AD AD8339

Quad I/Q Demodulator And Phase Shifter
Preliminary Technical Data
AD8339
FEATURES
Quad Integrated I/Q Demodulator
16 Phase Select on each Output (22.5° per step)
Quadrature Demodulation Accuracy
Phase Accuracy ±1°
Amplitude Balance ±0.25 dB
Bandwidth
4LO: LF – 100 MHz; RF: LF - 25 MHz
Baseband: determined by external filtering
Output Dynamic Range 158 dB (1 Hz Bandwidth)
LO Drive > –10 dBm (50 Ω); 200 mVpp
Supply: ±5 V
Power Consumption 73 mW/channel (290 mW total)
Power Down via SPI (Each Channel and Complete Chip)
APPLICATIONS
Medical Imaging (CW Ultrasound Beamforming)
Phased Array Systems
Radar
Adaptive Antennas
Communication Receivers
FUNCTIONAL BLOCK DIAGRAM
RF1
2
BIAS
RSET
0
φ
I1
90
φ
Q1
90
φ
Q2
0
φ
I2
4
RF2
2
4xLO
RF3
2
Serial
Interface
/4
4
2
VPOS
COMM
VNEG
SCLK
SDI
SDO
CSB
0
φ
I3
90
φ
Q3
90
φ
Q4
0
φ
I4
2
RF4
Figure 1. Functional Block Diagram
GENERAL DESCRIPTION
The AD8339 is a Quad I/Q demodulator intended to be driven by a
low noise preamplifier with differential outputs; it is optimized for the
LNA in the AD8332/4/5 family of VGAs. The part consists of four
identical I/Q demodulators with a 4x local oscillator (LO) input that
divides this signal and generates the necessary 0° and 90° phases of
the internal LO that drive the mixers. The four I/Q demodulators can
be used independently of each other (assuming that a common LO is
acceptable) since each has a separate RF input.
The major application is continuous wave (CW) analog beamforming
in ultrasound. Since in a beamforming application the outputs of
many channels are summed coherently, the signals need to be phase
aligned. A reset pin for the LO divider that synchronizes multiple ICs
to start in the same quadrant is provided. 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 CH2 has an
I/Q phase lead of 45°, then by choosing the correct code one can
phase align CH2 with CH1.
The mixer outputs are provided in current form so that they can be
easily summed. The summed current outputs, one each for the I and
Q signals, will need to be converted to a voltage by a high dynamic
range current-to-voltage (I-V) converter. A good choice for this
transimpedance amplifier is the AD8021 because of its low noise.
Following the current summation the combined signal is presented to
a high resolution AD converter (ADC) like the AD7665 (16b/570
ksps).
An SPI compatible serial interface is provided for ease of
programming the phase of each channel; the interface allows daisychaining by shifting the data through each chip from SDI to SDO. The
SPI also allows for power down of each individual channel and the
complete chip. During power down the serial interface remains active
so that the device can be programmed again.
The dynamic range is >158 dB (1 Hz BW) at the I and Q outputs.
Note that the following transimpedance amplifier is an important
element in maintaining this dynamic range and attention needs to be
paid to component selection.
The AD8339 will be available in a 6x6 mm 40 pin LFCSP for the
industrial temperature range of -40°C to +85°C.
Rev. PrA - 12/19/06
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.
Specifications subject to change without notice. No license is granted by implication
or otherwise under any patent or patent rights of Analog Devices. Trademarks and
registered trademarks are the property of their respective companies.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
www.analog.com
Tel: 781.329.4700
Fax: 781.326.8703
© 2007 Analog Devices, Inc. All rights reserved.
AD8339
Preliminary Technical Data
TABLE OF CONTENTS
AD8339 Specifications.................................................................... 3
Dynamic Range and Noise........................................................ 11
Absolute Maximum Ratings............................................................ 5
Summation of Multiple Channels (Analog Beamforming).. 12
ESD Caution.................................................................................. 5
Phase Compensation and Analog Beamforming................... 12
Pin Configuration and Function Descriptions............................. 6
Serial Interface ............................................................................ 13
Equivalent Input Circuits ................................................................ 7
ENBL Bits ................................................................................ 13
Typical Performance Characteristics ............................................. 8
Applications..................................................................................... 14
Test Circuits....................................................................................... 9
Logic Inputs and Interfaces....................................................... 14
Theory of Operation ...................................................................... 10
Reset Input .................................................................................. 14
Quadrature Generation ............................................................. 10
Outline Dimensions ....................................................................... 15
I/Q Demodulator and Phase Shifter ........................................ 10
REVISION HISTORY
12/19/06 – Rev. Prelim A1
Rev. PrA | Page 2 of 15
Preliminary Technical Data
AD8339
AD8339 SPECIFICATIONS
Table 1. VS = ±5 V, TA = 25°C, 4 fLO = 20 MHz, fRF = 5.01 MHz, fBB = 10 kHz, PLO ≥ 0 dBm, per channel performance, dBm (50 Ω)
unless otherwise noted. Single channel AD8021 LPF values RFILT = 1.58 kΩ and CFILT = 1 nF (see Figure 2).
Parameter
OPERATING CONDITIONS
LO Frequency Range
RF Frequency Range
Baseband Bandwidth
LO Input Level
VSUPPLY (VS)
Temperature Range
DEMODULATOR PERFORMANCE
Input Impedance
Transconductance
Conditions
Min
4x internal LO at pins 4LOP and 4LON
Square Wave
Sine Wave
Mixing
Limited by external filtering
LF
TBD
LF
LF
±4.5
-40
RF - Differential
LO – Differential
Demodulated IOUT/VIN; Each Ix or Qx output after
low pass filtering measured from RF inputs
All Phases
IP1dB minus Input referred noise (dBm)
Typ
0
±5
Max
Unit
100
100
25
25
13
±5.5
+85
MHz
MHz
MHz
MHz
dBm
V
°C
7||7
100||1
kΩ||pF
kΩ||pF
1.1
158
Max Input Swing
Differential; Inputs biased at 2.5V; Pins RFxP,
RFxN
2.7
mS
dB (1Hz
BW)
Vpp
Peak Output Current (No Filtering)
0° Phase Shift
45° Phase Shift
Ref = 50 Ω
Ref = 1VRMS
fRF1 = 5.010 MHz, fRF2 = 5.015 MHz, fLO = 5.023
MHz
Baseband tones: -7 dBm @ 8 kHz and 13 kHz
Baseband tones: -1 dBm @ 8 kHz and -31 dBm
@13 kHz
Same conditions as IM3
Measured at RF inputs, worst phase, measured
into 50 Ω
Measured at baseband outputs, worst phase,
AD8021 disabled, measured into 50 Ω
All codes, see Figure XX
Output Noise ÷ Conversion Gain (see Figure XX)
Output noise ÷ 1.58 kΩ
With AD8332 LNA
RS = 50 Ω, RFB = ∞
RS = 50 Ω, RFB = 1.1k Ω
RS = 50 Ω, RFB = 274 Ω
Pins 4LOP and 4LON
Pins RFxP and RFxN
Pins 4LOP and 4LON (each pin)
For maximum differential swing; Pins RFxP and
RFxN (DC-coupled to AD8332 output)
Pins IxOP and QxOP
±2.4
±3.3
14.5
1.5
mA
mA
dBm
dBV
-75
TBD
dBc
dBc
30
TBD
dBm
dBm
TBD
dBm
4.7
TBD
TBD
dB
nV/√Hz
pA/√Hz
TBD
TBD
TBD
-2
-35
dB
dB
dB
Dynamic Range
Input P1dB
Third Order Intermodulation (IM3)
Equal Input Levels
Unequal Input Levels
Third Order Input Intercept (IIP3)
LO Leakage
Conversion Gain
Input Referred Noise
Output Current Noise
Noise Figure
Bias Current
LO Common Mode Range Range
RF Common Mode Voltage
Output Compliance Range
Rev. PrA | Page 3 of 15
3.8
0.2
2.5
-1.5
0.7
μA
μA
V
V
V
Preliminary Technical Data
AD8339
PHASE ROTATION PERFORMANCE
Phase Increment
Quadrature Phase Error
I/Q Amplitude Imbalance
Channel-to-Channel Matching
LOGIC INTERFACES
Logic Level High
Logic Level Low
Bias Current
Input Resistance
LO Divider RSET Setup Time
LO Divider RSET High Pulse Width
LO Divider RSET Setup Time
Phase Response Time
Enable Response Time
Output
Logic Level High
Logic Level Low
SPI TIMING CHARACTERISTICS
SCLK Frequency
CSB to SCLK Setup Time
SCLK High Pulse Width
SCLK Low Pulse Width
Data Access Time after SCLK Falling Edge
Data Setup Time Prior to SCLK Rising Edge
Data Hold Time after SCLK Rising Edge
CSB High Pulse Width
SCLK Fall to CSB Fall Hold Time
SCLK Fall to CSB Rise Hold Time
POWER SUPPLY
Supply Voltage
Quiescent Current
Over Temperature
Quiescent Power
Disable Current
PSRR
One CH is reference, others are stepped
16 Phase Steps per Channel
±1
0.25
°
°
dB
±1
±0.5
°
dB
22.5
Ix to Qx; all phases, 1σ
Ix to Qx; all phases, 1σ
Phase Match I-to-I and Q-to-Q; -40°C < TA < 85°C
Ampl. Match I-to-I and Q-to-Q; -40°C < TA < 85°C
Pins SDI,CSB,SCLK, RSTS,RSET
1.5
5
V
V
μA
μA
MΩ
ns
20
5
ns
ns
0.9
Logic High (pulled to +5V)
Logic Low (pulled to GND)
RSET rising edge to 4LOP-4LON (Differential)
rising edge
RSET falling edge prior to 4LOP-4LON
(Differential) rising edge
Measured from CSB going high
Measured from CSB going high (with 0.1 μF cap
on pin LODC)
Pin SDO
Loaded with 5 pF and next SDI input
Loaded with 5 pF and next SDI input
Pins SDI,SDO,CSB,SCLK, RSTS
fCLK
T1
T2
T3
T4
T5
T6
T7
T8
T9
Pins VPOS,VNEG
0.5
0
4
1.7
Rev. PrA | Page 4 of 15
1.9
0.2
0.5
10
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
TBD
±4.5
VPOS, all phase bits = 0
VNEG, all phase bits = 0
-40°C < TA < 85°C
Per Channel, all phase bits = 0
Per Channel max (depends on phase bits)
All Channels Disabled; SPI stays on
VPOS to Ix/Qx outputs (meas. @ AD8021 output)
VNEG to Ix/Qx outputs (meas. @ AD8021 output)
μs
μs
TBD
15
±5
37.5
-21
TBD
±5.5
TBD
73
TBD
2.6
TBD
TBD
V
V
MHz
ns
ns
ns
ns
ns
ns
ns
ns
V
mA
mA
mA
mW
mW
mA
dB
dB
Preliminary Technical Data
AD8339
ABSOLUTE MAXIMUM RATINGS
Table 2.
Parameter
Voltages
Supply Voltage VS
RF Inputs
4LO Inputs
Outputs (IxOP, QxOP)
Digital Inputs
SDO Output
LODC Pin
Thermal Data —4 Layer Jedec Board
No Air Flow (Exposed Pad Soldered
to PC Board)
θJA
θJB
θJC
ΨJT
ΨJB
Maximum Junction Temperature
Maximum Power Dissipation
(Exposed Pad Soldered to PC Board)
Operating Temperature Range
Storage Temperature Range
Lead Temperature Range (Soldering 60 sec)
Rating
±6 V
+6 V, GND
+6 V, GND
+1 V, -6 V
+6 V, GND
+6 V, GND
+6 V (max)
VPOS –1.5 V (min)
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.
TBD°C/W
TBD°C/W
TBD°C/W
TBD°C/W
TBD°C/W
150°C
TBD W
–40°C to +85°C
–65°C to +150°C
300°C
ESD 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 this product features
proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high energy
electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance
degradation or loss of functionality.
Rev. PrA | Page 5 of 15
Preliminary Technical Data
AD8339
31 VNEG
32 Q1OP
33 I1OP
34 RSET
35 VPOS
36 COMM
37 RF1N
38 RF1P
39 SDI
40 RSTS
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
RF2N
1
RF2P
2
30 Q2OP
COMM
3
28 VPOS
COMM
4
27 VPOS
SCLK
5
AD8339
26 4LOP
CSB
6
Top View
25 4LON
VPOS
7
(not to scale)
24 VNEG
VPOS
8
23 VNEG
RF3P
9
22 I3OP
Pin 1
Identifier
29 I2OP
VNEG 20
Q4OP 19
I4OP 18
LODC 17
VPOS 16
COMM 15
RF4N 14
RF4P 13
SDO 12
21 Q3OP
VPOS 11
RF3N 10
Figure 2. 40-Lead LFCSP
Table 3. Pin Function Descriptions
Pin No.
1, 2, 9, 10,
13, 14, 37,
38
3, 4, 15, 36
5
6
7, 8, 11,
16, 27, 28,
35
12
17
Mnemonic
RF1P-RF4P
RF1N-RF4N
Description
RF Inputs. No internal bias. The optimum common mode voltage for maximum symmetrical input differential
swing is 2.5 V if ±5 V supplies are used.
COMM
SCLK
CSB
VPOS
Ground
Serial Interface – Clock
Serial Interface – Chip Select Bar. Active Low.
Positive Supply. These pins should be decoupled with a ferrite bead in series with the supply, plus a 0.1 μF
and 1 nF capacitor between the VPOS pins and ground. Since the VPOS pins are internally connected, one set
of supply decoupling components on each side of the chip should be sufficient.
Serial Interface – Data Output. Normally connected to SDI of next chip or left open.
Decoupling Pin for LO. A 0.1 μF capacitor should be connected between this pin and ground. Value of cap
does influence chip enable/disable times.
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 through simply connecting them
(Wire-OR). The bias voltage should be set to 0 V or less by the transimpedance amplifier, see Figure 7.
Negative Supply. These pin should be decoupled with a ferrite bead in series with the supply, plus a 0.1 μF
and 1 nF capacitor between the pin and ground. Since the VNEG pins are internally connected, one set of
supply decoupling components should be sufficient.
LO Inputs. No internal bias; optimally biased by an LVDS driver. For best performance, these inputs should be
driven differentially.
LO Interface - Reset. Logic threshold is at about 1.1 V and therefore can be driven by >1.8 V CMOS logic.
Serial Interface – Data Input. Logic threshold is at about 1.1 V and therefore can be driven by >1.8 V CMOS
logic.
Reset for SPI Interface. Logic threshold is at about 1.1 V and therefore can be driven by >1.8 V CMOS logic. For
quick testing without the need to program the SPI, the voltage on the RSTS pin should be pulled to -1.4 V;
this enables all four channels in the Phase (I=1,Q=0) state.
SDO
LODC
18, 19, 21,
22, 29, 30,
32, 33
20, 23, 24,
31
I1OP-I4OP,
Q1OP-Q4OP
25, 26
4LOP, 4LON
34
39
RSET
SDI
40
RSTS
VNEG
Rev. PrA | Page 6 of 15
Preliminary Technical Data
AD8339
EQUIVALENT INPUT CIRCUITS
VPOS
RSTS
SCLK
SDI
SDO
CSB
VPOS
LOGIC
INTERFACE
RFxP
COMM
RFxN
COMM
Figure 3. Logic Inputs
Figure 6. RF Inputs
VPOS
COMM
4LOP
Ix
Qx
4LON
COMM
VNEG
Figure 4. Local Oscillator Inputs
Figure 7. Output Drivers
VPOS
LODC
COMM
Figure 5. LO Decoupling Pin
Rev. PrA | Page 7 of 15
Preliminary Technical Data
AD8339
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 (50Ω); single-ended sine wave; per channel
performance, differential voltages, dBm (50Ω), phase select code = 0000, unless otherwise noted (see Error! Reference source not
found.).
Rev. PrA | Page 8 of 15
Preliminary Technical Data
AD8339
TEST CIRCUITS
Rev. PrA | Page 9 of 15
Preliminary Technical Data
AD8339
THEORY OF OPERATION
The AD8339 is a quad I/Q demodulator with a programmable
phase shifter for each channel. The primary application is
phased array beamforming in medical ultrasound. Other
potential applications might be phased array radar, and smart
antennas for mobile communications. The AD8339 can also be
used in applications that require multiple well-matched I/Q
demodulators. The AD8339 is architecturally very similar to its
predecessor – the AD8333. The major differences are:
divide-by-four 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 4xLO input. Furthermore, the
divider is implemented such that the 4xLO signal re-clocks the
final flip-flops that generate the internal LO signals and thereby
minimizes noise introduced by the divide circuitry.
1.
For optimum performance, the 4xLO input is 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 the nominal ±5
V supplies.
2.
the addition of a serial (SPI) interface that allows daisychaining of multiple devices
reduced power per channel at the expense of a slight
decrease in dynamic range
RF2N
BIAS
2
COMM
3
SDI
RSTS
4
SCLK
5
CSB
VPOS
6
SCLK
RF3P
9
0
Q1OP
VNEG
32
31
I/V
29
I2OP
φ
I/V
28
VPOS
27
VPOS
26
4LOP
25
4LON
24
VNEG
I/V
90
CSB
Serial
Interface
(SPI)
φ
I/V
CHANNEL 3
φ
I/V
23
VNEG
φ
I/V
22
I3OP
21
Q3OP
CHANNEL 4
φ
10
11
12
13
14
15
16
17
18
19
20
SDO
RF4P
RF4N
COMM
VPOS
LODC
I4OP
Q4OP
VNEG
I/V
VPOS
SDO
The minimum 4xLO level is frequency dependent. 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
AD8339 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 is provided to synchronize the LO divider circuits in
different AD8339s when they are used in arrays. The RSET pin
resets the dividers to a known state after power is applied to
multiple AD8339s. A logic input must be provided to the RSET
pin when using more than one AD8339. Note that at least one
channel must be enabled for the LO interface to also be enabled
and the LO reset to work. See the Reset Input section in the
applications section for more detail.
I/Q DEMODULATOR AND PHASE SHIFTER
LO
Divide-by-4
V/I
RF3N
Q2OP
CHANNEL 2
V/I
8
30
φ
φ
7
VPOS
I/V
CHANNEL 1
V/I
V/I
COMM
I1OP
φ
1
RF2P
33
RSET
COMM
36
34
RF1N
37
VPOS
RF1P
38
35
SDI
39
40
RSTS
Figure 1 shows the block diagram and pinout of the AD8339.
Four RF inputs accept signals from the RF sources, and a local
oscillator (applied to differential input pins marked 4LOP and 4
LON) common to all channels, comprise the analog inputs.
Each channel has the option to program 16 delay states/360° (or
22.5°/step) selectable via the SPI port. The part has two reset
inputs: RSET is used to synchronize the LO dividers in multiple
AD8339s used in arrays; RSTS is used to set the SPI port bits to
all zeros. This can be useful in testing or when one quickly
wants to turn off the device without first programming the SPI
port.
Figure 1. 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
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 2.7 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 codes
programmed into the SPI latch (see Table 4); the phase bits are
labeled PHx0 through PHx3 where ‘0’ indicates LSB and ‘3’
indicates MSB. 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 a pair of
RF-inputs to an AD8339, 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, then 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
Rev. PrA | Page 10 of 15
Preliminary Technical Data
AD8339
current mirror. An external transimpedance amplifier is needed
to convert the I and Q outputs to voltages.
voltage noise density (en) of the AD8339 is nominally about
TBD nV/√Hz. For the noise of the AD8339 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 AD8339
or TBD nV/√Hz. If the noise of the circuitry before the AD8339
is less than TBD nV/√Hz then the system NF degrades more
than 1 dB. For example, if the noise contribution of the LNA
and source is equal to the AD8339, or TBD nV/√Hz, the
degradation is 3 dB. If the circuit noise preceding the AD8339 is
1.3× as large as that of the AD8339 (or about TBD nV/√Hz) the
degradation is 2 dB. For a circuit noise 1.45× that of the
AD8339 (TBD nV/√Hz) the degradation is 1.5 dB.
Table 4. Phase Select Code for Channel-to-Channel Phase
Shift
φ-Shift
0º
22.5º
45º
67.5º
90º
112.5º
135º
157.5º
180º
202.5º
225º
247.5º
270º
292.5º
315º
337.5º
PHx3 (MSB)
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
PHx2
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
PHx1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
PHx0 (LSB)
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
DYNAMIC RANGE AND NOISE
Figure 2 is an interconnection block diagram of two channels
(1/2 of the AD8339), more channels are easily added to the
summation (up to 16 when using an AD8021 as the summation
amplifier) by wire-or connecting the outputs as shown for two
channels. For optimum system noise performance, the RF
input signal is provided by a very low noise amplifier such as
the LNA of the AD8332/AD8334 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 2). 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 2 is increased
by 3 dB while the signal doubles (+6 dB), yielding an aggregate
SNR improvement of (+6 − 3) = +3 dB. For four channels the
dynamic range will increase by +6 dB and so on.
Judicious selection of the RF amplifier ensures the least
degradation in dynamic range. The input referred spectral
To determine the input referred noise it is important to know the
active low pass filter (LPF) values RFILT and CFILT, shown in Figure 2.
Typical filter values for a single channel are 1.58 kΩ and 1 nF, and
implement a 100 kHz single-pole LPF. In the case that two channels
are summed as is done on the evaluation board, the values would
be the same as for a single channel of the AD8333, namely 787 Ω
and 2.2 nF.
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 TBD nV/√Hz of
AD8339 noise results in about TBD nV/√Hz at the AD8021
output. Since the AD8021, including the 1.58 kΩ feedback resistor,
contributes another 6.3 nV/√Hz, the total output referred noise is
about TBD 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.
Because any amplifier has limited drive capability there will be a
finite number of channels that can be summed. This is explained in
great detail in the section below called – Channel Summing.
Rev. PrA | Page 11 of 15
Preliminary Technical Data
AD8339
RFB
TRANSMITTER
T/R
SW
AD8332 LNA OR
AD8335 PREAMP
TRANSDUCER
CH1
PHASE
SELECT
CH1
RF
AD8333
½
AD8339
0°
2
4
2
2
Φ
CFILT
I1
*
2
90°
CLOCK
GENERATOR
Φ
ΣI
Q1
AD8021
2
Q2
CFILT
2
Φ
2
I2
*
2
0°
Φ
2
CH2
PHASE
SELECT
ADC 16-BIT
570kSPS Q DATA
AD8021
TO
CHANNELS
**UP
Up to
168channels
of
PER AD8021
AD8339
per AD8021
05543-038
AD8332 LNA OR
AD8335 PREAMP
T/R
SW
ΣQ
4
CH2
RF
TRANSMITTER
RFILT
ADC 16-BIT I DATA
570kSPS
AD7665 OR
AD7686
÷4
90°
TRANSDUCER
RFILT
2
RFB
Figure 2. Interconnection Block Diagram for ½ of AD8339
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
AD8339 is in analog beamforming circuits for ultrasound.
PHASE COMPENSATION AND ANALOG
BEAMFORMING
Modern ultrasound machines used for medical applications
employ an array of receivers for beamforming, with typical CW
Doppler array sizes up to 64 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 cross-point 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 which also sums the signals from
the various channels, and then the combined signal is down-
converted by a very large dynamic range I/Q demodulator.
The resultant I and Q signals are filtered and then sampled by
two high resolution AD converters. 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
down-converted signal, and then combining all channels. The
AD8333 and the AD8339 provide the means to implement this
architecture. The down-conversion 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 AD converters are similar.
The AD8339 integrates the phase shifter, frequency conversion,
and I/Q demodulation into a single package, and directly yields
the baseband signal.
Figure 3 is a simplified diagram showing the idea for 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°.
TRANSDUCER
ELEMENTS TE1
AND TE2
CONVERT USW TO
ELECTRICAL
AD8332
USW AT TE1
SIGNALS
LEADS USW
ES1 LEADS
AT TE2 BY
ES2 BY 45°
45°
19dB
45°
LNA
Rev. PrA | Page 12 of 15
½AD8333
AD8339
PHASE BIT
SETTINGS
CH 1 REF
(NO PHASE
LEAD)
E1
E2
S1 AND S2
ARE NOW IN
PHASE
SUMMED
OUTPUT
S1 + S2
S1
19dB
LNA
CH 2
PHASE
LEAD 45°
S2
Figure 3. Simplified Example of the AD8339 Phase Shifter
05543-063
SUMMATION OF MULTIPLE CHANNELS (ANALOG
BEAMFORMING)
Preliminary Technical Data
AD8339
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
lower performance portable ultrasound applications, the
combination of the AD8335 and the AD8339 result in the
lowest power per channel. For optimum signal-to-noise
performance, the output of the LNA is applied directly to the
input of the AD8339. In order 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.
SERIAL INTERFACE
The AD8339 contains a 4-wire SPI compatible digital interface
(SDI, SCLK, CSB, and SDO). The interface is comprised of a 20bit shift register plus a latch. The shift register needs to be loaded
MSB first. The data allows control over each channel’s phases,
plus the last four bits shifted into the register determine the
enable state of the individual channels. Figure XYZ shows a block
and timing diagram of the serial interface. The shift direction is
to the “right” with MSB first. As soon CSB goes low, the data in
the latch is protected and new data can be loaded into the shift
register.
If only one AD8339 needs to be programmed, then only 20 bits
need to be shifted into the part before CSB goes high. As soon
as CSB goes high, the data loaded into the shift register will be
transferred to the latch. Depending on the data loaded the
corresponding channels will be enabled, and the phases on each
channel will be set. Figure XYZ shows how the timing might
look when two AD8339s have their data loaded.
ENBL Bits
If all four ENBL bits are set to ‘0’, then only the SPI port is
powered up. This feature allows for very low power
consumption (about 13 mW per AD8339 or 3.25 mW per
channel) when the CW Doppler function is not needed. Since
the SPI port stays alive even when the rest of the chip is
powered down, the part can be awakened again by simply
programming the port. As soon as the CSB signal goes high, the
part turns on again. It should be pointed out that this will take a
fair amount of time because of the external capacitor on the
LODC pin. It will take about 10-20 μs with the recommended
0.1 μF decoupling cap. The decoupling cap on this pin is
intended to reduce bias noise contribution in the LO divider
chain. The user can experiment with the value of this
decoupling capacitor to see what the smallest value can be
without any dynamic range degradation within the frequency
band of interest.
The SPI also has an additional pin that can be used in a test
mode, or as a quick way to reset the SPI and de-power the chip.
All bits in both the shift register and the latch can be reset to ‘0’
when pin RSTS is pulled above about 1.2 V. For quick testing
without the need to program the SPI, the voltage on the RSTS
pin should be first pulled high and then pulled to -1.4 V; this
enables all four channels in the (I=1,Q=0) state (all phase bits
are 0000).
Figure XYZ. SPI - Block and Timing Diagram
Rev. PrA | Page 13 of 15
Preliminary Technical Data
AD8339
APPLICATIONS
The AD8339 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) as in the AD8334/5 VGA family, the AD8339
forms a complete analog receiver for a high-performance
ultrasound system.
LOGIC INPUTS AND INTERFACES
All logic inputs of the AD8339 including the SPI and RSET pins
are CMOS compatible down to 1.8 V. Each logic input pin has a
Schmitt trigger activated input that contains a threshold that is
centered at about 1.1 V with a hysteresis of ±0.1 V around this
value.
The LO divider RSET pin has a slightly higher threshold at
about 1.3 V and a hysteresis of about ±0.1 V. This input also can
still be driven by 1.8 V CMOS logic.
The only logic output, SDO, generates a signal that has a logic
low level of about 0.2 V and a logic high level of about 1.9V to
allow for easy interfacing to the next AD8339 SDI input.
least the tSET-UP should be ≥ 5 ns. An optimal timing set-up
would be for the RSET pulse to go high on a 4 x LO falling edge
and go low on a 4 x LO falling edge; this gives 10 ns of set-up
time even at a 4 x LO frequency of 50 MHz (12.5 MHz internal
LO).
Synchronization of multiple AD8339s can be checked as
follows:
1.
Activate at least one channel per AD8339 by
setting the appropriate channel enable bit in the
serial interface.
2.
Set the phase code of all AD8339 channels the
same, for example, 0000.
3.
Apply the same test signal to all devices that
generates a sine wave in the baseband output and
measure the output of one channel per device.
4.
Apply a RSET pulse to all AD8339s.
5.
Since all the phase codes of the AD8339s should
be the same, the combined signal of multiple
devices should be N times bigger than a single
channel. If the combined signal is less than N times
one channel, then the LO phases of the individual
AD8339s are most likely in error.
RESET INPUT
The RSET pin is used to synchronize the LO dividers in
AD8339 arrays. Because they are driven by the same internal
LO, the four channels in any AD8339 are inherently
synchronous. However, when multiple AD8339s 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 AD8339s.
The 4 × LO divider of each AD8339 can initiate in one of four
possible states - 0°, 90°, 180°, and 270° relative to other
AD8339s. The internally generated I/Q signals of each AD8339
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 AD8339s.
The LO divider reset function has been improved in the
AD8339 over the AD8333. The RSET pin still provides an
asynchronous reset of the LO dividers by forcing the internal
LO to "hang", however, now the LO reset function is fast and
does not require a shut-down of the 4 x LO input signal.
The RSET 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 should be ≥ 20 ns minimum. When
the RSET pulse transitions from high to low, the LO dividers are
reactivated on the next rising edge of the 4 x LO clock. To
guarantee synchronous operation of an array of AD8339s the
RSET pulse needs to go low on all devices before the next rising
edge of the 4 x LO clock. Therefore it is best to have the RSET
pulse go low on the falling edge of the 4 x LO clock; at the very
Rev. PrA | Page 14 of 15
Preliminary Technical Data
AD8339
OUTLINE DIMENSIONS
Figure 8. 40-Lead Chip Scale Package
Rev. PrA | Page 15 of 15
PR06587-0-1/07(PrA)