AD AD8347ARU-REEL

a
0.8 GHz–2.7 GHz
Direct Conversion Quadrature Demodulator
AD8347*
FEATURES
Integrated RF and Baseband AGC Amplifiers
Quadrature Phase Accuracy 1ⴗ Typ
I/Q Amplitude Balance 0.3 dB Typ
Third Order Intercept (IIP3) +11.5 dBm @ Min Gain
Noise Figure 11 dB @ Max Gain
AGC Range 69.5 dB
Baseband Level Control Circuit
Low LO Drive –8 dBm
ADC Compatible I/Q Outputs
Single Supply 2.7 V–5.5 V
Power-Down Mode
Package 28-Lead TSSOP
APPLICATIONS
Cellular Basestations
Radio Links
Wireless Local Loop
IF Broadband Demodulator
RF Instrumentation
Satellite Modems
GENERAL DESCRIPTION
FUNCTIONAL BLOCK DIAGRAM
AD8347
28
LOIP
27
COM1
3
26
QOPN
IOPP
4
25
QOPP
VCMO
5
24
QAIN
IAIN
6
23
COM3
COM3
7
22
QMXO
IMXO
8
21
VPS3
COM2
9
20
VDT1
19
VAGC
RFIP 11
18
VDT2
VPS2 12
17
VGIN
IOFS 13
16
QOFS
15
ENBL
LOIN
1
VPS1
2
IOPN
PHASE
SPLITTER
PHASE
SPLITTER
DET
RFIN 10
VREF 14
BIAS
GAIN
CONTROL
amplifiers together provide 69.5 dB of gain control. A precision
control circuit sets the Linear-in-dB RF gain response to the gain
control voltage.
The AD8347 is a broadband Direct Quadrature Demodulator
with RF and baseband Automatic Gain Control (AGC) amplifiers.
It is suitable for use in many communications receivers,
performing Quadrature demodulation directly to baseband
frequencies. The input frequency range is 800 MHz to 2.7 GHz.
The outputs can be connected directly to popular A-to-D converters
such as the AD9201 and AD9283.
Baseband level detectors are included for use in an AGC loop to
maintain the output level. The demodulator dc offsets are
minimized by an internal loop, whose time constant is controlled
by external capacitor values. The offset control can also be
overridden by forcing an external voltage at the offset nulling pins.
The RF input signal goes through two stages of variable gain
amplifiers prior to two Gilbert-cell Mixers. The LO quadrature
phase splitter employs polyphase filters to achieve high quadrature accuracy and amplitude balance over the entire operating
frequency range. Separate I & Q channel variable-gain amplifiers
follow the baseband outputs of the mixers. The RF and baseband
The baseband variable gain amplifier outputs are brought off-chip
for filtering before final amplification. By inserting a channel
selection filter before each output amplifier high-level out-ofchannel interferers can be eliminated. Additional internal circuitry
also allows the user to set the dc common-mode level at the
baseband outputs.
*U.S. Patents Issued and Pending
REV. 0
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 that
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
www.analog.com
Fax: 781/326-8703
© Analog Devices, Inc., 2001
AD8347–SPECIFICATIONS
Parameter
(VS = 5 V; TA = 25ⴗC; FLO = 1.9 GHz; VVCMO = 1 V; FRF = 1.905 GHz; PLO = –8 dBm,
RLOAD = 10 k⍀, dBm with respect to 50 ⍀, unless otherwise noted.)
Conditions
Min
OPERATING CONDITIONS
LO/RF Frequency Range
LO Input Level
VGIN Input Level
VSUPPLY (VS)
Temperature Range
RF AMPLIFIER/DEMODULATOR
AGC Gain Range
Conversion Gain (Max)
Conversion Gain (Min)
Gain Linearity
Gain Flatness
Input P1 dB
Third Order Input Intercept (IIP3)
Second Order Input Intercept (IIP2)
LO Leakage (RF)
LO Leakage (MXO)
Demodulation Bandwidth
Quadrature Phase Error
I/Q Amplitude Imbalance
Noise Figure
Mixer AGC Output Level
Baseband DC Offset
Mixer Output Swing
0.8
–10
0.2
2.7
–40
Gain
Bandwidth
Output DC Offset (Differential)
Common-Mode Offset
Group Delay Flatness
Second Order Intermod. Distortion
Third Order Intermod. Distortion
Max
Unit
2.7
0
1.2
5.5
+85
GHz
dBm
V
V
°C
From RFIP/RFIN to IMXO and QMXO
(IMXO/QMXO Load >1 kΩ)
VVGIN = 0.2 V (Max Gain)
VVGIN = 1.2 V (Min Gain)
VVGIN = 0.3 V to 1 V
FLO = 0.8 GHz – 2.7 GHz, FBB = 1 MHz
VVGIN = 0.2 V
VVGIN = 1.2 V
FRF1 = 1.905 GHz,
FRF2 = 1.906 GHz, –10 dBm Each Tone,
(Min Gain)
FRF1 = 1.905 GHz,
FRF2 = 1.906 GHz, –10 dBm Each Tone,
(Min Gain)
At RFIP
At IMXO/QMXO
–3 dB
FRF = 1.9 GHz
FRF = 1.9 GHz
Max Gain
See TPC 30
At IMXO/QMXO, Max Gain
(Corrected, Ref to VREF)
Level at which IMD3 = 45 dBc
RLOAD = 200 Ω
RLOAD = 1 kΩ
–3
Mixer Output Impedance
BASEBAND OUTPUT AMPLIFIER
Typ
69.5
39.5
–30
±2
0.7
–30
–2
+11.5
dB
dB
dB
dB
dB p-p
dBm
dBm
dBm
+25.5
dBm
–60
–42
90
±1
0.3
11
24
2
dBm
dBm
MHz
Degree
dB
dB
mV p-p
mV
+3
65
65
3
mV p-p
mV p-p
Ω
30
65
± 50
±5
1.8
–49
dB
MHz
mV
mV
ns p-p
dBc
From IAIN to IOPP/IOPN and
QAIN to QOPP/QOPN
RLOAD = 10 kΩ
–3 dB (See TPC 18)
(VIOPP – VIOPN)
(VIOPP + VIOPN)/2 – VVCMO
0 MHz–50 MHz
FIN1 = 5 MHz, FIN2 = 6 MHz,
VIN1 = VIN2 = 8 mV p-p
FIN1 = 5 MHz, FIN2 = 6 MHz,
VIN1 = VIN2 = 8 mV p-p
Input Bias Current
Input Impedance
Output Swing Limit (Upper)
Output Swing Limit (Lower)
–200
–40
+200
+40
–67
dBc
2
1储3
µA
MΩ储pF
V
V
VS – 1.3
0.4
–2–
REV. 0
AD8347
Parameter
CONTROL INPUT/OUTPUTS
VCMO Input
Gain Control Input Bias Current
Offset Input Overriding Current
VREF Output
Conditions
Min
@ VS = 2.7 V
@ VS = 5 V
VGIN
IOFS, QOFS
RLOAD = 10 kΩ
IMXO/QMXO Connected Directly to
IAIN/QAIN Respectively
LO/RF INPUT
LOIP Input Return Loss
(See TPC 26 Through 29 for More Detail)
Measuring LOIP LOIN, ac-coupled to
Ground with 100 pF.
Measuring Through Evaluation Board
Balun with Termination
RFIP Input Pin
RFIP Input Return Loss
ENABLE
Power-Up Control
Power-Up Control
Power-Up Time
Power-Down Time
POWER SUPPLIES
Voltage
Current (Enabled)
Current (Standby)
Current (Standby)
Linear extrapolation back to
theoretical value at VGIN = 0
Low = Standby
High = Enabled
Time for Final BB Amps to be Within
90% of Final Amplitude
@ VS = 5 V
@ VS = 2.7 V
Time for Supply Current to be <4 mA
@ VS = 5 V
@ VS = 2.7 V
Unit
0.95
1.05
V
V
µA
µA
V
65.5
–3
–96.5
88
69.5
+0.5
–89
94
72.5
+4
–82.5
101
dB
dB
dB/V
dB
2.5
–4
dB
–9.5
–10
dB
dB
0
+VS – 1
0.5
+VS
V
V
20
10
µs
µs
30
1.5
µs
ms
VPS1, VPS2, VPS3
2.7
48
@5V
@5V
@ 3.3 V
Specifications subject to change without notice.
REV. 0
Max
1
1
<1
10
1.00
0.5
RESPONSE FROM RF INPUT TO
FINAL BB AMP
Gain @ VVGIN = 0.2 V
Gain @ VVGIN = 1.2 V
Gain Slope
Gain Intercept
Typ
–3–
64
400
80
5.5
80
V
mA
µA
µA
AD8347
ABSOLUTE MAXIMUM RATINGS *
PIN CONFIGURATION
Supply Voltage VPS1, VPS2, VPS3 . . . . . . . . . . . . . . . . . . . 5.5 V
LO and RF Input Power . . . . . . . . . . . . . . . . . . . . . . 10 dBm
Internal Power Dissipation . . . . . . . . . . . . . . . . . . . . 500 mW
␪JA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68°C/W
Maximum Junction Temperature . . . . . . . . . . . . . . . . 150°C
Operating Temperature Range . . . . . . . . . . . –40°C to +85°C
Storage Temperature Range . . . . . . . . . . . . –65°C to +150°C
Lead Temperature (Soldering 60 sec) . . . . . . . . . . . . . 300°C
*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.
LOIN
1
28
LOIP
VPS1
2
27
COM1
IOPN
3
26
QOPN
IOPP
4
25
QOPP
VCMO
5
24
QAIN
IAIN
6
23
COM3
COM3
7
22
QMXO
IMXO
8
21
VPS3
COM2
9
20
VDT1
RFIN 10
19
VAGC
RFIP 11
18
VDT2
VPS2 12
17
VGIN
IOFS 13
16
QOFS
VREF 14
15
ENBL
AD8347
TOP VIEW
(Not to Scale)
ORDERING GUIDE
Model
Temperature Range
Package Description
Package Option
AD8347ARU
–40°C to +85°C
Tube (28-Lead TSSOP) Thin
Shrink Small Outline Package
13" Tape and Reel
7" Tape and Reel
Evaluation Board
RU-28
AD8347ARU-REEL
AD8347ARU-REEL7
AD8347-EVAL
VPS1
VPS2
VPS3
VREF
IMXO IOFS
AD8347
ENBL
IAIN
IOPP
IOPN
VREF
BIAS
CELL
VREF
VCMO
VCMO
RFIN
PHASE
SPLITTER
2
RFIP
PHASE
SPLITTER
1
VCMO
LOIN
LOIP
COM3
COM2
VGIN
GAIN
CONTROL
INTERFACE
DET 1
COM3
DET 2
VREF
VDT1 VAGC VDT2
QMXO QOFS
QAIN
COM1
QOPP
QOPN
Figure 1. Block Diagram
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 AD8347 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.
–4–
WARNING!
ESD SENSITIVE DEVICE
REV. 0
AD8347
PIN FUNCTION DESCRIPTIONS
Pin
No.
Mnemonic
Equiv.
Cir.
Description
1, 28
LOIN, LOIP
A
2
3, 4
VPS1
IOPN, IOPP
B
5
VCMO
C
6
IAIN
D
7, 23
8, 22
COM3
IMXO, QMXO
B
9
10, 11
COM2
RFIN, RFIP
E
12
13, 16
VPS2
IOFS, QOFS
F
14
VREF
G
15
17
ENBL
VGIN
H
C
18, 20
VDT2, VDT1
D
19
VAGC
I
21
VPS3
24
QAIN
D
25, 26
QOPP, QOPN
B
27
COM1
REV. 0
LO Input. For optimum performance, these inputs should be driven differentially. Typical input
drive level is equal to –8 dBm. To improve the match to a 50 Ω source, connect a 200 Ω shunt
resistor between LOIP and LOIN. A single-ended drive is also possible but this will slightly
increase LO leakage.
Positive Supply for LO Section. This pin should be decoupled with 0.1 µF and 100 pF capacitors.
I Channel Differential Baseband Output. Typical output swing is equal to 760 mV p-p differential
in AGC mode. The common mode level on these pins is programmed by the voltage on VCMO.
Baseband Amplifier Common-Mode Voltage. The voltage applied to this pin sets the output
common-mode level of the baseband amplifiers. This pin can either be connected to VREF
(Pin 14) or to a reference voltage from another device (typically an ADC).
I Channel Baseband Amplifier Input. This pin, which has a high input impedance, should be
biased to VREF (approximately 1 V). If IAIN is connected directly to IMXO, biasing will be
provided by IMXO. If an ac-coupled filter is placed between IMXO and IAIN, this pin can be
biased from VREF through a 1 kΩ resistor. The gain from IAIN to the differential outputs
IOPN/IOPP is 30 dB.
Ground for Biasing and Baseband Sections
I & Q Channel Baseband Mixer/VGA Outputs. These are low impedance outputs whose bias
levels are equal to VREF. IMXO and QMXO are typically connected to IAIN and QAIN
respectively, either directly or through filters. These outputs have a maximum current limit of
about 1.5 mA. This allows for a 600 mV p-p swing into a 200 Ω load. This corresponds to an
input level of –40 dBm @ max gain of 39.5 dB. At lower output levels, IMXO and QMXO, can
drive a lower load resistance, subject to the same current limit.
RF Section Ground
RF Input. RFIN must be ac-coupled to ground. The RF input signal should be ac-coupled into
RFIP. For a broadband 50 Ω input impedance, connect a 200 Ω resistor from the signal side of
RFIP’s coupling capacitor to ground. Please note that RFIN and RFIP are not interchangeable
differential inputs. RFIN is the ground reference for the input system.
Positive Supply for RF Section. This pin should be decoupled with 0.1 µF and 100 pF capacitors.
I Channel and Q Channel Offset Nulling Inputs. To null the dc-offset on the I Channel and
Q Channel Mixer Outputs (IMXO, QMXO), connect a 0.1 µF capacitor from these pins to
ground. Alternately, a forced voltage of approximately 1 V on these pins will disable the offset
compensation circuit.
Reference Voltage Output. This output voltage (1 V) is the main bias level for the device and
can be used to externally bias the inputs and outputs of the baseband amplifiers.
Chip Enable Input. Active high.
Gain Control Input. The voltage on this pin controls the gain on the RF and baseband VGAs.
The gain control is applied in parallel to all VGAs. The gain control voltage range is from 0.2 V
to 1.2 V and corresponds to a gain range from +39.5 dB to –30 dB. This is the gain to the output
of the baseband VGAs (i.e., QMXO and IMXO). There is an additional 30 dB of gain in the
baseband amplifiers. Note that the gain control function has a negative sense (i.e., increasing
control voltage decreases gain). In AGC mode, this pin is connected directly to VAGC.
Detector Inputs. These pin are the inputs to the on-board detector. VDT2 and VDT1, which
have high input impedances, are normally connected to IMXO and QMXO respectively.
AGC Output. This pin provides the output voltage from the on-board detector. In AGC mode,
this pin is connected directly to VGIN.
Positive Supply for Biasing and Baseband Sections. This pin should be decoupled with 0.1 µF
and 100 pF capacitors.
Q Channel Baseband Amplifier Input. This pin, which has a high input impedance, should be
biased to VREF (approximately 1 V). If QAIN is connected directly to QMXO, biasing will be
provided by QMXO. If an ac-coupled filter is placed between QMXO and QAIN, this pin can
be biased from VREF through a 1 kΩ resistor. The gain from QAIN to the differential outputs
QOPN/QOPP is 30 dB.
Q Channel Differential Baseband Output. Typical output swing is equal to 1 V p-p differential.
The common-mode level on these pins is programmed by the voltage on VCMO.
LO Section Ground
–5–
AD8347
EQUIVALENT CIRCUITS
VPS1
VPS3
VPS3
LOIN
IOPP, IOPN,
QOPP, QOPN,
IMXO, QMXO
PHASE
SPLITTER
CONTINUES
VCMO
CURRENT MIRROR
LOIP
COM3
COM3
COM1
Circuit A
Circuit B
VPS3
Circuit C
VPS3
VPS2
IAIN
QAIN
IOFS
QOFS
RFIP
CURRENT MIRROR
RFIN
COM3
COM3
COM2
Circuit D
Circuit E
Circuit F
VPS3
VPS3
VPS3
VREF
VAGC
ENBL
COM3
COM3
Circuit G
COM3
Circuit H
Circuit I
Figure 2. Equivalent Circuits
–6–
REV. 0
Typical Performance Characteristics– AD8347
RF AMP AND DEMODULATOR
TA = –40ⴗC
35
30
25
20
TA = +85ⴗC
2.5
10
8
6
15
10
4
2
0
TA = –40ⴗC
TA = +25ⴗC
–10
–15
–20
–2
–4
2.0
VS = 2.7V, TA = +25ⴗC
GAIN – dB
TA = +25ⴗC
5
0
–5
TA = +85ⴗC
0.3
0.4
0.5
–8
0.6
0.7
0.8
VGIN – V
0.9
1.0
1.1
VS = 2.7V, TA = +85ⴗC
–1.0
800
8
6
4
TA = –40ⴗC
2
0
–2
TA = +25ⴗC
–4
TA = +85ⴗC
0.3
0.4
0.6
0.7
0.8
VGIN – V
0.9
1.0
1.1
VS = 5V, TA = –40ⴗC
–33
–36
–10
1.2
–37
800
41
VS = 2.7V, TA = +25ⴗC
40
VS = 5V,
TA = +25ⴗC
39
37
38
GAIN – dB
VS = 5V, TA = –40ⴗC
36
1000 1200 1400 1600 1800 2000 2200 2400 2600
RF FREQUENCY – MHz
TPC 5. Gain vs. FLO, VGIN = 1.2 V, FBB = 1 MHz
42
VS = 2.7V, TA = –40ⴗC
VS = 2.7V, TA = +25ⴗC
VS = 2.7V, TA = +85ⴗC
–35
35
–32
VS = 5V, TA = +85ⴗC
TPC 2. Gain and Linearity Error vs. VGIN, VS = 2.7 V,
FLO = 1900 MHz, FBB = 1 MHz
38
–31
–34
–8
0.5
VS = 2.7V, TA = –40ⴗC
–30
–6
–25
–30
–35
0.2
VS = 5V,
TA = +25ⴗC
VS = 2.7V, TA = +25ⴗC
–29
GAIN – dB
TA = +25ⴗC
TA = +85ⴗC
–10
–15
–20
GAIN – dB
–28
LINEARITY ERROR – dB
MIXER GAIN – dB
–27
12
10
5
0
–5
VS = 2.7V, TA = +85ⴗC
34
VS = 5V, TA = +85ⴗC
VS = 5V,
TA = +25ⴗC
37
36
VS = 2.7V, TA = –40ⴗC
VS = 2.7V, TA = +85ⴗC
35
VS = 5V, TA = –40ⴗC
34
33
VS = 5V, TA = +85ⴗC
33
32
32
31
31
30
800
30
1000 1200 1400 1600 1800 2000 2200 2400 2600
RF FREQUENCY – MHz
TPC 3. Gain vs. FLO, VGIN = 0.2 V , FBB = 1 MHz
REV. 0
1000 1200 1400 1600 1800 2000 2200 2400 2600
RF FREQUENCY – MHz
TPC 4. Gain vs. FLO, VGIN = 0.7 V, FBB = 1 MHz
14
15
10
39
VS = 5V, TA = +85ⴗC
–0.5
–12
1.2
TA = –40ⴗC
VS = 5V,
TA = +25ⴗC
VS = 5V, TA = –40ⴗC
–10
45
40
40
VS = 2.7V, TA = –40ⴗC
1.0
0
TPC 1. Gain and Linearity Error vs. VGIN, VS = 5 V,
FLO = 1900 MHz, FBB = 1 MHz
35
30
25
20
1.5
0.5
–6
–25
–30
–35
0.2
12
LINEARITY ERROR – dB
MIXER GAIN – dB
3.0
14
45
40
1
10
BASEBAND FREQUENCY – MHz
100
TPC 6. Gain vs. FBB, VGIN = 0.2 V, FLO = 1900 MHz
–7–
AD8347
10
9
15
VS = 2.7V,
T = +85ⴗC
14
A
8
VS = 2.7V, TA = +85ⴗC
6
5
IIP3 – dBm
GAIN – dB
12
VS = 5V, TA = +85ⴗC
4
VS = 2.7V, TA = +25ⴗC
3
2
1
VS = 5V,
TA = +25ⴗC
0
VS = 2.7V, TA = –40ⴗC
–2
10
BASEBAND FREQUENCY – MHz
9
–10
–12
VS = 2.7V, TA = –40ⴗC
–27
IIP3 – dBm
GAIN – dB
–30
VS = 5V,
TA = –40ⴗC
–31
–32
VS = 2.7V,
TA = +85ⴗC
VS = 2.7V,
TA = +25ⴗC
–18
–20
–22
VS = 2.7V, TA = –40ⴗC
–24
–33
VS = 5V, TA = –40ⴗC
VS = 5V, TA = +85ⴗC
–26
–34
VS = 5V, TA = +85ⴗC
–28
1
–30
800
100
10
BASEBAND FREQUENCY – MHz
TPC 8. Gain vs. FBB, VGIN = 1.2 V, FLO = 1900 MHz
0
15
VS = 2.7V, TA = +85ⴗC
VS = 2.7V, TA = –40ⴗC
14
VS = 5V,
TA = +85ⴗC
–10
VS = 5V, TA = +85ⴗC
VS = 5V,
TA = –40ⴗC
–20
IIP3 – dBm
–15
1000 1200 1400 1600 1800 2000 2200 2400 2600
RF FREQUENCY – MHz
TPC 11. IIP3 vs. FLO, VGIN = 0.2 V, FBB = 1 MHz,
–5
INPUT P1dB – dBm
VS = 2.7V,
TA = +85ⴗC
VS = 5V, TA = +25ⴗC
–16
–29
–35
–14
VS = 2.7V,
TA = +25ⴗC
VS = 5V,
TA = +25ⴗC
1000 1200 1400 1600 1800 2000 2200 2400 2600
RF FREQUENCY – MHz
TPC 10. IIP3 vs. FLO, VGIN = 1.2 V, FBB = 1 MHz
–28
VS = 2.7V, TA = +25ⴗC
5
800
100
TPC 7. Gain vs. FBB, VGIN = 0.7 V, FLO = 1900 MHz
–25
10
6
–4
1
VS = 2.7V, TA = –40ⴗC
VS = 5V, TA = –40ⴗC
7
VS = 5V, TA = –40ⴗC
–3
11
8
–1
–26
VS = 5V, TA = +25ⴗC
13
7
–5
VS = 5V, TA = +85ⴗC
VS = 5V,
TA = +25ⴗC
VS = 2.7V, TA = +85ⴗC
13
12
–25
VS = 2.7V,
TA = +25ⴗC
–30
VS = 2.7V,
TA = +25ⴗC
VS = 2.7V, TA = –40ⴗC
–35
0.20
10
0.30
0.40
0.50
VS = 5V, TA = +25ⴗC
11
0.60
0.70 0.80
VGIN – V
0.90
1.00
1.10
1.20
TPC 9. Input 1 dB Compression Point (OP1 dB) vs. VGIN,
FLO = 1900 MHz, FBB = 1 MHz
VS = 5V, TA = –40ⴗC
0 5 10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85 90 95 100
BASEBAND FREQUENCY – MHz
TPC 12. IIP3 vs. FBB, VGIN = 1.2 V, FLO = 1900 MHz
–8–
REV. 0
AD8347
70
VS = 5V, TA = +85ⴗC
–16
IIP3 – dBm
5
VS = 2.7V, TA = +85ⴗC
–18
–20
VS = 5V, TA = +25ⴗC
–22
–24
VS = 5V, TA = –40ⴗC
–26
VS = 2.7V,
TA = +25ⴗC
–28
50
0
40
–5
30
10
0
0.2
0 5 10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85 90 95 100
BASEBAND FREQUENCY – MHz
2.5
QUADRATURE PHASE ERROR – Degrees
45
IIP2 – dBm
40
35
30
25
0.4
0.5
0.6
VGIN – V
0.7
0.8
0.9
–30
1.0
1.5
1.0
0.5
LO FREQUENCY = 2700MHz
0
–0.5
–1.0
–1.5
LO FREQUENCY = 800MHz
LO FREQUENCY = 1900MHz
–2.0
–18
–16
–14 –12 –10
–8
–6
LO INPUT LEVEL – dBm
–4
–2
0
TPC 17a. Quadrature Error vs. LO Power Level,
Temperature = 25 ⴗC, VGIN = 0.2 V, VS = 5 V
14.0
13.5
12.5
13.0
NOISE FIGURE – dB
NOISE FIGURE – dB
2.0
–2.5
–20
1000 1200 1400 1600 1800 2000 2200 2400 2600
RF FREQUENCY – MHz
TPC 14. IIP2 vs. FLO, VGIN = 1.2 V, Baseband
Tone1 = 5 MHz, –10 dBm, Baseband Tone2 = 6 MHz,
–10 dBm, Temperature = 25 ⴗC, VS = 5 V
13.0
0.3
–25
VS =2.7V
VS = 5V
TPC 16. Noise Figure and IIP3 vs. VGIN,
Temperature = 25 ⴗC, FLO = 1900 MHz, FBB = 1 MHz
20
800
–15
VS = 2.7V
20
–20
VS = 2.7V,
TA = –40ⴗC
TPC 13. IIP3 vs. FBB, VGIN = 0.2 V, FLO = 1900 MHz
50
–10
VS = 5V
–32
–34
10
60
–14
–30
15
12.0
11.5
11.0
12.5
2700MHz
12.0
11.5
1900MHz
11.0
10.5
VS = 5V
10.5
VS = 2.7V
10.0
800MHz
9.5
10.0
800
9.0
–20
1000 1200 1400 1600 1800 2000 2200 2400 2600
LO FREQUENCY – MHz
TPC 15. Noise Figure vs. LO Frequency (FLO),
Temperature = 25 ⴗC, VGIN = 0.2 V, FBB = 1 MHz
REV. 0
–18
–16
–14 –12 –10
–8
–6
LO INPUT LEVEL – dBm
–4
–2
TPC 17b. Noise Figure vs. LO Input Level,
Temperature = 25 ⴗC, VGIN = 0.2 V, VS = 5 V
–9–
0
IIP3
–12
NOISE FIGURE – dB
–10
AD8347
BASEBAND OUTPUT AMPLIFIERS
20
TA = –40ⴗC, VS = 5V
32
BASEBAND AMPLIFIER OUTPUT IP3 – dBV rms
34
TA = –40ⴗC, VS = 2.7V
30
TA = +25ⴗC, VS = 5V
GAIN – dB
28
TA = +85ⴗC, VS = 2.7V
26
24
TA = +25ⴗC, VS = 2.7V
TA = +85ⴗC, VS = 5V
22
20
18
16
1
10
BASEBAND FREQUENCY – MHz
15
VS = 5V, TA = 25ⴗC
10
VS = 2.7V, TA = +25ⴗC
5
VS = 2.7V,
TA = +85ⴗC
0
–5
–20
–25
–30
COMMON-MODE OFFSET – mV
OP1 – dBV rms
TA = +25ⴗC, VS = 2.7V
TA = +85ⴗC, VS = 2.7V
–15
VS = 2.7V, MEAN + ␴
6
TA = –40ⴗC, VS = 2.7V
–10
100
TPC 20. OIP3 vs. FBB, VVCMO = 1 V
TA = +25ⴗC,
VS = 5V
–5
10
BASEBAND FREQUENCY – MHz
1
100
TA = +85ⴗC, VS = 5V
0
VS = 2.7V, TA = –40ⴗC
–15
8
TA = –40ⴗC, VS = 5V
VS = 5V,
TA = +85ⴗC
–10
TPC 18. Gain vs. FBB, VVCMO = 1 V
5
VS = 5V, TA = –40ⴗC
–20
VS = 2.7V, MEAN
4
VS = 5V, MEAN
VS = 5V,
MEAN + ␴
2
0
–2
VS = 2.7V, MEAN – ␴
–4
VS = 5V, MEAN – ␴
–6
0.5
–25
1
10
BASEBAND FREQUENCY – MHz
TPC 19. OP1 vs. FBB, VVCMO = 1 V
100
1.0
1.5
2.0
VVCMO – V
2.5
3.0
3.5
TPC 21. Common-Mode Output Offset Voltage vs. VVCMO,
Temperature = 25 ⴗC (␴ = 1 Standard Deviation)
–10–
REV. 0
AD8347
RF AMP/DEMOD AND BASEBAND OUTPUT AMPLIFIERS
65
1.0
VS = 2.7V, TA = –40ⴗC
VS = 5V, TA = –40ⴗC
VS = 2.7V, TA = +25ⴗC
VS = 5V, TA = +25ⴗC
VOLTAGE GAIN – dB
55
0.8
I TO Q AMPLITUDE MISMATCH – dB
75
VS = 2.7V,
TA = +85ⴗC
45
35
VS = 5V, TA = +85ⴗC
25
15
5
0.6
0.4
0.2
0.3
–0.2
0.4
0.5
0.6
0.7
0.8
VGIN – V
0.9
1.0
1.1
–1.0
1.2
0
1.0
0.5
VS = 5V, TA = +25ⴗC
0
–0.5
–1.0
VS = 5V, TA = +85ⴗC
VS = 5V, TA = –40ⴗC
35
40
–4
–6
RF WITH TERMINATION
–8
–10
RF WITHOUT TERMINATION
–12
800
1000 1200 1400 1600 1800 2000 2200 2400 2600
RF FREQUENCY – MHz
TPC 23. Quadrature Phase Error vs. FLO, VVGIN = 0.7 V,
VS = 5 V
2.0
10
15
20
25
30
BASEBAND FREQUENCY – MHz
–2.0
2.5
5
–2
1.5
–1.5
0
TPC 25. I/Q Amplitude Imbalance vs. FBB,
Temperature = 25 ⴗC, VS = 5 V
RETURN LOSS – dBm
QUADRATURE PHASE ERROR – Degrees
TA = –40ⴗC
–0.6
–2.5
800
QUADRATURE PHASE ERROR – Degrees
TA = +25ⴗC
–0.4
TPC 22. Voltage Gain vs. VVGIN, FLO = 1900 MHz,
FBB = 1 MHz
2.0
TA = +85ⴗC
0
–0.8
–5
0.2
2.5
1000 1200 1400 1600 1800 2000 2200 2400 2600
RF FREQUENCY – MHz
TPC 26. Return Loss of RFIP vs. FRF, VVGIN = 0.7 V, VS = 5 V
1.5
1.0
0.5
2.7GHz
0
TA = +85ⴗC
WITH TERMINATION
800MHz
–0.5
TA = +25ⴗC
–1.0
TA = –40ⴗC
2.7GHz
–1.5
800MHz
WITHOUT TERMINATION
–2.0
–2.5
0
5
10
15
20
25
30
BASEBAND FREQUENCY – MHz
35
40
TPC 24. Quadrature Phase Error vs. FBB, VVGIN = 0.7 V,
VS = 5 V
REV. 0
TPC 27. S11 of RFIN vs. FRF, VVGIN = 0.7 V, VS = 5 V
–11–
AD8347
30
TA = –40ⴗC
A
MIXER OUTPUT VOLTAGE – mV p-p
–2
LO PORT WITHOUT TERMINATION
RETURN LOSS – dBm
1.20
T = +85ⴗC
–4
–6
–8
–10
–12
25
1.00
TA = +25ⴗC
20
0.80
TA = +85ⴗC
TA = +25ⴗC
15
0.60
TA = –40ⴗC
10
0.40
5
0.20
AGC VOLTAGE – V
0
LO PORT WITH TERMINATION
–14
800
0
–70
1000 1200 1400 1600 1800 2000 2200 2400 2600
RF FREQUENCY – MHz
TPC 28. Return Loss of LOIP vs. FLO, VVGIN = 0.7 V, VP = 5 V
–50
–40
–30
–20
–10
RF INPUT POWER – dBm
0
10
0
TPC 30. AGC Voltage and Mixer Output Level vs. RF Input
Power, FLO = 1900 MHz, FBB = 1 MHz, VS = 5 V
85
80
WITH TERMINATION
SUPPLY CURRENT – mA
800MHz
2.7GHz
–60
2.7GHz
75
VP = 5V
70
VP = 5.5V
65
60
VP = 3V
55
800MHz
VP = 2.7V
50
WITHOUT TERMINATION
45
–40 –30 –20 –10
TPC 29. S11 of LOIN vs. FLO, VVGIN = 0.7 V, VS = 5 V
0
10 20 30 40
TEMPERATURE – ⴗC
50
60
70
80
TPC 31. Supply Current vs. Temperature, VVGIN = 0.7 V,
VVCMO = 1 V
–12–
REV. 0
AD8347
VPS1
VPS2
VPS3
VREF
IMXO IOFS
AD8347
IOPP
IOPN
VREF
BIAS
CELL
ENBL
IAIN
VCMO
VREF
VCMO
RFIN
PHASE
SPLITTER
1
PHASE
SPLITTER
2
RFIP
VCMO
LOIN
LOIP
COM3
COM2
VGIN
GAIN
CONTROL
INTERFACE
DET 1
COM3
DET 2
VREF
VDT1 VAGC VDT2
QMXO QOFS
QAIN
COM1
QOPP
QOPN
Figure 3. Block Diagram
CIRCUIT DESCRIPTION
OVERVIEW
The AD8347 is a direct I/Q demodulator usable in digital
wireless communication systems including Cellular, PCS, and
Digital Video receivers. An RF signal in the frequency range of
800 MHz–2700 MHz is directly downconverted to the I & Q
components at baseband using a Local Oscillator (LO) signal at
the same frequency as the RF signal.
The RF input signal goes through two stages of variable gain
amplifiers before splitting up to reach two Gilbert-cell Mixers.
The mixers are driven by a pair of Local Oscillator (LO)
signals which are in quadrature (90 degrees of phase difference).
The outputs of the mixers are applied to baseband I & Q channel
variable-gain amplifiers. The outputs from these baseband
variable gain amplifiers are brought out to pins for external
filtering. The filter outputs are then applied to a pair of on-chip,
fixed-gain baseband amplifiers. These amplifiers gain up the
outputs from the external filters to a level compatible with most
A-to-D Converters. A sum-of-squares detector is available for
use in an Automatic Gain Control (AGC) loop to set the output
level. The RF and baseband amplifiers provide approximately
69.5 dB of gain control range. Additional on-chip circuits allow
the setting of the dc level at the I & Q channel baseband outputs, as well as nulling the dc offset at each channel.
RF Variable Gain Amplifiers (VGA)
These amplifiers use the patented X-AMP approach with NPNdifferential pairs separated by sections of resistive attenuators.
The gain control is achieved through a gaussian interpolator
where the control voltage sets the tail currents to be supplied to
the different differential pairs according to the gain desired. In
the first amplifier, the combined output currents from the transconductance cells go through a cascode stage to resistive loads
with inductive peaking. In the second amplifier the differential
currents are split and fed to the two Gilbert-cell mixers through
separate cascode stages.
Mixers
Two double balanced Gilbert-cell mixers, one for each channel,
perform the In-phase (I) and Quadrature (Q) down conversion.
Each mixer has four cross-connected transistor pairs which are
X-AMP is a registered trademark of Analog Devices, Inc.
REV. 0
terminated in resistive loads and feed the differential baseband
variable gain amplifiers for each channel. The bases of the mixer
transistors are driven by the quadrature LO signals.
Baseband Variable Gain Amplifiers
The baseband VGA’s also use the X-AMP approach with NPNdifferential pairs separated by sections of resistive attenuators.
The same interpolator controlling the RF amplifiers controls the
tail currents of the differential pairs. The outputs of these amplifiers are provided off chip for external filtering. Automatic offset
nulling minimizes the dc offsets at both I & Q channels. The
common-mode output voltage is set to be the same as the reference
voltage (1.0 V) generated in the Bias section, also made available
at the VREF pin.
Output Amplifiers
The output amplifiers gain up the signal coming back from each
of the external filters to a level compatible with most high speed
A-to-D converters. These amplifiers are based on an active-feedback
design to achieve the high gain bandwidth and low distortion.
LO and Phase-Splitters
The incoming LO signal is applied to a polyphase phase-splitter
to generate the LO signals for the I channel and Q channel
mixers. The polyphase phase-splitters are RC networks connected in a cyclical manner to achieve gain balance and phase
quadrature. The wide operating frequency range of these phasesplitters is achieved by cascading multiple sections of these
networks with staggered RC constants. Each branch goes through
a buffer to make up for the loss and high frequency roll-off. The
output from the buffers then go into another polyphase phasesplitter to enhance the accuracy of phase quadrature. Each LO
signal gets buffered again to drive the mixers.
Output Level Detector
Two signals proportional to the square of each output channel
are summed together and compared to a built-in threshold to
create an AGC voltage (VAGC). The inputs to this rms detector
are referenced to VREF.
Bias
An accurate reference circuit generates the reference currents
used by the different sections. The reference circuit is controlled
by an external power-up (ENBL) logic signal which, when set
low, puts the whole chip into a sleep mode typically requiring
–13–
AD8347
less than 400 µA of supply current. The reference voltage (VREF)
of 1.0 V, which serves as the common-mode reference for the
baseband circuits, is made available for external use.
OPERATING THE AD8347
Basic Connections
Figure 4 shows the basic connections for operating the AD8347.
The device is powered through three power supply pins: VPS1,
VPS2, and VPS3. These pins supply current to different parts of
the overall circuit. VPS1 and VPS2 power the Local Oscillator (LO)
and RF sections, respectively, while VPS3 powers the baseband
amplifiers. While all of these pins should be connected to the same
supply voltage, each pin should be separately decoupled using two
capacitors. 100 pF and 0.1 µF are recommended (values close
to these may also be used).
A supply voltage in the range 2.7 V to 5.5 V should be used. The
quiescent current is 64 mA when operating from a 5 V supply.
By pulling the ENBL pin low, the device goes into its power- down
mode. The power-down current is 400 µA when operating on a
5 V supply and 80 µA on a 2.7 V supply.
Like the supply pins, the individual sections of the circuit are
separately grounded. COM1, COM2, and COM3 provide ground
for the LO, RF, and baseband sections respectively. All of these
pins should be connected to the same low impedance ground.
RF Input and Matching
The RF input signal should be ac-coupled into the RFIP pin and
RFIN should be ac-coupled to ground. To improve broadband
matching to a 50 Ω source, a 200 Ω resistor may be connected
from the signal side of RFIP’s coupling capacitor to ground.
LO Drive Interface
For optimum performance the LO inputs, LOIN and LOIP,
should be driven differentially. M/A-COM balun, ETC1-1-13
is recommended. Unless an (ac-coupled) transformer is being
used to generate the differential LO, the inputs must be ac-coupled
as shown. To improve broadband matching to a 50 Ω source, a
200 Ω shunt resistor may be connected between LOIP and LOIN.
An LO drive level of –8 dBm is recommended. TPC 17a shows
the relationship between LO drive level, LO frequency, and
quadrature error for a typical device.
A single-ended drive is also possible as shown in Figure 5, but
this will slightly increase LO leakage. The LO signal should be
applied through a coupling capacitor to LOIP, and LOIN should
be ac-coupled to ground. Because the inputs are fully differential, the drive orientation can be reversed. As in the case of the
differential drive, a 200 Ω resistor connected across LOIP and
LOIN improves the match to a 50 Ω source.
+VS
(2.7V–5.5V)
IOPP
24mV p-p
(AGC MODE)
1V BIAS (VREF)
C9
C10
C5
C6
C7
C8
0.1␮F 100pF 0.1␮F 100pF 0.1␮F 100pF
760mV p-p
DIFFERENTIAL
(AGC MODE)
VCM = 1V
C13
0.1␮F
VPS1
VPS3
VPS2
IOFS
IMXO
VREF
AD8347
ENBL
IOPN
IOPN
VREF
VREF
BIAS
CELL
IOPP
IAIN
VCMO
C1
100pF
RFIN
R1
200⍀
RF INPUT
0.8GHz–2.7GHz
0dBm MAX
(AGC MODE)
LOIN
PHASE
SPLITTER
2
RFIP
C2
100pF
LO INPUT
–8dBm
0.8GHz–2.7GHz
C4
100pF
VCMO
PHASE
SPLITTER
1
LOIP
COM3
VCMO
3
4
1
5
R17
200⍀
T1
C3
ETC 1-1-13
100pF (M/A-COM)
COM2
VGIN
GAIN
CONTROL
INTERFACE
COM3
DET 1
DET 2
VREF
COM1
QOPN
VDT1 VAGC VDT2
C15
0.1␮F
QOFS
C14
0.1␮F
QMXO
QAIN
24mV p-p
(AGC MODE)
1V BIAS (VREF)
QOPP
QOPN
760mV p-p
DIFFERENTIAL
(AGC MODE)
VCM = 1V
QOPP
Figure 4. Basic Connections
–14–
REV. 0
AD8347
Mixer Output Level and Drive Capability
100pF
LOIN
LO
200⍀
I & Q channel baseband outputs, IMXO and QMXO are low
impedance outputs (ROUT @ 3 Ω) whose bias level is equal to
VVREF, the voltage on Pin 14. The achievable output level on
IMXO/QMXO is limited by their current drive capability of
1.5 mA max. This would allow for a 600 mV p-p swing into a
200 Ω load. At lower output levels, IMXO and QMXO can
drive smaller load resistances, subject to the same current limit.
These output stages are not, however, designed to drive 50 Ω
loads directly.
AD8347
LOIP
100pF
Figure 5. Single-Ended LO Drive
Operating the VGA
A three-stage VGA sets the gain in the RF section. Two of the
three stages come before the mixer while the third amplifies the
mixer output. All three stages are driven in parallel. The gain
range of the first RF VGA and that of the second RF VGA
combined with the mixer are both –13 dB to +10 dB. The
gain range of the baseband VGA is –4 dB to +19.5 dB. So the
overall gain range from the RF input to the IMXO/QMXO pins
is –30 dB to approximately +39.5 dB.
Operating the VGA in AGC Mode
While the VGA can be driven by an external source such as a
DAC, the AD8347 has an on-board sum of squares detector
which allows the AD8347 to operate in an automatic leveling
mode. The connections for operating in this mode are shown in
Figure 4. The two mixer outputs are connected to the detector
inputs VDT1 and VDT2. The summed detector output drives
an internal integrator which in turn delivers a gain correction
voltage to the VAGC pin. A 0.1 µF capacitor from VAGC to
ground sets the dominant pole of the integrator circuit. VAGC,
which should be connected to VGIN, adjusts gain until an
internal threshold is reached. This threshold corresponds to a level
at the IMXO/QMXO pins of approximately 8.5 mV rms. This
level will change slightly as a function of RF input power (see
TPC 30). For a CW (sine wave) input this corresponds to
The gain of the VGA is set by the voltage on the VGIN pin,
which is a high impedance input. The gain control function
(which is linear-in-dB) and linearity are shown in TPC 1 and
TPC 2 at 1.9 GHz. Note that the sense of the gain control
voltage is negative so as the gain control voltage ranges from 0.2 V
to 1.2 V, the gain decreases from +39.5 dB to –30 dB.
R19
1k⍀
+VS +5V
R20
4k⍀
C9
C10
C5
C6
C7
C8
0.1␮F 100pF 0.1␮F 100pF 0.1␮F 100pF
2.5V
IOPP
120mV p-p
1V BIAS
3.8V p-p
DIFFERENTIAL
VCM = 2.5V
C13
0.1␮F
VPS1
VPS3
VPS2
IMXO
VREF
IOFS
AD8347
ENBL
IOPP
IOPN
IOPN
VREF
VREF
BIAS
CELL
IAIN
VCMO
C1
100pF
RFIN
R1
200⍀
RF
INPUT
LOIN
PHASE
SPLITTER
2
RFIP
C2
100pF
LO INPUT
–8dBm
0.8GHz–2.7GHz
C4
100pF
VCMO
PHASE
SPLITTER
1
3
COM3
VCMO
4
R17
200⍀
LOIP
1
5
T1
C3
ETC 1-1-13
100pF (M/A-COM)
COM2
VGIN
GAIN
CONTROL
INTERFACE
COM3
DET 1
DET 2
COM1
VREF
QOPN
VDT1 VAGC VDT2
QMXO
R21
4k⍀
QOFS
C14
0.1␮F
QAIN
QOPP
QOPN
120mV p-p
1V BIAS
3.8V p-p
DIFFERENTIAL
VCM = 2.5V
R22
1k⍀
QOPP
Figure 6. Adjusting AGC Level to Increase Baseband Amplifier Output Swing
REV. 0
–15–
AD8347
approximately 24 mV p-p. If this signal is applied directly to the
subsequent baseband amplifier stage, the final baseband output
is 760 mV p-p differential. (See Baseband Amplifier section.)
The differential output offset voltages of the baseband amplifiers
are typically ± 50 mV. This offset voltage results from both input
and output effects.
If the VGA gain is being set from an external source, the on-board
detector inputs (VDT1 and VDT2) are not used and should be
tied to VREF.
The overall signal-to-noise ratio can be improved by increasing
the VGA gain by driving it with an external voltage or by changing
the setpoint of the AGC circuit. (See Changing the AGC Setpoint.)
Note that in subsequent sections, peak-to-peak calculations
assume a sine wave input. If the input signal has a higher peakto-average ratio, the mixer output peak-to-peak voltage at which
the AGC loop settles will be higher.
Driving Capacitive Loads
Changing the AGC Setpoint
The AGC circuit can be easily set up to level at voltages higher
than the nominal 24 mV p-p as shown in Figure 6. The voltages
on Pins IMXO and QMXO are attenuated before being applied
to the detector inputs. In the example shown, an attenuation
factor of 0.2 (–14 dB) between IMXO/QMXO and the detector
inputs, will cause the VGA to level at approximately 120 mV p-p
(note that resistor divider network must be referenced to VVREF).
This results in a peak-to-peak output swing at the baseband
amplifier outputs of 3.8 V differential, that is, 1.6 V to 3.4 V on
each side. Note that VVCMO has been increased to 2.5 V to avoid
signal clipping at the baseband outputs. Due to the attenuation
between the mixer output and the detector input, the variation
in the settled mixer output level, versus RF input power, will be
greater than the variation shown in TPC 30. The variation will
be greater by a factor equal to the inverse of the attenuation factor.
Baseband Amplifiers
The final baseband amplifier stage takes the signals from IMXO/
QMXO and amplifies them by 30 dB, or a factor of 31.6. This
results in a maximum system gain of 69.5 dB. When the VGA is
in AGC mode, the baseband I & Q outputs (IOPN, IOPP,
QOPN, and QOPP) deliver a differential voltage of approximately 760 mV p-p (380 mV p-p on each side).
In applications where the baseband amplifiers are driving unbalanced capacitive loads, some series resistance should be placed
between the amplifier and the capacitive load. For example, for
a 10 pF load, four 220 Ω series resistors (one in each baseband
output) should be used.
External Baseband Amplification
The baseband output offset voltage and noise can be reduced by
bypassing the internal baseband amplifiers and amplifying the
mixer output signal using a high quality differential amplifier. In
the example shown in Figure 7, two AD8132 differential amplifiers are used to gain the mixer output signals up by 20 dB. In this
example, the setpoint of the AGC circuit has been increased so that
the input to the external amplifiers is approximately 72 mV p-p.
This results in final baseband output signals of 720 mV p-p.
The closed-loop bandwidth of the amplifiers in Figure 7 is equal
to roughly 20 MHz. Higher bandwidths are achievable, but at
the cost of lower closed-loop gain. In Figure 7, the output common
mode levels (VOCM, Pin 2) of the differential amplifiers are set
by the AD8347’s VREF (approximately 1 V). The output common
mode levels can also be set externally (e.g., by the reference voltage
from an ADC).
The single-ended input signal to the baseband amplifiers is
applied at the high impedance inputs IAIN and QAIN. As can
be seen in Figure 4, the baseband amplifier operates internally
as a differential amplifier, with the second input being driven by
VVREF. As a result, the input signal to the baseband amplifier
should be biased at VVREF.
The output common-mode level of the baseband amplifiers is
set by the voltage on Pin 5, VCMO. This pin can either be
connected to VREF (Pin 14) or to an external reference voltage
from a device such as an analog-to-digital converter (ADC).
VVCMO has a nominal range from 0.5 V to 2.5 V. However, since
the baseband amplifiers can only swing down to 0.4 V, higher
values of VVCMO will generally be required to avoid low-end
signal clipping. On the other hand, the positive swing at each
output is limited to 1.3 V below the supply voltage. So the max
p-p swing is given by 2 ⫻ (VPS – 1.3 – 0.4) V differentially.
For example, in order for the baseband output amplifier to be able
to deliver an output swing of 2 V p-p (1 V p-p on each side),
VVCMO must be in the range from 0.9 V to 2.5 V.
+5V
R19A
4.99k⍀
AD8347
72mV p-p
IMXO
VDT1
VREF
0.1␮F
10␮F
R17A
499⍀
R22
20k⍀
AD8132
R23
10k⍀
720mV p-p
DIFFERENTIAL
VCM = 1V
R18A
499⍀
4.99k⍀
R20A
0.1␮F
10␮F
–5V
+5V
R24
10k⍀
4.99k⍀
R19B
VDT2
R25
20k⍀
0.1␮F
10␮F
R17B
499⍀
QMXO
72mV p-p
R18B
499⍀
AD8132
4.99k⍀
R20B
0.1␮F
720mV p-p
DIFFERENTIAL
VCM = 1V
10␮F
–5V
Figure 7. External Baseband Amplification Example
–16–
REV. 0
AD8347
Filter Design Considerations
50
Baseband low-pass or band-pass filtering can be conveniently
performed between the mixer outputs (IMXO/QMXO) and the
input to the baseband amplifiers. Because the output impedance
of the mixer is low (roughly 3 Ω) and the input impedance of
the baseband amplifier is high, it is not practical to design a
filter which is reactively matched to these impedances. An LC
filter can be matched by placing a series resistor at the mixer
output and a shunt resistor (terminated to VVREF) at the input to
the baseband amplifier.
45
GROUP DELAY – ns
40
Because the mixer output drive level is limited to a maximum current of 1.5 mA, the characteristic impedance of the filter should be
greater than 50 Ω, especially if larger signal swings are to be achieved.
Figure 8 shows the schematic for a 100 Ω, fourth order elliptic
low-pass filter with a 3 dB cutoff frequency of 20 MHz. Source
and load impedances of approximately 100 Ω ensure that the
filter sees a matched source and load. This also ensures that the
mixer output is driving an overall load of 200 Ω. Note that the
shunt termination resistor is tied to VREF and not to ground.
The frequency response and group delay of this filter are shown
in Figures 9 and 10.
C1
4.7pF
RS
95.3⍀
L1
R3
0.68␮H 2⍀
C3
8.2pF
L3
1.2␮H
C2
150pF
IMXO
R4
2⍀
C4
82pF
VREF
AD8347
RL
100⍀
IAIN
VDT1
(SEE
TEXT)
Figure 8. Typical Baseband Low-Pass Filter
30
25
20
15
10
5
0
1
10
FREQUENCY – MHz
100
Figure 10. Group Delay of 20 MHz Baseband Low-Pass
Filter
If the VGA is operating in AGC mode, the detector input (VDT1/
VDT2) can be tied either to the input or output of the filter.
Connecting the detector input to the input of the filter (i.e.,
IMXO and QMXO) will cause the VGA leveling point to be
determined by the composite of the wanted signal and any unfiltered
components such as blockers or signal harmonics. Connecting
VDT1/VDT2 to the outputs of the filters ensures that the leveling
point of the AGC circuit is based upon the amplitude of the
filtered output only. The latter option is more desirable as it
results in a more constant baseband output. However, when
using this method, the leveling point of the AGC should be set
so that out-of-band blockers do not overdrive the mixer output.
DC Offset Compensation
Feedthrough of the LO signal to the RF input port results in
self-mixing of the LO signal. This produces a dc component
at the mixer output that is frequency-dependent.
The AD8347 includes an internal circuit which actively nulls
out any dc offsets that appear at the mixer output. The dc-bias
level of the mixer output (which should ideally be equal to VVREF,
the bias level for the baseband sections of the chip) is continually
being compared to VVREF. Any differences between the mixer
output level and VVREF, will force a compensating voltage on to
the mixer output.
0
–10
–20
ATTENTUATION – dB
35
–30
The time constant of this correction loop is set by the capacitors
which are connected to pins IOFS and QOFS (each output can
be compensated separately). For normal operation 0.1 µF capacitors
are recommended. The corner frequency of the compensation
loop is given approximately by the equation
–40
–50
–60
–70
–80
1
10
FREQUENCY – MHz
f 3 dB =
100
Figure 9. Frequency Response of 20 MHz Baseband
Low-Pass Filter
40
(C in µF )
COFS OFS
The corner frequency must be set to a frequency that is much
lower than the symbol rate of the demodulated data. This prevents
the compensation loop from falsely interpreting the data stream
as a changing offset voltage.
To disable the offset compensation circuits, IOFS and QOFS
should be tied to VREF.
REV. 0
–17–
AD8347
Evaluation Board
Figure 11 shows the schematic of the AD8347 evaluation board.
Note that uninstalled components are indicated with the “open”
designation. The board is powered by a single supply in the
range of 2.7 V to 5.5 V. Table I details the various configuration
options of the evaluation board.
TP1
J3
LO
+VS
J7
IMXO
L2
(OPEN)
C2
100pF
R6
0⍀
L1
(OPEN)
R8
(OPEN)
C18
(OPEN)
C22
(OPEN)
C4
(OPEN)
C20
(OPEN)
R39
(OPEN)
C19
(OPEN)
C21
(OPEN)
C11
100pF
C17
(OPEN)
J4
RFIP
LK5
R18
C12
200⍀ 100pF
LK1
+VS
C7
0.1␮F
TP2
C8
100pF
2
VPS1
COM1 27
3
IOPN
QOPN 26
4
IOPP
QOPP 25
5
VCMO
6
IAIN
COM3
7
COM3
QMXO 22
8
IMXO
VPS3 21
9
COM2
VDT1 20
RFIN
VAGC 19
QAIN 24
VPS2
VGIN 17
13
IOFS
QOFS 16
VREF
ENBL 15
R34
(OPEN)
LK4
C10
100pF
VDT2 18
RFIP
12
R33
0⍀
TP5
23
11
14
J2
QOPP
LOIN 28
LOIP
10
J1
QOPN
R38
0⍀
AD8347
1
L4
(OPEN)
L6
(OPEN)
L5
(OPEN)
C30
(OPEN)
C26
(OPEN)
C31
(OPEN)
+VS
C25
C9
0.1␮F LK6 (OPEN)
C29
(OPEN)
C28
(OPEN)
SW1
J9
VAGC
J10
VGIN
TP6
VPOS
A
J8
QMXO
C27
(OPEN)
C15
0.1␮F
R40
(OPEN) LK3
LK2
C13
0.1␮F
TP3
R37
0⍀
C3
100pF
R17
200⍀
C6
C5
0.1␮F 100pF
C1
0.1␮F
J11
VCMO
5 T1
ETC 1-1-13
1
3
R36
0⍀
J5
IOPP
L3
(OPEN)
4
R35
0⍀
J6
IOPN
C14
0.1␮F
B
C16
0.1␮F
Figure 11. Evaluation Board Schematic
–18–
REV. 0
AD8347
Figure 12. Silkscreen of Component Side
Figure 13. Layout of Component Side
REV. 0
Figure 14. Layout of Circuit Side
–19–
AD8347
Component
Function
Default Condition
TP1, TP4, TP5
TP2, TP6
TP3
LK1, J11
Power Supply and Ground Vector Pins
IOFS and QOFS Probe Points
VREF Probe Point
Baseband Amplifier Output Bias: Installing this link connects VREF
to VCMO. This sets the bias level on the baseband amplifiers to VREF,
which is equal to approximately 1 V. Alternatively, the bias level of the
baseband amplifiers can be set by applying an external voltage to SMA
connector J11.
AGC Mode: Installing LK2 and LK6 connects the mixer outputs IMXO
and QMXO to the detector inputs VDT2 and VDT1. By installing LK3,
which connects VGIN to VAGC, the AGC mode is activated. The AGC
voltage can be observed on SMA connector J9. With LK3 removed, the
gain control signal for the internal variable gain amplifiers should be
applied to SMA connector J10.
Baseband Filtering: Installing LK4 and LK5, connects the mixer
outputs IMXO and QMXO directly to the baseband amplifier inputs
IAIN and QAIN. With R6 and R33 installed (0 Ω), IAIN and QAIN
can be observed on SMA connectors J7 and J8. By removing LK4 and LK5
and installing R8 and R34, LC filters can be inserted between the
mixer outputs and the baseband amplifier inputs. R8 and R34 can be
used to increase the effective output impedance of IMXO and QMXO.
(These outputs have low output impedances.) R39 and R40 can be used
to provide terminations for the filter at IAIN and QAIN. (IAIN and QAIN
are high impedance inputs.) R39 and R40 are terminated to VREF.
Baseband Amplifier Output Series Resistors
Not Applicable
Not Applicable
Not Applicable
LK1 Installed
LK4, LK5
R6, R33,
L1–L5
C4, C17–C22, C25–C31
R8, R34, R39, R40
R35, R36, R37, R38
SW1
Device Enable: When in position A, the ENBL pin is connected to +VS
and the AD8347 is in operating mode. In position B, the ENBL pin is
grounded, putting the device in power-down mode.
LK2, LK6, LK3 Installed
LK4, LK5 Installed
R6 = R33 = 0 Ω (Size 0603)
L1–L5 = Open (Size 0805)
C4, C17–C22, C25–C31 =
Open (Size 0805)
R8 = R34 = Open (0603)
R39 = R40 = Open (0603)
R35 = R36 = R37 = R38 =
0 Ω (Size 0603)
SW1 = A
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
28-Lead TSSOP
(RU-28)
0.386 (9.80)
0.378 (9.60)
28
15
PRINTED IN U.S.A.
LK2, LK6, LK3, J9, J10
C02675–.8–10/01(0)
Table I. Evaluation Board Configuration Options
0.177 (4.50)
0.169 (4.30)
0.256 (6.50)
0.246 (6.25)
1
14
PIN 1
0.006 (0.15)
0.002 (0.05)
SEATING
PLANE
0.0433 (1.10)
MAX
0.0256 (0.65)
BSC
0.0118 (0.30)
0.0075 (0.19)
0.0079 (0.20)
0.0035 (0.090)
–20–
8ⴗ
0ⴗ
0.028 (0.70)
0.020 (0.50)
REV. 0