DC to 50 MHz, Dual I/Q Demodulator and
Phase Shifter
AD8333
Rev. B
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FEATURES
Dual integrated I/Q demodulator
16 phase select on each output (22.5° per step)
Quadrature demodulation accuracy
Phase accuracy: ±0.1°
Amplitude balance: ±0.05 dB
Bandwidth
4 LO: 100 kHz to 200 MHz
RF: dc to 50 MHz
Baseband: determined by external filtering
Output dynamic range: 159 dB/Hz
LO drive > 0 dBm (50 Ω); 4 LO > 1 MHz
Supply: ±5 V
Power consumption: 190 mW/channel (380 mW total)
Power down
APPLICATIONS
Medical imaging (CW ultrasound beamforming)
Phased array systems (radar and adaptive antennas)
Communication receivers
FUNCTIONAL BLOCK DIAGRAM
90°
0°
90°
0°
Φ
Φ
Φ
Φ
I1
Q1
Q2
I2
CH1
PHASE
SELECT
CH2
PHASE
SELECT
+
+
–
–
LOC
OSC ÷4
AD8333
CH1
RF
CH2
RF
05543-001
ENABLE
RESET
Figure 1.
GENERAL DESCRIPTION
The AD8333 is a dual-phase shifter and I/Q demodulator that
enables coherent summing and phase alignment of multiple
analog data channels. It is the first solid-state device suitable for
beamformer circuits, such as those used in high performance
medical ultrasound equipment featuring CW Doppler. The RF
inputs interface directly with the outputs of the dual-channel,
low noise preamplifiers included in the AD8332.
A divide-by-4 circuit generates the internal 0° and 90° phases
of the local oscillator (LO) that drive the mixers of a pair of
matched I/Q demodulators.
The AD8333 can be applied as a major element in analog
beamformer circuits in medical ultrasound equipment.
The AD8333 features an asynchronous reset pin. When used in
arrays, the reset pin sets all the LO dividers in the same state.
Sixteen discrete phase rotations in 22.5° increments can be
selected independently for each channel. For example, if CH1 is
used as a reference and the RF signal applied to CH2 has an I/Q
phase lead of 45°, CH2 can be phase aligned with CH1 by
choosing the correct code.
Phase shift is defined by the output of one channel relative to
another. For example, if the code of Channel 1 is adjusted to
0000 and that of Channel 2 to 0001 and the same signal is
applied to both RF inputs, the output of Channel 2 leads that
of Channel 1 by 22.5°.
The I and Q outputs are provided as currents to facilitate
summation. The summed current outputs are converted to
voltages by a high dynamic-range, current-to-voltage (I-V)
converter, such as the AD8021, configured as a transimpedance
amplifier. The resultant signal is then applied to a high resolution
ADC, such as the AD7665 (16 bit/570 kSPS).
The two I/Q demodulators can be used independently in other
nonbeamforming applications. In that case, a transimpedance
amplifier is needed for each of the I and Q outputs, four in total
for the dual I/Q demodulator.
The dynamic range is 161 dB/Hz at each I and Q output, but the
following transimpedance amplifier is an important element in
maintaining the overall dynamic range, and attention needs to
be paid to optimal component selection and design.
The AD8333 is available in a 32-lead LFCSP (5 mm × 5 mm)
package for the industrial temperature range of −40°C to +85°C.
AD8333
Rev. B | Page 2 of 28
TABLE OF CONTENTS
Features .............................................................................................. 1
Applications....................................................................................... 1
Functional Block Diagram .............................................................. 1
General Description......................................................................... 1
Revision History ............................................................................... 2
Specifications..................................................................................... 3
Absolute Maximum Ratings............................................................ 5
ESD Caution.................................................................................. 5
Pin Configuration and Function Descriptions............................. 6
Equivalent Input Circuits ................................................................ 7
Typical Performance Characteristics ............................................. 8
Test Circuits ..................................................................................... 14
Theory of Operation ...................................................................... 17
Quadrature Generation ............................................................. 17
I/Q Demodulator and Phase Shifter ........................................ 17
Dynamic Range and Noise........................................................ 18
Summation of Multiple Channels (Analog Beamforming).. 19
Phase Compensation and Analog Beamforming................... 19
Channel Summing ..................................................................... 20
Dynamic Range Inflation.......................................................... 22
Disabling the Current Mirror and Decreasing Noise............ 22
Applications..................................................................................... 24
Logic Inputs and Interfaces....................................................... 24
Reset Input .................................................................................. 24
Connecting to the LNA of the AD8331/
AD8332/AD8334/AD8335 VGAs............................................ 24
LO Input ...................................................................................... 25
Evaluation Board........................................................................ 25
Outline Dimensions....................................................................... 27
Ordering Guide .......................................................................... 27
REVISION HISTORY
5/07—Rev. A to Rev. B
Changes to Features and Figure 1................................................... 1
Changes to Table 1............................................................................ 3
Changes to Figure 41 to Figure 43................................................ 14
Changes to Figure 44 to Figure 47................................................ 15
Changes to Figure 48 to Figure 51................................................ 16
Changes to Figure 55...................................................................... 20
Changes to Evaluation Board Section.......................................... 25
Changes to Ordering Guide .......................................................... 27
5/06—Rev. 0 to Rev. A
Changes to Figure 62...................................................................... 26
10/05—Revision 0: Initial Version
AD8333
Rev. B | Page 3 of 28
SPECIFICATIONS
VS = ±5 V, TA = 25°C, 4 fLO = 20 MHz, fRF = 5.01 MHz, fBB = 10 kHz, PLO ≥ 0 dBm, single-ended, sine wave; per channel performance, dBm
(50 Ω), unless otherwise noted (see Figure 41).
Table 1.
Parameter Conditions Min Typ Max Unit
OPERATING CONDITIONS
LO Frequency Range 4× internal LO at Pin 4LOP and Pin 4LON
Square wave 0.01 200 MHz
Sine wave, see Figure 22 2 200 MHz
RF Frequency Range Mixing DC 50 MHz
Baseband Bandwidth Limited by external filtering DC 50 MHz
LO Input Level See Figure 22 0 13 dBm
VSUPPLY (VS) ±4.5 ±5 ±6 V
Temperature Range −40 +85 °C
DEMODULATOR PERFORMANCE
RF Differential Input Impedance 6.7||6.5 kΩ||pF
LO Differential Input Capacitance 0.6 pF
Transconductance Demodulated IOUT/VIN, each Ix or Qx output after low-pass
filtering measured from RF inputs
All phases 2.17 mS
Dynamic Range IP1dB, input referred noise (dBm) 159 dB/Hz
Maximum RF Input Swing Differential; inputs biased at 2.5 V; Pin RFxP and Pin RFxN 2.8 V p-p
Peak Output Current (No Filtering) 0° phase shift ±4.7 mA
45° phase shift ±6.6 mA
Input P1dB Ref = 50 Ω 14.5 dBm
Ref = 1 VRMS 1.5 dBV
Third-Order Intermodulation (IM3) fRF1 = 5.010 MHz, fRF2 = 5.015 MHz, fLO = 5.023 MHz
Equal Input Levels Baseband tones: −7 dBm @ 8 kHz and 13 kHz −75 dBc
Unequal Input Levels Baseband tones: −1 dBm @ 8 kHz and −31 dBm @ 13 kHz −77 dBc
Third-Order Input Intercept (IP3) Same conditions as IM3 30 dBm
LO Leakage Measured at RF inputs, worst phase, measured into 50 Ω
(limited by measurement)
<−97 dBm
Measured at baseband outputs, worst phase, 8021 disabled,
measured into 50 Ω
−60 dBm
Conversion Gain All codes, see Figure 41 4.7 dB
Input Referred Noise Output noise/conversion gain, see Figure 41 10 nV/√Hz
Output Current Noise Output noise ÷ 787 Ω 22 pA/√Hz
Noise Figure With AD8332 LNA
R
S = 50 Ω, RFB = ∞ 7.8 dB
R
S = 50 Ω, RFB = 1.1 kΩ 9.0 dB
R
S = 50 Ω, RFB = 274 Ω 11.0 dB
Bias Current Pin 4LOP and Pin 4LON −3 μA
Pin RFxP and Pin RFxN −70 μA
LO Common-Mode Voltage Range Pin 4LOP and Pin 4LON (each pin) 0.2 3.8 V
RF Common-Mode Voltage For maximum differential swing; Pin RFxP and Pin RFxN
(dc-coupled to AD8332 LNA output)
2.5 V
Output Compliance Range Pin IxPO and Pin QxPO −1.5 +0.7 V
AD8333
Rev. B | Page 4 of 28
Parameter Conditions Min Typ Max Unit
PHASE ROTATION PERFORMANCE One CH is reference, other is stepped
Phase Increment 16 phase steps per channel 22.5 Degrees
Quadrature Phase Error I1 to Q1 and I2 to Q2, 1σ −2 ±0.1 +2 Degrees
I/Q Amplitude Imbalance I1 to Q1 and I2 to Q2, 1σ ±0.05 dB
Channel-to-Channel Matching Phase match I1/I2 and Q1/Q2; −40°C < TA < 85°C ±1 Degrees
Amplitude match I1/I2 and Q1/Q2; −40°C < TA < 85°C ±0.25 dB
LOGIC INTERFACES
Logic Level High Pin PHxx, Pin RSET, and Pin ENBL 1.7 5 V
Logic Level Low Pin PHxx, Pin RSET, and Pin ENBL 0 1.3 V
Bias Current
Pin PHxx and Pin ENBL Logic high 10 40 90 μA
Logic low −30 −7 +10 μA
Pin RSET Logic high 50 120 180 μA
Logic low −70 −20 0 μA
Input Resistance Pin PHxx and Pin ENBL 60 kΩ
Pin RSET 20 kΩ
Reset Hold Time Reset is asynchronous; clock disabled when RSET goes HI
until 300 ns after RSET goes LO; see Figure 58
300 ns
Minimum Reset Pulse Width 300 ns
Reset Response Time See Figure 35 300 ns
Phase Response Time See Figure 38 5 μs
Enable Response Time See Figure 34 300 ns
POWER SUPPLY Pin VPOS and Pin VNEG
Supply Voltage ±4.5 ±5 ±6 V
Quiescent Current, All Phase Bits = 0 @ 25°C
Pin VPOS 38 44 51 mA
Pin VNEG −24 −20 −16 mA
Over Temperature −40°C < TA < 85°C
Pin VPOS, all phase bits = 0 40 54 mA
Pin VNEG −24 −19 mA
Quiescent Power Per channel, all phase bits = 0 170 mW
Per channel, any 0 or 1 combination of phase bits 190 mW
Disable Current All channels disabled
Pin VPOS 1.0 1.25 1.5 mA
Pin VNEG −300 −200 −100 μA
PSRR
Pin VPOS to Ix/Qx outputs (measured @ AD8021 output) −81 dB
Pin VNEG to Ix/Qx outputs (measured @ AD8021 output) −75 dB
AD8333
Rev. B | Page 5 of 28
ABSOLUTE MAXIMUM RATINGS
Table 2.
Parameter Rating
Voltages
Supply Voltage, VS6 V
RF Pins Input VS, GND
LO Inputs VS, GND
Code Select Inputs, V VS, GND
Thermal Data—4-Layer JEDEC Board No Air
Flow (Exposed Pad Soldered to PCB)
θJA 41.0°C/W
θJB 23.6°C/W
θJC 4.4°C/W
ΨJT 0.4°C/W
ΨJB 22.4°C/W
Maximum Junction Temperature 150°C
Maximum Power Dissipation
(Exposed Pad Soldered to PC Board)
1.5 W
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.
ESD CAUTION
AD8333
Rev. B | Page 6 of 28
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
PIN 1
INDICATOR
1
PH12
2
PH13
3
COMM
4
4LOP
5
4LON
6
LODC
7
PH23
8
PH22
24
I1PO
23
Q1PO
22
Q1NO
21
VNEG
20
COMM
19
Q2NO
18
Q2PO
17
I2PO
9
PH21
10
PH20
11
VPOS
12
RF2P
13
RF2N
14
VPOS
15
RSET
16
I2NO
32
PH11
31
PH10
30
VPOS
29
RF1P
28
RF1N
27
VPOS
26
ENBL
25
I1NO
AD8333
TOP VIEW
(Not to Scale)
05543-002
Figure 2. 32-Lead LFCSP Pin Configuration
Table 3. Pin Function Descriptions
Pin No. Mnemonic Description
1, 2,
7, 8
PH12, PH13
PH23, PH22
Quadrant Select LSB, MSB. Binary code. These logic inputs select the quadrant: 0° to 90°, 90° to180°,
180° to 270°, 270° to 360° (see Table 4). Logic threshold is at about 1.5 V and therefore can be driven by
3 V CMOS logic (see Figure 3).
3, 20 COMM Ground. These two pins are internally tied together.
4, 5 4LOP, 4LON LO Inputs. No internal bias; therefore, these pins need to be biased by external circuitry. For optimum
performance, these inputs should be driven differentially with a signal level that is not less than what is
shown in Figure 22. Bias current is only −3 μA. Single-ended drive is also possible if the inputs are biased
correctly (see Figure 4).
6 LODC Decoupling Pin for LO. A 0.1 μF capacitor should be connected between this pin and ground (see Figure 5).
9, 10,
31, 32
PH21, PH20
PH10, PH11 Phase Select LSB, MSB. Binary code. These logic inputs select the phase for a given quadrant: 0°, 22.5°, 45°, 67.5°
(see Table 4). Logic threshold is at about 1.5 V and therefore can be driven by 3 V CMOS logic (see Figure 3).
11, 14,
27, 30
VPOS Positive Supply. These pins should be decoupled with a ferrite bead in series with the supply, plus a 0.1 μF and
100 pF capacitor between the VPOS pins and ground. Because the VPOS pins are internally connected, one set
of supply decoupling components for all four pins should be sufficient.
12, 13,
28, 29
RF2P, RF2N
RF1N, RF1P
RF Inputs. These pins are biased internally; however, it is recommended that they be biased by dc coupling to
the output pins of the AD8332 LNA. The optimum common-mode voltage for maximum symmetrical input
differential swing is 2.5 V if ±5 V supplies are used (see Figure 6).
15 RSET Reset for Divide-by-4 in LO Interface. Logic threshold is at about 1.5 V and therefore can be driven by
3 V CMOS logic (see Figure 3).
16, 19,
22, 25
I2NO, Q2NO
Q1NO, I1NO
Negative I/Q Outputs. These outputs are not connected for normal usage but can be used for filtering if needed.
Together with the positive I/Q outputs, they allow bypassing the internal current mirror if a lower noise output
circuit is available; VNEG needs to be tied to GND to disable the current mirror (see Figure 7).
17, 18,
23, 24
I2PO, Q2PO
Q1PO, I1PO
Positive I/Q Outputs. These outputs provide a bidirectional current that can be converted back to a voltage via
a transimpedance amplifier. Multiple outputs can be summed together by simply connecting them together.
The bias voltage should be set to 0 V or less by the transimpedance amplifier (see Figure 7).
21 VNEG Negative Supply. This pin should be decoupled with a ferrite bead in series with the supply, plus a 0.1 μF and
100 pF capacitor between the pin and ground.
26 ENBL Chip Enable. Logic threshold is at about 1.5 V and therefore can be driven by 3 V CMOS logic (see Figure 3).
AD8333
Rev. B | Page 7 of 28
EQUIVALENT INPUT CIRCUITS
LOGIC
INTERFACE
VPOS
COMM
PHxx
ENBL
RSET
05543-003
Figure 3. Logic Inputs
4LOP
4
LON
COMM
VPOS
05543-004
Figure 4. Local Oscillator Inputs
LODC
VPOS
COMM
05543-005
Figure 5. LO Decoupling Pin
COMM
VPOS
RFxN
RFxP
05543-006
Figure 6. RF Inputs
COMM
VNEG
IxNO
QxNO
IxPO
QxPO
05543-007
Figure 7. Output Drivers
AD8333
Rev. B | Page 8 of 28
TYPICAL PERFORMANCE CHARACTERISTICS
VS = ±5 V, TA = 25°C, 4fLO = 20 MHz, fLO = 5 MHz, fRF = 5.01 MHz, fBB = 10 kHz, PLO ≥ 0 dBm (50 Ω); single-ended sine wave;
per channel performance, differential voltages, dBm (50 Ω), phase select code = 0000, unless otherwise noted (see Figure 41).
1.5
–1.5
–2.0 2.0
REAL (Normalized)
IMAGINARY (Normalized)
1.0
0.5
0
–0.5
–1.0
–1.5 –1.0 –0.5 0 0.5 1.0 1.5
CODE 0000
CODE 0100
CODE 1100
CODE 1000
CODE 0001
CODE 0010
CODE 0011
05543-008
f = 1MHz
Q
I
Figure 8. Normalized Vector Plot of Phase, CH2 with Respect to CH1;
CH1 Is Fixed at 0°, CH2 Stepped 22.5°/Step, All Codes Displayed
360
0
0000 1111
CODE (Binary)
PHASE (Degrees)
315
270
225
180
135
90
45
0010 0100 0110 1000 1010 1100 1110
05543-009
1MHz
5MHz
Figure 9. Phase of CH2 with Respect to CH1 vs. Code at 1 MHz and 5 MHz
1.0
–1.0
0000 1111
CODE (Binary)
AMPLITUDE ERROR (dB)
0.5
0
–0.5
–1.0
1.0
0.5
0
–0.5
0010 0100 0110 1000 1010 1100 1110
f = 5MHz
f = 1MHz
05543-010
Figure 10. Amplitude Error of CH2 with Respect to CH1 vs.
Code at 1 MHz and 5 MHz
2
–2
0000 1111
CODE (Binary)
PHASE ERROR (Degrees)
1
0
–1
–2
2
1
0
–1
0010 0100 0110 1000 1010 1100 1110
f = 5MHz
f = 1MHz
05543-011
Figure 11. Phase Error of CH2 with Respect to CH1 vs.
Code at 1 MHz and 5 MHz
05543-012
20µs
500mV
Figure 12. I or Q Output of CH2 with Respect to CH1, First Quadrant Shown
7
3
1M 50M
RF FREQUENCY (Hz)
GAIN (dB)
10M
6
5
4
05543-013
CHANNEL 1, I OUTPUT SHOWN
CODE 0000
CODE 0001
CODE 0010
CODE 0011
Figure 13. Conversion Gain vs. RF Frequency, First Quadrant,
Baseband Frequency = 10 kHz
AD8333
Rev. B | Page 9 of 28
2.0
–2.0
1M 100M
RF FREQUENCY (Hz)
QUADRATURE PHASE ERROR (Degrees)
1.5
1.0
0.5
0
–0.5
–1.0
–1.5
10M
05543-014
Figure 14. Representative Range of Quadrature Phase Errors vs.
RF Frequency, CH1 or CH2, All Codes
2.0
–2.0
100 100k
BASEBAND FREQUENCY (Hz)
QUADRATURE PHASE ERROR (Degrees)
1.5
1.0
0.5
0
–0.5
–1.0
–1.5
1k 10k
05543-015
Figure 15. Range of Quadrature Phase Error vs. Baseband Frequency,
CH1 and CH2 ( see Figure 43)
0.5
–0.5
1M 50M
RF FREQUENCY (Hz)
I/Q AMPLITUDE IMBALANCE (dB)
10M
0.4
0.3
0.2
0.1
0
–0.1
–0.2
–0.3
–0.4
05543-016
Figure 16. Representative Range of Amplitude Imbalance of I/Q vs.
RF Frequency, CH1 or CH2, All Codes
0.5
–0.5
100 100k
BASEBAND FREQUENCY (Hz)
I/Q AMPLITUDE IMBALANCE (dB)
0.4
0.3
0.2
0.1
0
–0.1
–0.2
–0.3
–0.4
1k 10k
05543-017
Figure 17. Representative Range of I/Q Amplitude Imbalance vs.
Baseband Frequency, CH1 and CH2 ( see Figure 43)
2.0
–2.0
1M 50M
RF FREQUENCY (Hz)
AMPLITUDE ERROR (dB)
10M
1.5
1.0
0.5
0
–0.5
–1.0
–1.5
05543-018
f
BB
= 10kHz
I2/I1 DISPLAYED
CODE 0000
–40°C
+25°C
+85°C
CODE 0001
–40°C
+25°C
+85°C
CODE 0010
–40°C
+25°C
+85°C
CODE 0011
–40°C
+25°C
+85°C
Figure 18. Typical I2/I1 or Q2/Q1 Amplitude Match vs. RF Frequency
First Quadrant, at Three Temperatures
8
–4
1M
05543-043
RF FREQUENCY (Hz)
PHASE ERROR (Degrees)
10M 50M
6
4
2
0
–2
f
BB
= 10kHz
I2/I1 DISPLAYED
CODE 0000
–40°C
+25°C
+85°C
CODE 0001
–40°C
+25°C
+85°C
CODE 0010
–40°C
+25°C
+85°C
CODE 0011
–40°C
+25°C
+85°C
Figure 19. I2/I1 or Q2/Q1 Phase Error vs. RF Frequency,
Baseband Frequency = 10 kHz, at Three Temperatures
AD8333
Rev. B | Page 10 of 28
2.8
2.0
1M 50M
RF FREQUENCY (Hz)
TRANSCONDU
C
TANCE (ms)
10M
2.7
2.6
2.5
2.4
2.3
2.2
2.1
05543-020
CODE 0000
CODE 0001
CODE 0010
CODE 0011
CHANNEL 1, I OUTPUT SHOWN
TRANSCONDUCTANCE = [(V
BB
/787Ω)V
RF
]
Figure 20. Transconductance vs. RF Frequency, First Quadrant
10
–80
–20 0
POWER (dBm)
GAIN (dB)
0
–10
–20
–30
–40
–50
–60
–70
–15 –10 –5
05543-021
f = 5MHz
GAIN = V
BB
/V
RF
CODE 0000
CODE 0001
CODE 0010
CODE 0011
Figure 21. Conversion Gain vs. LO Level, First Quadrant
5
–40
100k 100M
FREQUENCY (Hz)
MINIMUM LO LEVEL (dBm)
1M 10M
0
–5
–10
–15
–20
–25
–30
–35
ALL CODES
REGION OF USEABLE
LO LEVELS
05543-022
Figure 22. Minimum LO Level vs. RF Frequency, Single-Ended,
Sine Wave LO Drive to Pin 4LOP or Pin 4LON
10
–30
05.0
COMMON-MODE VOLTAGE (V)
GAIN (dB)
05543-019
5
0
–5
–10
–15
–20
–25
0.51.01.52.02.53.03.54.04.5
GAIN = V
BB
/V
RF
+85°C
+25°C
–40°C
Figure 23. LO Common-Mode Range at Three Temperatures
20
0
1M 50M
RF FREQUENCY (Hz)
IP1dB (dBm)
18
16
14
12
10
8
6
4
2
05543-023
10M
Figure 24. IP1dB vs. Frequency, Baseband Frequency = 10 kHz,
First Quadrant (see Figure 42)
10M
0
–90
1M 50M
RF FREQUENCY (Hz)
IM3 (dBc)
–10
–20
–30
–40
–50
–60
–70
–80
BOTH CHANNELS
–7dBm
3 8 13 18
IM3 PRODUCTS
LO = 5.023MHz
RF1 = 5.015MHz
RF2 = 5.010MHz
05543-024
Figure 25. Representative Range of IM3 vs. RF Frequency,
First Quadrant (see Figure 49)
AD8333
Rev. B | Page 11 of 28
10M
40
0
1M 50M
RF FREQUENCY (Hz)
OIP3 (dBm)
35
30
25
20
15
10
5
BOTH CHANNELS
05543-025
Figure 26. Representative Range of OIP3 vs. RF Frequency,
First Quadrant (see Figure 49)
35
0
1k 100k
BASEBAND FREQUENCY (Hz)
OIP3 (dBm)
10k
30
25
20
15
10
5
05543-026
CHANNEL 1 RF
CHANNEL 2 RF
Figure 27. OIP3 vs. Baseband Frequency (see Figure 48)
0
–80
1M 50M
RF FREQUENCY (Hz)
LO LEAKAGE (dBm)
10M
–10
–20
–30
–40
–50
–60
–70
LO LEVEL = 0dBm
05543-027
I1
I2
Q1
Q2
Figure 28. LO Leakage vs. RF Frequency at Baseband Outputs
0
–140
1M 50M
RF FREQUENCY (Hz)
LO LEAKAGE (dBm)
10M
05543-028
LO LEVEL = 0dBm
–20
–40
–60
–80
–100
–120
RF1P
RF2P
RF1N
RF2N
Figure 29. LO Leakage vs. RF Frequency at RF Inputs
16 –142.9
0
1M 50M
RF FREQUENCY (Hz)
NOISE (nV/ Hz)
NOISE (dBm)
10M
14 –144.1
12 –145.4
10 –147.0
8 –148.9
6 –151.4
4 –154.9
2 –161.0
05543-029
I1
Q1
Figure 30. Input Referred Noise vs. RF Frequency
20
0
1M
05543-064
RF FREQUENCY (Hz)
NOISE FIGURE (dB)
10M 50M
18
16
14
12
10
8
6
4
2
Figure 31. Noise Figure vs. RF Frequency with AD8332 LNA
AD8333
Rev. B | Page 12 of 28
172
152
1M 50M
RF FREQUENCY (Hz)
DYNAMIC RANGE (dB)
10M
170
168
166
164
162
160
158
156
154
05543-030
I1
Q1
I1 + I2
Q1 + Q2
Figure 32. Dynamic Range vs. RF Frequency, IP1dB Minus Noise Level,
Single Channel and Two Channels Summed
6
–10
–3.0 1.0
05543-044
VOLTAGE (V)
GAIN (dB)
4
2
0
–2
–4
–6
–8
–2.5 –2.0 –1.5 –1.0 –0.5 0 0.5
GAIN = V
BB
/V
RF
CODE 0000
CODE 0010
Figure 33. Output Compliance Range (IxPO, QxPO) (see Figure 50)
200ns2V
500mV
05543-045
Figure 34. Enable Response—Top: Enable Signal
Bottom: Output Signal (see Figure 44)
200ns
2V
500mV
05543-046
Figure 35. Reset Response—Top: Signal at Reset Pin
Bottom: Output Signal (see Figure 45)
40µs
5V
1V 1V
05543-047
Figure 36. Phase Switching Response—CH2 Leads CH1 by 45°,
Top: Input to PH21, Select Code = 0010
Red: Ref CH1 IOUT; Gray: CH2 IOUT Phase Shifted 45°,
CH1 Ref Phase Select Code = 0000
40µs
5V
1V 1V
05543-048
Figure 37. Phase Shifting Response—CH2 Leads CH1 by 90°,
Top: Input to PH21, Select Code = 0100
Red: Ref CH1 IOUT, Gray: CH2 IOUT Phase Shifted 90°,
CH1 Ref Phase Code = 0000
AD8333
Rev. B | Page 13 of 28
5V
1V 1V 40µs
05543-049
Figure 38. Phase Shifting Response—CH2 Leads CH1 by 180°,
Top: Input to PH23 Select Code = 1000
Red: Ref CH1 IOUT, Gray: CH2 IOUT Phase Shifted 180°,
CH1 Ref Phase Code = 0000
0
–90
100k 50M
05543-050
FREQUENCY (Hz)
PSRR (dB)
1M 10M
–10
–20
–30
–40
–50
–60
–70
–80
VNEG
VPOS
Figure 39. PSRR vs. Frequency (see Figure 51)
60
0
–50 90
05543-051
TEMPERATURE (°C)
QUIESCENT SUPPLY CURRENT (mA)
50
40
30
20
10
–30 –10 10 30 50 70
VNEG
VPOS
Figure 40. Quiescent Supply Current vs. Temperature
AD8333
Rev. B | Page 14 of 28
TEST CIRCUITS
OSCILLOSCOPE
LPF
50Ω
SIGNAL
GENERATOR
120nH
FB 0.1µF
0.1µF
AD8332
LNA 20Ω
20Ω
SIGNAL
GENERATOR
50Ω
AD8333
RFxP IxxO
RFxN QxxO
AD8021
A
D8021
4LOP
787Ω
787Ω
2.2nF
2.2nF
05543-032
Figure 41. Default Test Circuit
OSCILLOSCOPE
LPF
50Ω
SIGNAL
GENERATOR
120nH
FB 0.1µF
0.1µF
AD8332
LNA 20Ω
20Ω
SIGNAL
GENERATOR
50Ω
AD8333
RFxP IxxO
RFxN QxxO
AD8021
A
D8021
4LOP
100Ω
100Ω
10nF
10nF
05543-033
Figure 42. P1dB Test Circuit
OSCILLOSCOPE
LPF
50Ω
SIGNAL
GENERATOR
120nH
FB 1µF
1µF
AD8332
LNA 20Ω
20Ω
SIGNAL
GENERATOR
50Ω
AD8333
RFxP IxxO
RFxN QxxO
AD8021
A
D8021
4LOP
787Ω
787Ω
05543-034
Figure 43. Phase and Amplitude vs. Baseband Frequency
AD8333
Rev. B | Page 15 of 28
OSCILLOSCOPE
LPF
50Ω
SIGNAL
GENERATOR
120nH
FB 1µF
1µF
AD8332
LNA 20Ω
20Ω
SIGNAL
GENERATOR
50Ω
AD8333
RFxP IxxO
RFxN QxxO
AD8021
A
D8021
4LOP
SIGNAL
GENERATOR
50Ω
ENBL
787Ω
787Ω
05543-035
Figure 44. Enable Response
OSCILLOSCOPE
LPF
50Ω
SIGNAL
GENERATOR
120nH
FB 1µF
1µF
AD8332
LNA 20Ω
20Ω
SIGNAL
GENERATOR
50Ω
AD8333
RFxP IxxO
RFxN QxxO
AD8021
A
D8021
4LOP
SIGNAL
GENERATOR
50Ω
RST
787Ω
787Ω
05543-036
Figure 45. Reset Response
OSCILLOSCOPE
LPF
50Ω
SIGNAL
GENERATOR
120nH
FB 0.1µF
0.1µF
A
D8332
LNA 20Ω
20Ω
SIGNAL
GENERATOR
50Ω
AD8333
RFxP IxxO
RFxN QxxO
4LOP 50Ω50Ω
05543-037
Figure 46. RF Input Range
SPECTRUM
ANALYZER
SIGNAL
GENERATOR
50Ω
AD8333
RFxP IxxO
RFxN QxxO
AD8021
A
D8021
4LOP
6.98kΩ
6.98kΩ
270pF
270pF
0.1µF
05543-052
Figure 47. Noise Test Circuit
AD8333
Rev. B | Page 16 of 28
120nH
FB 0.1µF
0.1µF
AD8332
LNA 20Ω
20Ω
SIGNAL
GENERATOR
50Ω
SIGNAL
GENERATOR
50Ω
SIGNAL
GENERATOR
50Ω
AD8333
RFxP IxxO
RFxN QxxO
AD8021
A
D8021
4LOP
787Ω
787Ω
100pF
100pF
05543-053
COMBINER
–6dB
SPECTRUM
ANALYZER
Figure 48. OIP3 vs. Baseband Frequency
120nH
FB 0.1µF
0.1µF
AD8332
LNA 20Ω
20Ω
SIGNAL
GENERATOR
50Ω
SIGNAL
GENERATOR
50Ω
SIGNAL
GENERATOR
50Ω
AD8333
RFxP IxxO
RFxN QxxO
AD8021
A
D8021
4LOP
787Ω
787Ω
2.2nF
2.2nF
05543-054
COMBINER
–6dB
SPECTRUM
ANALYZER
Figure 49. OIP3 and IM3 vs. RF Frequency
OSCILLOSCOPE
LPF
50Ω
SIGNAL
GENERATOR
120nH
FB 0.1µF
0.1µF
AD8332
LNA 20Ω
20Ω
SIGNAL
GENERATOR
50Ω
AD8333
RFxP IxxO
RFxN QxxO
AD8021
A
D8021
4LOP
787Ω
787Ω
2.2nF
2.2nF
05543-055
Figure 50. Output Compliance Range
NETWORK
ANALYZER
LPF
50Ω
SIGNAL
GENERATOR
120nH
FB 0.1µF
0.1µF
A
D8332
LNA 20Ω
20Ω
SIGNAL
GENERATOR
50Ω
AD8333
RFxP IxxO
RFxN QxxO
4LOP
05543-056
Figure 51. PSRR Test Circuit
AD8333
Rev. B | Page 17 of 28
THEORY OF OPERATION
The AD8333 is a dual I/Q demodulator with a programmable
phase shifter for each channel. The primary applications are
phased array beamforming in medical ultrasound, phased array
radar, and smart antennas for mobile communications. The
AD8333 can also be used in applications that require two well-
matched I/Q demodulators.
Figure 52 shows the block diagram and pinout of the AD8333.
Three analog and nine quasi-logic level inputs are required.
Two RF inputs accept signals from the RF sources and a local
oscillator (applied to the differential input pins marked 4LOx)
common to both channels comprise the analog inputs. Four
logic inputs per channel define one of 16 delay states/360° (or
22.5°/step) selectable with the PHx0 to PHx3. The reset input is
used to synchronize AD8333s used in arrays.
90°
0°
90°
0°
Φ
Φ
Φ
÷4
Φ
BUF
BIAS
AD8333
32
PH11
9
PH21
31
PH10
10
PH20
30
VPOS
11
V
POS
29
RFIP
12
RF2P
28
RFIN
13
RF2N
27
VPOS
14
V
POS
26
ENBL
15
RSET
25
I1NO
16
I2NO
24
I1PO
1
PH12
23
Q1PO
2
PH13
22
Q1NO
3
C
OMM
20
COMM
5
4LON
21
VNEG
4
4LOP
19
Q2NO
6
LODC
18
Q2PO
7
PH23
17
I2PO
8
PH22
CHANNEL 1
ΦSEL
LOGIC
CHANNEL 2
ΦSEL
LOGIC
0
5543-057
Figure 52. Block Diagram and Pinout
Each of the current formatted I and Q outputs sum together for
beamforming applications. Multiple channels are summed and
converted to a voltage using a transimpedance amplifier. If
desired, channels can also be used individually.
QUADRATURE GENERATION
The internal 0° and 90° LO phases are digitally generated
by a divide-by-4 logic circuit. The divider is dc-coupled and
inherently broadband; the maximum LO frequency is limited
only by its switching speed. The duty cycle of the quadrature LO
signals is intrinsically 50% and is unaffected by the asymmetry
of the externally connected 4LOx inputs. Furthermore, the
divider is implemented such that the 4LOx signals reclock the
final flip-flops that generate the internal LO signals and thereby
minimizes noise introduced by the divide circuitry.
For optimum performance, the 4LOx inputs are driven
differentially but can also be driven single ended. A good
choice for a drive is an LVDS device. The common-mode
range on each pin is approximately 0.2 V to 3.8 V with nominal
±5 V supplies.
The minimum LO level is frequency dependent (see Figure 22).
For optimum noise performance, it is important to ensure that
the LO source has very low phase noise (jitter) and adequate
input level to assure stable mixer-core switching. The gain
through the divider determines the LO signal level vs. RF
frequency. The AD8333 can be operated to very low frequencies
at the LO inputs if a square wave is used to drive the LO.
Beamforming applications require a precise channel-to-channel
phase relationship for coherence among multiple channels. A
reset pin (RSET) is provided to synchronize the 4LOx divider
circuits when the AD8333s are used in arrays. The RSET pin
resets the counters to a known state after power is applied to
multiple AD8333s. A logic input must be provided to the RSET
pin when using more than one AD8333. See the Reset Input
section for more details.
I/Q DEMODULATOR AND PHASE SHIFTER
The I/Q demodulators consist of double-balanced Gilbert cell
mixers. The RF input signals are converted into currents by
transconductance stages that have a maximum differential input
signal capability of 2.8 V p-p. These currents are then presented
to the mixers, which convert them to baseband: RF − LO and
RF + LO. The signals are phase shifted according to the code
applied to Pin PHx0 to Pin PHx3 (see Table 4). The phase shift
function is an integral part of the overall circuit (patent pending).
The phase shift listed in Column 1 of Table 4 is defined as being
between the baseband I or Q channel outputs. As an example,
for a common signal applied to the RF inputs of an AD8333, the
baseband outputs are in phase for matching phase codes.
However, if the phase code for Channel 1 is 0000 and that of
Channel 2 is 0001, Channel 2 leads Channel 1 by 22.5°.
Following the phase shift circuitry, the differential current
signal is converted from differential to single ended via a
current mirror. An external transimpedance amplifier is
needed to convert the I and Q outputs to voltages.
AD8333
Rev. B | Page 18 of 28
Judicious selection of the RF amplifier ensures the least
degradation in dynamic range. The input referred spectral
voltage noise density (en) of the AD8333 is nominally 9 nV/√Hz
to 10 nV/√Hz. For the noise of the AD8333 to degrade the
system noise figure (NF) by 1 dB, the combined noise of the
source and the LNA should be about twice that of the AD8333
or 18 nV/√Hz. If the noise of the circuitry before the AD8333 is
<18 nV/√Hz, the system NF degrades more than 1 dB. For
example, if the noise contribution of the LNA and source is
equal to the AD8333, or 9 nV/√Hz, the degradation is 3 dB. If
the circuit noise preceding the AD8333 is 1.3× as large as that of
the AD8333 (or about 11.7 nV/√Hz), the degradation is 2 dB.
For a circuit noise 1.45× that of the AD8333 (13.1 nV/√Hz),
degradation is 1.5 dB.
Table 4. Phase Select Code for Channel-to-Channel Phase Shift
φ-Shift PHx3 PHx2 PHx1 PHx0
0° 0 0 0 0
22.5° 0 0 0 1
45° 0 0 1 0
67.5° 0 0 1 1
90° 0 1 0 0
112.5° 0 1 0 1
135° 0 1 1 0
157.5° 0 1 1 1
180° 1 0 0 0
202.5° 1 0 0 1
225° 1 0 1 0
247.5° 1 0 1 1
270° 1 1 0 0
292.5° 1 1 To determine the input referred noise, it is important to know
the active low-pass filter (LPF) values RFILT and CFILT, shown in
Figure 53. Typical filter values (for example, those used on the
evaluation board) are 787 Ω and 2.2 nF and implement a
90 kHz single-pole LPF. If the RF and LO are offset by 10 kHz,
the demodulated signal is 10 kHz and is passed by the LPF. The
single-channel mixing gain, from the RF input to the AD8021
output (for example, I1´, Q1´) is approximately 1.7 × 4.7 dB.
This together with the 9 nV/√Hz AD8333 noise results in about
15.3 nV/√Hz at the AD8021 output. Because the AD8021,
including the 787 Ω feedback resistor, contributes another
4.4 nV/√Hz, the total output referred noise is about 16 nV/√Hz.
This value can be adjusted by increasing the filter resistor while
maintaining the corner frequency, thereby increasing the gain.
The factor limiting the magnitude of the gain is the output
swing and drive capability of the op amp selected for the I-to-V
converter, in this instance the AD8021.
0 1
315° 1 1 1 0
337.5° 1 1 1 1
DYNAMIC RANGE AND NOISE
Figure 53 is an interconnection block diagram of the AD8333.
For optimum system noise performance, the RF input signal is
provided by a very low noise amplifier, such as the LNA of the
AD8332 or the preamplifier of the AD8335. In beamformer
applications, the I and Q outputs of a number of receiver
channels are summed (for example, the two channels illustrated
in Figure 53). The dynamic range of the system increases by the
factor 10log10(N), where N is the number of channels (assuming
random uncorrelated noise.) The noise in the two channel
example of Figure 53 is increased by 3 dB while the signal
doubles (6 dB), yielding an aggregate SNR improvement of
(6 − 3) = 3 dB.
Φ
Φ
Φ
Φ
I1
Q1
Q2
I2
22
2 2
2 2
2 2
4
4
2
2
0°
90°
90°
0°
AD8333
÷4
CLOCK
GENERATOR
TRANSMITTER
TRANSDUCER
TRANSMITTER
TRANSDUCER
T/R
SW
RFB
RFB
AD8332 LNA OR
AD8335 PREAMP
AD8332 LNA OR
AD8335 PREAMP
CH1
RF
CH2
RF
CH1
PHASE
SELECT
CH2
PHASE
SELECT
T/R
SW
AD8021
AD8021
AD7665 OR
AD7686
CFILT
CFILT
RFILT
RFILT
IDATA
QDATA
ADC 16-BIT
570kSPS
ADC 16-BIT
570kSPS
05543-038
*
*
*UP TO 8 CHANNELS
PER AD8021
ΣQ
ΣI
Figure 53. Interconnection Block Diagram
AD8333
Rev. B | Page 19 of 28
SUMMATION OF MULTIPLE CHANNELS (ANALOG
BEAMFORMING)
Beamforming, as applied to medical ultrasound, is defined as
the phase alignment and summation of signals generated from a
common source but received at different times by a multielement
ultrasound transducer. Beamforming has two functions: it imparts
directivity to the transducer, enhancing its gain, and it defines a
focal point within the body from which the location of the
returning echo is derived. The primary application for the
AD8333 is in analog beamforming circuits for ultrasound.
PHASE COMPENSATION AND ANALOG
BEAMFORMING
Modern ultrasound machines used for medical applications
employ a 2n binary array of receivers for beamforming, with
typical array sizes of 16 or 32 receiver channels phase-shifted
and summed together to extract coherent information. When
used in multiples, the desired signals from each of the channels
can be summed to yield a larger signal (increased by a factor N,
where N is the number of channels), while the noise is increased
by the square root of the number of channels. This technique
enhances the signal-to-noise performance of the machine. The
critical elements in a beamformer design are the means to align
the incoming signals in the time domain, and the means to sum
the individual signals into a composite whole.
In traditional analog beamformers incorporating Doppler, a
V-to-I converter per channel and a crosspoint switch precede
passive delay lines used as a combined phase shifter and
summing circuit. The system operates at the receive frequency
(RF) through the delay line, and then the signal is down-
converted by a very large dynamic range I/Q demodulator.
The resultant I and Q signals are filtered and sampled by two
high resolution ADCs. The sampled signals are processed to
extract the relevant Doppler information.
Alternatively, the RF signal can be processed by downconversion
on each channel individually, phase shifting the downconverted
signal, and then combining all channels. The AD8333 provides
the means to implement this architecture. The downconversion
is done by an I/Q demodulator on each channel, and the summed
current output is the same as in the delay line approach. The
subsequent filters after the I-to-V conversion and the ADCs
are similar.
The AD8333 integrates the phase shifter, frequency conversion,
and I/Q demodulation into a single package and directly yields
the baseband signal. To illustrate, Figure 54 is a simplified
diagram showing two channels. The ultrasound wave USW
is received by two transducer elements, TE1 and TE2, in an
ultrasound probe and generates signals E1 and E2. In this
example, the phase at TE1 leads the phase at TE2 by 45°.
E1
E2 19dB
LNA
19dB
LNA
S1
S2
45°
USW AT TE1
LEADS USW
AT T E2 BY
45°
TRANSDUCER
ELEMENTS TE1
AND TE2
CONVERT USW TO
ELECTRICAL
SIGNALS
AD8332
ES1 LEADS
ES2 BY 45°
AD8333
PHASE BIT
SETTINGS
CH 1 REF
(NO PHASE
LEAD)
CH 2
PHASE
LEAD 45°
S1 AND S2
ARE NOW IN
PHASE SUMMED
OUTPUT
S1 + S2
05543-063
Figure 54. Simplified Example of the AD8333 Phase Shifter
In a real application, the phase difference depends on the
element spacing, λ (wavelength), speed of sound, angle of
incidence, and other factors. The signals ES1 and ES2 are
amplified 19 dB by the low noise amplifiers in the AD8332.
For optimum signal-to-noise performance, the output of the
LNA is applied directly to the input of the AD8333. To sum the
signals ES1 and ES2, ES2 is shifted 45° relative to ES1 by setting
the phase code in Channel 2 to 0010. The phase-aligned current
signals at the output of the AD8333 are summed in an I-to-V
converter to provide the combined output signal with a
theoretical improvement in dynamic range of 3 dB for the
sum of two channels.
AD8333
Rev. B | Page 20 of 28
CHANNEL SUMMING
In a beamformer using the AD8333, the bipolar currents at the I
and Q outputs are summed directly. Figure 55 illustrates 16
summed channels (for clarity shown as current sources) as an
example of an active current summing circuit using the AD8333,
AD8021s as first-order current summing circuits, and AD797s
as low noise second-order summing circuits. Beginning with
the op amps, there are a few important considerations in the
circuit shown in Figure 55.
The op amps selected for the first-order summing amplifiers
must have good frequency response over the full operating
frequency range of the AD8333s and be able to source the
current required at the AD8333 I and Q outputs.
The total current of each of the AD8333s is 6.6 mA for the
multiples of the 45° phase settings (Code 0010, Code 0110,
Code 1010, and Code 1110) and divided about equally between
the baseband frequencies (including a dc component) and the
second harmonic of the local oscillator frequency. The desired
CW signal tends to be much less (<40 dB) than the unwanted
interfering signals. When determining the large signal
requirements of the first-order summing amplifiers and low-
pass filters, the very small CW signal can be ignored. The
number of channels that can be summed is limited by the
output drive current capacity of the op amp selected: 60 mA
to 70 mA for a linear output current for ±5 V and ±12 V,
respectively, for the AD8021. Because the AD8021 implements
an active LPF together with R1x and C1x, it must absorb the
worst-case current provided by the AD8333, for example,
6.6 mA. Therefore, the maximum number of channels that the
AD8021 can sum is 10 for ±12 V or eight for ±5 V supplies.
In practical applications, CW channels are used in powers of
two, thus the maximum number per AD8021 is eight.
Another consideration for the op amp selected as an I-to-V
converter is the compliance voltage of the AD8333 I and Q
outputs. The maximum compliance voltage is 0.5 V, and a dc
bias must be provided at these pins. The AD8021 active LPF
satisfies these requirements; it keeps the outputs at 0 V via the
virtual ground at the op amp inverting input while providing
any needed dc bias current.
3
+
2
3
+
2
3AD797
+
2
ΣA
FIRST ORDER
SUMMING AMPLIFIERS
C1A
18nF LPF1A
88kHz
R1A
100Ω
–
–
ΣB
–
0.1µF
0.1µF
AD8021
–5V
+5V
C2A
1µF
C3A
5.6nF
R2A
698Ω
R3A
698Ω
LPF2A
81kHz
HPF1A
100Hz
+2.8V BASEBAND
SIGNAL
C1B
18nF
R1B
100Ω
0.1µF
0.1µF
AD8021
+5V
–5V
C2B
1µF
C3B
5.6nF
R2B
698Ω
R3B
698Ω
R4
+10V
–10V
0.1µF
0.1µF
SECOND ORDER
SUMMING AMPLIFIER
05543-058
(SAME AS ABOVE)
EIGHT AD8333 I OR Q OUTPUTS,
6.6mA PEAK EACH
(IF THE PHASE SETTING IS 45°)
3.3mA AT DC + 3.3mA AT 2LO
Figure 55. A 16-Channel Beamformer
AD8333
Rev. B | Page 21 of 28
As previously noted, a typical CW signal has a large dc and
very low frequency component compared to its desired low CW
Doppler baseband frequency, and another unwanted component
at the 2 × LO. The dc component flows through the gain resistors
R1x, while the 2 × LO flows through the capacitors C1x. The
smaller desired CW Doppler baseband signal is in the frequency
range of 1 kHz to 50 kHz.
Because the output current of the AD8333 contains the baseband
frequency, a dc component, and the 2 × LO frequency voltages,
the desired small amplitude baseband signal must be extracted
after a series of filters. These are shown in Figure 55 as LPFn,
HPFn, and gain stages.
Before establishing the value of CLPF1, the resistor RLPF1 is
selected based on the peak operating current and the linear
range of the op amp. Because the peak current for each AD8333
is 6.6 mA and there are eight channels to be summed, the total
peak current required is 52.8 mA. Approximately half of this
current is dc and the other half at a frequency of 2 × LO. Therefore,
about 26.4 mA flows through the resistor while the remaining
26.4 mA flows through the capacitor. R1 was selected as 100 Ω
and, after filtering, generates a peak dc and very low frequency
voltage of 2.64 V at the AD8021 output. For power supplies of
±5 V, 100 Ω is a good choice for R1.
However, because the CW signal needs to be amplified as
much as possible and the noise degradation of the signal path
minimized, the value of R1 should be as large as possible. A
larger supply helps in this regard, and the only factor limiting
the largest supply voltage is the required power.
For a ±10 V supply on the AD8021, R1 can be increased to
301 Ω and realize the same headroom as with a ±5 V supply. If a
higher value of R1 is used, C1 must be adjusted accordingly (in
this example 1/3 the value of the original value) to maintain the
desired LPF roll-off. The principal advantage of a higher supply
is greater dynamic range, and the trade-off is power consumption.
The user must weigh the trade-offs associated with the supply
voltage, R1, C1, and the following circuitry. A suggested design
sequence is:
• Select a low noise, high speed op amp. The spectral density
noise (en) should be <2 nV/√Hz and the 3 dB BW ≥ 3 × the
expected maximum 2 × LO frequency.
• Divide the maximum linear output current by 6.6 mA to
determine the maximum number of AD8333 channels that
can be summed.
• Select the largest value of R1 that permits the output voltage
swing within the power supply rails.
• Calculate the value of C1 to implement the LPF corner that
allows the CW Doppler signal to pass with maximum
attenuation of the 2 × LO signal.
The filter LPF1 establishes the upper frequency limit of the
baseband frequency and is selected well below the 2 × LO
frequency, typically 100 kHz or less, or, as an example, 88 kHz
as shown in Figure 55.
A useful equation for calculating C1 is
1
12π
1
1
LP
F
fR
C= (1)
As previously mentioned, the AD8333 output current contains a
dc current component. This dc component is converted to a
large dc voltage by the AD8021 LPF. Capacitor C2 filters this dc
component and, with R2 + R3, establishes a high-pass filter with
a low frequency cutoff of about 100 Hz. Capacitor C3 is much
smaller than C2 and, consequently, can be neglected. C2 can be
calculated by
1
)32(2π
1
2
HPF
fRR
C+
= (2)
To achieve maximum attenuation of the 2 × LO frequency, a
second low-pass filter, LPF2, is established using the parallel
combination of R2 and R3, and C3. Its −3 dB frequency is
()
33||22π
1
2CRR
fLPF = (3)
In the example shown in Figure 55, fLPF2 = 81 kHz.
Finally, the feedback resistor of the AD797 must be calculated.
This is a function of the input current (number of channels)
and the supply voltage.
The second-order summing amplifier requires a very low noise
op amp, such as the AD797, with 0.9 nV/√Hz, because the
amplifier gain is determined by Feedback Resistor R4 divided
by the parallel combination of the LPF2 resistors seen looking
back toward the AD8021s. Referring to Figure 55, the AD797
inband (100 Hz to 88 kHz) gain is expressed as
[]
)(||)( R2BR2BR3AR2A
R4
++ (4)
The AD797 noise gain can increase to unacceptable levels
because the denominator of the gain equation is the parallel
resistance of all the R2 + R3 resistors in the AD8021 outputs.
For example, for a 64-channel beamformer, the resistance seen
looking back toward the AD8021s is about 1.4 k/8 = 175 .
For this reason, the value of (R2x + R3x) should be as large as
possible to minimize the noise gain of the AD797. (Note that
this is the case for the AD8021 stages because they look back
into the high impedance current sources of the AD8333s.)
Due to these considerations, it is advantageous to increase the
gain of the AD8021s as much as possible because the value of
(R2x + R3x) can be increased proportionally. Resistors (R2x +
R3x) convert the CW voltages to currents that are summed at
the inverting inputs of the AD797 op amp and amplified and
converted to voltages by R4.
AD8333
Rev. B | Page 22 of 28
The value of R4 needs to be chosen iteratively as follows:
• Determine the number of AD8021 first-order summing
amplifiers. In Figure 55, there are two; for a 32-channel
beamformer, there would be four, and for a 64-channel
beamformer, there would be eight.
• Determine the output noise after the AD8021s. A first-order
calculation can be based on a value of AD8333 output
current noise of about 20 pA/√Hz. For the values in Figure 55,
this results is about 6 nV/√Hz for eight channels after the
AD8021s. Adding the noise of the AD8021 and the 100
feedback resistor results in about 6.5 nV/√Hz total noise after
the AD8021 LPF in the CW Doppler band.
• Determine the noise of the circuitry after the AD797 and the
desired signal level.
• Determine the voltage and current noise of the second-order
summing amplifiers.
• Choose a value for R2x + R3x and for R4. Determine the
resulting output noise after the AD797 for one channel and
then multiply by the square root of the number of summed
AD8021s. Next, check AD797 output noise (both current and
voltage noise). Ideally, the sum of the noise of the resistors
and the AD797 is less than a factor-of-3 than the noise due to
the AD8021 outputs.
• Check the following stages output noise against the
calculated noise from the combiner circuit and AD8333s;
ideally the noise from the following stage should be less than
1/3 of the calculated noise.
• If the combined noise is too large, experiment with
increasing/decreasing values for R2x + R3x and R4.
To simplify, the user can also simulate or build a combiner
circuit for optimum performance. It should be noted that the
~20 pA/√Hz out of the AD8333 is for the AD8333 with shorted
RF inputs. In an actual system, the current noise out of the
AD8333 is most likely dominated by the noise from the AD8332
LNA and the noise from the source and other circuitry before
the LNA. This helps ease the design of the combiner. The
preceding procedures for determining the optimum values for
the combiner are based on the noise floor of the AD8333 only.
As an example, for a 32-channel beamformer using four low-
pass filters, as shown in Figure 55, (R2x + R3x) = 1.4 k and
R4 = 6.19 kΩ. The theoretical noise increase of √N is degraded
by only about 1 dB.
DYNAMIC RANGE INFLATION
Although all 64 channels could theoretically be summed
together at a single amplifier, it is important to realize that the
dynamic range of the summed output increases by 10 × log10(N)
if all channels have uncorrelated noise, where N is the number
of channels to be summed.
The summed signal level increases by a factor of N while the
noise increases only as √N. In the case of 64 channels, this is an
increase in dynamic range of 18 dB. Note that the AD8333
dynamic range is already about 160 dB/Hz; the summed
dynamic range is 178 dB/Hz (equivalent to about 29.5 b/Hz).
In a 50 kHz noise bandwidth, this is 131 dB (21.7 bits).
DISABLING THE CURRENT MIRROR AND
DECREASING NOISE
The noise contribution of the AD8333 can potentially be
reduced if the current mirrors that convert the internal
differential signals to single ended are bypassed (see Figure 56).
Current mirrors interface to the AD8021 I-V converters shown
in Figure 53, and output capacitors across the positive and negative
outputs provide low-pass filtering. The AD8021s force the
AD8333 output voltage to 0 V and process the bipolar output
current; however, the internal current mirrors introduce a
significant amount of noise. This noise can be reduced if they
are disabled and the outputs externally biased.
The mirrors are disabled by connecting VNEG to ground and
providing external bias networks, as shown in Figure 56. The
larger the drop across the resistors, the less noise they contribute to
the output; however, the voltage on the IxxO and QxxO nodes
cannot exceed 0.5 V. Voltages exceeding approximately 0.7 V
turn on the PNP devices and forward bias the ESD protection
diodes. Inductors provide an alternative to resistors, enabling
reduced static power by eliminating the power dissipation in the
bias resistors.
VNEG
1
1
NOTE THAT PIN VNEG AND PIN COMM
ARE CONNECTED TOGETHER.
COMM
IxNO
QxNO
IxPO
QxPO
I-V
I-V
05543-039
OTHER
CHANNELS
Figure 56. Bypassing the Internal Current Mirrors
With inductors, the main limitation might be low frequency
operation, as is the case in CW Doppler in ultrasound where
the frequency range of interest goes from a few hundred Hertz
to about 30 kHz. In addition, it is still important to provide
enough gain through the I-to-V circuitry to ensure that the bias
resistor and I-to-V converter noise do not contribute significantly
to the noise from the AD8333 outputs. Another approach could
be to provide a single external current mirror that combines all
channels; it would also be possible to implement a high-pass
filter with this circuit to help with offset and low frequency
reduction.
AD8333
Rev. B | Page 23 of 28
The main disadvantage of the external bias approach is that now
two I-V amplifiers are needed because of the differential output
(see Figure 56). For beamforming applications, the outputs
would still be summed as before, but now there is twice the
number of lines. Only two bias resistors are needed for all
outputs that are connected together. The resistors are scaled by
dividing the value of a single output bias resistor through N,
the number of channels connected in parallel. The bias current
depends on the phase selected: for phase 0°, this is about
2.5 mA per side, while in the case of 45°, this is about 3.5 mA
per side. The bias resistors should be chosen based on the
larger bias current value of 3.5 mA and the chosen VNEG.
VNEG should be at least −5 V and can be larger for additional
noise reduction.
Excessive noise or distortion at high signal levels degrades the
dynamic range of the signal. Transmitter leakage and echoes
from slow moving tissue generate the largest signal amplitudes
in ultrasound CW Doppler mode and are largest near dc and at
low frequencies. A high-pass filter introduced immediately
following the AD8333 reduces the dynamic range. This is
shown by the two coupling capacitors after the external bias
resistors in Figure 56. Users have to determine what is acceptable
in their particular application. Care must be taken in designing
the external circuitry to avoid introducing noise via the external
bias and low frequency reduction circuitry.
AD8333
Rev. B | Page 24 of 28
APPLICATIONS
The AD8333 is the key component of a phase-shifter system
that aligns time-skewed information contained in RF signals.
Combined with a variable gain amplifier (VGA) and low noise
amplifier (LNA), the AD8333 forms a complete analog receiver
for a high performance ultrasound system. Figure 57 is a block
diagram of a complete receiver using the AD8333 and the
AD8332 family.
PROCESSOR
I1
Q1
16-BIT
ADC
16-BIT
ADC PROCESSOR
I2
Q2
PROCESSOR
HS ADC
PROCESSOR
HS ADC
AD8332
LNA1
LNA2
AD8333
FROM
T
RANSDUCE
R
T/R SWITCH
FROM
T
RANSDUCE
R
T/R SWITCH
05543-059
Figure 57. Block Diagram—Ultrasound Receiver Using the AD8333
and AD8332 LNA
As a major element of an ultrasound system, it is important to
consider the many I/O options of the AD8333 necessary to
perform its intended function. Figure 61 shows the basic
connections.
LOGIC INPUTS AND INTERFACES
The logic inputs of the AD8333 are all bipolar-level sensitive
inputs. They are not edge triggered, nor are they to be confused
with classic TTL or other logic family input topologies. The
voltage threshold for these inputs is VPOS × 0.3, so for a 5 V
supply the threshold is 1.5 V, with a hysteresis of ±0.2 V.
Although the inputs are not of themselves logic inputs, any 5 V
logic family can drive them.
RESET INPUT
The RSET pin is used to synchronize the LO dividers in
AD8333 arrays. Because they are driven by the same internal
LO, the two channels in any AD8333 are inherently synchronous.
However, when multiple AD8333s are used, it is possible that
their dividers wake up in different phase states. The function of
the RSET pin is to phase align all the LO signals in multiple
AD8333s.
The 4 × LO divider of each AD8333 can initiate in one of four
possible states: 0°, 90°, 180°, or 270°. The internally generated
I/Q signals of each AD8333 LO are always at a 90° angle relative
to each other, but a phase shift can occur during power-up
between the internal LOs of the different AD8333s.
The RSET pin provides an asynchronous reset of the LO
dividers by forcing the internal LO to hang. This mechanism
also allows the measurement of nonmixing gain from the RF
input to the output.
The rising edge of the active high RSET pulse can occur at any
time; however, the duration must be ≥ 300 ns minimum (tPW-MIN).
When the RSET pulse transitions from high to low, the LO
dividers are reactivated; however, there is a short delay until the
divider recovers to a valid state. To guarantee synchronous
operation of an array of AD8333s, the 4 LO clock must be
disabled when the RSET transitions high and remain disabled
for at least 300 ns after RSET transitions low.
THE TIMING OF THE RISING
EDGE OF RSET IS NOT
CRITICAL AS LONG AS THE
t
PW-MIN
IS SATISFIED
t
HOLD
=HOLDTIME
t
PW-MIN
= MINIMUM PULSE WIDTH
4×LO
RSET
t
PW-MIN
t
HOLD
05543-060
Figure 58. Timing of the RSET Signal to 4 LO
Synchronization of multiple AD8333s can be checked as
follows:
• Set the phase code of all AD8333 channels the same, for
example, 0000.
• Apply a test signal to a single channel that generates a sine
wave in the baseband output and measure the output.
• Apply the same test signal to all channels simultaneously and
measure the output.
• Since all the phase codes of the AD8333s are the same, the
combined signal should be N times bigger than the single
channel. The combined signal is less than N times one channel if
any of the LO phases of individual AD8333s are in error.
CONNECTING TO THE LNA OF THE AD8331/
AD8332/AD8334/AD8335 VGAs
RFxP
RFxN
+5V
–5V
AD8333
AD8332
LNA
05543-061
Figure 59. Connecting the AD8333 to the LNA of an AD8332
The RFxx inputs (Pin 12, Pin 13, Pin 28, and Pin 29) are
optimized for maximum dynamic range when dc-coupled to
the differential output pins of the LNA of the AD8331/AD8332/
AD8334 or the AD8335 series of VGAs and can be connected
directly, as shown in Figure 59.
AD8333
Rev. B | Page 25 of 28
If amplifiers other than the AD8332 LNA are connected to the
input, attention must be paid to their bias and drive levels. For
maximum input signal swing, the optimum bias level is 2.5 V,
and the RF input must not exceed 5 V to avoid turning on the
ESD protection circuitry. If ac coupling is used, a bias circuit,
such as that illustrated in Figure 60, is recommended. An
internal bias network is provided; however, additional external
biasing can center the RF input at 2.5 V.
LO INPUT
The LO input is a high speed, fully differential, analog input
that responds to differences in the input levels (and not logic
levels). The LO inputs can be driven with a low common-mode
voltage amplifier, such as the National Semiconductor
DS90C401 LVDS driver.
The graphs shown in Figure 22 and Figure 23 show the range of
common-mode voltages and useable LO levels when the LO
input is driven with a single-ended sine wave. Logic families,
such as TTL or CMOS, are unsuitable for direct coupling to
the LO input.
AD8333
RFxP
RFxN
–5V
+5
V
3.74kΩ
1.4kΩ
1.4kΩ
5.23kΩ
0.1µF
0.1µF
RF IN
05543-062
EVALUATION BOARD
Figure 62 is the evaluation board schematic. Consult the
AD8333-EVAL data sheet for further details.
Figure 60. AC Coupling the AD8333 RF Input
PH11
31
PH10
30
VPOS
29
RFIP
28
RFIN
27
VPOS
26
ENBL
25
I1N0
10
9
PH20
11
VPOS
12
RF2P
13
RF2N
14
VPOS
15
RSET
16
I2NO
32
PH12 I1PO
124
PH13 Q1PO
223
COMM Q1NO
322
4LOP VNEG
421
4LON COMM
520
LODC Q2NO
619
PH21
Q2PO
718
PH23
PH22 I2PO
817
0.1µF
0.1µF
31.6kΩ
33.2kΩ33.2kΩ
31.6kΩ
0.1µF
+5V
*
LOCAL
OSC
+
–
CHANNEL 1
+ I OUT
CHANNEL 2
+ Q OUT
CHANNEL 1
+ Q OUT
CHANNEL 2
+ I OUT
120nH FB
–5V
0.1µF
+5V
V
POS
120nH FB
0.1µF
CHANNEL 1
RF IN
CHANNEL 2
RF IN
CHANNEL 1
PHASE
SELECT BITS
CHANNEL 2
PHASE
SELECT BITS
–
–
+
+
RESET
INPUT
VPOS
0.1µF
AD8333
*OPTIONAL BIAS NETWORK. THESE COMPONENTS
MAY BE DELETED IF THE LO IS DC-COUPLED FROM
AN LVDS SOURCE BIASED AT 1.2V.
05543-040
Figure 61. AD8333 Basic Connections
AD8333
Rev. B | Page 26 of 28
13 14 15 16
COMM
Q2NO
Q1PO
Q1NO
Q2PO
PH12
4LOP
PH13
VNEG
I2PO
8
7
6
5
1
4
3
2
19
17
18
24
20
23
22
21
26 25
2730 29 28
PH22
LODC
PH23
4LON
COMM
PH21
PH20
RF2N
VPOS
VPOS
I2NO
RSET
RF2P
I2PO
VPOS
VPOS
RFIN
31
RFIP
PH10
ENBL
PH11 I1N0
32
AD8333
RST
+5V
SW12
SW13
SW14
SW11
SW23
Q2
I2
I1
Q1
R33
0Ω
1
8
34
5
6
VPOS
SW15
LOP
+
–
+
–
+
–
+
–
VPS
IN2
29
30
3132 28 252627
COM1
LOP1
VIP1
VIN1
ENBL
VCM1
ENBV
HILO
LMD2
LON2
VPS2
INH2
LMD1
LON1
VPS1
INH1
8
7
6
5
1
4
3
2
COMM
VOL2
VOH2
VOH1
VOL1
NC
VPSV
COMM
20
17
18
19
21
22
23
24
VIP2
VIN2
LOP2
COM2
RCLMP
VCM2
MODE
GAIN
IN1
VPS
VPS
+5VS
TP2
TP1
TP4
TP3
TP8
TP7
TP6
TP5
4
32
5
17
6
8
+
+
R9
274Ω
C39
0.018µF
C1
0.1µF
C2
22pF
L1
120nH FB
C6
0.1µF
C4
0.1µF
L2
120nH FB
C3
22pF
C40
0.018µF
R10
274Ω
C5
0.1µF
Z1
AD8332
C14
0.1µF
C11
0.1µF
9101112
+5V
L5 120nH FB
C42
0.1µF
C43
1nF
R1
100Ω
C13
0.1µF
R6
3.48kΩ
C9
0.1µF
Z3
DS90C401
R7
1.5kΩ
R13
49.9Ω
R22
20Ω
R23
20Ω
+5V
910111213141516
R4
OPT
R2
0Ω
R3
0Ω
C17
0.1µF
R5
OPT
C36
0.1µF C48
0.1µF
–5V
–5V
L4
120nH FB
L7
120nH FB
C47
0.1µF
–5VS
A3
AD8021
27
1
8
34
5
6
A1
AD8021
27
+5VS
C46
0.1µF
R40
787Ω
C29
2.2nF
C28
5pF
R39
787Ω
C26
2.2nF
R32
0Ω
–5VS
C27
5pF
C45
0.1µF
GND1 GND2 GND3 GND4
–5V
–5V
+5V
+5V
C8
10µF
10V
C7
10µF
10V
+5VS
C44
0.1µF
L6
120nH FB
+5VS
+5VS
C49
0.1µF
R41
787Ω
C31
2.2nF
1
8
34
5
6
27
A4
AD8021
1
8
34
5
6
27
C30
5pF
–5VS
R42
787Ω
C50
0.1µF
C32
2.2nF
R38
0Ω
–5VS
C33
5pF
A2
AD8021
R35
0Ω
C52
0.1µF
+5VS
C51
0.1µF
+5VS
C41
0.1µF
+5V
R26
20Ω
R25
20ΩSW5
SW6
SW7
SW8 VPOS
L3
120nH FB
C24
0.1µF
R15
OPT
05543-042
C12
0.1µF
Z3 SPARE
Figure 62. AD8333 Evaluation Board Schematic
AD8333
Rev. B | Page 27 of 28
OUTLINE DIMENSIONS
COMPLIANT TO JEDEC STANDARDS MO-220-VHHD-2
041806-A
0.30
0.23
0.18
0.20 REF
0.80 MAX
0.65 TYP
0.05 MAX
0.02 NOM
12° MAX
1.00
0.85
0.80 SEATING
PLANE
COPLANARITY
0.08
1
32
8
9
25
24
16
17
0.50
0.40
0.30
3.50 REF
0.50
BSC
PIN 1
INDICATOR
TOP
VIEW
5.00
BSC SQ
4.75
BSC SQ
3.25
3.10 SQ
2.95
PIN 1
INDICATOR
0.60 MAX
0.60 MAX
0.25 MIN
EXPOSED
PAD
(BOTTOM VIEW)
THE EXPOSE PAD IS NOT CONNECTED
INTERNALLY. FOR INCREASED RELIABILITY
OF THE SOLDER JOINTS AND MAXIMUM
THERMAL CAPABILITY IT IS RECOMMENDED
THAT THE PAD BE SOLDERED TO
THE GROUND PLANE.
Figure 63. 32-Lead Lead Frame Chip Scale Package [LFCSP_VQ]
5 mm × 5 mm Body, Very Thin Quad
(CP-32-2)
Dimensions shown in millimeters
ORDERING GUIDE
Model Temperature Range Package Description Package Option
AD8333ACPZ1−40°C to +85°C 32-Lead Lead Frame Chip Scale Package [LFCSP_VQ] CP-32-2
AD8333ACPZ-REEL1−40°C to +85°C 32-Lead Lead Frame Chip Scale Package [LFCSP_VQ] CP-32-2
AD8333ACPZ-REEL71−40°C to +85°C 32-Lead Lead Frame Chip Scale Package [LFCSP_VQ] CP-32-2
AD8333ACPZ-WP1, 2−40°C to +85°C 32-Lead Lead Frame Chip Scale Package [LFCSP_VQ] CP-32-2
AD8333-EVALZ1 Evaluation Board
1 Z = RoHS Compliant Part.
2 WP = Waffle pack.
AD8333
Rev. B | Page 28 of 28
NOTES
©2005–2007 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D05543-0-5/07(B)
