AD AD6121ACP

a
CDMA 3 V Receiver IF Subsystem
with Integrated Voltage Regulator
AD6121
FEATURES
Fully Compliant with IS98A and PCS Specifications
CDMA, W-CDMA, AMPS, and TACS Operation
Linear IF Amplifier
5.9 dB Noise Figure
–47.5 dB to +47 dB Linear-in-dB Gain Control
Quadrature Demodulator
Demodulates IFs from 50 MHz to 350 MHz
Integral Low Dropout Regulator
200 mV Voltage Drop
Accepts 2.9 V to 4.2 V Input from Battery
Low Power
10 mA at Midgain
<1 ␮A Sleep Mode Operation
Companion Transmitter IF Chip Available (AD6122)
GENERAL DESCRIPTION
The AD6121 is a low power receiver IF subsystem specifically
designed for CDMA applications. It consists of high dynamic
range IF amplifiers with voltage controlled gain, a divide-by-two
quadrature generator, an I and Q demodulator, and a powerdown control input. An integral low dropout regulator allows
operation from battery voltages from 2.9 V to 4.2 V.
The gain control input accepts an external gain control voltage
input from a DAC. It provides 94.5 dB of gain control with a
nominal 52.5 dB/V scale factor when using an internal voltage
reference. The gain control interface reference input can be
connected to either the internal reference or an external reference.
The I and Q demodulator provides differential quadrature baseband outputs to interface with CDMA baseband converters. A
divide-by-two quadrature generator followed by dual polyphase
filters ensures maximum ± 2.5° quadrature accuracy.
APPLICATIONS
CDMA, W-CDMA, AMPS, and TACS Operation
QPSK Receivers
The AD6121 IF Subsystem is fabricated using a 25 GHz f t
BiCMOS silicon process and is packaged in a 28-lead SSOP
and a 32-leadless LPCC chip scale package (5 mm × 5 mm).
FUNCTIONAL BLOCK DIAGRAM
ROOFING
FILTER
IF
OUTPUT
DEMODULATOR
INPUT
IOUT
CDMA
INPUT
IOUT
IF AMPLIFIERS
I
2
LOCAL
OSCILLATOR
INPUT
Q
QOUT
AD6121
FM
INPUT
QOUT
QUADRATURE DEMODULATOR
INPUT STAGE
VREG
PTAT
TEMPERATURE
COMPENSATION
CDMA/FM
SELECT
GAIN CONTROL
SCALE FACTOR
GAIN
CONTROL
VOLTAGE
INPUT
LOW
DROPOUT
REGULATOR
VPOS
POWER- POWERDOWN 2 DOWN 1
GAIN
1.23V
CONTROL REFERENCE
VOLTAGE
OUTPUT
REFERENCE
INPUT
REV. B
Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, nor for any infringements of patents or other rights of third parties
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781/329-4700
World Wide Web Site: http://www.analog.com
Fax: 781/326-8703
© Analog Devices, Inc., 2000
(TA = +25ⴗC, VCC = 3.0 V, LO = 2 ⴛ IF, REFIN = 1.23 V, LDO Enabled, unless otherwise
IN is noted.
AD6121–SPECIFICATIONS noted) Note: All power measurements in dBm are referred to 1 k⍀ unless Z
Specification
TOTAL GAIN
Maximum Gain
Minimum Gain
IF AMPLIFIER
CDMA and FM Input
Noise Figure
Input Third-Order Intercept
Input 1 dB Compression Point
Gain Flatness
CDMA Input Capacitance
CDMA Input Resistance
FM Input Capacitance
FM Input Resistance
Output Capacitance
Output Resistance
GAIN CONTROL INTERFACE
Gain Scaling
Gain Scaling Accuracy
Gain Control Response Time
Input Resistance at REFIN
Input Resistance at VGAIN
DEMODULATOR
Differential Input Impedance
Differential Input Capacitance at
Demodulator Input
Input Third Order Intercept
Demodulation Gain
I/Q Output
Differential Output Voltage
Bandwidth
Resistance
Quadrature Accuracy
Amplitude Balance
LO Input Impedance
LO Input Capacitance
CONTROL INTERFACES
Logic Threshold High
Logic Threshold Low
Input Current for Logic High
Mode Control Response Time
Turn-On Response Time
Turn-Off Response Time
LOW DROPOUT REGULATOR
Conditions
Min
Max
Units
IF Amplifiers and Demodulator Powered Up
IF Amplifiers Powered Up and Demodulator Powered Down
IF Amplifier and Demodulator Powered Up
+47
+41.4
–47.5
dB
dB
dB
IF = 85.38 MHz
Maximum Gain
Maximum Gain
Maximum Gain
IF ± 630 kHz, CDMA Mode
Differential
Differential
Differential
Differential
Differential
Differential
5.9
–42.8
–51.6
± 0.25
2.8
850
2.3
670
1.35
1.1
dB
dBm
dBm
dB
pF
Ω
pF
Ω
pF
kΩ
52.5
±3
695
10
100
dB/V
dB/V
ns
MΩ
kΩ
1
kΩ
2.9
–6.1
5.6
pF
dBm
dB
Using Internal Reference
Within a Gain Control Range of 90 dB
Minimum Gain to Maximum Gain
LO = 172.76 MHz , –15 dBm Referred to 50 Ω,
Baseband Frequency = 1 MHz
10 kΩ, 2 pF Differential Parallel Load Impedance
–3 dB
Single-Ended
700
16
630
Differential
Differential
± 0.1
1.5
4.16
CDMA/FM Pin High Selects CDMA, Low Selects FM
PD1 and PD2 Pins Low Select IC ON, High Selects IC OFF
To 200 µA Supply Current
1.34
1.30
0.1
430
2.8
6.8
V
V
µA
ns
µs
µs
mV p-p
MHz
Ω
± 2.5
Degree
± 0.35 dB
kΩ
pF
4.2
2.70
200
1.23
V
V
mV
V
2.9–5.0
2.7–3.6
10
0.78
V
V
mA
µA
External PNP Pass Transistor, VCE SAT = –0.4 V Max
hFE = 100/300 Min/Max
Input Range
Nominal Output
Voltage Drop
Reference Output
POWER SUPPLY
Supply Range Using Internal LDO
Supply Range Bypassing Internal LDO
Supply Current
Standby Current
Typ
2.9
Supply Input at Pin LDOE
Supply Input at Pins DVCC, IFVCC, LDOC
VGAIN = 1.5 V
OPERATING TEMPERATURE
TMIN to TMAX
–40
+85
°C
Specifications subject to change without notice.
–2–
REV. B
AD6121
ABSOLUTE MAXIMUM RATINGS 1
NOTES
1
Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; functional operation of the
device at these or any other conditions above those indicated in the operational
section of this specification is not implied. Exposure to absolute maximum rating
conditions for extended periods may affect device reliability.
2
Thermal Characteristics: 28-lead SSOP Package: θJA = 115.25°C/W.
Supply Voltage VPS1, VPS2 to COM1, COM2 . . . . . . . +5 V
Internal Power Dissipation2 . . . . . . . . . . . . . . . . . . . 600 mW
Operating Temperature Range . . . . . . . . . . . –40°C to +85°C
Storage Temperature Range . . . . . . . . . . . . –65°C to +150°C
Lead Temperature Range (Soldering 60 sec) . . . . . . . . +300°C
PIN CONFIGURATION
DEMIPP
IFOPN
DEMIPN
IFOPP
CDMAIPP
CDMA/FM
LPCC Package
CDMAIPN
SSOP Package
28 IFOPP
CDMAIPP 2
27 IFOPN
CDMAIPN 3
26 DEMIPN
IFGND 4
25 DEMIPP
IFGND 1
24 LDOGND
FMIPP 5
24 LDOGND
IFGND 2
23 LDOGND
FMIPN 6
23 IOPP
FMIPP 3
22 IOPP
22 IOPN
TOP VIEW
(Not to Scale) 21
DGND 8
QOPP
LDOB 13
16 VGAIN
LDOE 14
15 PD2
LOIPN 8
17 REFOUT
9
10 11 12 13 14 15 16
REFIN
17 REFIN
19 QOPN
18 PD1
VGAIN
18 REFOUT
LDOC 12
DGND 6
PD2
DVCC 11
20 QOPP
LOIPP 7
LDOE
19 PD1
LDOB
20 QOPN
21 IOPN
AD6121 Top View
(Not to Scale)
IFVCC 5
LDOC
LOIPP 9
LOIPN 10
FMIPN 4
NC
AD6121
32 31 30 29 28 27 26 25
DVCC
IFVCC 7
NC
CDMA/FM 1
NC = NO CONNECT
ORDERING GUIDE
Model
Temperature
Range
Package
Description
Package
Option
AD6121ARS
AD6121ARSRL
AD6121ACP
AD6121ACPRL
–40°C to +85°C
–40°C to +85°C
–40°C to +85°C
–40°C to +85°C
Shrink Small Outline Package (SSOP)
28-Lead SSOP on Tape and Reel
Chip Scale Package (LPCC)
32-Leadless LPCC on Tape and Reel
RS-28
CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily
accumulate on the human body and test equipment and can discharge without detection.
Although the AD6121 features proprietary ESD protection circuitry, permanent damage may
occur on devices subjected to high-energy electrostatic discharges. Therefore, proper ESD
precautions are recommended to avoid performance degradation or loss of functionality.
REV. B
–3–
CP-32
WARNING!
ESD SENSITIVE DEVICE
AD6121
PIN FUNCTION DESCRIPTIONS
SSOP
Pin
Number
LPCC
Pin
Number
Pin Label
Description
Function
1
2
3
4
5
6
7
8
9
10
CDMA/FM
CDMAIPP
CDMAIPN
IFGND
FMIPP
FMIPN
IFVCC
DGND
LOIPP
LOIPN
NC
DVCC
LDOC
13
12
LDOB
14
13
LDOE
15
14
PD2
16
15
VGAIN
Selects CDMA or FM Input
CDMA “Positive” Input
CDMA “Negative” Input
IF Ground
FM “Positive” Input
FM “Negative” Input
IF VCC
Digital Ground
Local Oscillator “Positive” Input
Local Oscillator “Negative” Input
No Connect
Digital VCC
Low Dropout Regulator Pass
Transistor Collector Connection
Low Dropout Regulator Pass
Transistor Base Connection
Low Dropout Regulator Pass
Transistor Emitter Connection
Demodulator Power-Down
Control Input
Gain Control Voltage Input
CMOS-compatible; HIGH = CDMA, LOW = FM.
AC-coupled, IF input from CDMA SAW filter.
AC-coupled, IF input from CDMA SAW filter.
Ground.
AC-coupled, IF input from FM SAW filter.
AC-coupled, IF input from FM SAW filter.
VCC for IF AGC amplifiers.
Ground.
AC-coupled, Differential Local Oscillator Input.
AC-coupled, Differential Local Oscillator Input.
11
12
30
31
32
1, 2
3
4
5
6
7
8
9, 25
10
11
17
16
REFIN
18
17
REFOUT
19
18
PD1
20
21
22
23
24
25
26
27
28
19
20
21
22
23, 24
26
27
28
29
QOPN
QOPP
IOPN
IOPP
LDOGND
DEMIPP
DEMIPN
IFOPN
IFOPP
VCC for control logic.
Connects to collector of external PNP pass transistor.
Connects to base of external PNP pass transistor.
Connects to emitter of external PNP pass transistor
and DVCC, IFVCC.
Demodulator Power-Down Control Input CMOScompatible; HIGH = Modulator Off, LOW = Modulator On.
Accepts gain control input voltage from external DAC.
Max Gain = 2.5 V. Min Gain = 0.5 V.
Gain Control Reference Input
Accepts 1.23 V reference input from REFOUT (Pin 17)
or external reference.
Reference Output
Provides 1.23 V reference output to REFIN (Pin 18) and
CDMA baseband IC reference input so that gain control
DAC and AD6121 use same reference.
IF Amplifier Power-Down
IF Amplifier Power-Down Control Input, CMOS comControl Input
patible; HIGH = Entire IC Powers Down, LOW = IF
Amplifier On.
Q Output “Negative”
Connects to Q “Negative” Input of baseband IC.
Q Output “Positive”
Connects to Q “Positive” Input of baseband IC.
I Output “Negative”
Connects to I “Negative” Input of baseband IC.
I Output “Positive”
Connects to I “Positive” Input of baseband IC.
Ground
Ground.
Demodulator “Positive” IF Input
Demodulator input from roofing filter.
Demodulator “Negative” IF Input Demodulator input from roofing filter.
IF Amplifier “Negative” IF Output IF output to roofing filter.
IF Amplifier “Positive” IF Output IF output to roofing filter.
–4–
REV. B
AD6121
Test Figures
AD6121
1:8
110⍀ 10nF
RF
SOURCE
909⍀
110⍀ 10nF
CDMAIPP
IFOPP
1k⍀
CDMAIPN
10nF
453⍀
10nF
453⍀
4:1
TO
SPECTRUM
ANALYZER
205⍀
IFOPN
INDUCTOR CHOSEN FOR PEAK RESPONSE
AT THE TEST FREQUENCY (SEE TEXT)
a. CDMA Input Port Characterization Impedance Match
AD6121
453⍀ 10nF
RF
SOURCE
FMIPP
IFOPP
FMIPN
IFOPN
50⍀
10nF
b. FM Input Port Characterization Impedance Match
Figure 1. Quadrature Modulator Characterization Input and Output Impedance Matches
0.1␮F
+15V
1:4
453⍀
RF
SOURCE
10nF
DEMIPP
205⍀
453⍀
X1
IOPP
X2
IOPN
10nF
DEMIPN
V–1
VP
A=1
Y1
Y2
V–1
VN
OUT
50⍀
I CHANNEL
AD830
0.1␮F
AD6121
–15V
QUADRATURE
DEMODULATOR
0.1␮F
LO
SOURCE
10nF
+15V
LOIPP
LOIPN
X1
QOPP
X2
QOPN
10nF
V–1
VP
A=1
Y1
Y2
V–1
VN
ALL SIGNAL PATHS MUST BE EQUAL
LENGTHS FOR I/Q MEASUREMENTS
OUT
50⍀
Q CHANNEL
AD830
0.1␮F
–15V
Figure 2. IF Amplifier Characterization Input and Output Impedance Matches
R&S
SMT03
RF
CDMA
IN
SYNC
REFERENCE
R&S
SMT03
RF
DEMOD
IN
LO
INPUT
HP8508A
VECTOR
VOLTMETER
I CHANNEL
CH2
Q CHANNEL
DC I/O
RF
R&S FSEA
SPECTRUM
ANALYZER
RF INPUT
HPE3610
POWER SUPPLY
HP34970A
DATA ACQUISITION
& SWITCH CONTROL
ALL DC MEASUREMENT
AND CONTROL SIGNALS
Figure 3. General Test Set
REV. B
CH1
FM IN
SYNC
REFERENCE
R&S
SMT03
IF OUT
AD6121
–5–
50⍀
TERMINATOR
AD6121
AD6121
REACTIVE
CONJUGATE
MATCH
NOISE
SOURCE
1:8
10nF
CDMAIPP
10nF
IFOPP
1k⍀
10nF
4:1
450⍀
205⍀
10nF 450⍀
CDMAIPN
TO NOISE
FIGURE
METER
IFOPN
INDUCTOR CHOSEN FOR PEAK RESPONSE
AT THE TEST FREQUENCY
Figure 4. IF Amplifier Noise Figure Test Set
HP8116A
FUNCTION GEN
ROHDE & SCHWARZ
SMT03
4kHz, 0.5V TO 2.5V
SQ WAVE
80MHz, –50dBm
TEKTRONIX
TDS 744A
CH 1
WITH 10
VGAIN
PROBE
CDMA IN
AD6121
CHARACTERIZATION
BOARD
CH 2
WITH COAX CABLE
50⍀
IF OUT
a. Response Time From Gain Control to IF Output
HP8116A
FUNCTION GEN
ROHDE & SCHWARZ
SMT03
4kHz, 0V TO 2.7V
SQ WAVE
80MHz, –50dBm
TEKTRONIX
TDS 744A
CH 1
WITH 10
PD1, PD2
AD6121
PROBE
CDMA IN
CHARACTERIZATION
BOARD
CH 2
WITH COAX CABLE
50⍀
IF OUT
b. Response Time From PD1 and PD2 Control to IF Output
Figure 5. Response Time Setup
Typical Performance Characteristics
60.00
60.00
40.00
40.00
20.00
20.00
GAIN – dB
GAIN – dB
TA = +25ⴗC
0.00
–20.00
0.00
–20.00
TA = +85ⴗC
TA = +85ⴗC
TA = –40ⴗC
–40.00
–40.00
TA = +25ⴗC
–60.00
0.5
TA = –40ⴗC
1
1.5
VGAIN – Volts
2
–60.00
0.5
2.5
Figure 6. IF Amplifier’s Gain vs. VGAIN, IF = 70 MHz,
TA = –40 °C, +25 °C and +85 °C
1
1.5
VGAIN – Volts
2
2.5
Figure 7. IF Amplifier’s Gain vs. VGAIN, IF = 85 MHz,
TA = –40 °C, +25 °C and +85 °C
–6–
REV. B
AD6121
–30.00
40.00
–32.00
–34.00
20.00
–36.00
0.00
IIP3 – dBm
GAIN – dB
TA = +85ⴗC
–20.00
–38.00
–40.00
–42.00
–44.00
TA = +25ⴗC
–46.00
–40.00
–48.00
TA = –40ⴗC
–60.00
0.5
1.5
VGAIN – Volts
1
2
–50.00
0
2.5
Figure 8. IF Amplifier’s Gain vs. VGAIN, IF = 210 MHz,
TA = –40 °C, +25 °C and +85 °C
50
100
150
200
FREQUENCY – MHz
250
300
Figure 11. IF Amplifier’s Input IP3 vs. Frequency, VGAIN =
+2.5 V, TA = +25 °C
25
4.00
3.50
NOISE FIGURE – dB
GAIN STEP ERROR – dB
20
3.00
2.50
2.00
TA = +85ⴗC
1.50
15
2.7VPOS
10
1.00
5
TA = +25ⴗC
3.6VPOS
0.50
3.0VPOS
TA = –40ⴗC
0.00
0
2
1
1.5
VGAIN – Volts
0.5
0
–10
2.5
Figure 9. IF Amplifier’s Gain Error vs. VGAIN, TA = –40 °C,
+25 °C and +85 °C
25
–10
20
NOISE FIGURE – dB
0
–20
IF = 85MHz
–30
50
15
2.7VPOS
10
3.6VPOS
–40
–20
0
GAIN – dB
20
40
0
–10
60
0
10
3.0VPOS
20
GAIN – dB
30
40
Figure 13. IF Amplifier Noise Figure vs. GAIN,
IF= 210 MHz, TA = +25 °C
Figure 10. IF Amplifier’s Input IP3 vs. Gain, IF = 85 MHz,
210 MHz, TA = +25 °C
REV. B
40
5
–40
–50
–60
30
Figure 12. IF Amplifier Noise Figure vs. GAIN, IF= 85 MHz,
TA = +25 °C
IF = 210MHz
IIP3 – dBm
20
GAIN – dB
10
0
–7–
50
AD6121
–10
50.00
TA = –40ⴗC
–20
TA = +85ⴗC
INPUT P1dB – dBm
MAXIMUM GAIN – dB
40.00
TA = +25ⴗC
30.00
20.00
–30
–40
–50
10.00
–60
0.5
0.00
0
50
100
150
200
FREQUENCY – MHz
250
300
1
1.5
VGAIN – V
2
2.5
Figure 17. IF Amplifier Input 1 dB Compression Point vs.
VGAIN, IF = 85.38 MHz
Figure 14. IF Amplifier Maximum Gain vs. Frequency,
TA = –40 °C, +25 °C and +85 °C
6
60.00
TA = –40ⴗC
40.00
5
20.00
4
GAIN – dB
GAIN – dB
VGAIN = +2.5V
0.00
VGAIN = +1.5V
TA = +25ⴗC
TA = +85ⴗC
3
2
–20.00
1
–40.00
VGAIN = +0.5V
0
–60.00
0
100
200
FREQUENCY – MHz
300
0
10
5
BASEBAND FREQUENCY – MHz
15
Figure 18. Demodulator I Channel Gain vs. Baseband
Frequency, IF = 85 MHz
Figure 15. IF Amplifier Gain vs. Frequency, VGAIN =
+0.5 V, +1.5 V and = +2.5 V
20
–40.00
–42.00
–44.00
10
TA = –40ⴗC
TA = +25ⴗC
TA = +85ⴗC
–48.00
GAIN – dB
P1dB – dBm
–46.00
–50.00
–52.00
–54.00
0
–10
–56.00
–58.00
–60.00
0
50
200
100
150
FREQUENCY – MHz
250
–20
0
300
300
100
200
INTERMEDIATE FREQUENCY – MHz
400
Figure 19. Demodulator I Channel Gain vs. IF, Baseband
Frequency = 1 MHz, TA = –40 °C, +25 °C and +85 °C
Figure 16. IF Amplifier 1 dB Compression Point vs. Frequency, VGAIN = +2.5 V
–8–
REV. B
AD6121
2.5
0.25
PHASE ERROR – Degrees
AMPLITUDE BALANCE I–Q – dB
0.3
0.2
IF = 210MHz
IF = 85MHz
0.15
0.1
2.0
TA = –40ⴗC
1.5
TA = +25ⴗC
TA = +85ⴗC
1.0
0.05
0
0
10
5
BASEBAND FREQUENCY – MHz
0.5
0
15
Figure 20. Demodulator I and Q Amplitude Balance vs.
Baseband Frequency, IF = 85 MHz and 210 MHz
10
5
BASEBAND FREQUENCY – MHz
15
Figure 23. Demodulator Phase Error vs. Baseband Frequency, IF = 85 MHz, TA = –40 °C, +25 °C and +85 °C
5
6
IF = 85MHz
TA = +85ⴗC
4
0
IIP3 – dBm
GAIN – dB
TA = +25ⴗC
2
–5
TA = –40ⴗC
–10
0
IF = 210MHz
–2
0
10
5
BASEBAND FREQUENCY – MHz
–15
15
Figure 21. Demodulator I Channel Gain vs. Baseband
Frequency, IF = 85 MHz and 210 MHz
3
REGULATOR OUTPUT VOLTAGE – Volts
PHASE ERROR I–Q – Degrees
TA = +25ⴗC
2.0
TA = –40ⴗC
1.5
TA = +85ⴗC
1.0
0.5
TA = +85ⴗC
2
TA = +25ⴗC
1
TA = –40ⴗC
0
–1
0
100
200
300
INTERMEDIATE FREQUENCY – MHz
400
2
2.5
3
3.5
4
4.5
REGULATOR INPUT VOLTAGE – Volts
5
Figure 25. LDO Regulator Output Voltage vs. Input Voltage, TA = –40 °C, +25 °C and +85 °C
Figure 22. Demodulator Phase Error vs. IF, Baseband
Frequency = 1 MHz, TA = –40 °C, +25 °C and +85 °C
REV. B
400
Figure 24. Demodulator Input IP3 vs. IF, Baseband Frequency = 1 MHz, TA = –40 °C, +25 °C and +85 °C
2.5
0
100
200
300
INTERMEDIATE FREQUENCY – MHz
0
–9–
AD6121
amplifiers. The gain and input bandwidth of the AD6121 are
identical for both the FM and CDMA operating modes. When
the CDMA/FM pin is high, CDMA mode is enabled. When the
pin is low, FM mode is enabled.
16
CURRENT CONSUMPTION – mA
14
TA = +85ⴗC
TA = +25ⴗC
12
The IF amplifiers operate in two different configurations, one
with the I and Q demodulator powered up and another with the
I and Q demodulator powered down. The I and Q demodulator
power setting is configured with pin PD2. The power-down
control is further discussed in the section of this data sheet
entitled Power-Down Control.
10
8
TA = –40ⴗC
6
4
When the demodulator is powered up, the outputs of the IF
amplifiers are internally dc-biased and there is no need for external pull-up inductors. A roofing filter is required (see section
entitled Roofing Filter in this data sheet) when using the IF
amplifiers with the I and Q demodulator powered up. Under
these conditions, the IF amplifiers and the low noise attenuator
input stage has +41.4 dB of gain.
2
0
0.5
1
1.5
VGAIN – Volts
2
2.5
Figure 26. Current Consumption vs. VGAIN, TA = –40 °C,
+25 °C and +85 °C
THEORY OF OPERATION
The AD6121 consists of high dynamic range IF amplifiers with
voltage controlled gain, a divide-by-two quadrature generator,
an I and Q demodulator, a low dropout regulator and powerdown control inputs (Figure 27).
The AD6121 accommodates both the desired CDMA signal
and an interferer 42 dB larger—approximately 6 mV p-p for the
desired signal and 700 mV p-p for the interferer—as specified in
the CDMA system.
IF Amplifiers and Gain Control
The IF gain is provided by two sections: a CDMA or FM input
stage followed by three cascaded IF amplifiers. The CDMA and
FM input stages use differential, continuously-variable attenuators based on Analog Devices’ patented X-AMP™ topology.
These low noise attenuators consist of a differential R-2R ladder
network, linear interpolator, and a fixed gain amplifier. The
bulk of the IF gain is provided by three cascaded, wideband
When the I and Q demodulator is powered down, the IF amplifiers have open collector outputs resulting in the need for pullup inductors. Under this configuration, and with the output of
the IF amplifiers loaded with 1 kΩ, the gain of the IF amplifiers
and low noise attenuator input stage is +47 dB. The pull-up
inductors should be chosen so that the parasitic capacitance
seen at the output of the IF amplifiers is resonated at the frequency of interest. Figure 28 shows how to configure the pull-up
inductors at the output of the IF amplifiers. The 10 nF capacitors are used for ac coupling.
In order to resonate the parasitic capacitors, rearrange Equation
1 to solve for L.
f0 =
1
(1)
2 π LCPAR
where f0 is the IF frequency in Hertz, CPAR is the total parasitic
capacitance in Farads, and L is the total shunt inductor value in
henrys.
ROOFING
FILTER
IF
OUTPUT
DEMODULATOR
INPUT
IOUT
CDMA
INPUT
IOUT
IF AMPLIFIERS
I
2
LOCAL
OSCILLATOR
INPUT
Q
QOUT
AD6121
FM
INPUT
QOUT
QUADRATURE DEMODULATOR
INPUT STAGE
VREG
PTAT
TEMPERATURE
COMPENSATION
CDMA/FM
SELECT
GAIN CONTROL
SCALE FACTOR
GAIN
CONTROL
VOLTAGE
INPUT
LOW
DROPOUT
REGULATOR
VPOS
POWER- POWERDOWN 2 DOWN 1
GAIN
1.23V
CONTROL REFERENCE
VOLTAGE
OUTPUT
REFERENCE
INPUT
Figure 27. Functional Block Diagram
X-AMP is a trademark of Analog Devices, Inc.
–10–
REV. B
AD6121
AD6121
2CPAR
L/2
2CPAR
L/2
the slope of the gain curve will change as a result of a change in
the required range for VGAIN. Figure 30 shows the piecewise
linear approximation of the gain curve for the AD6121.
10nF
IFOPP
VCC
10nF
10nF
MAXIMUM
GAIN
GAIN – V/V
IFOPN
Figure 28. IF Amplifiers’ Output Configuration When
I and Q Demodulator Is Powered Down
MINIMUM
GAIN
In order to confirm whether the pull-up inductors have been
properly designed, sweep the IF frequency and view the output
of the IF amplifiers on a spectrum analyzer. If the inductor
value is correct, the signal should peak at the IF frequency.
VGAIN – Volts
Figure 30. Piecewise Linear Approximation for the
AD6121 Gain Curve
The gain of the two amplifier sections (input stage followed by
amplifiers) changes sequentially for optimum signal-to-noise
ratio. For example, in CDMA mode, the gain of the CDMA
input amplifier first increases to maximum and then the gain of
the cascaded IF amplifiers increases to maximum. Likewise, when
decreasing gain, the gain of the cascaded amplifiers decreases to
minimum before the gain of the CDMA input amplifier.
Because the minimum and maximum gains for the AD6121 are
constant, we can approximate the VGAIN range for a given
REFIN voltage by using Equation 2.
VGAIN =
The gain control circuits contain both temperature compensation circuitry and a choice of internal or external reference for
adjusting the gain scale factor. The gain control input accepts an
external gain control voltage from a DAC. It provides 94.5 dB
of gain control range with a nominal 52.5 dB/V scale factor.
Either an internal or external reference may be used to set the
gain control scale factor.
The external gain control input signal should be free of noise. In
a typical wireless application, it is recommended to filter this
signal in order to reduce the noise that results from the DAC
that generates it. A simple RC filter can be employed, but care
should be taken with its design. If too big a resistor is used, a
large voltage drop may occur across the resistor resulting in
lower gain than expected (as a result of a lower voltage reaching
the AD6121). An RC filter with a 1 kHz bandwidth, employing
a 1 kΩ resistor is appropriate. This results in a 150 nF capacitor.
The resulting circuit is shown in Figure 29.
(GAIN – MinGain) × 1.6 REFIN
+ 0.4 REFIN
MaxGain – MinGain
(2)
Where MaxGain is the maximum gain (+47 dB) in dB, MinGain
is the minimum gain (–47.5 dB) in dB, REFIN is the reference
input voltage, in volts, VGAIN is the gain control voltage input,
in volts, and GAIN is the particular gain, in dB, we would have
for a given REFIN and VGAIN. Consequently, for any REFIN
we choose, we can calculate the VGAIN range by solving Equation 2 for VGAIN. For example, in order to determine the
VGAIN value for the maximum gain condition, given a 1.23 V
REFIN, we can solve Equation 2 for VGAIN by substituting
47 dB for GAIN and MaxGain, –47.5 dB for MinGain and
1.23 V for REFIN. VGAIN can then be calculated to be 2.46
V, or approximately 2.5 V. For the minimum gain condition,
we can determine the VGAIN value by substituting 47 dB for
MaxGain, –47.5 dB for Gain and MinGain and 1.23 V for
REFIN. VGAIN can then be calculated to be 0.492 V or approximately 0.5 V.
I and Q Demodulator
AD6121
FROM
BASEBAND
CONVERTER
1k⍀
VGAIN
150nF
100k⍀
Figure 29. Gain Voltage Filtering
The AD6121’s overall gain, expressed in decibels, is linear in
dB with respect to the automatic gain control (AGC) voltage,
VGAIN. Either REFOUT, or an external reference voltage
connected to REFIN, may be used to set the voltage range for
VGAIN. When the internal 1.23 V reference, REFOUT, is
connected to REFIN, VGAIN will control the AGC range when
it is typically set between 0.5 V and 2.5 V. Minimum gain occurs at minimum voltage on VGAIN and maximum gain occurs
at maximum voltage on VGAIN. The maximum and minimum
gain will not change with a change in voltage at REFIN. Rather,
REV. B
The I and Q demodulator provides differential quadrature baseband outputs to CDMA baseband converters. The demodulator
provides 5.6 dB of voltage gain in addition to the gain provided
by the IF amplifier stage. The outputs of the I and Q demodulator are filtered with a low-pass filter, which typically has a 16 MHz
bandwidth. A divide-by-two quadrature generator followed by
dual polyphase filters ensures a typical ± 1° quadrature accuracy
(Figure 31).
–11–
I
2 IF
LO INPUT
I
2
QUADRATURE
OUTPUT TO
DEMODULATOR
POLYPHASE
FILTERS
180
2
Q
Q
Figure 31. Simplified Quadrature Generator Circuit
AD6121
Power-Down Control
ROOFING FILTER
The AD6121 can operate with the IF amplifier and I and Q
demodulator stages both powered up, the IF amplifiers powered
up alone or both the IF amplifiers and demodulator powered
down. The AD6121 cannot operate with the demodulator powered up and the IF amplifiers powered down. The control for
these different modes is performed via the PD1 and PD2 pins.
Table I shows the decoding of the logic inputs.
When the IF amplifiers and I and Q demodulator of the AD6121
are both powered up, the parasitic impedances seen at the output of the IF amplifiers and inputs of the I and Q demodulator
are high enough to create a low-pass filter, which may attenuate
the IF signal. Consequently, the parasitic capacitance must be
cancelled by using an external inductor to form a parallel resonant circuit. The external inductor that is required and the
internal parasitic capacitors form what is known as the roofing
filter, with the resonant frequency given by Equation 1 (see IF
Amplifiers and Gain Control section of this data sheet).
Table I. AD6121 Operating Modes
PD1
PD2
IF Amplifiers
Demodulator
0
0
1
1
0
1
0
1
ON
ON
INVALID STATE
OFF
ON
OFF
INVALID STATE
OFF
Low Dropout Regulator
The AD6121 incorporates an integrated low dropout regulator.
The regulator accepts inputs from 2.9 V to 4.2 V and supplies
2.7 V at LDOC. The 2.7 V signal can be used to provide the dc
voltages required for the DVCC and IFVCC dc supplies. In order
to configure the low dropout regulator, an external pass transistor
is required. A pnp transistor with a minimum hFE of 100 and a
maximum hFE of 300 and a VCE(Sat.) of –0.4 V is required. In
order to use the low dropout regulator, configure the transistor
as shown in Figure 32. The 10 nF capacitor in Figure 32 is used
for decoupling the 2.7 V dc signal.
In addition to the low dropout regulator, there is a bandgap
voltage reference which produces a 1.23 V reference voltage at
pin REFOUT. This reference voltage will be present whenever a
voltage is applied to IFVCC and DVCC. This 1.23 V reference
voltage can then be used to provide the gain reference voltage
for the receive ADCs in the baseband converter.
LDOC
2.7V
10nF
PASS
TRANSISTOR
LDOE
2.7V TO 4.2V
Figure 32.
AD6121
LDOB
1.23V
REFOUT
Configuring the Low Dropout Regulator
It is possible to bypass the low dropout regulator on the AD6121
and use an external regulator instead. In order to bypass the
integrated low dropout regulator, connect pins LDOE, LDOB
and LDOC together and then connect them all to the external
regulator voltage. This configuration is shown in Figure 33.
Even when the low dropout regulator is bypassed, the 1.23 V
reference voltage at pin REFOUT is still present.
AD6121
LDOB
LDOE
AD6121
IFOPP
2CPAR
L
2CPAR
IFOPN
10nF
DEMIPP
10nF
DEMIPN
Figure 34. Roofing Filter Configuration
In order to confirm whether the roofing filter has been correctly
designed, sweep the IF frequency and view the output of the I
and Q demodulator on a spectrum analyzer. The output level
of the I or Q signal should be approximately flat from dc to
16 MHz, after which the low-pass filters at the I and Q output
will attenuate the signal. With the correct roofing filter inductor, the I and Q output signal will be higher than for any other
roofing filter inductor value.
It should be noted that the roofing filter is only required when
cascading the output from the IF amplifiers to the input of the I
and Q demodulator. If we are looking at the output of the IF
amplifiers, no roofing filter is required. Because the IF amplifiers’ outputs are open collector when the I and Q demodulator is
powered down, pull-up inductors will be required in order to set
the dc voltage (see the section of this data sheet entitled IF
Amplifiers and Gain Control) and to resonate the parasitic
capacitors that are present under these conditions.
LEVEL DIAGRAM
LDOC
FROM EXTERNAL
VOLTAGE
REGULATOR
The roofing filter may be composed of a shunt inductor between
the IF amplifiers differential output pins. Because the demodulator is powered up when the output of the IF amplifiers are fed
into the I and Q demodulator, the output of the IF amplifiers
are not open collector. As a result, pull up inductors are not
required. This configuration is shown in Figure 34. The 10 nF
capacitors are used for ac coupling.
REFOUT
1.23V
Figure 33. Configuration for Bypassing the Low Dropout
Regulator
Figure 35 is provided in order to better understand the different
voltage and power levels you can expect to see at different points
on the AD6121. It represents the levels that would be seen on
Rev. B of the AD6121 Customer Evaluation Board. When trying to make these measurements, a high impedance (10 MΩ)
active FET probe (for example, the TEK P6204 from Tektronix)
should be used to minimize the effects of loading the circuits
with the probe.
–12–
REV. B
AD6121
IOUT
–19.6dBm DIFFERENTIAL
REFERRED TO 700⍀
247.8mV p-p DIFFERENTIAL
f = 85.38MHz
–61dBm DIFFERENTIAL
REFERRED TO 500⍀
1.78mV p-p DIFFERENTIAL
f = 85.38MHz
–60dBm
REFERRED TO 50⍀
632.5mV p-p DIFFERENTIAL
SIGNAL
GENERATOR
IOUT
–14dBm DIFFERENTIAL
REFERRED TO 700⍀
472mV p-p DIFFERENTIAL
I
LOCAL
OSCILLATOR INPUT
168.76MHz
100mV p-p DIFFERENTIAL
2
Q
VGAIN = 2.5V
GAIN = +41.4dB
QOUT
QOUT
AD830
50⍀
ZIN = 700⍀
AT 85.38MHz
SPECTRUM
ANALYZER
50⍀
AD830
1:8
50⍀
50⍀
50⍀
1k⍀
–5.55dBm
REFERRED TO 100⍀
472mV p-p
ZIN = 500⍀
–8.55dBm
REFERRED TO 50⍀
236mV p-p
Figure 35. AD6121 Signal Level Diagram for AD6121 Customer Sample Board, Rev. B
CDMA/FM
AD6121
CDMAIPN
CDMAIPP
IFOPP
IFOPN
IFGND
CDMA
BASEBAND
IC
DEMIPN
FMIPN
DEMIPP
FMIPP
LDOGND
IOPP
IOPN
IFVCC
DGND
I INPUT POS
I INPUT NEG
I
LOIPP
2
LOIPN
Q
QOPP
QOPN
DVCC
LDOC
LDOB
VCC
LDOE
Q INPUT POS
Q INPUT NEG
PD1
REFOUT
LOW
DROPOUT
REGULATOR
GAIN
CONTROL
SCALE
FACTOR
VGAIN
PD2
TEMP
COMP
EXT REF IN
REFIN
1k⍀
RX AGC DAC
159nF
Figure 36. Typical Application Showing Interface to Baseband IC with SSOP Package
add matching networks. The board is configured for an IF frequency of 85.38 MHz when shipped.
OUTPUT INTERFACES
The AD6121 interfaces to CDMA baseband converters requiring either IF or baseband inputs. The baseband output is provided by direct connection of the AD6121’s baseband output to
the baseband input of the baseband converter (Figure 36). The
output interfaces are controlled by the AD6121’s power-down
modes.
The AD830s are used to provide differential to single ended
conversion for analysis of the differential I and Q outputs. As a
result, the output can be displayed on a spectrum analyzer or
other test equipment requiring a single ended input.
AD6121 CUSTOMER EVALUATION BOARD
The AD6121 customer evaluation board consists of an AD6121,
I/O connectors, 3 two-pin headers, a 20-pin dual header and
two AD830 High Speed Video Difference Amplifiers. It allows
the user to evaluate the AD6121’s I and Q demodulator and IF
amplifiers operating together or separately. The board is identical
for both the SSOP and LPCC packages. Because the AD6121 can
operate at any IF frequency from 50 MHz to 350 MHz, pads
are provided on the LOIPP, IFIP, CDMAIP and DMOD IN
inputs as well as the IF OUT output ports to allow the user to
REV. B
Prior to applying a CDMA or FM input signal, the appropriate
mode must be selected. FM mode will be selected by shorting
the two pins of the two pin header labeled FM/CDMA. Open
circuiting these two pins will select CDMA mode.
In order to test the power-down modes of the AD6121, locate
the bank of 3 two-pin headers on the evaluation board. In order
to have both the IF amplifiers and the I and Q demodulator
powered up, short circuit each of the two pins on the two pin
headers labeled PD1 and PD2. In order to power down the
demodulator and keep the IF amplifiers powered up, short
circuit the 2 pins on the header labeled PD1 and open circuit
–13–
AD6121
the header labeled PD2. As described in Table I of this data
sheet, it is invalid to have PD1 open circuited and PD2 short
circuited. In order to power down the IF amplifiers and demodulator, open circuit both PD1 and PD2.
Table III lists the connections for the 20-pin power supply
connector.
As shipped, the board is configured as follows:
Pin
Number
Table III. 20-Pin Power Supply Connection Information
1. J1 is open circuited and J2 is short circuited. This enables the
LDO regulator. In order to bypass the LDO regulator, short
circuit J1 and open circuit J2.
2. X18, X26, X25 and X23 are short circuited resulting in
the IF amplifiers’ output being connected to the I and Q
demodulator’s input.
2
3. L4, the roofing filter inductor is optimized for an IF frequency of 85.38 MHz.
4. L2 and L3 are open circuited, although the components are
soldered on one pad of each set of solder pads.
In order to evaluate the IF amplifiers and I and Q demodulator
independent of each other, the roofing filter will have to be
removed from the circuit and the pull up inductors will have to
be added at the output of the IF amplifiers. When evaluating the
IF amplifiers alone, the I and Q demodulator should be powered down as described earlier in this section. The 470 nH pull
up inductors required for the 85.38 MHz IF frequency are
provided with the board, however, they will need to be soldered
down to pads L2 and L3. The roofing filter should be disconnected from the circuit and the output ports for the IF amplifiers as well as the input ports for the I and Q demodulator
should be connected. This is accomplished by open circuiting
X18, X25, X26 and X33 and short circuiting X19, X21, X27
and X29.
Table II describes the high frequency signal connectors on the
AD6121 customer sample board.
Table II. Evaluation Board SMA Signal Connector Descriptions
Connector
Description
LOIPP
FMIP
Local oscillator positive input at 2 × IF frequency
FM signal input port. The differential to single
ended conversion performed on board by a balun.
Impedance matched to 50 Ω for a 85.38 MHz IF
frequency.
CDMA signal input port. The differential to single
ended conversion performed on board by a balun.
Impedance matched to 50 Ω for a 85.38 MHz IF
frequency.
IF Amplifier output port. The differential to single
ended conversion performed on board by a balun.
Impedance matched to 50 Ω for a 85.38 MHz IF
frequency.
Demodulator input port. The differential to single
ended conversion performed on board by a balun.
Impedance matched to 50 Ω for a 85.38 MHz IF
frequency.
I channel output port for the I and Q demodulator.
Q channel output port for the I and Q demodulator
CDMAIP
IF OUT
DMOD IN
I CH
Q CH
1
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
Function
VPOS for AD6121.
2.9 V–4.2 V using the LDO Regulator.
2.7 V–4.2 V bypassing the LDO Regulator.
VPOS for AD6121.
2.9 V–4.2 V using the LDO Regulator.
2.7 V–4.2 V bypassing the LDO Regulator.
Ground.
Ground.
Ground.
Ground.
Ground.
PD1. Connects to 2-pin header labeled PD1.
Ground.
PD2. Connects to 2-pin header labeled PD2.
Ground.
FM/CDMA. Selects FM or CDMA mode.
Connected to 2-pin header labeled FM/CDMA.
Ground.
REFOUT. 1.23 V output reference voltage from
Pin 18 on AD6121.
Ground.
VGAIN. Gain control voltage input. Connected to
Pin 16 on AD6121.
Ground.
VREGOUT. The 2.7 V output of the LDO regulator
when it is enabled. Connects to Pin 12 on AD6121.
–15 V for AD830 Amplifier.
+15 V for AD830 Amplifier.
A schematic diagram of the evaluation board is shown in
Figure 37.
–14–
REV. B
AD6121
VREGOUT
C23
L2
10nF 470nH
C12
10nF
VREGOUT
FM/CDMA
X2
0⍀
C1
10nF
X5
0⍀
1:8
2
CDMAIP
X3
120nH
X1
T1
X9
0⍀
X7
0⍀
Z = 500⍀
X8
X13
1k⍀
X11
T2
5
C4
10nF
X7
0⍀
IFVCC
6
7
8
C6
0.01␮F
X16
0⍀
9
LO IN
X15
C7
10nF
X17
10
DVCC
C9
10nF
VREGOUT
AD6121
CDMA/FM
IFOPP
CDMAIPP
IFOPN
CDMAIPN DEMIPN
IFGND
DEMIPP
C24
L3
10nF 470nH
28
X18
0⍀
11
12
13
J2
0⍀
FMMT4403CT-ND
14
VREG IN
L4
620nH
FMIPP
LDOGND
FMIPN
IOPP
U1
IOIPN
IFVCC
QOPP
DGND
LOIPP
QOPN
LOIPN
PD1
DVCC
REFOUT
LDOC
REFIN
–15V
P1
1
3
5
7
9
11
13
15
17
19
P2
2
4
6
8
10
12
14
16
18
20
L1
470nH
R4
10k⍀
R5
10k⍀
X24
X26
0⍀
C14
10nF
26
C13
10nF
X25
0⍀
C15
10nF
25
X29
X33
0⍀
8:1
X31
68nH
DMOD
IN
X30
180nH
X28
X32
T4
24
C16
0.1␮F
+15V
23
X1
X2 V–1
22
U2
VP
A=1
Y1
21
Y2 V–1
VN
SOIC
PACKAGE
OUT
AD830
I CH
R7
50⍀
20
–15V
C17
0.1␮F
19
PD1
C18
0.1␮F
18
+15V
17
X1
LDOB
LDOE
VGAIN
PD2
X2 V–1
16
15
PD2
C21
10nF
R9
0⍀
R6
10k⍀
A=1
Y2 V–1
C20
10nF
U3
VP
Y1
J5
0⍀
VN
SOIC
PACKAGE
OUT
AD830
R8
50⍀
Q CH
–15V
C19
0.1␮F
REFOUT
VGAIN
VREG IN
2.9V – 4.2V
IFVCC
PD1
PD2
FM/CDMA
REFOUT
VGAIN 0.5V – 2.5V
VREGOUT
PD1
PD2
FM/CDMA
DVCC
+15V
INDICATES A 50⍀ TRACE
Figure 37. Schematic Diagram of AD6121 Evaluation Board
REV. B
IF
OUT
C23
27
VPOS
VPOS
2.9V – 4.2V
X22
4pF
X20
X21
X23
150nH
T3
J1
Q1
8:1
X27
FMIP
X10
150nH
3
4
C3
10nF
X5
0⍀
1:8
R1
1k⍀
C2
10nF
X6
X4
1
X19
–15–
C5
18pF
R3
10⍀
C11
10nF
C8
18pF
R2
10⍀
C10
10nF
VREGOUT
VREGOUT
AD6121
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
28-Lead Shrink Small Outline Package (SSOP)
(RS-28)
28
C00945b–.5–6/00 (rev. B)
0.407 (10.34)
0.397 (10.08)
15
0.311 (7.9)
0.301 (7.64)
0.212 (5.38)
0.205 (5.21)
1
14
0.07 (1.79)
0.066 (1.67)
0.078 (1.98) PIN 1
0.068 (1.73)
0.0256
0.008 (0.203) (0.65)
0.002 (0.050) BSC
0.015 (0.38)
SEATING
0.010 (0.25)
PLANE
0.009 (0.229)
0.005 (0.127)
8
0
0.03 (0.762)
0.022 (0.558)
32-Leadless Chip Scale Package (LPCC)
(CP-32)
0.205 (5.20)
0.197 (5.00) SQ
0.189 (4.80)
0.128 (3.25)
0.106 (2.70) SQ
0.049 (1.25)
32
1
25
24
0.015 (0.38)
0.012 (0.30)
0.009 (0.23)
BOTTOM
VIEW
17
PIN 1
INDICATOR
8
9
16
0.138 (3.50) BSC
0.018 (0.45)
0.016 (0.40)
0.014 (0.35)
0.039 (1.00)
0.035 (0.90)
0.031 (0.80)
0.010
(0.25)
REF
0.020 (0.50)
BSC
0.002 (0.05)
0.001 (0.02)
0.000 (0.00)
PRINTED IN U.S.A.
CONTROLLING DIMENSIONS ARE IN MILLIMETERS
DIMENSIONS MEET JEDEC MO-220-VHHD-2
–16–
REV. B