MAXIM MAX2036CCQ+D

19-4420; Rev 0; 1/09
Ultrasound VGA Integrated
with CW Octal Mixer
Features
The MAX2036 8-channel variable-gain amplifier (VGA)
and programmable octal mixer array is designed for
high linearity, high dynamic range, and low-noise performance targeting ultrasound imaging and Doppler
applications. Each amplifier features differential inputs
and outputs and a total gain range of 50dB (typ). In
addition, the VGAs offer very low output-referred noise
performance suitable for interfacing with 10-bit ADCs.
The MAX2036 VGA is optimized for less than ±0.5dB
absolute gain error to ensure minimal channel-to-channel
ultrasound beamforming focus error. The device’s differential outputs are designed to directly drive ultrasound
ADCs through an external passive anti-aliasing filter. A
switchable clamp is also provided at each amplifier’s
output to limit the output signals, thereby preventing
ADC overdrive or saturation.
Dynamic performance of the device is optimized to
reduce distortion to support second-harmonic imaging.
The device achieves a second-harmonic distortion
specification of -62dBc at VOUT = 1.5VP-P and fIN =
5MHz, and an ultrasound-specific* two-tone third-order
intermodulation distortion specification of -52dBc at
VOUT = 1.5VP-P and fIN = 5MHz.
The MAX2036 also integrates an octal quadrature mixer
array and programmable LO phase generators for a
complete CW beamforming solution. The LO phase
selection for each channel can be programmed using a
digital serial interface and a single high-frequency
clock or the LOs for each complex mixer pair can be
directly driven using separate 4 x LO clocks. The serial
interface is designed to allow multiple devices to be
easily daisy-chained in order to minimize program interface wiring. The LO phase dividers can be programmed to allow 4, 8, or 16 quadrature phases. The
input path of each CW mixer consists of a selectable
lowpass filter for optimal CWD noise performance. The
outputs of the mixers are summed into I and Q differential current outputs. The mixers and LO generators are
designed to have exceptionally low noise performance
of -155dBc/Hz at 1kHz offset from a 1.25MHz carrier.
The MAX2036 operates from a +5.0V power supply,
consuming only 120mW/channel in VGA mode and
269mW/channel in normal power CW mode. A lowpower CW mode is also available and consumes only
226mW/channel. The device is available in a lead-free
100-pin TQFP package (14mm x 14mm) with an
exposed pad. Electrical performance is guaranteed
over a 0°C to +70°C temperature range.
♦ 8-Channel Configuration
♦ High Integration for Ultrasound Imaging
Applications
♦ Pin Compatible with the MAX2035 Ultrasound
VGA
VGA Features
♦ Maximum Gain, Gain Range, and Output-Referred
Noise Optimized for Interfacing with 10-Bit ADCs
Maximum Gain of 39.5dB
Total Gain Range of 50dB
-60nV/√Hz Ultra-Low Output-Referred Noise at
5MHz
♦ ±0.5dB Absolute Gain Error
♦ 120mW Consumption per Channel
♦ Switchable Output VGA Clamp Eliminating ADC
Overdrive
♦ Fully Differential VGA Outputs for Direct ADC
Drive
♦ Variable Gain Range Achieves 50dB Dynamic
Range
♦ -62dBc HD2 at VOUT = 1.5VP-P and fIN = 5MHz
♦ Two-Tone Ultrasound-Specific* IMD3 of -52dBc at
VOUT = 1.5VP-P and fIN = 5MHz
CWD Mixer Features
♦ Low Mixer Noise of -155dBc/Hz at 1kHz Offset
from 1.25MHz Carrier
♦ Serial-Programmable LO Phase Generator for 4, 8,
16 LO Quadrature Phase Resolution
♦ Optional Individual Channel 4 x fLO LO Input
Drive Capability
♦ 269mW Power Consumption per Channel (Normal
Power Mode) and 226mW Power Consumption
per Channel (Low-Power Mode)
♦ CWD Implementation Is Fully Compliant with All
Patents Related to Ultrasound Imaging
Techniques
Applications
Ultrasound Imaging
Sonar
Ordering Information
PART
TEMP RANGE
MAX2036CCQ+D
0°C to +70°C
PIN-PACKAGE
100 TQFP-EP†
MAX2036CCQ+TD
0°C to +70°C
100 TQFP-EP†
+Denotes a lead(Pb)-free/RoHS-compliant package.
T = Tape-and-reel package.
D = Dry packing.
†EP = Exposed pad.
*See the Ultrasound-Specific IMD3 Specification in the
Applications Information section.
Pin Configuration appears at end of data sheet.
________________________________________________________________ Maxim Integrated Products
1
For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642,
or visit Maxim’s website at www.maxim-ic.com.
MAX2036
General Description
MAX2036
Ultrasound VGA Integrated
with CW Octal Mixer
ABSOLUTE MAXIMUM RATINGS
VCC, VREF to GND .................................................-0.3V to +5.5V
Any Other Pins to GND...............................-0.3V to (VCC + 0.3V)
CW Mixer Output Voltage to GND (CW_IOUT+, CW_IOUT-,
CW_QOUT+, CW_QOUT-) ................................................13V
VGA Differential Input Voltage (VGIN_+, VGIN_-)............8.0VP-P
Analog Gain Control Differential Input Voltage
(VG_CTL+, VG_CTL-) ..................................................8.0VP-P
CW Mixer Differential Input Voltage
(CWIN_+, CWIN_-).......................................................8.0VP-P
CW Mixer LVDS LO Differential Input Voltage..................8.0VP-P
Continuous Power Dissipation (TA = +70°C)
100-Pin TQFP (derated 45.5mW/°C above +70°C)..3636.4mW
Operating Temperature Range...............................0°C to +70°C
Junction Temperature ......................................................+150°C
θJC (Note 1) .....................................................................+2°C/W
θJA (Note 1)....................................................................+22°C/W
Storage Temperature Range .............................-40°C to +150°C
Lead Temperature (soldering, 10s) .................................+300°C
Note 1: Package thermal resistances were obtained using the method described in JEDEC specification JESD51-7, using a fourlayer board. For detailed information on package thermal considerations, refer to www.maxim-ic.com/thermal-tutorial.
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
DC ELECTRICAL CHARACTERISTICS—VGA MODE
(Figure 7, VCC = VREF = 4.75V to 5.25V, VCM = (3/5)VREF, TA = 0°C to +70°C, VGND = 0, LOW_PWR = 0, M4_EN = 0, CW_FILTER = 0
or 1, TMODE = 0, PD = 0, CW_VG = 1, CW_M1 = 0, CW_M2 = 0, no RF signals applied, capacitance to GND at each of the VGA
differential outputs is 60pF, differential capacitance across the VGA outputs is 10pF, RL = 1kΩ, CW mixer outputs pulled up to +11V
through four separate ±0.1% 115Ω resistors, all CW channels programmed off. Typical values are at VCC = VREF = 5V, TA = +25°C,
unless otherwise noted.) (Note 2)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
4.75
5
5.25
V
4.75
5
5.25
V
PD = 0
204
231
PD =1
27
33
VGA MODE
Supply Voltage Range
VCC
VCC External Reference Voltage
Range
VREF
(Note 3)
Refers to VCC supply
current plus VREF current
Total Power-Supply Current
mA
VCC Supply Current
IVCC
192
216
mA
VREF Current
IREF
12
15
mA
Refers to VCC supply current
24
27
mA
Minimum gain
+2
Maximum gain
-2
Current Consumption per
Amplifier Channel
Differential Analog Control
Voltage Range
Differential Analog Control
Common-Mode Voltage
VCM
2.85
Analog Control Input Source/Sink
Current
VP-P
3
3.15
V
4.5
5
mA
0.8
V
LOGIC INPUTS
CMOS Input High Voltage
VIH
CMOS Input Low Voltage
VIL
2
2.3
_______________________________________________________________________________________
V
Ultrasound VGA Integrated
with CW Octal Mixer
(Figure 7, VCC = VREF = 4.75V to 5.25V, TA = 0°C to +70°C, VGND = 0, LOW_PWR = 0, M4_EN = 0, CW_FILTER = 0 or 1, TMODE = 0,
PD = 0, CW_VG = 0, CW_M1 = 0, CW_M2 = 0, no RF signals applied, capacitance to GND at each of the VGA differential outputs is
60pF, differential capacitance across the VGA outputs is 10pF, RL = 1kΩ, CW mixer outputs pulled up to +11V through four separate
±0.1% 115Ω resistors. Typical values are at VCC = VREF = 5V, TA = +25°C, unless otherwise noted.) (Note 2)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
CW MIXER MODE
Current in Full-Power Mode
5V VCC Supply
ICC_FP
Refers to VCC supply current (all 8 channels)
245
265
mA
Current in Full-Power Mode
11V VMIX Supply
IMIX_FP
Refers to VMIX supply current (all 8 channels)
106
120
mA
Current in Full-Power Mode
5V VREF Supply
IREF_FP
Refers to VREF supply current (all 8 channels)
17
21
mA
PDISS_FP
Total power dissipation (all 8 channels
including both 5V (VCC and VREF) and 11V
mixer pullup supply power dissipation in the
device) (Note 4)
2.15
2.41
W
Power Dissipation in Full-Power
Mode
Current in Low-Power Mode
5V VCC Supply
ICC_LP
LOW_PWR = 1; refers to VCC supply
current (all 8 channels)
245
265
mA
Current in Low-Power Mode
11V VMIX Supply
IMIX_LP
LOW_PWR = 1; refers to VMIX supply
current (all 8 channels)
53
60
mA
Current in Low-Power Mode
5V VREF Supply
IREF_LP
LOW_PWR = 1; refers to VREF supply
current (all 8 channels)
17
21
mA
LOW_PWR = 1; total power dissipation (all 8
channels including both 5V (VCC and VREF)
and 11V mixer pullup supply power
dissipation in the device) (Note 4)
1.81
2.06
W
Mixer LVDS LO Input CommonMode Voltage
Modes 1 and 2 (Note 5)
1.25
±0.2
V
LVDS LO Differential Input
Voltage
Modes 1 and 2
700
mVP-P
LVDS LO Input Common-Mode
Current
Per pin
150
LVDS LO Differential Input
Resistance
Modes 1 and 2 (Note 6)
30
Mixer IF Common-Mode Output
Current
Common-mode current in each of the
differential mixer outputs (Note 7)
DATA Output High Voltage
DOUT voltage when terminated in DIN
(daisy chain) (Note 8)
DATA Output Low Voltage
DOUT voltage when terminated in DIN
(daisy chain) (Note 8)
Power Dissipation in Low-Power
Mode
PDISS_LP
200
3.25
200
µA
kΩ
3.75
4.5
mA
V
0.5
V
_______________________________________________________________________________________
3
MAX2036
DC ELECTRICAL CHARACTERISTICS—CM MIXER MODE
MAX2036
Ultrasound VGA Integrated
with CW Octal Mixer
AC ELECTRICAL CHARACTERISTICS—VGA MODE
(Figure 7, VCC = VREF = 4.75V to 5.25V, VCM = (3/5)VREF, TA = 0°C to +70°C, VGND = 0, LOW_PWR = 0, M4_EN = 0, CW_FILTER = 1,
TMODE = 0, PD = 0, CW_VG = 1, CW_M1 = 0, CW_M2 = 0, VG_CLAMP_MODE = 1, fRF = fLO/16 = 5MHz, capacitance to GND at
each of the VGA differential outputs is 60pF, differential capacitance across the VGA outputs is 10pF, RL = 1kΩ, CW mixer outputs
pulled up to +11V through four separate ±0.1% 115Ω resistors, differential mixer inputs are driven from a low-impedance source.
Typical values are at VCC = VREF = 5V, TA = +25°C, unless otherwise noted.) (Note 2)
PARAMETER
SYMBOL
CONDITIONS
MIN
CW_VG set from logic 1 to 0 or from 0 to 1
(Note 9)
Mode Select Response Time
TYP
MAX
2
UNITS
µs
VGA MODE
Large-Signal Bandwidth
f-3dB
Differential Input Resistance
RIN
Input Effective Capacitance
CIN
VOUT = 1.5VP-P,
3dB bandwidth,
gain = 20dB
Differential output
capacitance is 10pF,
capacitance to GND at
each single-ended output
is 60pF, RL = 1kΩ
17
No capacitive load,
RL = 1kΩ
22
MHz
170
fRF = 10MHz, each input to ground
200
15
230
Ω
pF
100
Ω
Maximum Gain
39.5
dB
Minimum Gain
-10.5
dB
50
dB
Differential Output Resistance
ROUT
Gain Range
Absolute Gain Error
TA = +25°C, -2.0V < VG_CTL < -1.8V,
VREF = 5V
±0.6
TA = +25°C, -1.8V < VG_CTL < +1.2V,
VREF = 5V
±0.5
TA = +25°C, +1.2V < VG_CTL < +2.0V,
VREF = 5V
±1.2
VGA Gain Response Time
50dB gain change to within 1dB final value
Input-Referred Noise
VG_CTL set for maximum gain, no input signal
VG_CTL set for
+20dB of gain
Output-Referred Noise
Second Harmonic
Third-Order Intermodulation
Distortion
Channel-to-Channel Crosstalk
4
HD2
IMD3
1
µs
2
nV/√Hz
No input signal
60
VOUT = 1.5VP-P,
1kHz offset
120
VG_CLAMP_MODE = 1,
VG_CTL set for +20dB of gain,
fRF = 5MHz, VOUT = 1.5VP-P
-55
VOUT = 1VP-P differential, fRF = 10MHz,
VG_CTL set for +20dB of gain
nV/√Hz
-62
dBc
VG_CLAMP_MODE = 1,
VG_CTL set for +20dB of gain,
fRF = 10MHz, VOUT = 1.5VP-P
VG_CTL set for +20dB of gain,
fRF1 = 5MHz, fRF2 = 5.01MHz,
VOUT = 1.5VP-P, VREF = 5V (Note 3)
dB
-62
-40
-52
dBc
-80
dB
_______________________________________________________________________________________
Ultrasound VGA Integrated
with CW Octal Mixer
(Figure 7, VCC = VREF = 4.75V to 5.25V, TA = 0°C to +70°C, VGND = 0, LOW_PWR = 0, M4_EN = 0, CW_FILTER = 1, TMODE = 0,
PD = 0, CW_VG = 0, CW_M1 = 0, CW_M2 = 0, VG_CLAMP_MODE = 1, fRF = fLO/16 = 5MHz, capacitance to GND at each of the
VGA differential outputs is 60pF, differential capacitance across the VGA outputs is 10pF, RL = 1kΩ, CW mixer outputs pulled up to
+11V through four separate ±0.1% 115Ω resistors, differential mixer inputs are driven from a low-impedance source. Typical values
are at VCC = VREF = 5V, TA = +25°C, unless otherwise noted.) (Note 2)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
Maximum Output Voltage at
Clamp ON
VG_CLAMP_MODE = 0,
VG_CTL set for +20dB of gain,
350mVP-P differential input
2.2
VP-P
differential
Maximum Output Voltage at
Clamp OFF
VG_CLAMP_MODE = 1,
VG_CTL set for +20dB of gain,
350mVP-P differential input
3.4
VP-P
differential
CW MIXER MODE
Mixer RF Frequency Range
0.9
Mixer LO Frequency Range
1
7.6
MHz
7.5
MHz
Mixer IF Frequency Range
100
kHz
Maximum Input Voltage Range
1.8
VP-P
differential
Differential Input Resistance
633
CW_FILTER = 1
1440
Mode 3, fRF = fLO/4 = 1.25MHz, measured at a
1kHz offset frequency; clutter tone at 0.9VP-P
differential measured at the mixer input
Input-Referred Noise Voltage
Third-Order Intermodulation
Distortion
CW_FILTER = 0
IMD3
Ω
6
nV/√Hz
Mode 3, RF terminated into 50Ω;
fLO/4 = 1.25MHz, measured at 1kHz offset
4.6
Mode 1, fRF1 = 5MHz at 0.9VP-P differential
input, Doppler tone fRF2 = 5.01MHz at 25dBc
from clutter tone, fLO/16 = 5MHz (Note 10)
-50
Mixer Output Voltage Compliance
(Note 11)
Channel-to-Channel Phase
Matching
Measured under zero beat conditions,
fRF = 5MHz, fLO/16 = 5MHz (Note 12)
±3
Degrees
Channel-to-Channel Gain
Matching
Measured under zero beat conditions,
fRF = 5MHz, fLO/16 = 5MHz (Note 12)
±2
dB
Transconductance
(Note 13)
4.75
dBc
CW_FILTER = 1
fRF = 1.1MHz at 1VP-P
differential,
fLO/16 = 1MHz
CW_FILTER = 0
(low LPF cutoff
frequency)
fRF = 1.1MHz at 1VP-P
differential,
fLO/16 = 1MHz
12.00
V
2.8
mS
2.8
_______________________________________________________________________________________
5
MAX2036
AC ELECTRICAL CHARACTERISTICS—CW MIXER MODE (continued)
MAX2036
Ultrasound VGA Integrated
with CW Octal Mixer
AC ELECTRICAL CHARACTERISTICS—CW MIXER MODE (continued)
(Figure 7, VCC = VREF = 4.75V to 5.25V, TA = 0°C to +70°C, VGND = 0, LOW_PWR = 0, M4_EN = 0, CW_FILTER = 1, TMODE = 0,
PD = 0, CW_VG = 0, CW_M1 = 0, CW_M2 = 0, VG_CLAMP_MODE = 1, fRF = fLO/16 = 5MHz, capacitance to GND at each of the VGA
differential outputs is 60pF, differential capacitance across the VGA outputs is 10pF, RL = 1kΩ, CW mixer outputs pulled up to +11V
through four separate ±0.1% 115Ω resistors, differential mixer inputs are driven from a low-impedance source. Typical values are at
VCC = VREF = 5V, TA = +25°C, unless otherwise noted.) (Note 2)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
10
MHz
SERIAL SHIFT REGISTER
Serial Shift Register Programming
Rate
Minimum Data Set-Up Time
tDSU
30
ns
Minimum Data Hold Time
tHLD
2
ns
Minimum Data Clock Time
tDCLK
100
ns
Minimum Data Clock Pulse Width
High
tDCLKPWH
30
ns
Minimum Data Clock Pulse Width
Low
tDCLKPWL
30
ns
tLD
30
ns
tMIXCLK
30
ns
tCLH
30
ns
Minimum Load Line
Minimum Load Line High to Mixer
Clock On
Minimum Data Clock to Load
Line High
Note 2: Specifications at TA = +25°C and TA = +70°C are guaranteed by production. Specifications at TA = 0°C are guaranteed by
design and characterization.
Note 3: Noise performance of the device is dependent on the noise contribution from the supply to VREF. Use a low-noise supply
for VREF. VCC and VREF can be connected together to share the same supply voltage if the supply for VCC exhibits low
noise.
Note 4: Total on-chip power dissipation is calculated as PDISS = VCC x ICC + VREF x IREF + [11V - (IMIX/4) x 115] x IMIX.
Note 5: Note that the LVDS CWD LO clocks are DC-coupled. This is to ensure immediate synchronization when the clock is first
turned on. An AC-coupled LO is problematic in that the RC time constant associated with the coupling capacitors and the
input impedance of the pin causes there to be a period of time (related to the RC time constant) when the DC level on the
chip side of the capacitor is outside the acceptable common-mode range and the LO swing does not exceed both the
logic thresholds required for proper operation. This problem associated with AC-coupling would cause an inability to
ensure synchronization among beamforming channels. The LVDS signal is terminated differentially with an external 100Ω
resistor on the board.
Note 6: External 100Ω resistor terminates the LVDS differential signal path.
Note 7: The mixer common-mode current (3.25mA/channel) is specified as the common-mode current in each of the differential
mixer outputs (CW_QOUT+, CW_QOUT-, CW_IOUT+, CW_IOUT-).
Note 8: Specification guaranteed only for DOUT driving DIN of the next device in a daisy-chain fashion.
Note 9: This response time does not include the CW output highpass filter. When switching to VGA mode, the CW outputs stop
drawing current and the output voltage goes to the rail. If a highpass filter is used, the recovery time can be excessive and
a switching network is recommended as shown in the Applications Information section.
Note 10: See the Ultrasound-Specific IMD3 Specification in the Applications Information section.
Note 11: Mixer output-voltage compliance is the range of acceptable voltages allowed on the CW mixer outputs.
Note 12: Channel-to-channel gain-and-phase matching measured on 30 pieces during engineering characterization at room temperature. Each mixer is used as a phase detector and produces a DC voltage in the IQ plane. The phase is given by the angle
of the vector drawn on that plane. Multiple channels from multiple parts are compared to each other to produce the phase
variation.
Note 13: Transconductance is defined as the quadrature summing of the CW differential output current at baseband divided by the
mixer’s input voltage.
6
_______________________________________________________________________________________
Ultrasound VGA Integrated
with CW Octal Mixer
VOUT = 1VP-P DIFFERENTIAL
GAIN = 20dB
-10
-20
3.5
PSMR (dBc)
3.0
2.5
2.0
IMD3 (dBc)
-50
-60
-70
1.5
-30
f = 10MHz
-40
-50
-60
1.0
-80
0
-90
7.5 10.0 12.5 15.0 17.5 20.0
-80
0
25
FREQUENCY (MHz)
50
75
-5
5
15
25
35
45
GAIN (dB)
FREQUENCY (kHz)
SECOND-HARMONIC DISTORTION
vs. GAIN
THIRD-HARMONIC DISTORTION
vs. GAIN
0
VOUT = 1VP-P DIFFERENTIAL
-10
-15
100 125 150 175 200
0
-20
MAX2036 toc05
5.0
VOUT = 1VP-P DIFFERENTIAL
-10
-20
-30
-30
f = 12MHz
-40
-50
HD3 (dBc)
2.5
MAX2036 toc04
0
f = 2MHz, 5MHz
-70
0.5
HD2 (dBc)
OVERDRIVE PHASE DELAY (ns)
VOUT = 1.5VP-P DIFFERENTIAL
VMOD = 50mVP-P, fCARRIER = 5MHz,
GAIN = 20dB
-40
0
MAX2036 toc02
VIN1 = 35mVP-P DIFFERENTIAL
VIN2 = 87.5mVP-P DIFFERENTIAL
GAIN = 20dB
4.0
-30
MAX2036 toc01
5.0
4.5
TWO-TONE ULTRASOUND-SPECIFIC
IMD3 vs. GAIN
POWER-SUPPLY MODULATION RATIO
MAX2036 toc03
OVERDRIVE PHASE DELAY
vs. FREQUENCY
f = 5MHz
-60
-70
f = 12MHz
-40
f = 5MHz
-50
-60
-70
-80
-90
-90
-100
-100
-15
-5
f = 2MHz
-80
f = 2MHz
5
15
25
35
45
GAIN (dB)
-15
-5
5
15
25
45
OVERLOAD RECOVERY TIME
OVERLOAD RECOVERY TIME
MAX2036 toc07
MAX2036 toc06
f = 5MHz
OUTPUT OVERLOAD TO 1VP-P
35
GAIN (dB)
DIFFERENTIAL
INPUT
200mV/div
f = 5MHz DIFFERENTIAL
INPUT
200mV/div
DIFFERENTIAL
OUTPUT
500mV/div
DIFFERENTIAL
OUTPUT
500mV/div
OUTPUT OVERLOAD TO 100mVP-P
_______________________________________________________________________________________
7
MAX2036
Typical Operating Characteristics
(Figure 7, VCC = VREF = 4.75V to 5.25V, VGND = 0, PD = 0, VG_CLAMP_MODE = 1, fRF = 5MHz, capacitance to GND at each of the
VGA differential outputs is 60pF, differential capacitance across the VGA outputs is 10pF, RL = 1kΩ, TA = 0°C to +70°C. Typical values are at VCC = VREF = 5V, VCM = 3.0V, TA = +25°C, unless otherwise noted.)
Typical Operating Characteristics (continued)
(Figure 7, VCC = VREF = 4.75V to 5.25V, VGND = 0, PD = 0, VG_CLAMP_MODE = 1, fRF = 5MHz, capacitance to GND at each of the
VGA differential outputs is 60pF, differential capacitance across the VGA outputs is 10pF, RL = 1kΩ, TA = 0°C to +70°C. Typical values are at VCC = VREF = 5V, VCM = 3.0V, TA = +25°C, unless otherwise noted.)
-85
-70
-80
-90
-90
-95
-100
-110
-15
-5
5
15
25
35
10
GAIN vs. DIFFERENTIAL ANALOG
CONTROL VOLTAGE (VG_CTL)
GAIN (dB)
15
5
-5
-15
-1.5
-0.5
0.5
1.5
30
35
25
30
25
15
20
10
15
5
1
10
100
0.1
1000
1
10
100
FREQUENCY (MHz)
LARGE-SIGNAL BANDWIDTH
vs. FREQUENCY
LARGE-SIGNAL BANDWIDTH
vs. FREQUENCY
LARGE-SIGNAL BANDWIDTH
vs. FREQUENCY
MAX2036 toc14
20
VOUT = 1.5VP-P DIFFERENTIAL
VG_CTL = +1.2VP-P DIFFERENTIAL
15
10
15
5
-5
GAIN (dB)
0
GAIN (dB)
10
10
0
-5
-15
0
-10
-20
-5
-15
-25
-20
1
10
FREQUENCY (MHz)
100
1000
1000
-10
5
-10
VOUT = 1.5VP-P DIFFERENTIAL
VG_CTL = +1.7VP-P DIFFERENTIAL
5
20
0.1
MAX2036 toc10
0
0.1
FREQUENCY (MHz)
VOUT = 1.5VP-P DIFFERENTIAL
VG_CTL = +0.2VP-P DIFFERENTIAL
45
20
VG_CTL (VP-P DIFFERENTIAL)
30
25
35
VOUT = 1.5VP-P DIFFERENTIAL
VG_CTL = -0.8VP-P DIFFERENTIAL
35
40
2.5
25
40
10
-2.5
15
LARGE-SIGNAL BANDWIDTH
vs. FREQUENCY
MAX2036 toc15
GAIN (dB)
25
5
LARGE-SIGNAL BANDWIDTH
vs. FREQUENCY
GAIN (dB)
35
-5
GAIN (dB)
VOUT = 1.5VP-P DIFFERENTIAL
VG_CTL = -2VP-P DIFFERENTIAL
45
-15
100
50
MAX2036 toc11
f = 5MHz
40
FREQUENCY (MHz)
GAIN (dB)
45
50
30
1
45
MAX2036 toc12
-100
60
MAX2036 toc13
-80
-60
f = 5MHz
70
MAX2036 toc16
-75
80
OUTPUT-REFERRED NOISE VOLTAGE (nV/√Hz)
-50
CROSSTALK (dB)
CROSSTALK (dB)
VOUT = 1VP-P DIFFERENTIAL
GAIN = 20dB, ADJACENT CHANNELS
-40
-70
8
MAX2036 toc09
VOUT = 1.5VP-P DIFFERENTIAL
f = 10MHz, ADJACENT CHANNELS
-65
-30
MAX2036 toc08
-60
OUTPUT-REFERRED NOISE VOLTAGE
vs. GAIN
CHANNEL-TO-CHANNEL CROSSTALK
vs. FREQUENCY
CHANNEL-TO-CHANNEL CROSSTALK
vs. GAIN
GAIN (dB)
MAX2036
Ultrasound VGA Integrated
with CW Octal Mixer
-30
0.1
1
10
100
FREQUENCY (MHz)
1000
0.1
1
10
100
FREQUENCY (MHz)
_______________________________________________________________________________________
1000
Ultrasound VGA Integrated
with CW Octal Mixer
-25
-30
-30
THIRD HARMONIC
-40
-50
-60
SECOND HARMONIC
-70
-80
-60
-80
-85
-90
-95
1000
0
0.5
-55
-60
THIRD HARMONIC
-65
-70
-75
SECOND HARMONIC
-80
-85
-90
2.5
200
3.0
25
45
65
85
800
1100
1400
1700
2000
HARMONIC DISTORTION
vs. FREQUENCY
TWO-TONE ULTRASOUND-SPECIFIC IMD3
vs. FREQUENCY
VOUT = 1VP-P DIFFERENTIAL
GAIN = 20dB
-20
THIRD HARMONIC
0
VOUT = 1VP-P DIFFERENTIAL
GAIN = 20dB
-10
-20
-30
-40
-50
-60
SECOND HARMONIC
-70
-30
-40
-50
-80
-60
0
105
10
20
30
40
-70
50
0
5
10
15
20
25
DIFFERENTIAL OUTPUT LOAD (pF)
FREQUENCY (MHz)
FREQUENCY (MHz)
GAIN ERROR HISTOGRAM
OUTPUT COMMON-MODE OFFSET VOLTAGE
vs. GAIN
DIFFERENTIAL OUTPUT IMPEDANCE
MAGNITUDE vs. FREQUENCY
35
30
25
20
15
160
25
0
-4.50 -3.00 -1.50 0.75 2.25 3.75
-3.75 -2.25 -0.75 1.50 3.00 4.50
GAIN ERROR (dB)
140
120
-25
100
80
-75
5
180
50
-50
10
200
MAX2036 toc25
75
OFFSET VOLTAGE (mV)
40
100
ZOUT (Ω)
SAMPLE SIZE = 188 UNITS
fIN_ = 5MHz, GAIN = 20dB
MAX2036 toc24
50
MAX2036 toc23
5
500
DIFFERENTIAL OUTPUT LOAD (Ω)
-100
-100
0
2.0
-90
-95
45
1.5
IMD3 (dBc)
-50
1.0
DIFFERENTIAL OUTPUT VOLTAGE (VP-P)
0
-10
HARMONIC DISTORTION (dBc)
MAX2036 toc20
VOUT = 1VP-P DIFFERENTIAL
f = 5MHz, GAIN = 20dB
-45
SECOND HARMONIC
-75
-100
10
100
FREQUENCY (MHz)
MAX2036 toc19
-70
-100
1
THIRD HARMONIC
-65
-40
-40
HARMONIC DISTORTION (dBc)
-55
-90
HARMONIC DISTORTION
vs. DIFFERENTIAL OUTPUT LOAD CAPACITANCE
% OF UNITS
-50
-35
0.1
VOUT = 1VP-P DIFFERENTIAL
f = 5MHz, GAIN = 20dB
-45
MAX2036 toc22
-20
-20
-40
HARMONIC DISTORTION (dBc)
-15
f = 5MHz, GAIN = 20dB
-10
MAX2036 toc21
GAIN (dB)
-10
0
MAX2036 toc18
VOUT = 1VP-P DIFFERENTIAL
VG_CTL = +2VP-P DIFFERENTIAL
HARMONIC DISTORTION (dBc)
MAX2036 toc17
0
-5
HARMONIC DISTORTION
vs. DIFFERENTIAL OUTPUT LOAD RESISTANCE
HARMONIC DISTORTION
vs. DIFFERENTIAL OUTPUT VOLTAGE
LARGE-SIGNAL BANDWIDTH
vs. FREQUENCY
60
-100
-15
-5
5
15
GAIN (dB)
25
35
45
0.1
1
10
100
FREQUENCY (MHz)
_______________________________________________________________________________________
9
MAX2036
Typical Operating Characteristics (continued)
(Figure 7, VCC = VREF = 4.75V to 5.25V, VGND = 0, PD = 0, VG_CLAMP_MODE = 1, fRF = 5MHz, capacitance to GND at each of the
VGA differential outputs is 60pF, differential capacitance across the VGA outputs is 10pF, RL = 1kΩ, TA = 0°C to +70°C. Typical values are at VCC = VREF = 5V, VCM = 3.0V, TA = +25°C, unless otherwise noted.)
Typical Operating Characteristics (continued)
(Figure 7, VCC = VREF = 4.75V to 5.25V, VGND = 0, LOW_PWR = 0, M4_EN = 0, CW_FILTER = 1, TMODE = 0, PD = 0, CW_VG = 0,
CW_M1 = 0, CW_M2 = 0, CW mixer outputs pulled up to +11V through four separate ±0.1% 115Ω resistors, differential mixer inputs
are driven from a low impedance source.)
CW FILTER RESPONSE
(CW_FILTER = 1)
CW FILTER RESPONSE
(CW_FILTER = 0)
2
0
0
-5
LOSS (dB)
-2
LOSS (dB)
MAX2036 toc27
5
MAX2036 toc26
4
-4
-6
-8
-10
-15
-20
-10
-25
-12
-30
-14
0
5
10
15
5
10
15
20
FREQUENCY (MHz)
FREQUENCY (MHz)
CW IMD3 vs. FREQUENCY
(MODE 1, VRF = 900mVP-P DIFFERENTIAL
VCC = VREF)
INPUT-REFERRED NOISE vs. CLUTTER
VOLTAGE (MODE 4, F_CLUTTER = 1.25MHz
AT 1kHz OFFSET)
-48
-49
-50
-51
-52
4.75
5.00
5.25
-53
MAX2036 toc29
14
INPUT-REFERRED NOISE (nV√Hz)
-47
12
10
8
6
4
2
-54
0
0
2
4
FRF (MHz)
10
0
20
MAX2036 toc28
-46
IMD3 (dBc)
MAX2036
Ultrasound VGA Integrated
with CW Octal Mixer
6
8
0
0.5
1.0
1.5
CLUTTER VOLTAGE (VP-P DIFF)
______________________________________________________________________________________
2.0
Ultrasound VGA Integrated
with CW Octal Mixer
PIN
NAME
FUNCTION
1
CWIN2-
2
CWIN2+
CW Mixer Channel 2 Inverting Differential Input
3
VGIN3-
VGA Channel 3 Inverting Differential Input
4
VGIN3+
VGA Channel 3 Noninverting Differential Input
5, 10, 19, 24,
29, 34, 58,
79, 81, 96
GND
CW Mixer Channel 2 Noninverting Differential Input
Ground
6
CWIN3-
7
CWIN3+
CW Mixer Channel 3 Inverting Differential Input
8
VGIN4-
VGA Channel 4 Inverting Differential Input
CW Mixer Channel 3 Noninverting Differential Input
9
VGIN4+
VGA Channel 4 Noninverting Differential Input
11
CWIN4-
CW Mixer Channel 4 Inverting Differential Input
12
CWIN4+
CW Mixer Channel 4 Noninverting Differential Input
13
EXT_C1
External Compensation. Connect a 4.7μF capacitor to ground as close as possible to the pin to
bypass the internal biasing circuitry.
14
EXT_C2
External Compensation. Connect a 4.7μF capacitor to ground as close as possible to the pin to
bypass the internal biasing circuitry.
15
EXT_C3
External Compensation. Connect a 4.7μF capacitor to ground as close as possible to the pin to
bypass the internal biasing circuitry.
16, 42, 46,
54, 72, 82, 87
VCC
5V Power Supply. Connect to an external +5V power supply. Bypass each VCC supply to ground
with 0.1μF capacitors as close as possible to the pins.
17
VGIN5-
VGA Channel 5 Inverting Differential Input
18
VGIN5+
VGA Channel 5 Noninverting Differential Input
20
CWIN5-
CW Mixer Channel 5 Inverting Differential Input
21
CWIN5+
22
VGIN6-
VGA Channel 6 Inverting Differential Input
23
VGIN6+
VGA Channel 6 Noninverting Differential Input
25
CWIN6-
CW Mixer Channel 6 Inverting Differential Input
26
CWIN6+
27
VGIN7-
VGA Channel 7 Inverting Differential Input
28
VGIN7+
VGA Channel 7 Noninverting Differential Input
30
CWIN7-
CW Mixer Channel 7 Inverting Differential Input
31
CWIN7+
CW Mixer Channel 7 Noninverting Differential Input
CW Mixer Channel 5 Noninverting Differential Input
CW Mixer Channel 6 Noninverting Differential Input
32
VGIN8-
VGA Channel 8 Inverting Differential Input
33
VGIN8+
VGA Channel 8 Noninverting Differential Input
35
CWIN8-
CW Mixer Channel 8 Inverting Differential Input
36
CWIN8+
CW Mixer Channel 8 Noninverting Differential Input
37, 93
VREF
5V Reference Supply. Connect to a low-noise power supply. Bypass to GND with a 0.1μF capacitor
as close as possible to the pins. Note that noise performance of the device is dependent on the
noise contribution from the supply to VREF. Use a low-noise supply for VREF. VCC and VREF can be
connected together to share the same supply voltage if the supply for VCC exhibits low noise.
______________________________________________________________________________________
11
MAX2036
Pin Description
Ultrasound VGA Integrated
with CW Octal Mixer
MAX2036
Pin Description (continued)
PIN
12
NAME
FUNCTION
External Resistor. Connect a 0.1% 7.5k resistor to ground as close as possible to the pin to set
the bias for the internal biasing circuitry.
38
EXT_RES
39
CW_VG
40
PD
Power-Down Switch. Drive PD high to set the device in power-down mode. Drive PD low for normal
operation.
41
CW_FILTER
CW Filter Mode Corner Frequency Select. Selects in corner frequency of the internal lowpass filter
for the CW path. Set CW_FILTER to a logic-high for a corner frequency of 9.5MHz. Set CW_FILTER
to a logic-low for a corner frequency of 4.5MHz.
43
M4_EN
Mode 4 Enable. Set M4_EN to a logic-high to override the serial port and activate all 8 channels of
the CW path.
44
LOW_PWR
45
DOUT
47
N.C.
No Connect. Leave this pin unconnected.
48
LO8
CW LO Input for Channel 8. LO clock input for modes 3 and 4.
49
VGOUT8+
VGA Channel 8 Noninverting Differential Output
50
VGOUT8-
VGA Channel 8 Inverting Differential Output
CW Mixer VGA Enable. Selects for VGA or CW mixer operation. Set CW_VG to a logic-high to enable
the VGAs while the CW mixers are powered down. Set CW_VG to a logic-low to enable the CW
mixers while the VGAs are powered down.
Low-Power Enable. Set high to enable low-power CW mixer mode for the device.
Serial Port Data Output. Data output for ease of daisy-chaining CW channels for analog beamforming programming.
51
LO7
52
VGOUT7+
CW LO Input for Channel 7. LO clock input for modes 3 and 4.
VGA Channel 7 Noninverting Differential Output
53
VGOUT7-
VGA Channel 7 Inverting Differential Output
55
LO6
56
VGOUT6+
CW LO Input for Channel 6. LO clock input for modes 3 and 4.
VGA Channel 6 Noninverting Differential Output
57
VGOUT6-
VGA Channel 6 Inverting Differential Output
59
LO5
60
VGOUT5+
CW LO Input for Channel 5. LO clock input for modes 3 and 4.
VGA Channel 5 Noninverting Differential Output
61
VGOUT5-
VGA Channel 5 Inverting Differential Output
62
VG_CTL-
63
VG_CTL+
VGA Analog Gain Control Differential Input. Set the differential to -2V for maximum gain (+39.5dB)
and +2V for minimum gain (-10.5dB).
64
LO_LVDS-
CW LVDS LO Inverting Differential Input. LO clock inverting input for modes 1 and 2.
65
LO_LVDS+
CW LVDS LO Noninverting Differential Input. LO clock noninverting input for modes 1 and 2.
66
LO4
67
VGOUT4+
CW LO Input for Channel 4. LO clock input for modes 3 and 4.
VGA Channel 4 Noninverting Differential Output
68
VGOUT4-
VGA Channel 4 Inverting Differential Output
69
LO3
70
VGOUT3+
CW LO Input for Channel 3. LO clock input for modes 3 and 4.
VGA Channel 3 Noninverting Differential Output
71
VGOUT3-
VGA Channel 3 Inverting Differential Output
73
LO2
74
VGOUT2+
CW LO Input for Channel 2. LO clock input for modes 3 and 4.
VGA Channel 2 Noninverting Differential Output
75
VGOUT2-
VGA Channel 2 Inverting Differential Output
______________________________________________________________________________________
Ultrasound VGA Integrated
with CW Octal Mixer
PIN
NAME
FUNCTION
76
LO1
77
VGOUT1+
VGA Channel 1 Noninverting Differential Output
78
VGOUT1-
VGA Channel 1 Inverting Differential Output
80
DIN
Serial Port Data Input. Data input to program the serial shift registers.
83
CLK
Serial Port Data Clock. Clock input for programming the serial shift registers.
84
CW_M1
CW Mode Select Input 1. Input for programming beamforming mode 1, 2, 3, or 4. See Table 1 for
mode programming details.
85
CW_M2
CW Mode Select Input 2. Input for programming beamforming mode 1, 2, 3, or 4. See Table 1 for
mode programming details.
86
CW LO Input for Channel 1. LO clock input for modes 3 and 4.
VGA Clamp Mode Enable. Drive VG_CLAMP_MODE high to enable high VGA clamp mode. VGA
VG_CLAMP_
output is clamped at typically 2.4VP-P differential. Drive VG_CLAMP_MODE low to enable low VGA
MODE
clamp mode. VGA output is clamped at typically 2.8VP-P differential.
Serial Port Load. Loads the data from the serial shift registers into the I/Q phase dividers. Pull LOAD
bus from high to low, and from low to high for programming the I/Q phase dividers.
88
LOAD
89
CW_QOUT+
CW Mixer Noninverting Differential Quadrature Output. CW Mixer output for 8 quadrature mixers
combined.
90
CW_QOUT-
CW Mixer Inverting Differential Quadrature Output. CW Mixer output for 8 quadrature mixers
combined.
91
CW_IOUT-
CW Mixer Inverting Differential In-Phase Output. CW mixer output for 8 in-phase mixers combined.
92
CW_IOUT+
CW Mixer Noninverting Differential In-Phase Output. CW Mixer output for 8 in-phase mixers combined.
94
VGIN1-
VGA Channel 1 Inverting Differential Input
95
VGIN1+
VGA Channel 1 Noninverting Differential Input
97
CWIN1-
CW Mixer Channel 1 Inverting Differential Input
98
CWIN1+
CW Mixer Channel 1 Noninverting Differential Input
99
VGIN2-
VGA Channel 2 Inverting Differential Input
100
VGIN2+
VGA Channel 2 Noninverting Differential Input
—
EP
Exposed Pad. Internally connected to GND. Connect EP to a large PCB ground plane to maximize
thermal performance.
______________________________________________________________________________________
13
MAX2036
Pin Description (continued)
MAX2036
Ultrasound VGA Integrated
with CW Octal Mixer
Detailed Description
The MAX2036 is an 8-channel VGA integrated with a
programmable octal quadrature mixer array designed
for ultrasound imaging and Doppler applications. The
device is optimized for efficient power consumption,
high dynamic range, and exceptionally low-noise
performance. The VGA path features differential inputs,
analog variable gain control, differential outputs for
direct ADC drive, and a selectable output voltage
clamp to avoid ADC overdrive. The integrated octal
quadrature mixer array includes serial-programmable
LO phase generators for CWD beamforming applications. The LO phase dividers can be programmed for 4,
8, or 16 quadrature phases. Lowpass filters are integrated at the input paths of each CW mixer. The outputs for the mixers are summed into single I/Q
differential current outputs.
The MAX2036 also integrates an octal quadrature mixer
array and programmable LO phase generators for a
complete continuous wave (CW) Doppler beamforming
solution. The LO phase selection for each channel is
programmed using a digital serial interface and a single high-frequency clock, or the LOs for each complex
mixer pair can be directly driven using separate 4 x LO
clocks. The serial interface is designed to allow multiple
devices to be easily daisy chained in order to minimize
program interface wiring. The LO phase dividers can
be programmed to allow 4, 8, or 16 quadrature phases.
The input path of each CW mixer consists of a selectable lowpass filter for optimal CWD noise performance.
The outputs of the mixers are summed into single I and
Q differential current outputs. The mixers and LO generators are designed to have exceptionally low noise
performance of -155dBc/Hz at 1kHz offset from a
1.25MHz carrier, measured with 900mVP-P differential
clutter signal.
High-Level Wave Mixer and
Programmable Beamformer
Functional Diagram
+5V
+5V (LOW NOISE)
VCC
VREF
MAX2036
VG_CTL+
VG_CTL-
VG_CLAMP_MODE
50Ω
VGIN1+
VGIN1-
VGOUT1+
VGA
VGOUT150Ω
•
•
•
•
•
•
• •
• •
• •
•
•
•
•
•
•
50Ω
VGIN8+
VGOUT8+
VGA
VGIN8-
VGOUT850Ω
LOW_PWR
PD
CWIN1+
CW_IOUT+
CW_IOUT-
I&Q
CWIN1•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
CWIN8+
I&Q
CWIN8-
CW_QOUT+
CW_QOUT-
Variable Gain Amplifier (VGA)
The MAX2036’s VGAs are optimized for high linearity,
high dynamic range, and low output-noise performance, making this component ideal for ultrasound
imaging applications. The VGA paths also exhibit a
channel-to-channel crosstalk of -80dB at 10MHz and an
absolute gain error of less than ±0.5dB for minimal
channel-to-channel focusing error in an ultrasound system. Each VGA path includes circuitry for adjusting
analog gain, an output buffer with differential output
ports (VGOUT_+, VGOUT_-) for driving ADCs, and differential input ports (VGIN_+, VGIN_-), which are ideal
for directly interfacing to the MAX2034 quad LNA. See
the High-Level Wave Mixer and Programmable BeamFormer Functional Diagram for details.
14
CW_VG
CW_FILTER
GND
The VGA has an adjustable gain range from -10.5dB to
+39.5dB, achieving a total dynamic range of 50dB
(typ). The VGA gain can be adjusted using the differential gain-control inputs VG_CTL+ and VG_CTL-. Set the
differential gain-control input voltage at +2V for minimum gain and -2V for maximum gain. The differential
analog control common-mode voltage is 3V (typ).
______________________________________________________________________________________
Ultrasound VGA Integrated
with CW Octal Mixer
Octal Continuous Wave (CW) Mixer
The MAX2036 CW mixers are designed using an active
double-balanced topology. The mixers achieve high
dynamic range and high-linearity performance, with
exceptionally low noise, which is ideal for ultrasound
CWD signal reception. The octal quadrature mixer
array provides noise performance of -155dBc/Hz at
1kHz from a 1.25MHz carrier, and a two-tone, thirdorder, ultrasound-specific intermodulation product of
typically -50dBc. See the Ultrasound-Specific IMD3
Specification in the Applications Information section.
The octal array exhibits quadrature and in-phase differential current outputs (CW_QOUT+, CW_QOUT-,
CW_IOUT+, CW_IOUT-) to produce the total CWD
beamformed signal. The maximum differential current
output is typically 3mAP-P and the mixer output-compliance voltage ranges from 4.75V to 12V.
Power-Down
The device can also be powered down with PD. Set PD
to logic-high for power-down mode. In power-down
mode, the device draws a total supply current of 27mA.
Set PD to a logic-low for normal operation
Overload Recovery
The device is also optimized for quick overload recovery for operation under the large input-signal conditions
that are typically found in ultrasound input buffer
imaging applications. See the Typical Operating
Characteristics for an illustration of the rapid recovery
time from a transmit-related overload.
High-Level CW Mixer and Programmable
Beamformer Functional Diagram
VREF
VCC
CWIN8
•
•
•
CWIN2
CW_FILTER
M4_EN
MAX2036
•
•
•
CW_IOUT+
CW_IOUTCW_IOUT2+
I Q
•
•
•
• •
•
CW_QOUT2-
CW_QOUT•
•
•
• •
•
CWIN1
I Q
CW_QOUT+
I Q
5
DIN
CHANNEL 8
I/Q
DIVIDER
PHASE
SELECTOR
5
5-BIT
SR
5-BIT
SR
CW_M1
CW_M2
LO2
•
•
•
LO8
5
5-BIT
SR
•
•
•
LOAD
CHANNEL 2
I/Q
DIVIDER
PHASE
SELECTOR
•
•
•
• •
•
LO_LVDS-
CHANNEL 1
I/Q
DIVIDER
PHASE
SELECTOR
•
•
•
LO_LVDS+
•
•
•
• •
•
LO1
DOUT
CLK
GND
LOW_PWR
PD
______________________________________________________________________________________
15
MAX2036
VGA Clamp
A clamp is provided to limit the VGA output signals to
avoid overdriving the ADC or to prevent ADC saturation.
Set VG_CLAMP_MODE low to clamp the VGA differential
outputs at 2.2VP-P. Set the VG_CLAMP_MODE high to
disable the clamp.
MAX2036
Ultrasound VGA Integrated
with CW Octal Mixer
CW Mixer Output Summation
The outputs from the octal mixer array are summed internally to produce the total CWD summed beamformed
signal. The octal array produces eight differential quadrature (Q) outputs and eight differential in-phase (I) outputs. All quadrature and in-phase outputs are summed
into single I and Q differential current outputs
(CW_QOUT+, CW_QOUT-, CW_IOUT+, CW_IOUT-).
LO Phase Select
The LO phase dividers can be programmed through
the shift registers to allow for 4, 8, or 16 quadrature
phases for a complete CW beamforming solution.
the divide-by-16 circuit. The first 4 bits of the shift register are for programming the 16 phases; the fifth bit turns
each channel on/off individually. For mode 1, set both
CW_M1 and CW_M2 to a logic-low. See Table 2.
Table 2. Mode 1 Logic Table (B4 = 0:
Channel On/B4 = 1 Channel Off)
MODE 1
CW_M1 = 0
CW_M2 = 0
MSB
LSB
SHUTDOWN
PHASE
(DEG)
D
C
B
A
SD
(B0)
(B1)
(B2)
(B3)
(B4)
0
0
0
0
0
0/1
22.5
0
0
0
1
0/1
CWD Beamforming Modes
There are four separate modes of operating the CWD
beamformer. See Table 1 for a summary of the different
modes of operation. The mode of operation can be
selected by the CW_M1 and CW_M2 logic inputs.
Phase generation is controlled through the serial interface. See the Serial Interface section in the Applications
Information section for details on how to program for
different quadrature phases.
Mode 1
For mode 1 operation, the LO_LVDS input frequency is
typically 16 x fLO. As the CWD LO frequency range is
1MHz to 7.5MHz, the input frequency ranges from
16MHz to 120MHz. This high LO clock frequency
requires a differential LVDS input. The 16 x fLO input is
then divided by 16 to produce 16 phases. These 16
phases are generated for each of the 8 channels and
programmed for the selected phase by a serial shift
register. Each channel has a corresponding 5-bit shift
register, which is used to program the output phase of
45
0
0
1
0
0/1
67.5
0
0
1
1
0/1
90
0
1
0
0
0/1
112.5
0
1
0
1
0/1
135
0
1
1
0
0/1
157.5
0
1
1
1
0/1
180
1
0
0
0
0/1
202.5
1
0
0
1
0/1
225
1
0
1
0
0/1
247.5
1
0
1
1
0/1
270
1
1
0
0
0/1
292.5
1
1
0
1
0/1
315
1
1
1
0
0/1
337.5
1
1
1
1
0/1
Table 1. Summary of CWD Beamforming Methods
CW_M1
CW_M2 MODE
LO INPUT
CLOCK
PHASE
FREQUENCY INTERFACE RESOLUTION
NO. OF
CLOCK
INPUTS
PER CHIP
PROGRAM
BY SERIAL
SHIFT
REGISTER
(SSR)
NO. OF
USEFUL
BITS IN
SSR
0
0
1
16 x
LVDS
16 phases
1
Yes
4
0
0
1
2
8x
LVDS
8 phases
1
Yes
3
1 MSB
1
0
3
4x
3V CMOS
4 phases
8
Yes
2
2 MSBs
3V CMOS
Quadrature
provided
8
No
N/A
N/A
1
1
4
4x
N/A = Not applicable.
16
NO. OF
DON’TCARE
BITS IN
SSR
______________________________________________________________________________________
Ultrasound VGA Integrated
with CW Octal Mixer
Table 3. Mode 2 Logic Table (DC = Don’t
Care, B4 = 0: Channel On/B4 = 1: Channel
Off)
MODE 2
CW_M1 = 0
CW_M2 = 1
SHUTDOWN
D
C
B
A
SD
PHASE
(DEG)
(B0)
(B1)
(B2)
(B3)
(B4)
0
DC
0
0
0
0/1
45
DC
0
0
1
0/1
90
DC
0
1
0
0/1
135
DC
0
1
1
0/1
180
DC
1
0
0
0/1
225
DC
1
0
1
0/1
270
DC
1
1
0
0/1
315
DC
1
1
1
0/1
Mode 3
The LO_LVDS input is not used in this mode. Separate
4 x fLO clock inputs are provided using LO1–LO8 for
each channel. The CWD LO frequency range is 1MHz to
7.5MHz, and the input frequency provides ranges from
4MHz to 30MHz. Note that the LO clock frequency can
utilize 3V CMOS inputs. The 4 x fLO LO1–LO8 inputs are
divided by 4 to produce 4 phases. These 4 phases are
Table 4. Mode 3 Logic Table (DC = Don’t
Care, B4 = 0: Channel On/B4 = 1: Channel
Off)
MODE 3
CW_M1 = 1
CW_M2 = 0
SHUTDOWN
PHASE
(DEG)
D
C
B
A
SD
(B0)
(B1)
(B2)
(B3)
(B4)
0
DC
DC
0
0
0/1
90
DC
DC
0
1
0/1
180
DC
DC
1
0
0/1
270
DC
DC
1
1
0/1
generated for each of the 8 channels and programmed
for the selected phase by the serial shift register. For
mode 3, 4 phases are generated, and only 2 of the 4
phase-programming bits are required where the 2phase programming MSBs are don’t-care bits. For
mode 3, set CW_M1 to a logic-high and set CW_M2 to
a logic-low. See Table 4.
Mode 4
The LO_LVDS input is not used in this mode. The
appropriate phases are externally provided using separate 4 x fLO LO1–LO8 inputs for each channel. A 4 x fLO
input is required so the device can internally generate
accurate duty-cycle independent quadrature LO drives.
Note that the serial shift register is not used in this
mode. The CWD LO frequency range is 1MHz to
7.5MHz and the input frequency ranges from 4MHz to
30MHz. The appropriate inputs are provided at LO1 to
LO8. A reset line is provided to the customer so that all
the CWD channels can be synchronized. The reset line
is implemented through the RESET. For mode 4, set
both CW_M1 and CW_M2 to logic-high. See Table 5.
Table 5. Mode 4 Logic Table
MODE 4
CW_M1 = 1
CW_M2 = 1
PHASE
(DEG)
Serial bus
not used in
mode 4
SHUTDOWN
D
C
B
A
SD
(B0)
(B1)
(B2)
(B3)
(B4)
N/A
N/A
N/A
N/A
N/A
N/A = Not applicable.
______________________________________________________________________________________
17
MAX2036
Mode 2
The LO_LVDS input frequency is 8 x fLO (typ) for mode
2 operation. The CWD LO frequency range is 1MHz to
7.5MHz, and the input frequency ranges from 8MHz to
60MHz. This high LO clock frequency requires a differential LVDS input. The 8 x fLO input is then divided by 8
to produce 8 phases. These 8 phases are generated
for each of the 8 channels and programmed for the
selected phase by the serial shift register. Note that the
serial shift register is common to modes 1, 2, and 3,
where each channel has a corresponding 5-bit shift
register, which is used to program the output phase.
However, since mode 2 generates 8 phases only, 3 of
the 4 phase-programming bits are used; 5 bits are still
loaded per channel using the serial shift register, but
the phase-programming MSB is a don’t-care bit. The
fifth bit in the shift register always turns each channel
on/off individually. For mode 2, set CW_M1 to a logiclow and set CW_M2 to a logic-high. See Table 3.
MAX2036
Ultrasound VGA Integrated
with CW Octal Mixer
DATA_IN
CLOCK
CHANNEL 1
A B C D SD
CHANNEL 2
A B C D SD
CHANNEL 3
A B C D SD
CHANNEL 4
A B C D SD
B3 B2 B1 B0 B4
B3 B2 B1 B0 B4
B3 B2 B1 B0 B4
B3 B2 B1 B0 B4
CHANNEL 5
A B C D SD
CHANNEL 6
A B C D SD
CHANNEL 7
A B C D SD
CHANNEL 8
A B C D SD
B3 B2 B1 B0 B4
B3 B2 B1 B0 B4
B3 B2 B1 B0 B4
B3 B2 B1 B0 B4
DATA_OUT
Figure 1. Data Flow of Serial Shift Register
Synchronization
Figure 1 illustrates the serial programming of the 8 individual channels through the serial data port. Note that
the serial data can be daisy chained from one part to
another, allowing a single data line to be used to program multiple chips in the system.
CW Lowpass Filter
The MAX2036 also includes selectable lowpass filters
between each CW differential input pair and corresponding mixer input. Shunt capacitors and resistors
are integrated on chip for high band and low band. The
parallel capacitor/resistor networks, which appear differentially across each of the CW differential inputs, are
selectable through the CW_FILTER. Drive CW_FILTER
high to set the corner frequency of the filter to be fC =
9.5MHz. Drive CW_FILTER low to set the corner frequency equal to fC = 4.5MHz. The CW_VG allows the
filter inputs to be disconnected from input nodes (internal to chip) to prevent overloading the LNA output and
to not change the PW input common-mode voltage.
VGA and CW Mixer Operation
During normal operation, the MAX2036 is configured
such that either the VGA path is enabled while the mixer
array is powered down (VGA mode), or the quadrature
mixer array is enabled while the VGA path is powered
down (CW mode). During VGA mode, besides powering down the CW mixer array, the differential inputs to
the lowpass filters and CW mixers also are internally
disconnected from the input nodes, making the CW differential inputs (CWIN_+, CWIN_-) high impedance.
The CW mode disconnects the VGA inputs internally
from the input ports of the device. For VGA mode, set
CW_VG to a logic-high, while for CW mode, set CW_VG
to a logic- low.
Power-Down and Low-Power Modes
During device power-down, both the VGA and CW
mixer are disabled regardless of the logic set at
CW_VG. Both the VGA and CW mixer inputs are high
impedance since the internal switches to the inputs are
all disconnected. The total supply current of the device
reduces to 27mA. Set PD to a logic-high for device
power-down.
A low-power mode is available to lower the required
power for CWD operation. When selected, the complex
mixers operate at lower quiescent currents and the total
per-channel current is lowered to 53mA. Note that operation in this mode slightly reduces the dynamic performance of the device. Table 6 shows the logic function
of standard operating modes.
Table 6. Logic Function of Standard Operating Modes
PD
CW_VG
INPUT INPUT
LOW_PWR
VGA
CW
MIXER
INTERNA
INTERNAL
L SWITCH SWITCH TO LPF
TO VGA
AND CW MIXER
5V VCC CURRENT
CONSUMPTION (mA)
11V VMIX CURRENT
CONSUMPTION (mA)
0
1
1
N/A
Off
Off
Off
Off
27
1
0
N/A
Off
Off
Off
Off
27
0
0
0
0
Off
On
Off
On
245
106
0
0
1
Off
On
Off
On
245
53
0
1
N/A
On
Off
On
Off
204
0
N/A = Not applicable.
18
______________________________________________________________________________________
Ultrasound VGA Integrated
with CW Octal Mixer
Mode Select Response Time
The mode select response time is the time that the
device takes to switch between CW and VGA modes.
One possible approach to interfacing the CW outputs to
an instrumentation amplifier used to drive an ADC is
shown in Figure 2. In this implementation, there are four
large-value (in the range of 470nF to 1µF) capacitors
between each of the CW_IOUT+, CW_IOUT-,
CW_QOUT+, CW_QOUT- outputs and the circuitry they
are driving. The output of the CW mixer usually drives
the input of an instrumentation amplifier made up of op
amps whose input impedance is set by common-mode
setting resistors.
115Ω
115Ω
1μF
CW_IOUT-
50Ω
The highpass pole in this case is at fP = 1/(2 x pi x RC) ~
5Hz. Note that this low highpass corner frequency is
required in order to filter the downconverted clutter tone,
which appears at DC, but not interfere with CWD imaging
at frequencies as low as 400Hz. For example, if one wanted to use CWD down to 400Hz, then a good choice for
the highpass pole would be at least a decade below this
(< 40Hz) as not to incur rolloff due to pole. Remember, if
the highpass pole is set to 400Hz, the response is 3dB
down at that corner frequency. The placement of the
highpass pole at 5Hz in the above example is between
the DC and 40Hz limitations just discussed.
The bottom line is that any reasonably sized DC block
between the output of the mixer and the instrumentation
amplifier pose a significant time constant that slows the
mode select switching speed.
An alternative solution to the approach in Figure 2,
which enables faster mode select response time, is
shown in Figure 4.
31.6kΩ
+11V
0.022μF
31.6kΩ
CW_IOUT+
1μF
Figure 2. Typical Example of a CW Mixer’s Output Circuit
There are clearly both a highpass corner and a lowpass
corner present in this output network. The lowpass corner is set primarily by the 115Ω mixer pullup resistors,
the series 50Ω resistors, and the shunt 0.022µF capacitor. This lowpass corner is used to filter a combination
of LO leakage and upper sideband. The highpass corner, however, is of a larger concern due to the fact that
it is dominated by the combination of a 1µF DC blocking
capacitor and the pair of shunt 31.6kΩ resistors.
If drawn, the simplified dominant highpass network
would look like Figure 3.
1μF
31.6kΩ
+5V
Figure 4. Improved Mode Select Response Time Achieved with
DC-Coupled Input to Instrumentation Amplifier
In Figure 4, the outputs of the CWD mixers are DCcoupled into the inputs of the instrumentation amplifiers. Therefore, the op amps must be able to accommodate the full compliance range of the mixer outputs,
which is a maximum of +11V when the mixers are disabled, down to the +5V supply of the MAX2036 when
the mixers are enabled. The op amps can be powered
from +11V for the high rail and +5V for the low rail,
requiring a 6V op amp.
Figure 3. Simplified Circuit of Highpass Pole
______________________________________________________________________________________
19
MAX2036
Applications Information
MAX2036
Ultrasound VGA Integrated
with CW Octal Mixer
Serial Interface
The serial interface of the MAX2036 programs the LO for
16, 8, or 4 quadrature phases using a serial shift register
implementation. Data is shifted into the device on DIN.
The serial shift register clock is applied to the CLK input.
The serial shift register has 5 bits per channel. The first 4
bits are for phase programming, and the fifth bit enables
or disables each channel of the mixer array.
Each mixer can be programmed to 1 of 16 phases;
therefore, 4 bits are required for each channel for programming. The master high-frequency mixer clock is
applied to differential inputs LO_LVDS+ and LO_LVDS(for modes 1 and 2) and LO_ (for modes 3 and 4). The
LOAD input is provided to allow the user to load the
phase counters with the programming values to generate the correct LO phases. The input signals for mixing
are applied to the eight differential inputs, CWIN_+ and
CWIN_-. The summed I/Q baseband differential outputs
are provided on CW_IOUT+/- and CW_QOUT+/-.
CW_M1 and CW_M2 are used to select one of the four
possible modes of operation. See Table 1.
The serial interface is designed to allow multiple
devices to be easily daisy chained in order to minimize
program interface wiring. DOUT is available for this
daisy-chain function.
Programming the Beamformer
During normal CWD operation, the mixer clock at LO_ or
CW_LVDS± is on and the programming signals on DIN,
CLK, and LOAD are off. (LOAD = high, CLOCK = low,
and DATA_IN = don’t care, but fixed to a high or low). To
start the programming sequence, turn off the mixer
clock. Data is shifted into the shift register at a recommended 10MHz programming rate or 100ns minimum
data clock period/time. See Figure 5 for timing details.
After the shift registers are programmed, pull the LOAD
bus to logic-low and then back to logic-high to load the
internal counters into I/Q phase divider/selectors with
the proper values. LOAD must remain low for a minimum time of tCLH. The user turns on the mixer clock to
start beamforming. The clock must turn on such that it
starts at the beginning of a mixer clock cycle.
tDSU tHLD
tCLH
DIN
CLK
LOAD
tDCLKPWH
tDCLKPWL
tDCLK
MIXER
CLOCK ON
tLD
tLDMIXCLK
MIXER
CLOCK OFF
MIXER
CLOCK ON
MIXER
CLOCK OFF
MIXER
CLOCK ON
MIXER
CLOCK OFF
MIXER
CLOCK ON
Figure 5. Shift Register Timing Diagram
20
______________________________________________________________________________________
Ultrasound VGA Integrated
with CW Octal Mixer
Ultrasound-Specific IMD3 Specification
Unlike typical communications specs, the two input
tones are not equal in magnitude for the ultrasoundspecific IMD3 two-tone specification. In this measurement, f1 represents reflections from tissue and f2 represents reflections from blood. The latter reflections are
typically 25dB lower in magnitude, and hence the measurement is defined with one input tone 25dB lower than
the other. The IMD3 product of interest (f1 - (f2 - f1)) presents itself as an undesired Doppler error signal in ultrasound applications. See Figure 6.
External Compensation
External compensation is required for bypassing internal biasing circuitry. Connect, as close as possible,
individual 4.7µF capacitors from each pin EXT_C1,
EXT_C2, and EXT_C3 (pins 13, 14, 15) to ground.
-25dB
ULTRASOUND
IMD3
External Bias Resistor
An external resistor at EXT_RES is required to set the
bias for the internal biasing circuitry. Connect, as close
as possible, a 7.5kΩ (0.1%) resistor from EXT_RES (pin
38) to ground.
f1 - (f2 - f1)
f1
f2
f2 + (f2 - f1)
Analog Input and Output Coupling
In typical applications, the MAX2036 is being driven
from a low-noise amplifier (such as the MAX2034) and
the VGA is typically driving a discrete differential antialias filter into an ADC (such as the MAX1436 octal
ADC). The differential input impedance of the MAX2036
is typically 240Ω. The differential outputs of the VGA
are capable of driving a differential load capacitance to
GND at each of the VGA differential outputs of 60pF,
and differential capacitance across the VGA outputs is
10pF, RL = 1kΩ. The differential outputs have a common-mode bias of approximately 3.75V. AC-couple
these differential outputs if the next stage has a different common-mode input range.
Figure 6. Ultrasound IMD3 Measurement Technique
PCB Layout
The pin configuration of the MAX2036 is optimized to
facilitate a very compact physical layout of the device
and its associated discrete components. A typical
application for this device might incorporate several
devices in close proximity to handle multiple channels
of signal processing.
The exposed pad (EP) of the MAX2036’s TQFP-EP
package provides a low thermal-resistance path to the
die. It is important that the PCB on which the MAX2036
is mounted be designed to conduct heat from the EP.
In addition, provide the EP with a low-inductance path
to electrical ground. The EP MUST be soldered to a
ground plane on the PCB, either directly or through an
array of plated via holes.
______________________________________________________________________________________
21
MAX2036
CW Mixer Output Summation
The maximum differential current output is typically
3mA P-P and the mixer output compliance voltage
ranges from 4.75V to 12V per mixer channel. The mixer
common-mode current in each of the differential mixer
outputs is typically 3.25mA. The total summed current
would equal N x 3.25mA in each of the 115Ω load resistors (where N = number of channels). In this case, the
quiescent output voltage at +VSUM and -VSUM outputs
would be +11V - (N x 3.25mA x 115) = +11 - (8 x
3.25mA x 115) = 8.05V. The voltage swing at each output, with one channel driven at max output current (differential 3mA P-P ) while the other channels are not
driven, would be 1.5mAP-P x 115Ω or 174mVP-P and the
differential voltage would be 348mVP-P. The voltage
compliance range is defined as the valid range for
+VSUM and -VSUM in this example.
+VIN
22
-V
+V
100nF
100nF
100nF
MAX2034
ONE CHANNEL
ZIN IN CONTROL
D2, D1, D0
100nF
100nF
CW_FILTER
CW_VG
12μH
CWIN_-
CWIN_+
12μH
VGIN_-
VGIN_+
MAX2036
ONE CHANNEL
VCC
VG_CTL-
GND
LO DIVIDER
VG_CTL+
CWD I/Q LO
50Ω
50Ω
VREF
CW_QOUT+
CW_QOUT-
CW_IOUT-
CW_IOUT+
VGOUT_-
0.1μF
0.1μF
VGOUT_+
115Ω
115Ω
TO 10-BIT
IMAGING
ADC
+VMIX
115Ω
ADC
CWD
TO Q CHANNEL
CWD
Q CHANNELS
IN
CWD
I CHANNELS
IN
ADC
CWD
115Ω
TO I CHANNEL
+VMIX
THIRD-ORDER BUTTERWORTH
ANTI-ALIAS FILTER.
MAX2036
Ultrasound VGA Integrated
with CW Octal Mixer
Figure 7. Typical per-Channel Ultrasound Imaging Application
______________________________________________________________________________________
Ultrasound VGA Integrated
with CW Octal Mixer
51
VGOUT7VGOUT7+
LO7
52
53
54
VGOUT6+
LO6
VCC
55
56
57
LO5
GND
VGOUT659
58
VGOUT5VGOUT5+
61
60
VG_CTL+
VG_CTL63
62
LO_LVDS+
LO_LVDS65
64
VGOUT4+
LO4
66
67
68
69
VGOUT3VGOUT3+
LO3
VGOUT471
70
VCC
72
VGOUT2-
VGOUT2+
LO2
75
74
73
TOP VIEW
LO1
76
50
VGOUT8-
VGOUT1+
VGOUT1-
77
49
78
48
VGOUT8+
LO8
GND
DIN
GND
VCC
79
47
80
46
81
45
82
44
N.C.
VCC
DOUT
LOW_PWR
M4_EN
VCC
CW_FILTER
PD
CLK
83
43
CW_M1
CW_M2
VG_CLAMP_MODE
VCC
LOAD
CW_QOUT+
CW_QOUT-
84
42
85
41
86
40
87
39
88
38
90
36
CWIN8+
CW_IOUT-
91
35
CW_IOUT+
92
34
VREF
VGIN1VGIN1+
GND
CWIN1-
93
33
CWIN8GND
VGIN8+
94
32
95
31
96
30
97
29
CWIN1+
98
28
VGIN2VGIN2+
99
27
VGIN8CWIN7+
CWIN7GND
VGIN7+
VGIN7-
100
26
CWIN6+
MAX2036
89
VGIN6-
9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25
VGIN6+
GND
CWIN6-
8
VGIN5+
GND
CWIN5CWIN5+
7
EXT_C3
VCC
VGIN5-
6
EXT_C1
EXT_C2
5
GND
CWIN4CWIN4+
4
VGIN4+
3
VGIN3VGIN3+
GND
CWIN3CWIN3+
VGIN4-
2
CWIN2CWIN2+
1
37
CW_VG
EXT_RES
VREF
TQFP
Chip Information
PROCESS: Silicon Complementary Bipolar
Package Information
For the latest package outline information and land patterns, go
to www.maxim-ic.com/packages.
PACKAGE TYPE
PACKAGE CODE
DOCUMENT NO.
100 TQFP-EP
C100E+3
21-0116
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 ____________________ 23
© 2009 Maxim Integrated Products
Maxim is a registered trademark of Maxim Integrated Products, Inc.
MAX2036
Pin Configuration