ZL20250 Data Sheet

ZL20250
2.5G Multimode Transceiver
Data Sheet
Features
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September 2003
Quad Band GSM (800/900/1800/1900 MHz)
Compatible
Dual Band IS136 (800/1900 MHz) Compatible
GPRS Class 12 and EDGE Capable
Fully Integrated Dual Band Transceiver
Receive - IF to Baseband I and Q
Transmit - Baseband I / Q to RF
Integrated Filters
FM Demodulator
RF and IF Synthesizers
Fully Programmable via serial bus
3 Volt operation
Small scale package
Ordering Information
ZL20250/LCE (Tubes) 56 pin QFN
ZL20250/LCF (Tape and Reel) 56 pin QFN
-40°C to +85°C
Description
The ZL20250 is a fully integrated transceiver for
multimode IS136/GSM/GPRS/EDGE handsets. The
dual IF inputs to the receive path are amplified and
down-converted to baseband I and Q signals. Gain
control and baseband filtering are provided. A FM
demodulator is also provided where AMPS
compatibility is required.
Applications
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The transmit path consists of a quadrature modulator,
gain control at IF and up-conversion to RF. Dual band
RF outputs are provided.
GAIT IS136/GSM/EDGE Mobile Telephones
Dual Band (850/PCS1900) TDMA/AMPS Mobile
Telephones
Cellular 850MHz TDMA/AMPS Mobile
Telephones
PCS1900 TDMA Mobile Telephones
2.5G World Phones - Quad Band
(850/900/1800/1900)
Cellular Telematic Systems
ZL20250 also includes a fractional N RF synthesizer
and two IF synthesizers to provide all local oscillator
signals required.
Flexible programming is provided via a 3 wire serial
bus. Additional control pins allow accurate timing
control when switching between modes.
GSM/EDGE
Rx I
90°
Rx Q
IS136
FM
Demod
Rx VHF
PLL
RSSI
LOCK DET
Tx VHF
PLL
UHF LO O/P
UHF VCO
FM
Serial
Interface
Control
UHF
PLL
900 MHz Tx
IQ
Mod
Tx I
Tx Q
1900 MHz Tx
Tx IF Filter
(Opt)
Figure 1 - Block Diagram
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Zarlink Semiconductor Inc.
Zarlink, ZL and the Zarlink Semiconductor logo are trademarks of Zarlink Semiconductor Inc.
Copyright 2003, Zarlink Semiconductor Inc. All Rights Reserved.
ZL20250
Data Sheet
RX I+
FM OUT
RX I-
FM FB
RX VCO-
RX VCO+
VCC RX PLL
VCC RX
RX GAIN
IF0 IN-
IF0 IN+
IF1 IN-
IF1 IN+
VCC CONTROL
Package Diagram
SDAT
RX Q-
SCLK
RX Q+
RSSI
SLATCH
RX CP
TCXO
VCC VHF CP
VCC UHF PLL
UHF CP
ISET
LOCK DET
ZL20250
MGCX01
VCC UHF LO OUT
900 LO OUT
TX CP
TX RXB
1900 LO OUT
RESETB
TX I-
ENABLE1
TX I+
900 LO IN
VCC TX PLL
TX Q-
TX Q+
TX FILT OUT-
TX FILT OUT+
VCC TX
TX FILT IN-
TX FILT IN+
TX GAIN
TX 1900
ENABLE2
TX DEG1900
TX VCO+
TX 900
1900 LO IN
TX DEG900
TX VCO-
VCC TX RF
VCC UHF LO
Figure 2 - ZL20250 Package Diagram
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Zarlink Semiconductor Inc.
ZL20250
Data Sheet
Pin Description Table
No
Pin Name
Type
Description
1
SDAT
Input
Serial Interface - Data
2
SCLK
Input
Serial interface - Clock
3
SLATCH
Input
Serial Interface - Latch
4
TCXO
Input
Reference input from TCXO
5
VCC UHF PLL
Power
Power
6
UHF CP
Output
UHF PLL Charge Pump Output
7
VCC UHF LO OUT Power
Power to LO output stages
8
900 LO OUT
Output
900 MHz buffered LO output to external receiver mixer
9
1900 LO OUT
Output
1900 MHz buffered LO output to external receiver mixer
10
RESETB
Input
Reset (Active low)
11
ENABLE1
Input
Mode Control
12
900 LO IN
Input
900 MHz LO input
13
VCC UHF LO
Power
Power to UHF LO input stage
14
1900 LO IN
Input
1900 MHz LO input
15
VCC TX RF
Power
Power to transmit RF output stages
16
TX 900
Output
900 MHz transmit output
17
TX DEG900
Degeneration for 900 MHz output
18
TX DEG1900
Degeneration for 1900 MHz output
19
TX 1900
Output
1900 MHz transmit output
20
ENABLE2
Input
Mode Control
21
TX GAIN
Input
Transmit gain control
22
TX FILT IN+
Input
Input from transmit IF filter (optional)
23
TX FILT IN-
Input
24
VCC TX
Power
Power to transmit stages
25
TX FILT OUT+
Output
Output to transmit IF filter (optional)
26
TX FILT OUT-
Output
27
TX Q+
Input
28
TX Q-
Input
29
TX VCO+
30
TX VCO-
31
VCC TX PLL
Power
Power to Transmit VHF PLL
32
TX I+
Input
I transmit signal from baseband
33
TX I-
Input
34
TX RXB
Input
Transmit / Receive control
35
TX CP
Output
Transmit VHF PLL charge pump output
36
LOCK DET
Output
PLL Lock Detect Output
37
ISET
38
VCC VHF CP
Q transmit signal from baseband
Transmit Oscillator tank circuit
Connect 50 kohm resistor to ground to set internal reference current
Power
Power to VHF charge pump outputs
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Zarlink Semiconductor Inc.
ZL20250
Data Sheet
Pin Description Table (continued)
No
Pin Name
Type
Description
39
RX CP
Output
Receive VHF PLL charge pump output
40
RSSI
Output
RSSI Output
41
RX Q+
Output
Baseband Q signal
42
RX Q-
Output
43
RX I+
Output
44
RX I-
Output
45
FM OUT
Output
46
FM FB
Feedback to FM output stage
47
RX VCO-
Receive second LO Oscillator tank circuit
48
RX VCO+
49
VCC RX PLL
Power
Power to receive VHF PLL. Connect to VCC through 10 ohm resistor
50
VCC RX
Power
Power to receive stages
51
RX GAIN
Input
Receive gain control
52
IF0 IN-
Input
IF Input (0)
53
IF0 IN+
Input
GSM
54
IF1 IN-
Input
IF Input (1)
55
IF1 IN+
Input
IS136 Input
56
VCC CONTROL
Power
Power to serial interface logic
Baseband I signal
Demodulated FM output
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Zarlink Semiconductor Inc.
ZL20250
Data Sheet
Table of Contents
1.0 General Description ......................................................................................................................................... 8
1.1 Receive Path ............................................................................................................................................... 9
1.1.1 IS136.................................................................................................................................................. 9
1.1.2 AMPS FM......................................................................................................................................... 11
1.1.3 GSM ................................................................................................................................................. 14
1.2 Transmit..................................................................................................................................................... 16
1.3 UHF LO and Frequency Doubler............................................................................................................... 19
1.4 UHF Frequency Synthesizer ..................................................................................................................... 19
1.5 VHF Frequency Synthesizer...................................................................................................................... 22
1.6 Internal Clock Generation.......................................................................................................................... 23
1.7 VHF VCO................................................................................................................................................... 23
1.8 Power Supply Connections ....................................................................................................................... 24
2.0 Programming and Control ............................................................................................................................ 25
2.1 Power Control Registers - Address 0 to 3 ................................................................................................. 25
2.1.1 Power Control Modes - TDMA (GSM and IS136) ............................................................................ 27
2.1.2 Power Control Modes - AMPS ......................................................................................................... 28
2.2 Operating Register Address 4 ................................................................................................................... 29
2.3 Synthesizer Register - Address 5 .............................................................................................................. 33
2.3.1 UHF PLL and LO.............................................................................................................................. 33
2.3.2 UHF PLL Charge Pump Current ...................................................................................................... 34
2.3.3 Receive LO Set Up .......................................................................................................................... 34
2.3.4 Transmit LO Set Up ......................................................................................................................... 35
2.4 Control Register - Address 6 ..................................................................................................................... 35
2.4.1 IS136 Baseband Gain ...................................................................................................................... 35
2.4.2 TCXO Reference Selection............................................................................................................. 36
2.4.3 Discriminator Output Filtering........................................................................................................... 36
2.4.4 Transmit baseband Gain.................................................................................................................. 37
2.4.5 Mode Control.................................................................................................................................... 37
2.5 GSM/EDGE Baseband Control Register - Address 7................................................................................ 37
2.5.1 Q Channel Gain Adjust .................................................................................................................... 38
2.5.2 Baseband Offset Correction............................................................................................................. 38
2.6 Test Mode Register - Address 8................................................................................................................ 38
2.7 UHF PLL Divider Programming Register - Address 9 ............................................................................... 39
2.8 UHF PLL Reference Divider and Fractional N Programming Register - Address 10 ................................ 39
2.9 Receive VHF PLL Divider Programming Register - Address 11 ............................................................... 39
2.10 Receive VHF PLL Reference Divider Programming Register - Address 12............................................ 40
2.11 Transmit VHF PLL Divider Programming Register - Address 13 ............................................................ 40
2.12 Transmit VHF PLL Reference Divider Programming Register Address 14 ............................................. 40
2.13 PLL Lock Detect & Fractional N Compensation Programming Register Address 15 .............................. 40
2.13.1 Fractional N Compensation............................................................................................................ 41
2.13.2 PLL Lock detect counters............................................................................................................... 41
3.0 Absolute Maximum Ratings .......................................................................................................................... 41
4.0 Operating Conditions .................................................................................................................................... 41
5.0 Electrical Characteristics .............................................................................................................................. 43
6.0 Typical Performance Curves ........................................................................................................................ 51
6.1 Receive...................................................................................................................................................... 51
6.2 Transmit..................................................................................................................................................... 52
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Zarlink Semiconductor Inc.
ZL20250
Data Sheet
List of Figures
Figure 1 - Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
Figure 2 - ZL20250 Package Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
Figure 3 - ZL20250 Detailed Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Figure 4 - IS136 Receiver Signal Flow . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
Figure 5 - AMPS Receive Signal Flow . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
Figure 6 - GSM Receive Signal Flow . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
Figure 7 - Transmit Path . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
Figure 8 - External Transmit IF Filter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
Figure 9 - UHF Synthesizer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
Figure 10 - Count Sequence for UHF PLL with 4 modulus prescaler . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
Figure 11 - UHF Synthesizer - Fractional N Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
Figure 12 - VHF Frequency Synthesizer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
Figure 13 - Typical VCO Tank Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
Figure 14 - Serial Bus Timing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
Figure 15 - Transmit Output Stage Current versus Gain Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
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Zarlink Semiconductor Inc.
ZL20250
Data Sheet
List of Tables
Table 1 - IS136 Receive Gain and Filter Distribution . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
Table 2 - AMPS FM Receive Gain and Filter Distribution . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
Table 3 - GSM Receive Gain and Filter Distribution. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
Table 4 - Transmit Circuit blocks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
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Zarlink Semiconductor Inc.
ZL20250
1.0
Data Sheet
General Description
A detailed block diagram is shown in Figure 3. This shows the receive and transmit paths plus the LO generation
circuitry. Control is via a serial bus with the addition of direct inputs to control receive and transmit modes and
optimize power consumption.
MUX
IF0 IN+ 53
IF0 IN– 52
AMPS demod.
and RSSI
RX GAIN 51
π /2
IF1 IN+ 55
IF1 IN– 54
43 RX I+
44 RX I–
45 FM OUT
46 FM FB
40 RSSI
60kHz
dc
Offset
MUX
41 RX Q+
42 RX Q–
÷N
π /2
VCC UHF LO OUT
13
7
RX VCO–
I SET 37
Control
VCC TX PLL 31
RESETB
ENABLE1
ENABLE2
TX RXB
1900 LO IN
5
30
TX CP
14
Tank
Circuit
TX VCO+
6
Option
56 VCC CONTROL
Loop
Filter
TX VCO–
LO Select
and
Doubler
VCC UHF PLL
8
10
11
20
34
VCC VHF CP 38
Loop
Filter
UHF CP
900
LO OUT
36 LOCK DET
TCXO 4
900 LO IN
9
Control
VCC RX PLL 49
12
1900
LO OUT
39
Loop
Filter
DC offset
VCC RX
48
Tank
Circuit
RX CP
47
RX VCO+
50
Synth Programming
VCC UHF LO
PLL
29
35
Serial
interface
1 SDAT
2 SCLK
3 SLATCH
PLL
PLL
π /2
π /2
TX 1900 19
32 TX I+
33 TX I–
π /2
Σ
MUX
27 TX Q+
28 TX Q–
22
TX DEG900
VCC TX RF
TX FILT IN–
TX FILT IN+
Option
25
26
21
24
VCC TX
23
TX GAIN
15
TX FILT OUT–
17
TX FILT OUT+
18
TX DEG1900
TX 900 16
Figure 3 - ZL20250 Detailed Block Diagram
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Zarlink Semiconductor Inc.
ZL20250
1.1
Data Sheet
Receive Path
There are two IF inputs which will receive an input signal from IS136/AMPS and GSM IF filters. The differential input
stages are identical and are followed by an agc amplifier. Gain control is provided from an external analogue voltage.
After the agc amplifier the signal is then down-converted either to a low IF frequency or baseband and the signal flow
then depends on the mode selected. All internal signals are differential. The LO frequency for the down conversion
is derived from an on chip oscillator and PLL. The LO frequency can be programmed to be either oscillator frequency
divided by 2 or 4. When in divide by 2 mode a DLL (Delay Locked Loop) circuit can be selected to maintain accurate
quadrature. It is particularly important to have good quadrature in IS136/AMPS modes using a low IF frequency, to
achieve the required image rejection in conjunction with the following polyphase bandpass filter. It is also possible
to programme high side or low LO injection. Each receive mode will now be described in more detail
1.1.1
IS136
The IS136 receive signal path is shown in detail in Figure 4 and performance for each stage is summarized in the
following table.
Circuit
Block
IF Input (IF0)
AGC Amplifier
Quadrature
Down-converter
Gain
(dB)
Filter
Bandwidth
(If Applicable)
26
max
Description
Differential IF input stage
AGC Amplifier - Gain control range 90dB
Down-conversion to 60kHz IF
47
Anti-alias filter
230 kHz
Band Pass Filter
Low pass Butterworth (n= 3)
+/- 20 kHz
Switched capacitor polyphase Chebyshev. Also
provides typically 30 dB image rejection. Centre
frequency = 60 kHz. Clock frequencies 1.44 MHz and
720 kHz.
Gain Stage
Baseband Down-converter
Baseband filter 1
Baseband filter 2
Down conversion to baseband I and Q signals
7
37.5 kHz
Switched capacitor low pass Chebyshev. Clock
frequency = 240 kHz
60 kHz
Smoothing filter. Low pass Butterworth
Table 1 - IS136 Receive Gain and Filter Distribution
The output of the agc amplifier is down-converted using a quadrature mixer to a low IF of 60kHz. High side or low
side LO injection can be selected. The In Phase (I) and Quadrature (Q) signals at 60 kHz are then passed through
anti alias filter stage to remove any high frequency signals prior to subsequent sampling. The 60 kHz IF signals are
then fed into a switched capacitor polyphase bandpass filter which not only provides filtering but also provides image
rejection. This switched capacitor filter provides very stable performance and no calibration is required. After the
bandpass filter the 60 kHz IF signal is further amplified and then mixed down to baseband I and Q signals. Additional
filtering is required at baseband to remove spurii from the down-converter. This filtering is provide in two stages, the
first stage is a switched capacitor filter with the second stage being a smoothing filter to remove clock breakthrough
from the preceding switched capacitor filter. The differential baseband outputs can then be fed directly into analogue
to digital converters on a baseband processor.
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Zarlink Semiconductor Inc.
Receive
VHF VCO
Tank
Circuit
Div2 /Div4
Quadrature
Figure 4 - IS136 Receiver Signal Flow
Loop
Filter
Recieve
VHF PLL
Rx VHF
PLL
Anti
Alias
Filter
IF1
Quadrature
Downconverter
Anti
Alias
Filter
AGC
Amplifier
IF0
IF Input
Band
Pass
Filter
Gain
Receive Baseband
RSSI
Limiter
RSSI
Offset Q
Baseband
Filter 1
60 kHz
Baseband
Filter 1
Offset I
FM
Discriminator
Baseband
Filter 2
Baseband
Filter 2
Mx
Mx
RSSI
Q
I
ZL20250
Data Sheet
ZL20250
1.1.2
Data Sheet
AMPS FM
FM demodulation can be performed using the I and Q baseband signals if supported by the baseband. However the
ZL20250 also contains an FM demodulator, the AMPS receive signal path using this mode is shown in detail in
Figure 5 and performance for each stage is summarized in the following table.
Circuit
Block
Gain
(dB)
Filter
Bandwidth
(If Applicable)
IF Input (IF0)
AGC Amplifier
Differential IF input stage
26
max
AGC Amplifier - Gain control range 90dB. Includes IF input stage
gain.
Quadrature
Down-converter
Down-conversion to 60kHz IF
Anti-alias filter
Band Pass Filter
Description
230 kHz
73
+/- 16 kHz
Low pass Butterworth
Switched capacitor polyphase Chebyshev. Also provides typically
30dB image rejection. Centre frequency = 60 kHz. Clock frequency
1.44 MHz and 720 kHz.
Limiter
Provides limited output to discriminator. Also provides RSSI output.
FM Discriminator
Digital FM discriminator
Baseband filter 2 (I
Channel)
30 kHz
Smoothing filter. Low pass Butterworth. Provides filtering of FM
discriminator output.
Baseband filter 1
(I Channel)
25 kHz
Switched capacitor low pass Chebyshev. Clock frequency = 240
kHz. Provides additional filtering of discriminator output. Selected
using PDF and LPC bits
Baseband filter 1
(Q Channel)
25 kHz
Switched capacitor low pass Chebyshev. Clock frequency = 240
kHz. Provides additional filtering of discriminator output. Selected
using PDF and LPC bits
Baseband filter 2 (Q
Channel)
60kHz
Smoothing filter. Low pass Butterworth. Provides filtering of FM
discriminator output.
FM Output
30kHz
Configured using external components as bandpass filter.
Table 2 - AMPS FM Receive Gain and Filter Distribution
The signal path is initially the same as for IS136 with the down conversion to 60 kHz and channel filtering in the
bandpass filter. In FM mode however, the baseband I and Q output stages are disabled, and the 60 kHz IF signal
from the bandpass filter is input to a limiting amplifier and FM discriminator. The FM discriminator consists of a shift
register acting as a delay line. The output of the discriminator is a digital signal which must then be filtered to recover
the audio signal. The discriminator output is therefore routed through the baseband I and Q filters. The default
condition is to use the cascaded I and Q smoothing filters (baseband filter 2) with the cut-off frequency set to 30kHz.
This connection is automatically selected when programming FM mode. There is an option to use the cascaded
switched capacitor filters (baseband filter 1) with the cut off frequency set to 25 kHz to provide extra filtering. These
filters are selected using the PDF and LPC bits in control register 6 and are inserted between the smoothing filters
as shown in Figure 5. The final output stage uses external feedback components to provide a bandpass filter with a
bandwidth of at least 300 Hz to 10 KHz to cover the demodulated audio and control signals. The feedback
components can be modified to change the output level to optimise compatibility with baseband.
A RSSI output is provided. This is a full wave rectified output of the 60 kHz IF and therefore has a high 120 kHz
content. This requires an external low pass filter - typically 10kohm and 2.7nF. There is a trade-off between settling
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Zarlink Semiconductor Inc.
ZL20250
Data Sheet
time and filtering. This is different to conventional RSSI circuits which operate at typically 450 kHz which is much
easier to filter.
Although the AMPS receive path includes a limiting amplifier, gain control is also required. This is because the band
pass filter has limited dynamic range (50dB). At low signal levels the agc should be set to 1.6 volts to set the gain
20dB below maximum to obtain optimum signal handling and noise performance. At higher signal levels the gain
setting should be reduced to maintain the RSSI level approximately 10dB below maximum. Gain control would be
provided by the baseband controller which would also monitor the RSSI level. Fine gain control is not required and
can be implemented in large steps eg 20dB, allowing the use of a relatively slow gain control loop giving optimum
performance under fading conditions.
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Zarlink Semiconductor Inc.
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Zarlink Semiconductor Inc.
Receive
VHF VCO
Tank
Circuit
Div2 /Div4
Quadrature
Figure 5 - AMPS Receive Signal Flow
Loop
Filter
Recieve
VHF PLL
Rx VHF
PLL
Anti
Alias
Filter
IF1
Quadrature
Downconverter
AntiAlias
Filter
AGC
Amplifier
IF0
IF Input
Band
Pass
Filter
Gain
Receive Baseband
RSSI
Limiter
RSSI
Offset Q
Baseband
Filter 1
60 kHz
Baseband
Filter 1
Offset I
FM
Discriminator
Baseband
Filter 2
Baseband
Filter 2
Mx
Mx
FM FB
FM OUT
RSSI
Q
I
ZL20250
Data Sheet
ZL20250
1.1.3
Data Sheet
GSM
The GSM receive signal path is shown in detail in Figure 6 and performance for each stage is summarized in the
following table.
Circuit
Block
Gain
(dB)
Filter
Bandwidth
(If Applicable)
IF Input (IF0)
AGC Amplifier
Differential IF input stage
26
max
AGC Amplifier - Gain control range 90dB. Includes IF input
stage gain.
Quadrature
Down-converter
Anti-alias filter
Baseband Gain
Description
Down-conversion to baseband
54
230 kHz
Low pass Butterworth. Provides channel filtering in
GSM/EDGE mode
Baseband gain with offset correction.
Nominal gain is 35 dB and can be reduced in 3 dB steps to
14 dB
Table 3 - GSM Receive Gain and Filter Distribution
In GSM mode the bandpass filter and IS136 baseband stages are disabled. After passing through the agc amplifier
the signal is mixed down to baseband I and Q signals rather than to a low IF. The baseband signal must be dc
coupled and this can introduce a dc offset in the output, which may vary with different gain settings. The ZL20250
therefore includes the facility to correct the dc offset for each channel using an 8 bit offset correction word that must
be supplied by the baseband via the serial bus.
GSM Baseband gain can be programmed via serial bus. Reducing the baseband gain can be used to improve output
signal to noise ratio. The IF gain should be increased to mainatin the total overall gain. In practice a gain reduction
of 6 or 9 dB would give optimum performance
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Zarlink Semiconductor Inc.
Receive
VHF VCO
Tank
Circuit
Div2 /Div4
Quadrature
Figure 6 - GSM Receive Signal Flow
Loop
Filter
Recieve
VHF PLL
Rx VHF
PLL
Anti
Alias
Filter
IF1
Quadrature
Downconverter
Anti
Alias
Filter
AGC
Amplifier
IF0
IF Input
Band
Pass
Filter
Gain
Receive Baseband
RSSI
Limiter
RSSI
Offset Q
Baseband
Filter 1
60 kHz
Baseband
Filter 1
Offset I
FM
Discriminator
Baseband
Filter 2
Baseband
Filter 2
Mx
Mx
RSSI
Q
I
ZL20250
Data Sheet
ZL20250
1.2
Data Sheet
Transmit
Transmit operation is similar for all modes and a detailed diagram is shown in Figure 7. This diagram also shows the
UHF LO generation circuit blocks. A summary of the characteristics of the transmit path circuit blocks are given in
the table below. All circuit blocks are differential with the exception of the transmit RF outputs.
Circuit
Block
Gain
(dB)
Bandwidth
(If Applicable)
Reconstruction Filters
0 -12
IS136/AMPS
12.5 kHz
GSM
100 kHz
Quadrature Modulator
Transmit IF
Description
Baseband input stage. Gain is programmable in 3 dB steps from 0 to 12
dB.
Filter bandwidth is selected for IS136/AMPS or GSM.
There is also a by-pass mode so that the baseband I and Q signal can go
direct to the modulator
Generates a modulated IF signal
400 MHz
Provides gain control at IF frequency. This stage also includes a low
pass filter to remove harmonics and spurii from modulator output.
This stage also includes a buffered IF output which can be used with an
external IF filter.
Up-converter
SSB up-converter to RF frequency. The IF path includes phase shift
networks for the up-converter. This stage also includes the input circuit
from the optional external IF filter
Transmit RF
The 900 MHz and 1900 MHz RF stages each consist of 2 stages. The
first stage gain be set from -6 to +3 dB in 3 dB steps. Output stage
current is controlled by agc signal to reduce current consumption at low
output power levels. Each output stage requires an external
degeneration inductor
Table 4 - Transmit Circuit blocks
Differential baseband transmit I and Q signals from a baseband processor are input to the ZL20250. The baseband
signals are passed through filters - the filter bandwidth is selected for the appropriate mode i.e. IS136 or GSM. A
quadrature modulator modulates these baseband signals on to the transmit IF which is typically around 200 MHz.
This modulated IF signal is passed through an on chip low pass filter which removes harmonics of the IF and then
into a gain controlled amplifier. This amplifier is controlled by an external analogue signal and provides greater than
60dB gain control The output of the gain controlled amplifier can then be up-converted to RF or alternatively the
output can be sent to an off chip filter to provide further filtering and removal of noise before up-conversion. This filter
is a parallel tuned circuit as shown in Figure 8. The choice of component values is dependent on the IF frequency
being used. The filter output is then fed back on chip to the up-converter. A SSB mixer is used for the up-conversion
to remove the unwanted image. High side or low side LO injection can be selected
A buffer amplifier after the up-conversion provides a further 9 dB gain control in 3 dB increments. This gain is
programmable via the serial bus and can be used to optimize noise and linearity performance in particular
applications. Finally there are two RF output stages for 900 MHz and 1900 MHz frequency bands. Each RF output
is single ended and requires a simple matching network. The supply current of the output stages is automatically
reduced at low transmit gain control voltages improving the efficiency of the output buffer at low output power levels.
The supply current of the output buffer can also be controlled via the serial bus. This allows the supply current to be
reduced which is particularly useful when using AMPS or GSM where the linearity performance is less critical.
The FM modulation for AMPS can be done using I,Q modulation if available. Alternatively FM modulation can be
applied direct to the transmit IF VCO. The loop bandwidth for the transmit VHF PLL should be low ( ~100 Hz) to
ensure the PLL does not remove the modulation. A dc voltage should be applied across the Tx I+, Tx I- and the Tx
Q+, Tx Q- inputs to switch the modulator and generate an IF carrier signal. With a baseband gain of 0dB a dc voltage
of at least 1.5 volts should be applied; a lower voltage can be used with the baseband gain increased to compensate.
It is assumed that this bias can be provided by the baseband however if this is not possible then the simplest solution
is to connect 200kohm resistors between I+, Q+ inputs and Vcc and 200kohm resistors between I+,Q- inputs and
16
Zarlink Semiconductor Inc.
ZL20250
Data Sheet
ground assuming the transmit outputs from the baseband are in a high impedance state in AMPS mode. These
resistors do produce a small dc offset in TDMA mode however this is insignificant if the output impedance of
baseband transmit outputs is less than 1 kohm.As the FM modulation is applied direct to the VCO in this mode and
is external to the ZL20250, any necessary filtering of the FM signal must be provided externally.
17
Zarlink Semiconductor Inc.
Figure 7 - Transmit Path
18
Zarlink Semiconductor Inc.
900
LO OUT
1900
LO OUT
TX
DEG900
TX
900
TX
DEG1900
TX
1900
UHF LO
Buffer
Transmit RF
Frequency
Doubler
900 LO IN
900MHz
VCO
Mux
Quadrature
UHF LO Input Buffer
Σ
Mux
1900 LO IN
Mux
Transmit
UHF LO
1900MHz
VCO
Mux
-π /4
+π/4
Transmitter Upconverter
IF Input
TX FILT IN +/-
Loop
Filter
UHF CP
UHF PLL
UHF
Synthesiser
Transmit IF
TX FILT OUT +/-
Mux
Optional External
Transmit IF Filter
Low
Pass
Filter
Tank
Circuit
Loop
Filter
TX CP
Transmit
VHF PLL
Tx VHF
PLL
Baseband
Transmit
Filter
Optional By-pass
Mode
Baseband
Transmit
Filter
Transmit Reconstruction
Filters
TX VCO+/-
Div2 / Div4
Quadrature
Transmit
VHF VCO
Σ
Transmit
Quadrature
Modulator
TX
Q+/-
TX
I+/-
ZL20250
Data Sheet
ZL20250
Data Sheet
Figure 8 - External Transmit IF Filter
1.3
UHF LO and Frequency Doubler
Figure 8 also shows the UHF LO buffering and frequency doubler. The ZL20250 is designed to operate either with
separate external UHF VCOs for the 900 and 1900 MHz frequency bands, or alternatively a single 900 MHz VCO
can be used with the on-chip frequency doubler providing the LO for the 1900 MHz band. A UHF synthesizer is
included. The input to the UHF synthesizer will normally be the active UHF LO signal, however when using the
frequency doubler mode for 1900 MHz LO generation, the synthesizer input can be selected to be either the
frequency doubler output or the 900 MHz input LO signal. The UHF LO input buffer minimizes any load pulling effects
on the UHF VCO when internal modes are switched.
UHF LO output buffers are also provided. These can be used to drive an external mixer for the receive section. If not
required these buffers can be powered down.
1.4
UHF Frequency Synthesizer
A fractional N UHF synthesizer is included on the ZL20250 to provide LO signals for the transmit up-converter and
the external receive RF down-converters. The UHF synthesizer operates with an external VCO. A block diagram of
the synthesizer is shown in Figure 9.
.
Lock Detect
TCXO
Reference Counter
14 bit
Phase
Detector
UHF LO
Quad Modulus
Prescaler
64/65/72/73
+1
M Counter
13 bit
+8
B
3 bit
Fractional N
Counter
A
4 bit
+1
Frac N
Compensation
8 bits
Fractional N
Scaling DAC
5 bits
Fractional N
Compensation DAC
Figure 9 - UHF Synthesizer
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Zarlink Semiconductor Inc.
Charge
Pump
UHF
CP
ZL20250
Data Sheet
The synthesizer uses a 4 modulus prescaler with an 'M' counter and 'A' and 'B' swallow counters together with a
fractional N counter in the UHF counter allowing maximum flexibility. The reference counter is a simple 14 bit
counter. All counter values are programmed via the serial bus and programming details are shown in the
programming section. Each of the counters operates as count down. At the start of a count the counters are loaded
with their respective values. The initial prescaler ratio is dependent on the values loaded into the A and B counters;
when both the A and B counters reach zero the prescaler ratio is 64 and then remains until the M counter reaches
zero. The complete process is then repeated.
This can be shown in a simple example where M = 9, A = 4 and B = 2 which gives a total divide ratio of 596. The
count sequence is shown in Figure 10.
M Counter
9
8
7
6
5
4
3
2
1
9
8
A Counter
4
3
2
1
0
0
0
0
0
4
3
2
1
0
0
0
0
0
0
0
2
1
73
73
65
65
64
64
64
64
64
73
73
+1 Prescaler
B Counter
+8 Prescaler
Prescaler
Figure 10 - Count Sequence for UHF PLL with 4 modulus prescaler
At the start of the count sequence the '+1' and '+8' controls to the prescaler are both asserted and the prescaler ratio
is 73. After 2 cycles only the '+1' control is asserted and the divide ratio is 65. After a further 2 cycles the A counter
reaches zero as well and the prescaler ratio is 64 for the remainder of the count sequence. At the end of the
sequence all counters are reloaded and the sequence repeats.
The total divide ratio (N) for this type of counter is given by
N = 64*M + 8*B + A
M is always greater then A or B
A value of A = 0 does not support fractional N operation. Valid values of A are 1 to 8.
The values of M, B and A can be easily calculated from the total divide ratio as shown below.
M = INT ((N - 1)/64)
B = INT (((N - 1) - 64*M)/8)
A = N - 64*M - 8*B
The value of M must always be greater than A or B. The maximum value of B is 7.
20
Zarlink Semiconductor Inc.
ZL20250
Data Sheet
The UHF synthesizer also includes a fractional N capability which allows the use of higher comparison frequencies
but maintain narrow channel spacing. The use of higher comparison frequencies allows faster loop settling and
reduces comparison spur level. This is particularly important in TDMA mode where settling times of < 1.5 ms are
required and still obtain good spur performance.
Fractional N allows the use of non-integer divide ratios. For example if the total divide ratio is N + 1/5 the counter will
divide by N for 4 count cycles and N+1 on the fifth cycle giving the required total divide ratio over five cycles. The
ZL20250 can use 5,8,13 or 20 as the fractional denominator (also referred to as the fractional modulus) allowing
maximum flexibility in the choice of comparison frequencies.
An extra counter - fractional N counter - is required. The input to this counter is from the M counter output. The
fractional N modulus can be programmed to be 5,8,13, or 20. Each output pulse from the M counter will increment
the fractional N divided by the required fractional numerator. For example if the fraction is 2/5 then the fractional N
counter will increment by 2 for each output pulse from the M counter. When the fractional N counter overflows the A
counter is incremented by 1, thus generating an additional '+1' count sequence.
An example is shown in Figure 11 for a divide ratio of 596+2/5. The values for M, A, B are calculated using the integer
value (596) as in the previous example. The fractional denominator is programmed as 5 and the fractional numerator
as 2. At the end of the first count cycle (596) the fractional counter is incremented to 2. At the end of the third count
cycle the fractional N counter overflows, incrementing the A counter by 1 which gives a subsequent count cycle of
597. After five count cycles the sequence repeats with a total count of 2982 over the five count cycle giving a mean
value of 596 + 2/5.
Total Count Cycle
Count Value
Fractional N
Counter
Initial A
Counter
Value
0
596
596
597
596
597
596
2
4
1
3
0
2
4
4
5
4
5
4
Figure 11 - UHF Synthesizer - Fractional N Operation
A result of this count sequence is that the output phase of the total counter changes through the count cycle, which
causes the output pulse from the phase detector, and therefore the charge pump, to vary. This would cause large
fractional spurs on the synthesizer output. These spurs can be compensated by applying a current pulse with the
opposite polarity to the charge pump output. This compensation pulse has a fixed width of two reference clock
(TCXO) periods; the amplitude is proportional to the value in the fractional N counter. The correction current is scaled
by a 8 bit compensation DAC, with an externally provided input from the serial bus. This allows performance to be
optimized in a given application.
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Zarlink Semiconductor Inc.
ZL20250
Data Sheet
The compensation value can be calculated from the following formula:
Comp Value = 255 - INT((Icp * Ftcxo)/(0.0245 * 6 * MOD *Fvco))
where
Icp
= charge pump current (uA)
Ftcxo
= Reference frequency
MOD
= Fractional Modulus
Fvco
= UHF VCO Frequency
The synthesizer provides a lock detect output. When the output pulse from the phase detector is less than half a
reference clock period an in-lock signal is generated. These in-lock signals then clock a 4 bit counter into which a
threshold value has been programmed. When the required number of successive in-lock pulses have been
generated the lock detect output is set.
The ZL20250 has a single lock detect output pin for the UHF synthesizer and VHF synthesizers. The lock detect
signal is asserted when all active synthesizers are in lock. If a synthesizer has not been enabled in the power control
registers then that synthesizer will be inactive and will have no effect on the lock detect output.
1.5
VHF Frequency Synthesizer
The ZL20250 includes two VHF synthesizers to generate the second LO for the receiver and the transmit IF. They
operate with their respective on-chip VHF VCO's and off-chip loop filters. The tank circuits and tuning components
for the VCO's are also off chip. The two synthesizers are identical and are shown in Figure 12.
Lock Detect
TCXO
Reference Counter
14 bit
Phase
Detector
VHF LO
Dual Modulus
Prescaler
16/17
Charge
Pump
VHF
CP
M Counter
13 bit
+1
A
4 bit
Figure 12 - VHF Frequency Synthesizer
The synthesizer uses a 2 modulus 16/17 prescaler with an 'M' counter and an 'A' swallow counter. This allows
maximum flexibility when using this synthesizer. The reference counter is a simple 14 bit counter. All counter values
are programmed via the serial bus and programming details are shown in the programming section. Both counters
operate as count down. At the start of a count the counters are loaded with their respective values. The initial
22
Zarlink Semiconductor Inc.
ZL20250
Data Sheet
prescaler ratio is 17 assuming A > 0; when the A counter reaches zero the prescaler ratio is 16 until the M counter
reaches zero. The complete process is then repeated.
The total divide ratio (N) for this type of counter is given by
N = 16*M + A
M is always greater then A
The values of M and A can be easily calculated from the total divide ratio N.
M = INT (N/16)
A = N - 16*M
The maximum value for A is 15 and M must always be greater than A.
The VHF PLLs do not have fractional N capability however it is recommended that thay are operated at as high a
comparison frequency as allowed by the chosen frequency plan to minimise spurs levels.
Both VHF synthesizers have lock detection circuits. These operate in the same way as described for the UHF
synthesizer.
1.6
Internal Clock Generation
ZL20250 can use 14.4 MHz or 19.44MHz reference frequency (standard for IS136), or 13 MHz or 26 MHz (standard
for GSM). The appropriate reference must be programmed via the serial bus. The clock signals for the switched
capacitor filters and FM demodulator are generated from the reference TCXO signal. The internal divide ratios are
switched to give the optimum ratio. For dual mode applications (GSM/IS136) a 13 MHz or 26 MHz reference should
be used. This will give a small error in the switched capactor clock frequency used for IS136 but has negligible effect
on performance.
1.7
VHF VCO
ZL20200 has two VHF VCOs which operate with the VHF PLLs to provide the IF LO signals for both receive and
transmit IF signals. The oscillators are a differential design and require an external tank circuit. A basic circuit with
varactor is shown in Figure 13. It is recommended to include series resistors (eg 43 ohms) in each arm of the tank
circuit to prevent any spurious high frequency oscillation due to parasitic capacitances.
From PLL
Loop
Filter
10k
VCO+
43R
18p
nm
10k
18p
43R
VCO-
33n
Figure 13 - Typical VCO Tank Circuit
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Zarlink Semiconductor Inc.
ZL20250
1.8
Data Sheet
Power Supply Connections
The circuit blocks within ZL20250 have separate supply connections to minimize interaction between circuit blocks.
Details are shown in the earlier ‘Pin Names’ section. These supplies are also grouped to allow different groups of
supply pins to be connected to separate supplies for example, receive or transmit. These groups are shown below:
VCC – Control Supply
Pin No.
Pin Name
56
VCC CONTROL
VCC – TxRx Common (Synth)
Pin No.
Pin Name
5
VCC UHF PLL
7
VCC UHF LO OUT
13
VCC UHF LO
38
VCC VHF CP
8
900 LO OUT
9
1900 LO OUT
VCC – Rx
Pin No.
Pin Name
49
VCC RX PLL
50
VCC RX
VCC – Tx
Pin No.
Pin Name
15
VCC TX RF
24
VCC TX
31
VCC TX PLL
16
TX 900
19
TX 1900
The LO OUT and TX 900/1900 pins require bias and are normally connected to VCC through an inductor.
All supply pins within a group must be powered together. Each group of pins can be powered up independent of the
other groups.
24
Zarlink Semiconductor Inc.
ZL20250
2.0
Data Sheet
Programming and Control
Programming via the serial bus is via 24 bit words with a 4 bit address as shown below
23
22
21
20
19
18
17
17
15
14
13
12
11
10
9
8
7
6
5
Data
4
3
2
1
0
Address
Bit23 (MSB) is loaded first. Bits 3:0 are used as address bits for the control registers. Details of serial bus timing are
shown in Figure 14.
SCLK
t1
t2
t3
t6
SDAT
Bit 23
Bit 22
Bit 21
Bit 0
t4
SLATCH
ENABLE1/2
t5
t7
Figure 14 - Serial Bus Timing
2.1
Power Control Registers - Address 0 to 3
These registers are used in conjunction with the TX RXB and ENABLE1 and ENABLE2 control pins to power up the
required sections of the device for any required mode. This enables power consumption to be optimized under all
conditions. Figures 4 - 7, which show the receive and transmit paths in detail, show which sections are powered up
by each control bit.
The assignment is common for each of the registers 0 to 3 and is shown below.
Bit
Circuit Section
23
Not used
22
Receive Baseband section
21
UHF LO Buffer
20
Receive VHF VCO
25
Zarlink Semiconductor Inc.
ZL20250
Bit
Note 1:
Note 2:
Data Sheet
Circuit Section
19
UHF synthesizer
18
Receive RSSI circuit
17
Not used
16
Receive Quadrature down-converter
15
Receive VHF PLL
14
Receive IF input
13
Receive AGC amplifier
12
Transmit reconstruction filters
11
Transmit RF
10
Transmit UHF LO
9
UHF LO input buffer
8
Transmit IF
7
Transmit quadrature modulator
6
Transmit VHF PLL
5
Transmit VHF VCO
4
Transmit up-converter IF input
If a bit is set to logic 1 then that circuit section is powered on.
UHF LO input (bit 9) must be enabled for Transmit UHF LO (bit 10), UHF synthesizer (bit 19) and UHF LO Buffer (bit 21) to be
active.
The 4 registers address 0 to 3 are assigned as follows:
Register
Address
Register
Name
0
Receive
All circuit blocks required in receive mode should be set to 1. This register will be
selected when TX RXB is low. No circuits will be actually powered up if ENABLE1
and ENABLE 2 are both low.
1
Transmit
Transmit register All circuit blocks required in transmit mode should be set to 1. In
duplex modes e.g. AMPS then both receive and transmit circuits must be selected.
This register will be selected when TX RXB is high. No circuits will be actually
powered up if ENABLE1 and ENABLE 2 are both low
2
ENABLE1
Configuration
This register determines which circuit sections are powered up when ENABLE1 is
high. The contents of this register are logical ANDed with the contents of the
Receive or Transmit register as selected by TX RXB input.
3
ENABLE2
Configuration
This register determines which circuit sections are powered up when ENABLE2 is
high. The contents of this register are logical ANDed with the contents of the
Receive or Transmit register as selected by TX RXB input.
Description
26
Zarlink Semiconductor Inc.
ZL20250
Data Sheet
A feature of this programming approach is that once a phone operating mode has been selected and set up via the
serial bus, all power control can then be via the TX RXB, ENABLE1 and ENABLE2 control pins. Alternatively full
power control is possible via the 3 wire serial bus without the use of any external control pins.
If ENABLE1 and ENABLE2 are both low then the device is in Sleep mode. No circuits will be enabled unless either
ENABLE1 or ENABLE2 are high regardless of the contents of the receive and transmit registers.
An example of how these control bits can be used, is that the oscillators and PLL circuits can be powered up and
allowed to settle prior to powering up the complete transmit or receive path. In the case of the receive path the UHF
synthesizer, UHF LO input buffer, UHF LO Buffer and Receive VHF VCO, Receive VHF PLL bits would be set in the
ENABLE1 Configuration register. The ENABLE2 Configuration register would contain these bits plus the remainder
of the receive path bits, Receive IF input, Receive AGC amplifier, Receive quadrature down-converter and receive
baseband section.
This is demonstrated in the following examples.
2.1.1
Power Control Modes - TDMA (GSM and IS136)
In a TDMA system the transceiver will either operate in receive only, or transmit only mode. It is assumed that an
interim power on state will be used during which the oscillators and PLLs will be set up, and allowed to settle prior
to activating the full signal path. The suggested programming for the power control registers (0 - 3) is shown in the
table below.
Circuit
Section
Bit
Receive
Addr 0
Transmit
Addr 1
Enable 1
Config.
Addr 2
Enable 2
Config.
Addr 3
23
Not used
0
0
0
0
22
Receive Baseband section
1
0
0
1
21
UHF LO Buffer
0
0
0
0
20
Receive VHF VCO
1
0
1
1
19
UHF synthesizer
1
1
1
1
18
Receive RSSI circuit
0
0
0
0
17
Not used
0
0
0
0
16
Receive Quadrature down-converter
1
0
0
1
15
Receive VHF PLL
1
0
1
1
14
Receive IF input
1
0
0
1
13
Receive AGC amplifier
1
0
0
1
12
Transmit reconstruction filters
0
1
0
1
11
Transmit RF
0
1
0
1
10
Transmit UHF LO
0
1
0
1
9
UHF LO input buffer
1
1
1
1
8
Transmit IF
0
1
0
1
7
Transmit quadrature modulator
0
1
0
1
6
Transmit VHF PLL
0
1
1
1
27
Zarlink Semiconductor Inc.
Comments
Note 1
Note 2
ZL20250
Circuit
Section
Bit
Data Sheet
Receive
Addr 0
Transmit
Addr 1
Enable 1
Config.
Addr 2
Enable 2
Config.
Addr 3
5
Transmit VHF VCO
0
1
1
1
4
Transmit up-converter IF input
0
1
0
1
Note 1:
Note 2:
Comments
Not required if driving external receive mixer direct from UHF VCO.
Can be used for IS136 if required.
The receive register contains all bits required when in receive mode: the transmit register contains all bits required
in transmit mode. The Enable1 configuration register contains all bits required to power up oscillators and
synthesizers in both receive and transmit mode. The Enable2 configuration register contains all bits required to
power up the complete receive and transmit modes (this register can be set to all '1's if preferred).
The following words should therefore be programmed on the serial bus (Hex format):
Receive register (0)
Transmit register (1)
Enable1 Config. register (2)
Enable2 Config. register (3)
2.1.2
59E200
081FF1
188262
59FFF3
Power Control Modes - AMPS
When operating in AMPS mode the ZL20250 will operate in either Receive only or Duplex. The enable registers
should therefore be programmed as shown below.
Bit
Circuit Section
Receive
Addr 0
Transmit
Addr 1
Enable 1
Config.
Addr 2
Enable 2
Config.
Addr 3
23
Not used
0
0
0
0
22
Receive Baseband section
1
1
0
1
21
UHF LO Buffer
0
0
0
0
20
Receive VHF VCO
1
1
1
1
19
UHF synthesizer
1
1
1
1
18
Receive RSSI circuit
1
1
0
1
17
Not used
0
0
0
0
16
Receive Quadrature down-converter
1
1
0
1
15
Receive VHF PLL
1
1
1
1
14
Receive IF input
1
1
0
1
13
Receive AGC amplifier
1
1
0
1
12
Transmit reconstruction filters
0
1
0
1
11
Transmit RF
0
1
0
1
10
Transmit UHF LO
0
1
0
1
9
UHF LO input buffer
1
1
1
1
8
Transmit IF
0
1
0
1
28
Zarlink Semiconductor Inc.
Comments
Note 1
ZL20250
Bit
Circuit Section
Data Sheet
Receive
Addr 0
Transmit
Addr 1
Enable 1
Config.
Addr 2
Enable 2
Config.
Addr 3
7
Transmit quadrature modulator
0
1
0
1
6
Transmit VHF PLL
0
1
1
1
5
Transmit VHF VCO
0
1
1
1
4
Transmit up-converter IF input
0
1
0
1
Note 1:
Comments
Not required if driving external receive mixer direct from UHF VCO.
The receive register contains all bits required when in receive mode: the transmit register contains all bits required
in duplex mode. The Enable1 configuration register contains all bits required to power up oscillators and synthesizers
in both receive and duplex mode. The Enable2 configuration register contains all bits required to power up the
complete receive and duplex modes (this register can be set to all '1's if preferred).
The following words should therefore be programmed on the serial bus (Hex format):
Receive register (0)
Transmit register (1)
Enable1 Config. register (2)
Enable2 Config. register (3)
2.2
5DE200
5DFFF1
188262
5DFFF3
Operating Register Address 4
This registers selects internal setups for example IS136 or GSM. The bits are assigned for control of receive and
transmit bits as shown below:
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
RX<7:0>
TX <11:0>
Receive Set Up
Transmit Set Up
8
7
6
5
4
3
2
1
0
0
1
0
0
Address
The function of the receive bits is shown below:
Register
Bit No.
Control
Bit
23
RX<7>
Receive DLL disabled
Receive DLL enabled
22
RX<6>
Bandpass Filter BW = +/- 20 kHz
Bandpass Filter BW = +/- 16 kHz
21
RX<5>
GSM Filters active
Receive GSM filters bypassed
20
RX<4>
LO output = 900 MHz
LO Output = 1900 MHz
19
RX<3>
Receive output dc bias (I/Q) = 1.25 V
Receive output dc bias (I/Q) = Vcc/2
18
RX<2>
IS136 Mode IF1 Input enabled
GSM Mode IF0 Input enabled
17
RX<1>
AMPS
IS136
16
RX<0>
Not used
Not used
Action if '0'
Action if '1'
Bit 23 RX<7> is only applicable when VCO divide by 2 mode is selected in register 5.
29
Zarlink Semiconductor Inc.
ZL20250
Data Sheet
The function of the transmit bits is shown below:
Register Bit
No.
Control
Bit
15
TX<11>
14
TX<10>
13
TX<9>
12
TX<8>
11
TX<7>
10
TX<6>
9
TX<5>
8
TX<4>
7
TX<3>
900 MHz output
1900MHz output
6
TX<2>
Internal
External transmit IF Filter
5
TX<1>
IS136 baseband filters
GSM/EDGE baseband filters
4
TX<0>
Transmit baseband filters selected
Transmit baseband filters by-passed
Action if '0'
Action if '1'
Transmit output stage gain control
Control of RF Transmit output stage current with VGA control voltage.
Nominal value for TX<11:4> is 101010
Control bits TX<11:4> allow optimization of the transmit output stage. This allows variation of the decrease in supply
current with decreasing agc voltage and also allows optimization depending on output power and linearity
requirements. Figure 15 shows the variation of output stage supply current with agc voltage and the programmable
characteristics. The maximum current, agc threshold and slope can be programmed. The minimum current is not
programmable.
TX<11:10> (bits 15,14) allow the gain of the transmit output stage to be varied in 3 dB steps as shown in the table
below:
TX<11>
TX<10>
Gain (dB)
0
0
-6
0
1
-3
1
0
Nominal
1
1
+3
30
Zarlink Semiconductor Inc.
ZL20250
Data Sheet
Imax
Icc
Slope
Imin
Vagc
Vth
Figure 15 - Transmit Output Stage Current versus Gain Control
TX<9:8> (bits 13:12) control the agc voltage (Vth) at which the output stage current starts reducing. Typical values
are shown in the table below:
TX<9>
TX<8>
Vth (V)
0
0
1.09
0
1
1.25
1
0
1.48
1
1
2.81
TX<7:6> (bits 11,10) control the rate of current reduction as shown in Figure 15. Typical vales are shown in the
below:
TX<7>
TX<6>
Slope (mA/V)
0
0
8.5
0
1
10.5
1
0
12.0
1
1
14.0
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Zarlink Semiconductor Inc.
ZL20250
Data Sheet
TX<5:4> (bits 9:8) adjust the maximum current (Imax) of the transmit output stage. The gain of the output stage is
not changed. Typical values are shown in the table below:
TX<5>
TX<4>
Current
0
0
25%
0
1
50%
1
0
Nominal
1
1
150%
Using these controls allows the performance of the output stage to be optimized under various conditions; for
example, current cant can be reduced if non-linear operation is required.
The nominal value recommended for TX<11:4> is 10101010.
An example of setting up the control register (address 4) for various systems is shown below:
Bit
Name
GSM
(850)
GSM
(1900)
IS136
(900)
IS136
(1900)
AMPS
23
RX<7>
0
0
0
0
0
22
RX<6>
0
0
0
0
1
21
RX<5>
0
0
0
0
0
20
RX<4>
0
1
0
1
0
19
RX<3>
0
0
0
0
0
18
RX<2>
1
1
0
0
0
17
RX<1>
0
0
1
1
0
16
RX<0>
0
0
1
1
1
15
TX<11>
1
1
1
1
1
14
TX<10>
0
0
0
0
0
13
TX<9>
1
1
1
1
1
12
TX<8>
0
0
0
0
0
11
TX<7>
1
1
1
1
1
10
TX<6>
0
0
0
0
0
9
TX<5>
1
1
1
1
1
8
TX<4>
0
0
0
0
0
7
TX<3>
0
1
0
1
0
6
TX<2>
0
1
0
1
0
32
Zarlink Semiconductor Inc.
Comments
Note 1
Note 2
ZL20250
Data Sheet
Bit
Name
GSM
(850)
GSM
(1900)
IS136
(900)
IS136
(1900)
AMPS
5
TX<1>
1
1
0
0
0
4
TX<0>
0
0
0
0
0
Note 1:
Comments
The setting for RX<3> is dependent on the optimum common mode input voltage of the analog to digital converter in the
baseband.
Selects external transmit IF filter if used.
Note 2:
The following hex words are therefore recommended for the control register (address 4):
GSM (850)
GSM (1900)
IS136 (900)
IS136 (1900)
AMPS
2.3
04AA24
4AAE4
03AA04
13AAC4
41AA04
Synthesizer Register - Address 5
This register sets up LO options for receive and transmit and also UHF synthesizer set up.
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
0
UI
RX LO2 Set Up
UC
DL
UD
TX LO Set Up
UHF PLL Set Up
3
2
1
0
0
1
0
1
Address
Bits 23,17,14 are also used for UHF PLL and LO set up.
Bits 16,15 are not used and should be set to zero.
2.3.1
UHF PLL and LO
Register
Bit No.
23
Action if '0'
UHF PLL input = 900 MHz
Action if '1'
UHF PLL input = 1900 MHz
17
Fractional N Compensation selected
14
UHF Doubler Selected
8
Fractional N Denominator - see table below
7
6
Not Used - Set to 0
5
UHF PLL Charge Pump Current - see table below
4
Note 1:
Note 2:
Note 3:
Note 4:
Bit 14 is only effective if 1900 MHz mode has been selected (register 4 Bit 7).
Bit 23 is only effective if 1900 MHz mode has been selected (register 4 Bit 7) and the UHF frequency doubler selected
(Register 5 Bit 14). This control allows the use of the doubled frequency to be used as the input to the UHF PLL.
Fractional N Denominator
Bits 8,7 select the fractional N denominator for the UHF PLL as shown below:
33
Zarlink Semiconductor Inc.
ZL20250
2.3.2
Data Sheet
<8>
<7>
Frac N Denom.
0
0
5
0
1
8
1
0
13
1
1
20
UHF PLL Charge Pump Current
Bits 5,4 select the charge pump current for the UHF PLL as shown below:
2.3.3
<5>
<4>
Current (mA)
0
0
1.00
0
1
0.50
1
0
0.25
1
1
0.125
Receive LO Set Up
Register Bit No.
Action if '0'
Action if '1'
22
High side Rx second LO injection
Low side Rx second LO injection
21
Rx second LO = VCO/2
Rx second LO = VCO/4
20
Rx LO phase detector polarity normal
Rx LO phase detector polarity inverted
19
Receive VHF PLL Charge Pump Current - see table below
18
Bits 19,18 select the charge pump current for the receive VHF PLL as shown below:
<19>
<18>
Current (mA)
0
0
1.00
0
1
0.50
1
0
0.25
1
1
0.125
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Zarlink Semiconductor Inc.
ZL20250
2.3.4
Data Sheet
Transmit LO Set Up
Register
Bit No.
Action if '0'
Action if '1'
15
Transmit DLL disabled
Transmit DLL enabled
13
Low side Tx up-converter LO injection
High side Tx up-converter LO injection
12
Tx second LO = VCO/2
Tx second LO = VCO/4
11
Tx LO phase detector polarity normal
Tx LO phase detector polarity inverted
10
Transmit VHF PLL Charge Pump Current - see table below
9
Bits 10,9 select the charge pump current for the receive VHF PLL as shown below:
2.4
23
<9>
Current (mA)
0
0
1.00
0
1
0.50
1
0
0.25
1
1
0.125
Control Register - Address 6
22
21
20
19
0
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
0
BBG
2.4.1
<10>
TCXO
PDF
LPC
Tx Gain
R
Mode Control
3
2
1
0
0
1
1
0
Address
IS136 Baseband Gain
Bits 22:21 can be used to vary the gain of the baseband output stages in IS136 mode only. The gain of the 60 kHz
IF stage preceding the baseband mixer is also varied so that the overall gain of the device can be maintained if
required. The nominal gain is 20 dB and the recommended setting is BBG<1:0> = 11 to minimize output dc offsets.
BBG<1>
Bit 22
BBG<0>
Bit 21
IF Gain
(dB)
Baseband Gain
(dB)
Overall Gain
(dB)
0
0
14
6
20
0
1
17
6
23
1
0
17
0
17
1
1
20
0
20
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Zarlink Semiconductor Inc.
ZL20250
2.4.2
Data Sheet
TCXO Reference Selection
Bits 20:19 are used to set the device to the required TCXO reference frequency.
2.4.3
TCXO<1>
Bit 20
TCXO<0>
Bit 19
TCXO Frequency
(MHz)
0
0
13.0
0
1
14.4
1
0
19.44
1
1
26.0
Discriminator Output Filtering
Bits 17:14 set up on chip filtering of the FM output signal and are therefore only used in AMPS mode. Two cascaded
filters can be selected and the bandwidth can be set to 25 or 37.5 kHz cut-off. Bits 17,16 (PDF) select the filters and
bits 15,14 set the cutoff frequency.
<17>
<16>
<15>
<14>
Filter Selection
0
0
X
X
No filters
0
1
X
X
Filter 1 selected
1
0
X
X
Filter 2 selected
1
1
X
X
Filters 1 and 2 selected
X
X
0
0
Both filters 37.5 kHz
X
X
0
1
Filter 1 25kHz, Filter 2 37.5kHz
X
X
1
0
Filter 1 37.5 kHz, Filter 2 25 kHz
X
X
1
1
Both filters 25kHz
In GSM and IS136 modes Bits <17:14> should be set to 0000. It is recommended that if the additional discriminator
filtering is required in AMPS mode then both filters should be used with 25 kHz bandwidth, i.e. Bits<17:14> should
be set 1111.
36
Zarlink Semiconductor Inc.
ZL20250
2.4.4
Data Sheet
Transmit baseband Gain
Bits 13:11 set the transmit baseband gain as shown below:
2.4.5
<13>
<12>
<11>
Gain
(dB)
0
0
0
0
0
0
1
3
0
1
0
6
0
1
1
9
1
0
0
12
Mode Control
Bit 10 resets the contents of all registers to '0'. After the reset is complete bit 10 is also reset to '0'.
Bits 9:4 allow TXRXB, ENABLE1 and ENABLE2 to be programmed by either the external pins or via the serial bus.
This allows mode control to be either via the external pins or the serial bus. The default state is using the external
pins as this allows more accurate timing of power control.
Register Bit No.
9
Action if '0'
Action if '1'
Receive Register (0) selected
Transmit Register (1) selected
8
Enable2 Configuration Register (3) selected
7
Enable1 Configuration Register (2) selected
6
TXRXB Pin (34) selected
Serial Bus selected - Bit 9
5
Enable2 Pin (20) selected
Serial Bus selected - Bit 8
4
Enable1 Pin (11) selected
Serial Bus selected - Bit 7
Bits 9:7 can only be used if the appropriate bits 6:4 have been set to disable the external pins. If serial mode has
been selected then the operation of bits 9:7 is the same as the external TX RXB, ENABLE1 and ENABLE2 pins
respectively.
2.5
23
OE
GSM/EDGE Baseband Control Register - Address 7
22
21
BB Gain
20
19
18
17
16
15
14
13
12
11
Q Offset
10
9
8
7
I Offset
6
5
4
3
2
1
0
0
1
1
1
Address
This register is only used when in GSM/EDGE mode. The BB Gain bits enable the GSM baseband gain section to
be reduced in 3 dB increments. The nominal gain is 35 dB (000). The I and Q offset bits allow the GAM baseband
dc offset to be cancelled.
37
Zarlink Semiconductor Inc.
ZL20250
2.5.1
Data Sheet
Q Channel Gain Adjust
Bits 22:20 adjust Q channel gain.
2.5.2
<22>
<21>
<20>
Gain Adjustment(dB)
0
0
0
0
0
0
1
-3
0
1
0
-6
0
1
1
-9
1
0
0
-12
1
0
1
-15
1
1
0
-18
1
1
1
-21
Baseband Offset Correction
Bits 19:12 adjust the dc offset for the Q channel. Bit 19 is the sign bit and bit 12 the LSB. Bits 11:4 adjust the dc offset
for the I channel with bit 11 the sign bit and bit 4 the LSB. The coding is the same for both I and Q channels and is
shown below:
00000000
Maximum positive correction
00000001
01111110
01111111
Zero positive correction
11111111
Zero negative correction
11111110
10000001
10000000
Maximum negative correction
Bit 23 must be set to '1' to enable dc offset correction.
2.6
Test Mode Register - Address 8
This register is used for test purposes only and should not be used.
38
Zarlink Semiconductor Inc.
ZL20250
2.7
23
Data Sheet
UHF PLL Divider Programming Register - Address 9
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
0
M Counter
Value
B Counter
Value
x
3
2
1
0
1
0
0
1
A Counter
Value
Address
Bits 23:11 set M counter value (Bit 23 = MSB)
Bits 10:8 set B counter value - max value = 7 (Bit 10 = MSB)
Bits 7:4 set A counter value - max value = 7 (Bit 6 = MSB)
The A counter is a 4 bit counter to enable correct fractional N operation. Valid values of A are in the range 1 to 8.
Using the 64/65/72/73 four modulus prescaler the divide ratio (N) is given by:
N = 64 * M + 8 * B + A
Values of M, B, A can be easily calculated using the formulae in the synthesizer section.
2.8
23
UHF PLL Reference Divider and Fractional N Programming Register - Address 10
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
0
X
Frac N Numerator
3
2
1
0
1
0
1
0
UHF PLL Reference Counter Value
Address
Bit 23 is unused and should be set to '0'
Bits 22:18 set the fractional N numerator (Bit 22 = MSB)
Bits 17:4 set the Reference counter value (Bit 17 = MSB)
2.9
Receive VHF PLL Divider Programming Register - Address 11
23
22
21
0
0
0
X
X
X
20
19
18
17
16
15
14
13
12
11
10
M Counter Value
9
8
7
6
5
4
A Counter Value
3
2
1
0
1
0
1
1
Address
Bits 23:21 are unused and should be set to '0'
Bits 20:8 set M counter value (Bit 20 = MSB)
Bits 7:4 set A counter value - max value = 15 (Bit 7 = MSB)
Using the 16/17 two modulus prescaler the divide value (N) is given by:
N = 16 * M + A
Values of M, A can be easily calculated using the formulae in the synthesizer section, however the programming
register has been organized to simplify this.
39
Zarlink Semiconductor Inc.
ZL20250
Data Sheet
For example for a divide ratio of 13235, the binary equivalent is: 11001110110011. The programming values can be
selected as shown below:
Bit No.
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
Count Value
0
0
0
1
1
0
0
1
1
1
0
1
1
0
0
1
1
M
2.10
A
Receive VHF PLL Reference Divider Programming Register - Address 12
23
22
21
20
19
0
0
0
0
0
X
X
X
X
X
18
17
16
15
RS
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
1
1
0
0
Receive VHF PLL Reference Counter Value
Address
Bits 23:19 are unused and should be set to '0'
Bit 18 selects common reference divider for VHF receive and transmit PLLs ('0' to select). If a common reference
divider is selected then the transmit VHF reference divider is used which must be programmed in register 13.
Bits 17:4 set the Reference divider value (Bit 17 = MSB)
2.11
Transmit VHF PLL Divider Programming Register - Address 13
23
22
21
0
0
0
X
X
X
20
19
18
17
16
15
14
13
12
11
10
9
8
7
M Counter Value
6
5
4
3
2
1
0
1
1
0
1
A Counter Value
Address
Bits 23:21 are unused and should be set to '0'
Bits 20:8 set M counter value (Bit 20 = MSB)
Bits 7:4 set A counter value - max value = 15 (Bit 7 = MSB)
Programming is identical to that for the receive VHF PLL register 11.
2.12
Transmit VHF PLL Reference Divider Programming Register Address 14
23
22
21
20
19
18
0
0
0
0
0
0
X
X
X
X
X
X
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
1
1
1
0
Transmit VHF PLL Reference Counter Value
Address
Bits 23:18 are unused and should be set to '0'
Bits 17:4 set the Reference counter value (Bit 17 = MSB)
2.13
23
PLL Lock Detect & Fractional N Compensation Programming Register Address 15
22
21
20
19
18
17
Fractional N Compensation
16
15
14
13
12
11
10
9
8
Transmit VHF PLL
Lock Count
UHF PLL
Lock Count
40
Zarlink Semiconductor Inc.
7
6
5
4
Receive VHF PLL
Lock Count
3
2
1
0
1
1
1
1
Address
ZL20250
2.13.1
Data Sheet
Fractional N Compensation
Bits 23:16 set the value for fractional N compensation in the UHF PLL with bit 23 as MSB. The value for the
compensation is dependent on a number of parameters which are described in the synthesizer section.
2.13.2
PLL Lock detect counters
These 4 bit counters count the consecutive comparison cycles where the lock detect circuit gives an in-lock result.
When the counter reaches its programmed count then that PLL is deemed to have achieved full lock. This prevents
spurious false in-lock signals while the PLL is achieving lock up. There are separate counters for the UHF, Rx VHF
and Tx VHF PLLs which are programmed as shown above. Bits 15,11,7 are the MSB's for the UHF, Rx VHF and Tx
VHF PLL lock detector counters respectively. A non zero value must be programmed for the lock detect to operate
correctly.
3.0
Absolute Maximum Ratings
Supply Voltage
-0.3 to 3.6V
Voltage applied to any pin
-0.3 to Vcc + 0.3 V
Operating Temperature
-40°C to 85°C
Storage Temperature
-55°C to 125°C
Max Junction Temperature
125°C
This device is sensitive to ESD. Most pins have an ESD rating greater than 2000V (Human Body Model HBM),
however some pins have limited protection (800 to 2000V )in order to meet the RF performance. Anti-static
precautions should be used when handling this device.
4.0
Operating Conditions
Device operation is guaranteed under the following coonditions:
Condition
Min
Value
Typ
Max
Units
Comments
General
Supply Voltage
2.7
3.3
V
Operating Temperature
-40
+85
°C
Logic Input Voltage High – VIH
0.8Vcc
Volts
Logic Input Voltage Low – VIL
0.2Vcc
Volts
TCXO Reference Frequency
Frequency
13.0
MHz
GSM
Frequency
14.4
MHz
IS136
Frequency
19.44
MHz
IS136
41
Zarlink Semiconductor Inc.
ZL20250
Condition
Min
Value
Typ
Data Sheet
Max
Units
70
215
MHz
50
215
MHz
Comments
Receiver
Receiver IF Frequency
Transmitter
Transmit IF Frequency
I & Q common mode voltage
1.2
V
I & Q input voltage level
1.5
V p-p
Cellular band LO input level
-15
-10
-5
dBm
PCS band LO input level
-15
-10
-5
dBm
Cellular band LO frequency
900
1100
PCS1900 band frequency
1900
2200
0dB input buffer gain
MHz
Serial Control Timing
See Figure 14
SDATA Set Up t1
20
ns
SDATA Hold t2
20
ns
SCLK Pulse Width t3
50
ns
SLATCH Set up t4
20
ns
SLATCH Pulse Width t5
50
ns
SCLK Period t6
100
ns
Power Control Set up t7
20
ns
Serial Control Timing (cont’d)
42
Zarlink Semiconductor Inc.
ZL20250
5.0
Data Sheet
Electrical Characteristics
The electrical characteristics are guaranteed under the following conditions unless stated otherwise. Vcc =3.0 V, T
= 25°C, TCXO Ref Frequency = 19.44 MHz.
Value
Typ
Max
Units
10
40
µA
Logic inputs = 0V or Vcc
AMPS
32
38
mA
Note 1, AGC = 1.6V
IS136
33
39
mA
Note 1, AGC = 1.6V
GSM/EDGE
30
36
mA
Note 1, AGC = 1.6V
141
170
mA
VGA = 2.4V, Note 2
106
125
mA
VGA = 1V , Note 2
120
145
mA
VGA = 2.4V, Note 2
102
120
mA
VGA = 1V, Note 2
UHF PLL
12.5
15.0
mA
Note 3
Receive VHF PLL
5.2
6.3
mA
Transmit VHF PLL
4.9
6.0
mA
4
5
mA
Note 4
4.5
5.5
mA
900 or 1900 Band Note 5
Input Current
10
nA
Vin = 0 to Vcc
Input Capacitance
10
pF
Characteristics
Min
Comments
Supply Current
Sleep
Receive Operation
Transmit Operation
900 MHz Output
1900 MHz Output
Standby Operation
Additional Circuits
Frequency Doubler
UHF LO Output Buffer
Logic Inputs
Lock Detect Output
43
Zarlink Semiconductor Inc.
ZL20250
Characteristics
Min
Value
Typ
Max
Units
0.2Vcc
Volts
I out = 1mA
0.8Vcc
Volts
I out = -1 mA
10
kΩ
Output Voltage Low
Output Voltage High
Data Sheet
Comments
TCXO Input
Input Resistance
Input Capacitance
Input Sensitivity
0.5
10
pF
2
V p-p
Receiver - IS136
All parameters are measured at
an IF frequency of 135.06 MHz,
Rx VCO = 270 MHz unless
stated otherwise
Input impedance
500
Max Voltage Gain
80
Min Voltage Gain
Gain slope
50
NF Gainmax
Input V1dB Gainmin
101
IIP3 Gainmax
1500
91
Ω
dB
AGC = 2.4 V
AGC = 0.3 V
-13
5
dB
56
62
dB/V
dB
104
dBµV
Minimum gain
74
dBµV
Max Gain
+/- 0.5
dB
+/- 2
°
I/Q Quadrature Accuracy
3
Rs =800Ω
V p-p
Output dc Offset
+/-20
mV
Receiver AMPS (Fixed Gain)
Input impedance
AGC = 0.3 to 2V
8
I/Q Amplitude Matching
Output 1dB Compression
ac coupled
All parameters are measured at
an IF frequency of 135.06 MHz,
Rx VCO = 270 MHz unless
stated otherwise.
Vagc = 1.6V (Gain 20 dB below
maximum)
500
1500
Ω
Input Sensitivity
14
dBµV
Noise Figure
12
dB
Input IP3
93
dBµV
44
Zarlink Semiconductor Inc.
Note 6
ZL20250
Characteristics
Audio Output
Min
Value
Typ
Max
Units
900
1000
1100
mV
RSSI Dynamic Range
Accuracy
Data Sheet
50
+3
dB
RSSI Slope
16
mV/dB
Input Signal - Min
25
dBµV
Input Signal - Max
75
dBµV
Min RSSI Level
0.35
0.5
0.70
Max RSSI Level
1.45
1.55
1.65
1
V
kΩ
Bandpass Filter
IS136 and AMPS
Narrow bandwidth mode
Centre Frequency
3dB Bandwidth
Note 7
dB
-3
RSSI Output Impedance
Comments
60
kHz
+/- 16
+/- 18
kHz
Stop Band Attenuation
Relative to signal at 60kHz
0 to 3 kHz
67
69
dB
3 kHz to 10 kHz
61
63
dB
10 kHz to 22 kHz
48
51
dB
38 kHz
18
20
dB
82 kHz
18
20
dB
98 kHz to 110 kHz
48
50
dB
110 kHz to 117 kHz
61
63
dB
117 kHz to 123 kHz
68
70
dB
123 kHz to 1.36 MHz
71
73
dB
1.36 MHz to 1.52 MHz
36
48
dB
1.52 MHz to 10 MHz
71
73
dB
Image Attenuation
0 to -10kHz
61
dB
-10 kHz to -42 kHz
40
dB
45
Zarlink Semiconductor Inc.
ZL20250
Data Sheet
Min
Value
Typ
- 42 kHz to -78 kHz
30
40
- 78 kHz to -105 kHz
40
dB
-105 kHz to -1.36 MHz
61
dB
-1.36 MHz to -1.52 MHz
36
-1.52 MHz to -10 MHz
61
Characteristics
Gain Ripple
Max
Units
dB
48
dB
dB
1.0
1.5
dB
Receiver - GSM
70
215
MHz
Input impedance
500
1500
Ω
Max Voltage Gain
80
Min Voltage Gain
50
NF Gainmax
Input V1dB Gainmin
60kHz +/- 12.5kHz
All parameters are measured at
an IF frequency of 135.0 MHz,
Rx VCO = 270 MHz unless
stated otherwise. TCXO =
13.0MHz.
IF Frequency
Gain slope
Comments
100
IIP3 Gainmax
91
dB
AGC = 2.4 V
AGC = 0.3 V
-13
+5
dB
56
62
dB/V
AGC = 0.3 to 2V
8
dB
Rs =800Ω
104
dBµV
Minimum gain
73
dBµV
Max Gain
Baseband filter attenuation
100kHz
1
dB
315kHz
15
dB
600kHz
30
dB
10MHz
60
dB
Filter Ripple
Output dc Offset
1
dB
0 to 100kHz
20
mV
After offset calibration. Maximum
Base band gain
+/- 0.5
dB
+/- 2
°
10
I/Q Amplitude Matching
I/Q Quadrature Accuracy
Output 1dB Compression
3
V p-p
46
Zarlink Semiconductor Inc.
ZL20250
Characteristics
Baseband Gain Adjust
Min
Value
Typ
-21
Baseband Gain Step Resolution
Data Sheet
Max
Units
0
dB
3
Comments
3dB steps
dB
Transmitter
All parameters are measured at
an IF frequency of 180.0 MHz,
Tx VCO = 360 MHz unless
stated otherwise
I & Q modulator
I/Q Input Buffer Gain
-1
0
+1
dB
I/Q Input Buffer Gain
3
dB
I/Q Input Buffer Gain
6
dB
I/Q Input Buffer Gain
9
dB
I/Q Input Buffer Gain
12
dB
I & Q differential input resistance
80
kΩ
I & Q Baseband Filter
Attenuation (IS136/AMPS)
dc - 12.5 kHz
0.5
dB
85 - 180 kHz
12
17
dB
> 180 kHz
25
33
dB
I & Q Baseband Filter
Attenuation (GSM/EDGE)
dc to 100kHz
> 4MHz
1
55dB
dB
dB
Carrier Suppression
30
40
dB
Sideband Suppression
30
40
dB
45
60
dB
IF Variable gain amplifiers
Gain control range
Control voltage for minimum
gain
0.10
V
Control voltage for maximum
gain
AGC control voltage slope
33
38
2.4
V
43
dB/V
47
Zarlink Semiconductor Inc.
VGA = 0.5 to 1.2V
ZL20250
Characteristics
Min
Value
Typ
Max
Data Sheet
Units
Comments
IF Output Filter (option)
IF output impedance
500
Ω
To external filter
IF input impedance
1.5
kΩ
From external filter
IF output level
100
mV
800MHz RF output stage
Specifications assume 50 ohm
load driven via a matching
network.
Output Frequency = 836 MHz,
UHF LO = -10 dBm at 1016
MHz.
RF amplifier operating
frequency range
824
Output power
+8
ACPR (TDMA)
Output power AMPS
+10
Receive band noise (869 - 894
MHz)
849
MHz
+10
dBm
-36
dBc
Pout = +8dBm, Offset = 30kHz
-56
dBc
Pout = +8dBm, Offset = 60kHz
+14
dBm
-124
dBm/Hz
ftx = 849 MHz Pout = +8dBm
With external IF filter
Spurious Outputs
LO Leakage
-25
-21
dBc
Pout = +8dBm
Image Rejection
-27
-21
dBc
Pout = +8dBm
-20
dBm
Other Spurii
1900MHz RF output stage
(PCS)
RF amplifier operating
frequency range
Output power
ACPR (TDMA)
Specifications assume 50 ohm
load driven via a matching
network
Output Frequency = 1880 MHz,
UHF LO = -10 dBm at 2060
MHz.
1.88
+8
1.91
GHz
+10
dBm
-36
dBc
Pout = +8dBm, Offset = 30kHz
-56
dBc
Pout = +8dBm, Offset = 60kHz
48
Zarlink Semiconductor Inc.
ZL20250
Characteristics
Min
Receive band noise (1930-1990
MHz)
Value
Typ
Max
-128
Data Sheet
Units
dBm/Hz
Comments
ftx = 1910 MHz, Pout = +8dBm
With external IF filter
Spurious Outputs
LO Leakage
-30
-25
dBc
Pout = +8dBm
Image Rejection
-30
-25
dBc
Pout = +8dBm
-20
dBm
2200
MHz
Other Spurii
UHF Synthesiser
Input Frequency
800
Charge Pump Current
0.9
1
1.1
mA
0.45
0.5
0.55
mA
0.22
0.25
0.28
mA
0.11
0.125
0.14
mA
Vdd 0.4
V
15
%
Charge Pump Output
Compliance
0.4
Charge Pump sink/source
mismatch
Charge Pump off-state current
Fractional Compensation
5
88
Less than +/-10 % variation in
Iout
nA
98
108
µA
Full Scale
UHF Buffers
Load Impedance
200
Ω
Output Level (900 and 1900)
-11
dBm
Load = 200 ohms
Harmonic Level
-40
dBc
LO1900 Output
Rx and Tx IF Synthesisers
Input Frequency
100
430
MHz
Charge Pump Current
0.9
1
1.1
mA
0.45
0.5
0.55
mA
0.22
0.25
0.28
mA
0.11
0.125
0.14
mA
49
Zarlink Semiconductor Inc.
ZL20250
Characteristics
Charge Pump Output
Compliance
Min
Value
Typ
0.4
Charge Pump sink/source
mismatch
Charge Pump off-state current
Data Sheet
Max
Units
Vcc 0.4
V
15
%
5
Comments
Less than +/-10 % variation in
Iout
nA
Rx LO Oscillator
Frequency
140
Phase Noise
430
-99
MHz
dBc/Hz
Freq = 270 MHz, Offset = 30
kHz
Tx LO Oscillator
Frequency
Phase Noise
Note 1:
Note 2:
Note 3:
Note 4:
Note 5:
Note 6:
Note 7:
260
430
-99
MHz
dBc/Hz
Freq = 360 MHz, Offset = 30
kHz
All receive currents include all receiver sections plus Rx VHF and UHF PLL's, and UHF LO input buffer circuits. The LO output
buffer and frequency doubler are not included.
All transmit currents include all transmit sections plus Tx VHF and UHF PLL's, and UHF LO input buffer circuits. The LO
output buffer and frequency doubler are not included.
Includes UHF LO input buffer
This is only applicable in 1900 MHz band
The UHF LO output buffer need only be powered up if required to drive an external circuit, for example, a receive front end
mixer.
Input signal FM modulated with 8 kHz deviation by 1 kHz modulating signal. Specification is minimum input level to obtain 12
dB SINAD at FM Output (pin 45) using CCITT filter.
Input modulation: 1kHz modulating signal with 8 kHz deviation. Output level at FM out (pin 45) is set by external components.
See application section for details.
50
Zarlink Semiconductor Inc.
ZL20250
6.0
Typical Performance Curves
6.1
Receive
Data Sheet
AMPS Rx. - Icc v Temperature
IS136 R x. - Icc v T em perature
35
38
34
37
36
33
35
mA
mA
32
31
30
28
33
32
Vcc = 2.7V
29
34
Vcc = 2.7V
Vcc = 3.0V
31
Vcc = 3.3V
30
27
Vcc = 3.0V
Vcc = 3.3V
29
-40
25
T em perature °C
85
-40
85
Temperature °C
Rx. Gain v AGC (Vcc)
Rx. Gain v AGC (Temperature)
120
120
100
100
80
80
60
60
dB
dB
25
40
Vcc = 2.7V
40
T = -40°C
20
Vcc = 3.0V
20
T = 25°C
0
Vcc = 3.3V
0
T = 85°C
-20
-20
0
1
2
3
0
AGC Volts
1
2
AGC Volts
51
Zarlink Semiconductor Inc.
3
ZL20250
Data Sheet
Rx. RSSI
1.6
1.4
RSSI Voltage
1.2
1
0.8
0.6
-40°C
0.4
25°C
0.2
85°C
0
-150
-100
-50
0
Input Level dBm
6.2
Transmit
IS136 Tx. 900 MHz - Icc v AGC (Temperature)
180
180
160
160
140
140
120
120
100
Icc mA
Icc mA
IS136 Tx. 900 MHz - Icc v AGC (Vcc)
100
80
Vcc = 2.7V
60
Vcc = 3.0V
60
40
Vcc = 3.3V
40
80
-40°C
20
25°C
20
0
85°C
0
0
1
2
3
0
AGC Volts
1
2
AGC Volts
52
Zarlink Semiconductor Inc.
3
ZL20250
IS136 Tx.1900 MHz - Icc v AGC (Temperature)
IS136 Tx. 1900 MHz - Icc v AGC (Vcc)
160
160
140
140
120
120
100
Icc mA
100
Icc mA
Data Sheet
80
Vcc = 2.7V
60
80
-40°C
60
25°C
Vcc = 3.0V
40
20
20
0
0
0
1
2
85°C
40
Vcc = 3.3V
0
3
1
AGC Volts
20
20
10
10
0
0
-10
-10
-20
Vcc = 2.7V
-20
Vcc = 3.3V
-50
-60
-60
1
2
25°C
-40
-50
0
-40°C
-30
Vcc = 3.0V
-40
3
IS136 Tx. 900 MHz - Power Out v AGC (Temp.)
dBm
dBm
IS136 Tx. 900 MHz - Power Out v AGC (Vcc)
-30
2
AGC Volts
85°C
0
3
1
2
AGC Volts
AGC Volts
53
Zarlink Semiconductor Inc.
3
ZL20250
IS136 Tx 1900MHz - Power Out v AGC (Temp.)
20
20
10
10
0
0
-10
-10
dBm
dBm
IS136 Tx. 1900 MHz - Power Out v AGC (Vcc)
Data Sheet
-20
Vcc = 2.7V
-30
85°C
Vcc = 3.3V
-50
-60
-60
1
2
25°C
-40
-50
0
-40°C
-30
Vcc = 3.0V
-40
-20
3
0
AGC Volts
1
2
AGC Volts
54
Zarlink Semiconductor Inc.
3
L
Package Code
c Zarlink Semiconductor 2002 All rights reserved.
ISSUE
1
2
ACN
211130
213841
DATE
16Jun01
12Dec02
APPRD.
Previous package codes
For more information about all Zarlink products
visit our Web Site at
www.zarlink.com
Information relating to products and services furnished herein by Zarlink Semiconductor Inc. or its subsidiaries (collectively “Zarlink”) is believed to be reliable.
However, Zarlink assumes no liability for errors that may appear in this publication, or for liability otherwise arising from the application or use of any such
information, product or service or for any infringement of patents or other intellectual property rights owned by third parties which may result from such application or
use. Neither the supply of such information or purchase of product or service conveys any license, either express or implied, under patents or other intellectual
property rights owned by Zarlink or licensed from third parties by Zarlink, whatsoever. Purchasers of products are also hereby notified that the use of product in
certain ways or in combination with Zarlink, or non-Zarlink furnished goods or services may infringe patents or other intellectual property rights owned by Zarlink.
This publication is issued to provide information only and (unless agreed by Zarlink in writing) may not be used, applied or reproduced for any purpose nor form part
of any order or contract nor to be regarded as a representation relating to the products or services concerned. The products, their specifications, services and other
information appearing in this publication are subject to change by Zarlink without notice. No warranty or guarantee express or implied is made regarding the
capability, performance or suitability of any product or service. Information concerning possible methods of use is provided as a guide only and does not constitute
any guarantee that such methods of use will be satisfactory in a specific piece of equipment. It is the user’s responsibility to fully determine the performance and
suitability of any equipment using such information and to ensure that any publication or data used is up to date and has not been superseded. Manufacturing does
not necessarily include testing of all functions or parameters. These products are not suitable for use in any medical products whose failure to perform may result in
significant injury or death to the user. All products and materials are sold and services provided subject to Zarlink’s conditions of sale which are available on request.
Purchase of Zarlink’s I2C components conveys a licence under the Philips I2C Patent rights to use these components in and I2C System, provided that the system
conforms to the I2C Standard Specification as defined by Philips.
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Copyright Zarlink Semiconductor Inc. All Rights Reserved.
TECHNICAL DOCUMENTATION - NOT FOR RESALE