 bit-
periods
Tx PS to Output-Stable time 6 4.0 bit-
periods
Receive Parameters
Rx Amplifier
Input Impedance 1.0 M
Output Impedance 7 10.0 K
Voltage Gain 50.0 dB
Rx Filter Signal Input Level 8, 10 0.7 1.0 1.3 VP-P
Rx Time Delay 9 3.0 bit-
periods
High Speed GMSK Modem 20 CMX589A PRELIMINARY INFORMATION
1998 MX-COM, Inc. www.mxcom.com Tele: 800 638 5577 336 744 5050 Fax: 336 744 5054 Doc. # 20480183.002
4800 Bethania Station Road, Winston-Salem, NC 27105-1201 USA All trademarks and service marks are held by their respective companies.
Static Values Notes Min. Typ. Max. Units
On-Chip Xtal Oscillator
RIN 10.0 M
ROUT 11 50.0 k
Voltage Gain 11 25.0 dB
Table 9: Operating Characteristics
Operating Characteristics Notes:
1. Not including current drawn from the CMX589A pins by external circuitry. See Absolute Maximum
Ratings.
2. For VIN in the range VSS to VDD.
3. For a load of 10K or greater. Tx PS input at logic 0; Tx Enable = 1.
4. Data pattern of 1111000011110000…
5. Measured between the rising edge of Tx Clock and the center of the corresponding bit at Tx Out.
6. Time between the falling edge of the Tx PS and the Tx Out voltage stabilizing to normal output levels.
7. For a load of 10k or greater. Rx PS input at logic 0.
8. For optimum performance, Measured at the Rx Feedback pin for an 1111000011110000… pattern.
9. Measured between the center of bit at Rx Signal In and corresponding rising edge of the Rx Clock.
10. Levels are proportional to applied VDD
11. Small signal measurement at 1.0kHz with no load on Xtal output.
12. (Tx OUT enabled DC level) – (Tx Out disabled DC level) when transmitting a repeating 11110000 bit
pattern.
6.2 Packages
PIN 1
A
B
ALTERNATIVE
PIN
LOCATION
MARKING
E
L
T
P
J
Y
C
H
0.303 (7.70)
PackageTolerances
TYP. MAX.MIN.
A
B
C
E
H
DIM.
J
P
Y
T
L
0.047 (1.20)---------- 0.256 (6.50)
0.030 (0.75)
0.311 (7.90)
0.177 (4.50)
0.0256 (0.65)
0.020 (0.50)
0.248 (6.30) 0.006 (0.15)0.002 (0.05)
0.003 (0.08) 0.008 (0.20)
0.007 (0.17) 0.012 (0.30)
0.169 (4.30)
NOTE : All dimension s in inches (mm.)
Angles are in degrees
Figure 15: 24-pin TSSOP Mechanical Outline:
Order as part no. CMX589AE2
High Speed GMSK Modem 21 CMX589A PRELIMINARY INFORMATION
1998 MX-COM, Inc. www.mxcom.com Tele: 800 638 5577 336 744 5050 Fax: 336 744 5054 Doc. # 20480183.002
4800 Bethania Station Road, Winston-Salem, NC 27105-1201 USA All trademarks and service marks are held by their respective companies.
NOTE : All dimension s in inches (mm.)
Angles are in degrees
PackageTolerances
A
B
C
E
H
TYP. MAX.MIN.
DIM.
J
P
X
T
Y
Z
L
0.079 (2.00)0.066 (1.67) 0.312 (7.90)
10°
0.037 (0.95)
0.328 (8.33)
0.213 (5.39)
0.026 (0.65)
0.022 (0.55)
0.301 (7.65) 0.008 (0.21)0.002 (0.05)
0.005 (0.13) 0.009 (0.22)
0.010 (0.25) 0.015 (0.38)
0.318 (8.07)
0.205 (5.20)
X
C
HP
J
Y
E
Z
L
T
PIN 1
A
B
Figure 16: 24-pin SSOP Mechanical Outline:
Order as part no. CMX589AD5
0.597 (15.16)
PackageTolerances
A
B
C
E
H
TYP. MAX.MIN.DIM.
J
P
X
W
T
Y
K
L
0.105 (2.67)
0.093 (2.36) 0.419 (10.64)
45°
10°
0.050 (1.27)
0.046 (1.17)
0.613 (15.57)
0.299 (7.59)
0.050 (1.27)
0.016 (0.41)
0.390 (9.90) 0.020 (0.51)0.003 (0.08)
0.009 (0.23) 0.0125 (0.32)
0.013 (0.33) 0.020 (0.51)
0.036 (0.91)
0.286 (7.26)
Z
NOTE : All dimensions in inches (mm.)
Angles are in degrees
PIN 1
A
B
ALTERNATIVE
PIN
LOCATION
MARKING
X
P
J
Y
C
H
K
E
L
T
W
Z
Figure 17: 24-pin SOIC Mechanical Outline:
Order as part no. CMX589AD2
NOTE : All dimension s in inches (mm.)
Angles are in degrees
PackageTolerances
A
B
C
E
E1
H
TYP. MAX.MIN.DIM.
J
J1
P
Y
T
K
L
0.220 (5.59)
0.555 (14.04)
0.670 (17.02)
0.160 (4.05)
1.270 (32.26)
0.151 (3.84)
0.100 (2.54)
0.121 (3.07)
0.600 (15.24)
0.590 (14.99) 0.625 (15.88)
0.015 (0.38) 0.045 (1.14)
0.008 (0.20) 0.015 (0.38)
0.015 (0.38) 0.023 (0.58)
0.040 (1.02) 0.065 (1.65)
0.066 (1.67) 0.074 (1.88)
1.200 (30.48)
0.500 (12.70)
H
K
L
J1J1
JJPP
CC
BB
AA
PIN1PIN1 TT
EE
E1E1
Y
Figure 18: 24-pin PDIP Mechanical Outline:
Order as part no. CMX589AP4