TI AFE5818 Afe5818 16-channel, ultrasound, analog front-end with 140-mw/channel power, 0.75-nv/â hz noise, 14-bit, 65-msps or 12-bit, 80-msps adc, and passive cw mixer Datasheet

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AFE5818
SBAS687B – FEBRUARY 2015 – REVISED AUGUST 2015
AFE5818 16-Channel, Ultrasound, Analog Front-End with 140-mW/Channel Power,
0.75-nV/√Hz Noise, 14-Bit, 65-MSPS or 12-Bit, 80-MSPS ADC, and Passive CW Mixer
1
1 Features
•
•
•
•
•
•
•
•
•
•
•
•
16-Channel, Complete Analog Front-End:
– LNA, VCAT, PGA, LPF, ADC, and CW Mixer
LNA with Programmable Gain:
– Gain: 24 dB, 18 dB, and 12 dB
– Linear Input Range:
0.25 VPP, 0.5 VPP, and 1 VPP
– Input-Referred Noise:
0.63 nV/√Hz, 0.7 nV/√Hz, and 0.9 nV/√Hz
– Programmable Active Termination
Voltage-Controlled Attenuator (VCAT): 40 dB
Programmable Gain Amplifier (PGA):
24 dB and 30 dB
Total Signal Chain Gain: 54 dB (max)
3rd-Order, Linear-Phase LPF:
– 10 MHz, 15 MHz, 20 MHz, 30 MHz, 35 MHz,
and 50 MHz
Analog-to-Digital Converter (ADC):
– 14-Bit ADC: 75-dBFS SNR at 65 MSPS
– 12-Bit ADC: 72-dBFS SNR at 80 MSPS
LVDS Interface Maximum Speed of 1 Gbps
Noise and Power Optimizations (Full-Channel):
– 140 mW/Ch at 0.75 nV/√Hz, 65 MSPS
– 91.5 mW/Ch at 1.1 nV/√Hz, 40 MSPS
– 80 mW/Ch at CW Mode
Excellent Device-to-Device Gain Matching:
– ±0.5 dB (typical) and ±1.1 dB (max)
Low Harmonic Distortion
Fast and Consistent Overload Recovery
•
•
Passive Mixer for CWD:
– Low Close-In Phase Noise:
–156 dBc/Hz at 1 kHz Off 2.5-MHz Carrier
– Phase Resolution: λ / 16
– Supports 16X, 8X, 4X, and 1X CW Clocks
– 12-dB Suppression on 3rd and 5th Harmonics
– CWD High-Pass Filter Rejects Undesired LowFrequency Signals < 1 kHz
Small Package: 15-mm × 15-mm NFBGA-289
2 Applications
•
•
•
•
Medical Ultrasound Imaging
Nondestructive Evaluation Equipment
Sonar Imaging Equipment
Multichannel, High-Speed Data Acquisition
3 Description
The AFE5818 is a highly-integrated, analog front-end
(AFE) solution specifically designed for ultrasound
systems where high performance and small size are
required. The device integrates a complete time-gaincontrol (TGC) imaging path and a continuous wave
Doppler (CWD) path. The device also allows various
power and noise combinations to be selected to
optimize system performance. Therefore, the
AFE5818 is a suitable ultrasound AFE solution for
high-end and portable systems
Device Information(1)
PART NUMBER
AFE5818
PACKAGE
BODY SIZE (NOM)
NFBGA (289)
15.00 mm × 15.00 mm
(1) For all available packages, see the orderable addendum at
the end of the datasheet.
Simplified Block Diagram
Device (1 of 16 Channels)
SPI IN
SPI OUT
SPI Logic
VCAT
0 dB to -40 dB
LNA
PGA
24, 30 dB
LNA IN
3rd-Order LPF
with 10, 15, 20,
30, 35, and
50 MHz
12-, 14-Bit
ADC
LVDS
16X CLK
16 Phases
Generator
CW Mixer
Summing
Amplifier
Reference
Reference
1X CLK
16 x 8
Crosspoint SW
1X CLK
CW I/Q
VOUT
Differential
TGC VCNTL
1
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
AFE5818
SBAS687B – FEBRUARY 2015 – REVISED AUGUST 2015
www.ti.com
Table of Contents
1
2
3
4
5
6
7
8
Features .................................................................. 1
Applications ........................................................... 1
Description ............................................................. 1
Revision History..................................................... 2
Description (continued)......................................... 4
Device Comparison Table..................................... 5
Pin Configuration and Functions ......................... 6
Specifications....................................................... 11
8.1
8.2
8.3
8.4
8.5
8.6
8.7
8.8
8.9
9
Absolute Maximum Ratings ....................................
ESD Ratings............................................................
Recommended Operating Conditions.....................
Thermal Information ................................................
Electrical Characteristics.........................................
Digital Characteristics .............................................
Output Interface Timing ..........................................
Serial Interface Timing Characteristics ..................
Typical Characteristics ............................................
11
11
12
12
13
19
20
21
22
Detailed Description ............................................ 33
9.1
9.2
9.3
9.4
Overview .................................................................
Functional Block Diagram .......................................
Feature Description.................................................
Device Functional Modes........................................
33
34
35
72
9.5 Programming........................................................... 76
10 Application and Implementation........................ 78
10.1
10.2
10.3
10.4
Application Information..........................................
Typical Application ...............................................
Do's and Don'ts .....................................................
Initialization Set Up ...............................................
78
78
82
82
11 Power Supply Recommendations ..................... 83
11.1 Power Sequencing and Initialization ..................... 83
12 Layout................................................................... 84
12.1 Layout Guidelines ................................................. 84
12.2 Layout Example .................................................... 85
13 Register Maps...................................................... 91
13.1 Serial Register Map .............................................. 91
14 Device and Documentation Support ............... 149
14.1
14.2
14.3
14.4
14.5
Documentation Support ......................................
Trademarks .........................................................
Electrostatic Discharge Caution ..........................
Export Control Notice..........................................
Glossary ..............................................................
149
149
149
149
149
15 Mechanical, Packaging, and Orderable
Information ......................................................... 150
15.1 Tray Information .................................................. 151
4 Revision History
NOTE: Page numbers for previous revisions may differ from page numbers in the current version.
Changes from Revision A (July 2015) to Revision B
Page
•
Changed literature number to release full document to web.................................................................................................. 1
•
Deleted AFE58JD18 from document ..................................................................................................................................... 1
•
Added Device Comparison Table........................................................................................................................................... 5
•
Changed the common-mode voltage value from 1.5 V to 2.5 V in the descriptions of the CLKM_1X , CLKP_1X,
CLKM_16X , and CLKP_16X, rows in the Pin Functions table .............................................................................................. 7
•
Changed the pulldown resistor value from 100 kΩ to 20-kΩ in the description of the TX_TRIG pin in the Pin
Functions table ..................................................................................................................................................................... 10
•
Changed Absolute Maximum Ratings table: deleted Voltage at digital inputs row and added Voltage at all digital
inputs except CW clocks and Voltage at CW clock input pins rows .................................................................................... 11
•
Changed the typical specifications of last four rows of TGC Full-Signal Channel, Channel-to-channel noise
correlation factor parameter in the Electrical Characteristics table ..................................................................................... 14
•
Changed test conditions of second row in Power Dissipation, CW mode parameter in the Electrical Characteristics
table ..................................................................................................................................................................................... 18
•
Changed SDATA to SDIN in title of CMOS Digital Inputs section in the Digital Characteristics table ................................ 19
•
Changed typical specification from 25 to 50 in zo parameter of Digital Characteristics table .............................................. 19
•
Changed typical specifications of ADC Timing, Cd parameter in Output Interface Timing table.......................................... 20
•
Changed Figure 1................................................................................................................................................................. 21
•
Changed Figure 56 and Figure 57 ....................................................................................................................................... 31
•
Changed input to Serial Interface block from SDATA to SDIN in Functional Block Diagram .............................................. 34
•
Changed Figure 84: changed values of t_setup and t_hold ................................................................................................ 55
•
Deleted Setup and Hold Time Constraints for a Hardware RESET figure and associated description because this
data was determined to be misleading ................................................................................................................................ 55
•
Changed input to Serial Interface block from SDATA to SDIN in Figure 98 ........................................................................ 68
2
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SBAS687B – FEBRUARY 2015 – REVISED AUGUST 2015
Revision History (continued)
•
Changed input to Serial Interface block from SDATA to SDIN in Figure 99 ........................................................................ 69
•
Changed Test Patterns section to improve clarity................................................................................................................ 72
•
Changed AFE8 to AFE4 in Figure 103................................................................................................................................. 78
•
Added footnote to Figure 104 ............................................................................................................................................... 79
•
Changed Figure 108............................................................................................................................................................. 85
•
Changed SDATA to SDIN in list of SPI control signals in first paragraph of Serial Register Map section .......................... 91
•
Changed bit type from R/W to W in Register 0 ................................................................................................................... 92
•
Changed CUSTOM_PATTERN[13:0] to CUSTOM_PATTERN[15:0] in register address 5 of Table 14 ............................. 93
•
Changed Register 5 in the ADC Register Map section ........................................................................................................ 99
Changes from Original (February 2015) to Revision A
Page
•
Added AFE58JD18 to document ............................................................................................................................................ 1
•
Changed Voltage-Controlled Attenuator (VCAT), LVDS Interface Maximum Speed, and Noise and Power
Optimizations (Full-Channel) Features bullets ....................................................................................................................... 1
•
Deleted second to last Passive Mixer sub-bullet in Features section ................................................................................... 1
•
Added AFE58JD18-specific Features bullets ......................................................................................................................... 1
•
Changed Output Interface and Digital I/Q Demodulator column titles in Device Information table........................................ 1
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SBAS687B – FEBRUARY 2015 – REVISED AUGUST 2015
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5 Description (continued)
The AFE5818 has a total of 16 channels, with each channel consisting of a voltage-controlled amplifier (VCA), a
simultaneous sampling 14-bit and 12-bit analog-to-digital converter (ADC), and a continuous wave (CW) mixer.
The VCA includes a low-noise amplifier (LNA), a voltage-controlled attenuator (VCAT), a programmable gain
amplifier (PGA), and a low-pass filter (LPF). LNA gain is programmable and supports 250-mVPP to 1-VPP input
signals and programmable active termination. The ultra-low noise VCAT provides an attenuation control range of
40 dB and improves overall low-gain SNR, which benefits harmonic and near-field imaging. The PGA provides
gain options of 24 dB and 30 dB. In front of the ADC, an LPF can be configured at 10 MHz, 15 MHz, 20 MHz,
30 MHz, 35 MHz, or 50 MHz to support ultrasound applications with different frequencies.
The AFE5818 also integrates a low-power passive mixer and a low-noise summing amplifier to create an on-chip
CWD beamformer. 16 selectable phase delays can be applied to each analog input signal. Furthermore, a
unique third- and fifth-order harmonic suppression filter is implemented to enhance CW sensitivity
The high-performance, 14-bit ADC achieves 75-dBFS SNR. This ADC ensures excellent SNR at low-chain gain.
The device can operate at maximum speeds of 65 MSPS and 80 MSPS, providing a 14-bit and a 12-bit output,
respectively.
The ADC low-voltage differential signaling (LVDS) outputs enable a flexible system integration that is desirable
for miniaturized systems.
The AFE5818 also allows various power and noise combinations to be selected to optimize system performance.
Therefore, the AFE5818 is a suitable ultrasound AFE solution for both high-end and portable systems.
The AFE5818 is available in a 15-mm × 15-mm NFBGA-289 package (ZBV package, S-PBGA-N289) and are
specified for operation from –40°C to 85°C. The devices are also pin-to-pin compatible with the AFE5816 device
family.
4
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6 Device Comparison Table
DEVICE
PACKAGE
BODY SIZE (NOM)
AFE5816
16-channel, ultrasound, analog front-end (AFE) with 90-mW/channel, 1-nV/√Hz
noise, 14-bit, 65-MSPS or 12-bit, 80-MSPS ADC and passive CW mixer
NFBGA (289)
15.00 mm × 15.00 mm
AFE5812
Fully integrated, 8-channel ultrasound AFE with passive CW mixer, and digital I/Q
demodulator, 0.75 nV/√Hz, 14 and 12 bits, 65 MSPS, 180 mW/ch
NFBGA (135)
15.00 mm × 9.00 mm
AFE5809
8-channel ultrasound AFE with passive CW mixer, and digital I/Q demodulator,
0.75 nV/√Hz, 14 and 12 bits, 65 MSPS, 158 mW/ch
NFBGA (135)
15.00 mm × 9.00 mm
AFE5808A
8-channel ultrasound AFE with passive CW mixer, 0.75 nV/√Hz, 14 and 12 bits,
65 MSPS, 158 mW/ch
NFBGA (135)
15.00 mm × 9.00 mm
AFE5807
8-channel ultrasound AFE with passive CW mixer, 1.05 nV/√Hz, 12 bits, 80 MSPS,
117 mW/ch
NFBGA (135)
15.00 mm × 9.00 mm
AFE5803
8-channel ultrasound AFE, 0.75 nV/√Hz, 14 and 12 bits, 65 MSPS, 158 mW/ch
NFBGA (135)
15.00 mm × 9.00 mm
AFE5805
8-channel ultrasound AFE, 0.85 nV/√Hz, 12 bits, 50 MSPS, 122 mW/ch
NFBGA (135)
15.00 mm × 9.00 mm
AFE5804
8-channel ultrasound AFE, 1.23 nV/√Hz, 12 bits, 50 MSPS, 101 mW/ch
NFBGA (135)
15.00 mm × 9.00 mm
AFE5801
8-channel variable-gain amplifier (VGA) with octal high-speed ADC, 5.5 nV/√Hz,
12 bits, 65 MSPS, 65 mW/ch
VQFN (64)
9.00 mm × 9.00 mm
AFE5851
16-channel VGA with high-speed ADC, 5.5 nV/√Hz, 12 bits, 32.5 MSPS, 39 mW/ch
VQFN (64)
9.00 mm × 9.00 mm
VCA5807
8-channel voltage-controlled amplifier for ultrasound with passive CW mixer,
0.75 nV/√Hz, 99 mW/ch
HTQFP (80)
14.00 mm × 14.00 mm
VCA8500
8-channel, ultralow-power VGA with low-noise pre-amp, 0.8 nV/√Hz, 65 mW/ch
VQFN (64)
9.00 mm × 9.00 mm
ADS5294
Octal-channel, 14-bit, 80-MSPS ADC, 75-dBFS SNR, 77 mW/ch
HTQFP (80)
14.00 mm × 14.00 mm
ADS5292
Octal-channel, 12-bit, 80-MSPS ADC, 70-dBFS SNR, 66 mW/ch
HTQFP (80)
14.00 mm × 14.00 mm
ADS5295
Octal-channel, 12-bit, 100-MSPS ADC, 70.6-dBFS SNR, 80 mW/ch
HTQFP (80)
14.00 mm × 14.00 mm
VQFN (64)
9.00 mm × 9.00 mm
ADS5296A
DESCRIPTION
10-bit, 200-MSPS, 4-channel, 61-dBFS SNR, 150-mW/ch and 12-bit, 80-MSPS,
8-channel, 70-dBFS SNR, 65-mW/ch ADC
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AFE5818
SBAS687B – FEBRUARY 2015 – REVISED AUGUST 2015
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7 Pin Configuration and Functions
ZBV Package
NFBGA-289
Top View
1
2
3
4
A
INP16
INP15
INP14
INP13
INP12
INP11
INP10
B
ACT16
ACT15
ACT14
ACT13
ACT12
ACT11
C
INM16
INM15
INM14
INM13
INM12
INM11
D
CW_DC_
INM_IP
CW_DC_
INP_IP
CW_IP_
AMPINM
CW_IP_
AMPINP
CM_BYP1 AVDD_5V AVDD_5V AVDD_5V AVDD_5V AVDD_5V AVDD_5V AVDD_5V
E
CW_DC
_OUTP_
IP
CW_DC
_OUTM_
IP
CW_IP_
OUTP
CW_IP_
OUTM
CM_BYP2
AVDD
_3P3
AVDD
_3P3
AVSS
AVSS
AVSS
AVDD
_3P3
F
CW_DC
_OUTP_
QP
CW_DC
_OUTM_
QP
CW_QP_
OUTP
CW_QP_
OUTM
VHIGH1
AVDD
_3P3
AVDD
_3P3
AVSS
AVSS
AVSS
G
CW_DC_
INM_QP
CW_DC_
INP_QP
CW_QP_
AMPINM
CW_QP_
AMPINP
VHIGH2
AVDD
_3P3
AVDD
_3P3
AVSS
AVSS
H
AVSS
AVSS
AVSS
VCNTLP
NC
AVDD
_3P3
AVDD
_3P3
AVSS
J
ADC_
CLKP
ADC_
CLKM
AVSS
VCNTLM
NC
AVDD
_3P3
AVDD
_3P3
K
AVSS
AVSS
AVSS
NC
NC
AVDD
_3P3
L
NC
NC
DVDD_
1P2
NC
AVDD
_1P8
M
NC
NC
DVSS
DVDD_
1P2
N
NC
DVDD_
1P2
DVDD_
1P2
P
NC
DVDD_
1P2
DVDD_
1P2
R
NC
T
NC
DOUTM
16
DOUTM
15
DOUTM
14
U
NC
NC
NC
NC
6
9
10
11
12
13
14
15
16
17
INP9
NC
INP8
INP7
INP6
INP5
INP4
INP3
INP2
INP1
ACT10
ACT9
NC
ACT8
ACT7
ACT6
ACT5
ACT4
ACT3
ACT2
ACT1
INM10
INM9
NC
INM8
INM7
INM6
INM5
INM4
INM3
INM2
INM1
NC
NC
AVSS
AVSS
AVSS
AVDD
_3P3
AVDD
_3P3
AVDD
_3P3
AVSS
CLKP_
16X
CLKM_
16X
AVDD
_3P3
AVDD
_3P3
AVDD
_3P3
AVDD
_3P3
AVSS
AVSS
AVSS
AVSS
AVDD
_3P3
AVDD
_3P3
NC
NC
AVSS
AVSS
AVSS
AVDD
_3P3
AVDD
_3P3
NC
NC
NC
SDOUT
NC
AVSS
AVSS
AVSS
AVDD
_3P3
AVDD
_3P3
NC
NC
NC
NC
SCLK
AVDD
_3P3
AVSS
AVSS
AVSS
AVDD
_3P3
AVDD
_3P3
NC
NC
NC
NC
SEN
AVDD
_1P8
AVDD
_1P8
AVSS
AVSS
AVSS
AVDD
_1P8
AVDD
_1P8
AVDD
_1P8
NC
NC
SDIN
RESET
DVDD_
1P2
DVDD_
1P2
DVSS
DVSS
DVSS
DVSS
DVSS
DVDD_
1P2
DVDD_
1P2
DVDD_
1P2
TX_TRIG
PDN_
GBL
PDN_
FAST
DVDD_
1P2
DVDD_
1P2
DVDD_
1P2
DVSS
DVSS
DVSS
DVSS
DVSS
DVDD_
1P2
DVDD_
1P2
DVDD_
1P2
DVDD_
1P2
DVDD_
1P2
NC
DVDD_
1P8
DVDD_
1P8
DVDD_
1P8
DVDD_
1P8
DVSS
DVSS
DVSS
DVDD_
1P8
DVDD_
1P8
DVDD_
1P8
DVDD_
1P8
DVDD_
1P2
DVDD_
1P2
NC
NC
DOUTM
11
DOUTP11
FCLKM
NC
FCLKP
DOUTM6
DOUTP6
NC
DOUTP3
DOUTP2
DOUTP1
NC
DOUTP9
DCLKP
DOUTP8
DOUTP7
DOUTP5
DOUTP4
DOUTM3
DOUTM2
DOUTM1
NC
DOUTM9
DCLKM
DOUTM8
DOUTM7
DOUTM5
DOUTM4
NC
NC
NC
NC
DOUTP16 DOUTP15 DOUTP14
5
6
7
DOUTP13 DOUTP12 DOUTP10
DOUTM
13
DOUTM
12
DOUTM
10
8
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CLKM_1X CLKP_1X
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Pin Functions
PIN
NAME
NO.
ACT16
B1
ACT15
B2
ACT14
B3
ACT13
B4
ACT12
B5
ACT11
B6
ACT10
B7
ACT9
B8
ACT8
B10
ACT7
B11
ACT6
B12
ACT5
B13
ACT4
B14
ACT3
B15
ACT2
B16
ACT1
B17
I/O
DESCRIPTION
I
Active-termination input pins for channels 1 to 16.
1-μF capacitors are recommended. Bias voltage = 1.5 V.
ADC_CLKM (1)
J2
I
Differential clock input pin, negative. A single-ended clock is also supported.
Connect ADC_CLKM to dc ground when using a single-ended clock.
(Common-mode voltage = 0.7 V.)
ADC_CLKP
J1
I
Differential clock input pin, positive. A single-ended clock is also supported.
Connect the ADC clock to the ADC_CLKP pin in a single-ended clock.
(Common-mode voltage = 0.7 V.)
AVDD_1P8
L5-L7, L11-L13
I
1.8-V analog supply pins for the ADC
AVDD_3P3
E6, E7, E11-E14, F6, F7, F11-F14,
G6, G7, G11, G12, H6, H7, H11, H12,
J6, J7, J11, J12, K6, K7, K11, K12
I
3.3-V analog supply pins for the low-noise amplifier (LNA), voltage-controlled
attenuator (VCAT), programmable gain amplifier (PGA), low-pass filter (LPF),
and continuous wave (CW) blocks
D6-D12
I
5-V analog supply pins for the LNA, VCAT, PGA, LPF, and CW blocks
D15-D17, E8-E10, E15, F8-F10, F15F17, G8-G10, G15, H1-H3, H8-H10,
J3, J8-J10, K1-K3, K8-K10, L8-L10
I
Analog ground pins
I
Differential clock inputs for the 1X CW clock, negative. In differential mode, the
device forces a 2.5-V common-mode voltage on this pin. A single-ended clock
is also supported.
In single-ended clock mode, the CLKM_1X pin is internally pulled to ground.
In 1X clock mode, this pin is the quadrate-phase 1X CLKM for the CW mixer.
When CW mode is not used, this pin can be left floated.
I
Differential clock inputs for the 1X CW clock, positive. In differential mode, the
device forces a 2.5-V common-mode voltage on this pin. A single-ended clock
is also supported.
Connect the 1X CW clock to the CLKP_1X pin in a single-ended clock.
In 1X clock mode, this pin is the quadrate-phase 1X CLKP for the CW mixer.
When CW mode is not used, this pin can be left floated.
I
Differential clock inputs for the 32X, 16X, 8X, and 4X CW clocks, negative.
In differential mode, the device forces a 2.5-V common-mode voltage on this
pin. A single-ended clock is also supported.
In single-ended clock mode, the CLKM_16X pin is internally pulled to ground.
In 1X CW clock mode, this pin becomes the in-phase 1X CLKM for the CW
mixer. When CW mode is not used, this pin can be floated.
I
Differential clock inputs for the 32X, 16X, 8X, and 4X CW clocks, positive.
A single-ended clock is also supported.
Connect the 16X CW clock to the CLKP_16X pin in a single-ended clock.
In 1X CW clock mode, this pin becomes the in-phase 1X CLKP for the CW
mixer. In differential mode, the device forces a 2.5-V common-mode voltage
on this pin. When CW mode is not used, this pin can be floated.
O
Bypass to ground with a ≥ 1-μF capacitor.
To suppress ultra low-frequency noise, a 10-μF capacitor can be used.
Bias voltage = 1.5 V.
AVDD_5V
AVSS
CLKM_1X
CLKP_1X
CLKM_16X
G16
G17
E17
CLKP_16X
E16
CM_BYP1
D5
CM_BYP2
E5
(1)
M = negative, P = positive.
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Pin Functions (continued)
PIN
NAME
NO.
CW_DC_INM_IP
D1
CW_DC_INP_IP
D2
CW_DC_INM_QP
G1
CW_DC_INP_QP
G2
CW_DC_OUTM_IP
E2
CW_DC_OUTP_IP
E1
CW_DC_OUTM_QP
F2
CW_DC_OUTP_QP
F1
CW_IP_AMPINM
D3
CW_IP_AMPINP
D4
CW_IP_OUTM
E4
CW_IP_OUTP
E3
CW_QP_AMPINM
G3
CW_QP_AMPINP
G4
CW_QP_OUTM
F4
CW_QP_OUTP
F3
DCLKM
U9
DCLKP
T9
DOUTM1
T16
DOUTP1
R16
DOUTM2
T15
DOUTP2
R15
DOUTM3
T14
DOUTP3
R14
DOUTM4
U13
DOUTP4
T13
DOUTM5
U12
DOUTP5
T12
DOUTM6
R11
DOUTP6
R12
DOUTM7
U11
DOUTP7
T11
DOUTM8
U10
DOUTP8
T10
DOUTM9
U8
DOUTP9
T8
DOUTM10
U7
DOUTP10
T7
DOUTM11
R6
DOUTP11
R7
DOUTM12
U6
DOUTP12
T6
8
I/O
DESCRIPTION
I
In-phase CW high-pass filter differential inputs. An external capacitor must be
connected between CW_DC_INM_IP, CW_DC_OUTP_IP and
CW_DC_INP_IP, CW_DC_OUTM_IP. When CW high-pass filter (HPF) mode
is not used, these pins can be floated. Bias voltage = 1.5 V.
I
Quadrature-phase CW high-pass filter differential inputs. An external capacitor
must be connected between CW_DC_INM_QP, CW_DC_OUTP_QP and
CW_DC_INP_QP, CW_DC_OUTM_QP. When CW HPF mode is not used,
these pins can be floated. Bias voltage = 1.5 V.
O
In-phase CW high-pass filter differential outputs. An external capacitor must be
connected between CW_DC_INM_IP, CW_DC_OUTP_IP and
CW_DC_INP_IP, CW_DC_OUTM_IP. When CW HPF mode is not used, these
pins can be floated. Bias voltage = 1.5 V.
O
Quadrature-phase CW high-pass filter differential outputs. An external
capacitor must be connected between CW_DC_INM_QP, CW_DC_OUTP_QP
and CW_DC_INP_QP, CW_DC_OUTM_QP. When CW HPF mode is not
used, these pins can be floated. Bias voltage = 1.5 V.
I
In-phase CW summing amplifier differential inputs. An external capacitor must
be connected between CW_IP_AMPINM, CW_IP_OUTP and
CW_IP_AMPINP, CW_IP_OUTM. When CW HPF mode is not used, these
pins can be floated. Bias voltage = 1.5 V.
O
In-phase CW summing amplifier differential outputs. An external capacitor
must be connected between CW_IP_AMPINM, CW_IP_OUTP and
CW_IP_AMPINP, CW_IP_OUTM. When CW HPF mode is not used, these
pins can be floated. Bias voltage = 1.5 V.
I
Quadrature-phase CW summing amplifier differential inputs. An external
capacitor must be connected between CW_QP_AMPINM, CW_QP_OUTP and
CW_QP_AMPINP, CW_QP_OUTM. When CW mode is not used, these pins
can be floated. Bias voltage = 1.5 V.
O
Quadrature-phase CW summing amplifier differential outputs. An external
capacitor must be connected between CW_QP_AMPINM, CW_QP_OUTP and
CW_QP_AMPINP, CW_QP_OUTM. When CW mode is not used, these pins
can be floated. Bias voltage = 1.5 V.
O
Low-voltage differential signaling (LVDS) serialized data clock outputs
(receiver bit alignment)
O
LVDS serialized differential data outputs for channel 1
O
LVDS serialized differential data outputs for channel 2
O
LVDS serialized differential data outputs for channel 3
O
LVDS serialized differential data outputs for channel 4
O
LVDS serialized differential data outputs for channel 5
O
LVDS serialized differential data outputs for channel 6
O
LVDS serialized differential data outputs for channel 7
O
LVDS serialized differential data outputs for channel 8
O
LVDS serialized differential data outputs for channel 9
O
LVDS serialized differential data outputs for channel 10
O
LVDS serialized differential data outputs for channel 11
O
LVDS serialized differential data outputs for channel 12
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Pin Functions (continued)
PIN
NAME
NO.
DOUTM13
U5
DOUTP13
T5
DOUTM14
T4
DOUTP14
R4
DOUTM15
T3
DOUTP15
R3
I/O
DESCRIPTION
O
LVDS serialized differential data outputs for channel 13
O
LVDS serialized differential data outputs for channel 14
O
LVDS serialized differential data outputs for channel 15
O
LVDS serialized differential data outputs for channel 16
DOUTM16
T2
DOUTP16
R2
DVDD_1P2
L3, M4-M6, M12-M14, N2-N6, N12N16, P2, P3, P15, P16
I
1.2-V digital supply pins for the ADC digital block
DVDD_1P8
P4-P7, P11-P14
I
1.8-V digital supply pins for the ADC digital, digital I/Os, phase-locked loop
(PLL), and LVDS interface blocks
M3, M7-M11, N7-N11, P8-P10
I
ADC digital ground
O
LVDS serialized frame clock outputs (receiver word alignment)
DVSS
FCLKM
R8
FCLKP
R10
INM1
C17
I
Complimentary analog inputs for channel 1. Place a ≥ 15-nF capacitor to
ground. The HPF response of the LNA depends on the capacitors.
Bias voltage = 2.2 V.
INP1
A17
I
Analog inputs for channel 1. AC-couple to inputs with 0.1-μF capacitors.
Bias voltage = 2.2 V.
INM2
C16
I
Complimentary analog inputs for channel 2. Place a ≥ 15-nF capacitor to
ground. The HPF response of the LNA depends on the capacitors.
Bias voltage = 2.2 V.
INP2
A16
I
Analog inputs for channel 2. AC-couple to inputs with 0.1-μF capacitors.
Bias voltage = 2.2 V.
INM3
C15
I
Complimentary analog inputs for channel 3. Place a ≥ 15-nF capacitor to
ground. The HPF response of the LNA depends on the capacitors.
Bias voltage = 2.2 V.
INP3
A15
I
Analog inputs for channel 3. AC-couple to inputs with 0.1-μF capacitors.
Bias voltage = 2.2 V.
INM4
C14
I
Complimentary analog inputs for channel 4. Place a ≥ 15-nF capacitor to
ground. The HPF response of the LNA depends on the capacitors.
Bias voltage = 2.2 V.
INP4
A14
I
Analog inputs for channel 4. AC-couple to inputs with 0.1-μF capacitors.
Bias voltage = 2.2 V.
INM5
C13
I
Complimentary analog inputs for channel 5. Place a ≥ 15-nF capacitor to
ground. The HPF response of the LNA depends on the capacitors.
Bias voltage = 2.2 V.
INP5
A13
I
Analog inputs for channel 5. AC-couple to inputs with 0.1-μF capacitors.
Bias voltage = 2.2 V.
INM6
C12
I
Complimentary analog inputs for channel 6. Place a ≥ 15-nF capacitor to
ground. The HPF response of the LNA depends on the capacitors.
Bias voltage = 2.2 V.
INP6
A12
I
Analog inputs for channel 6. AC-couple to inputs with 0.1-μF capacitors.
Bias voltage = 2.2 V.
INM7
C11
I
Complimentary analog inputs for channel 7. Place a ≥ 15-nF capacitor to
ground. The HPF response of the LNA depends on the capacitors.
Bias voltage = 2.2 V.
INP7
A11
I
Analog inputs for channel 7. AC-couple to inputs with 0.1-μF capacitors.
Bias voltage = 2.2 V.
INM8
C10
I
Complimentary analog inputs for channel 8. Place a ≥ 15-nF capacitor to
ground. The HPF response of the LNA depends on the capacitors.
Bias voltage = 2.2 V.
INP8
A10
I
Analog inputs for channel 8. AC-couple to inputs with 0.1-μF capacitors.
Bias voltage = 2.2 V.
INM9
C8
I
Complimentary analog inputs for channel 9. Place a ≥ 15-nF capacitor to
ground. The HPF response of the LNA depends on the capacitors.
Bias voltage = 2.2 V.
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Pin Functions (continued)
PIN
NAME
NO.
I/O
DESCRIPTION
INP9
A8
I
Analog inputs for channel 9. AC-couple to inputs with 0.1-μF capacitors.
Bias voltage = 2.2 V.
INM10
C7
I
Complimentary analog inputs for channel 10. Place a ≥ 15-nF capacitor to
ground. The HPF response of the LNA depends on the capacitors.
Bias voltage = 2.2 V.
INP10
A7
I
Analog inputs for channel 10. AC-couple to inputs with 0.1-μF capacitors.
Bias voltage = 2.2 V.
INM11
C6
I
Complimentary analog inputs for channel 11. Place a ≥ 15-nF capacitor to
ground. The HPF response of the LNA depends on the capacitors.
Bias voltage = 2.2 V.
INP11
A6
I
Analog inputs for channel 11. AC-couple to inputs with 0.1-μF capacitors.
Bias voltage = 2.2 V.
INM12
C5
I
Complimentary analog inputs for channel 12. Place a ≥ 15-nF capacitor to
ground. The HPF response of the LNA depends on the capacitors.
Bias voltage = 2.2 V.
INP12
A5
I
Analog inputs for channel 12. AC-couple to inputs with 0.1-μF capacitors.
Bias voltage = 2.2 V.
INM13
C4
I
Complimentary analog inputs for channel 13. Place a ≥ 15-nF capacitor to
ground. The HPF response of the LNA depends on the capacitors.
Bias voltage = 2.2 V.
INP13
A4
I
Analog inputs for channel 13. AC-couple to inputs with 0.1-μF capacitors.
Bias voltage = 2.2 V.
INM14
C3
I
Complimentary analog inputs for channel 14. Place a ≥ 15-nF capacitor to
ground. The HPF response of the LNA depends on the capacitors.
Bias voltage = 2.2 V.
INP14
A3
I
Analog inputs for channel 14. AC-couple to inputs with 0.1-μF capacitors.
Bias voltage = 2.2 V.
INM15
C2
I
Complimentary analog inputs for channel 15. Place a ≥ 15-nF capacitor to
ground. The HPF response of the LNA depends on the capacitors.
Bias voltage = 2.2 V.
INP15
A2
I
Analog inputs for channel 15. AC-couple to inputs with 0.1-μF capacitors.
Bias voltage = 2.2 V.
INM16
C1
I
Complimentary analog inputs for channel 16. Place a ≥ 15-nF capacitor to
ground. The HPF response of the LNA depends on the capacitors.
Bias voltage = 2.2 V.
INP16
A1
I
Analog inputs for channel 16. AC-couple to inputs with 0.1-μF capacitors.
Bias voltage = 2.2 V.
A9, B9, C9, D13, D14, G13, G14, H5,
H13-H15, H17, J5, J13-J16, K4, K5,
K13-K16, L1, L2, L4, L14, L15, M1,
M2, N1, N17, P1, P17, R1, R5, R9,
R13, R17, T1, T17, U1-U4,U14-U17
—
PDN_FAST
M17
I
Partial power-down control pin for the entire device with an internal
16-kΩ pulldown resistor; active high. Note that a 1.8-V logic level is
recommended.
PDN_GBL
M16
I
Global (complete) power-down control pin for the entire device with an internal
16-kΩ pulldown resistor; active high. Note that a 1.8-V logic level is required.
RESET
L17
I
Hardware reset pin with an internal 16-kΩ pulldown resistor; active high.
Note that a 1.8-V logic level is required.
SCLK
J17
I
Serial interface clock pin with an internal 16-kΩ pulldown resistor.
Note that a 1.8-V logic level is required.
SDIN
L16
I
Serial interface data pin with an internal 16-kΩ pulldown resistor.
Note that a 1.8-V logic level is required.
SDOUT
H16
O
Serial interface readout pin for channels 1 to 16. This pin is in tri-state by
default. Note that a 1.8-V logic level is required.
SEN
K17
I
Serial interface enable, active low. This pin has a 16-kΩ pullup resistor.
Note that a 1.8-V logic level is required.
TX_TRIG
M15
I
This pin synchronizes test patterns across devices. This pin has a 20-kΩ
pulldown resistor. Note that a 1.8-V logic level is required.
NC
10
Unused pins. Do not connect.
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Pin Functions (continued)
PIN
NAME
NO.
VCNTLM
J4
VCNTLP
H4
VHIGH1
F5
VHIGH2
G5
I/O
DESCRIPTION
I
Differential attenuation control pins
O
Bypass to ground with a ≥ 1-μF capacitor. Bias voltage = 1 V.
8 Specifications
8.1 Absolute Maximum Ratings
over operating free-air temperature range (unless otherwise noted) (1) (2)
Supply voltage
MIN
MAX
AVDD_1P8
–0.3
2.2
AVDD_3P3
–0.3
3.9
AVDD_5V
–0.3
6
DVDD_1P2
–0.3
1.35
DVDD_1P8
–0.3
2.2
UNIT
V
Voltage at analog inputs
–0.3
minimum [3.6, AVDD_3P3 + 0.3]
V
Voltage at all digital inputs except CW clocks
–0.3
minimum [2.2, DVDD_1P8 + 0.3]
V
Voltage at CW clock input pins
–0.3
minimum [6, AVDD_5V + 0.3]
V
Peak solder temperature (2)
Temperature
(1)
(2)
260
Maximum junction temperature (TJ), any condition
105
Operating, TA
–40
85
Storage, Tstg
–55
150
°C
Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings
only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended
Operating Conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
Device complies with JSTD-020D.
8.2 ESD Ratings
VALUE
V(ESD)
(1)
(2)
Electrostatic discharge
Human body model (HBM), per ANSI/ESDA/JEDEC JS-001
(1)
Charged device model (CDM), per JEDEC specification JESD22-C101 (2)
UNIT
±1000
±250
V
JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.
JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.
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8.3 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)
PARAMETER
MIN
MAX
AVDD_1P8 voltage
1.7
1.9
V
AVDD_3P3 voltage
3.15
3.6
V
AVDD_5V voltage
4.75
5.25
V
DVDD_1P2 voltage
1.15
1.25
V
DVDD_1P8 voltage
V
1.7
1.9
VCNTLP – VCNTLM
0
1.5
Sample rate
5
80 (1)
–40
85
Ambient temperature, TA
(1)
UNIT
V
MHz
°C
The maximum speed supported is a function of ADC resolution. The number specified is for 12-bit mode.
8.4 Thermal Information
AFE5818
THERMAL METRIC (1)
ZBV (NFBGA)
UNIT
289 PINS
RθJA
Junction-to-ambient thermal resistance
28.4
°C/W
RθJC(top)
Junction-to-case (top) thermal resistance
5.3
°C/W
RθJB
Junction-to-board thermal resistance
13.8
°C/W
ψJT
Junction-to-top characterization parameter
0.6
°C/W
ψJB
Junction-to-board characterization parameter
13.5
°C/W
RθJC(bot)
Junction-to-case (bottom) thermal resistance
N/A
°C/W
(1)
12
For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953.
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8.5 Electrical Characteristics
At TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8 = 1.8 V, accoupled with a 0.1-µF capacitor at INP, 15-nF capacitor to ground at INM, no active termination, VCNTLP = VCNTLM = 0 V,
LNA = 18 dB, PGA = 24 dB, LPF filter = 15 MHz, low-noise mode, internal 500-Ω CW feedback resistor, 14-bit ADC
resolution, ADC_CLKP and ADC_CLKM = 50-MHz differential, LVDS mode to capture ADC data, input signal frequency fIN =
5 MHz, and output amplitude VOUT = –1 dBFS, unless otherwise noted. Minimum and maximum values are specified across
the full temperature range.
PARAMETER
TEST CONDITION
MIN
TYP
MAX
UNIT
TGC FULL-SIGNAL CHANNEL (VGA + LPF + ADC)
Low-noise mode, RS = 0 Ω, f = 2 MHz,
PGA = 24 dB
Low-noise mode, RS = 0 Ω, f = 2 MHz,
PGA = 30 dB
Low-power mode, RS = 0 Ω, f = 2 MHz,
PGA = 24 dB
en (RTI)
Input voltage noise over
LNA gain
Low-power mode, RS = 0 Ω, f = 2 MHz,
PGA = 30 dB
Medium-power mode, RS = 0 Ω, f = 2 MHz,
PGA = 24 dB
Medium-power mode, RS = 0 Ω, f = 2 MHz,
PGA = 30 dB
Input-referred current
noise
0.76
LNA = 18 dB
0.87
LNA = 12 dB
1.19
LNA = 24 dB
0.75
LNA = 18 dB
0.84
LNA = 12 dB
1.15
LNA = 24 dB
1.1
LNA = 18 dB
1.2
LNA = 12 dB
1.7
LNA = 24 dB
1.1
LNA = 18 dB
1.2
LNA = 12 dB
1.6
LNA = 24 dB
1
LNA = 18 dB
1.1
LNA = 12 dB
1.3
LNA = 24 dB
0.95
LNA = 18 dB
1
LNA = 12 dB
1.25
Low-noise mode
3.2
Medium-power mode
2.7
Low-power mode
2.3
LNA = 18 dB, RS = 50 Ω, no active termination
NF
LNA = 24 dB
Noise figure
LNA = 18 dB, RS = 400 Ω, no active termination
Low-noise mode
2.4
Medium-power mode
3.2
Low-power mode
3.7
Low-noise figure mode
3.4
Low-noise mode
1.2
Medium-power mode
1.2
Low-power mode
LNA gain = 24 dB
Maximum linear input
voltage
Input clamp voltage in
auto clamp mode
dB
0.83
250
LNA gain = 18 dB
500
LNA gain = 12 dB
1000
LNA gain = 24 dB
350
LNA gain = 18 dB
600
LNA gain = 12 dB
1150
mVPP
mVPP
24
Low-noise mode
30
PGA gain
Medium-power and low-power modes
LNA = 24 dB, PGA = 30 dB, low-noise mode
Total gain
pA/√Hz
1.2
Low-noise figure mode
VMAX
nV/√Hz
24
27.5
54
LNA = 24 dB, PGA = 30 dB, medium-power mode
51.5
LNA = 24 dB, PGA = 30 dB, low-power mode
51.5
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Electrical Characteristics (continued)
At TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8 = 1.8 V, accoupled with a 0.1-µF capacitor at INP, 15-nF capacitor to ground at INM, no active termination, VCNTLP = VCNTLM = 0 V,
LNA = 18 dB, PGA = 24 dB, LPF filter = 15 MHz, low-noise mode, internal 500-Ω CW feedback resistor, 14-bit ADC
resolution, ADC_CLKP and ADC_CLKM = 50-MHz differential, LVDS mode to capture ADC data, input signal frequency fIN =
5 MHz, and output amplitude VOUT = –1 dBFS, unless otherwise noted. Minimum and maximum values are specified across
the full temperature range.
PARAMETER
TEST CONDITION
MIN
TYP
MAX
UNIT
TGC FULL-SIGNAL CHANNEL (continued)
Without a signal
Channel-to-channel
noise correlation factor (1)
–20
With a signal, full band
With a signal, 1-MHz band over carrier
SNR
Signal-to-noise ratio
VCNTLP = 0 V
–10
VCNTLP = 0.8 V
–10
VCNTLP = 0 V
–10
VCNTLP = 0.8 V
–3.75
VCNTLP = 0.6 V (22-dB total channel gain)
65.7
68.5
VCNTLP = 0 V, LNA = 18 dB, PGA = 24 dB
59.3
62.5
VCNTLP = 0 V, LNA = 24 dB, PGA = 24 dB
Narrow-band SNR
SNR over 2-MHz band around carrier at VCNTLP = 0.6 V
(22-dB total gain)
Input common-mode
voltage
At INP and INM pins
dB
dBFS
58
73.8
At dc
77
dBFS
2.2
V
8
kΩ
50
Input resistance
100
Preset active termination enabled (2), across GBL_ACTIVE_TERM (register 196,
bits 7-6) register settings; see Table 74
Ω
200
400
Input capacitance
20
Input control voltage
VCNTLP – VCNTLM
0
Common-mode voltage
VCNTLP and VCNTLM
Tolerable noise at
VCNTLP – VCNTLM
For summation of 16 channels; see Figure 69
6
For summation of 64 channels; see Figure 69
3
0.75
Gain range
pF
1.5
V
V
nV/√Hz
–40
dB
35
dB/V
Between VCNTLP and VCNTLM
200
kΩ
Between VCNTLP and VCNTLM
1
pF
1.5
µs
Gain slope
VCNTLP = 0.1 V to 0.9 V
Input resistance
Input capacitance
TGC response time
VCNTLP = 0-V to 1.5-V step function
10
15
3rd-order, low-pass filter
–1-dB cutoff frequency across LPF_RPOG (register 195, bits 3-0)
register settings; see Table 72
20
30
MHz
35
50
Settling time
(1)
(2)
14
For change in LNA gain
14
For change in active termination setting
10
µs
The noise-correlation factor is defined as 10 × log10[Nc / (Nu + Nc)], where Nc is the correlated noise power in a single channel and Nu
is the uncorrelated noise power in a single channel. The noise-correlation factor measurement is described by the equation:
Nc / (Nu + Nc) = N_16CH / N_1CH / 240 – 1 / 15,
where N_16CH is the noise power of the summed 16 channels and N_1CH is the noise power of one channel.
Total device input impedance is given by the parallel combination of the mentioned active termination resistance and a passive
resistance of 15 kΩ.
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Electrical Characteristics (continued)
At TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8 = 1.8 V, accoupled with a 0.1-µF capacitor at INP, 15-nF capacitor to ground at INM, no active termination, VCNTLP = VCNTLM = 0 V,
LNA = 18 dB, PGA = 24 dB, LPF filter = 15 MHz, low-noise mode, internal 500-Ω CW feedback resistor, 14-bit ADC
resolution, ADC_CLKP and ADC_CLKM = 50-MHz differential, LVDS mode to capture ADC data, input signal frequency fIN =
5 MHz, and output amplitude VOUT = –1 dBFS, unless otherwise noted. Minimum and maximum values are specified across
the full temperature range.
PARAMETER
TEST CONDITION
MIN
TYP
MAX
UNIT
AC ACCURACY
LPF bandwidth tolerance
±5%
Channel-to-channel
group delay variation
2 MHz to 15 MHz
Channel-to-channel
phase variation
15-MHz signal
0 V < VCNTLP < 0.1 V (device-to-device)
Gain matching
2
ns
11
Degrees
±0.5
0.1 V < VCNTLP < 1.1 V (device-to-device)
–1.1
1.1 V < VCNTLP < 1.5 V (device-to-device)
±0.5
1.1
dB
120
LSB
±0.5
Output offset
–120
AC PERFORMANCE
HD2
HD3
Second-harmonic
distortion
Third-harmonic distortion
Input frequency = 2 MHz, output amplitude = –1 dBFS
–60
Input frequency = 5 MHz, output amplitude = –1 dBFS
–60
Input frequency = 5 MHz, output amplitude = –1 dBFS,
input amplitude = 500 mVPP, LNA = 18 dB, VCNTLP = 0.88 V
–55
Input frequency = 5 MHz, output amplitude = –1 dBFS,
input amplitude = 250 mVPP, LNA = 24 dB, VCNTLP = 0.88 V
–55
Input frequency = 2 MHz, output amplitude = –1 dBFS
–55
Input frequency = 5 MHz, output amplitude = –1 dBFS
–55
Input frequency = 5 MHz, output amplitude = –1 dBFS,
input amplitude = 500 mVPP, LNA = 18 dB, VCNTLP = 0.88 V
–55
Input frequency = 5 MHz, output amplitude = –1 dBFS,
input amplitude = 250 mVPP, LNA = 24 dB, VCNTLP = 0.88 V
–55
Input frequency = 2 MHz, output amplitude = –1 dBFS
–55
Input frequency = 5 MHz, output amplitude = –1 dBFS
–55
–60
THD
Total harmonic distortion
IMD3
Intermodulation distortion
Input frequency 1 = 5 MHz at –1 dBFS,
input frequency 2 = 5.01 MHz at –27 dBFS
Fundamental crosstalk
Signal applied to single channel
Phase noise
1 kHz off 5-MHz carrier (VCNTLP = 0 V)
dBc
dBc
dBc
dBc
-60
–132
dBFS
dBc/√Hz
LOW-NOISE AMPLIFIER (LNA)
16
HPF
High-pass filter
–3-dB cutoff frequency for INMx capacitor = 15 nF, across LNA_HPF_PROG
(register 203, bits 3-2) and RED_LNA_HPF_3X (register 205, bit 8) register
settings; see Table 89 and Table 91
50
100
kHz
150
200
Input-referred voltage
noise
RS = 0 Ω, f = 2 MHz, RIN = high-Z
LNA gain = 24 dB
0.63
LNA gain = 18 dB
0.70
LNA gain = 12 dB
0.9
LNA linear output
nV/√Hz
4
VPP
VCAT + PGA
VCAT input noise
PGA input noise
0-dB attenuation
2
–40-dB attenuation
10.5
24-dB and 30-dB attenuation
1.75
–3-dB HPF cutoff
frequency
nV/√Hz
nV/√Hz
80
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Electrical Characteristics (continued)
At TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8 = 1.8 V, accoupled with a 0.1-µF capacitor at INP, 15-nF capacitor to ground at INM, no active termination, VCNTLP = VCNTLM = 0 V,
LNA = 18 dB, PGA = 24 dB, LPF filter = 15 MHz, low-noise mode, internal 500-Ω CW feedback resistor, 14-bit ADC
resolution, ADC_CLKP and ADC_CLKM = 50-MHz differential, LVDS mode to capture ADC data, input signal frequency fIN =
5 MHz, and output amplitude VOUT = –1 dBFS, unless otherwise noted. Minimum and maximum values are specified across
the full temperature range.
PARAMETER
TEST CONDITION
MIN
TYP
MAX
UNIT
CW DOPPLER
en (RTI)
en
(RTO)
NF
Input voltage noise (CW)
Output voltage noise
(CW)
Noise figure
CW operating range
1 channel mixer, LNA = 24 dB, 500-Ω external feedback resistor
0.98
16 channel mixers, LNA = 24 dB, 32-Ω external feedback resistor
0.31
1 channel mixer, LNA = 18 dB, 500-Ω external feedback resistor
1.31
16 channel mixers, LNA = 18 dB, 32-Ω external feedback resistor
0.5
1 channel mixer, LNA = 24 dB, 500-Ω external feedback resistor
13.3
16 channel mixers, LNA = 24 dB, 32-Ω external feedback resistor
3.56
1 channel mixer, LNA = 18 dB, 500-Ω external feedback resistor
8.85
16 channel mixers, LNA = 18 dB, 32-Ω external feedback resistor
2.86
RS = 100 Ω, RIN = high-Z, fIN = 2 MHz, 1 channel, LNA = 18 dB
3.18
RS = 100 Ω, RIN = high-Z, fIN = 2 MHz, 16 channels, LNA = 18 dB
6.15
CW signal carrier frequency
CW clock frequency
CLK duty cycle
1X and 16X CLKs
Common-mode voltage
Internally provided
0.2
IMD3
Input dynamic range
Intermodulation distortion
VPP
65%
2.5
4
1 kHz off 2-MHz carrier (16X mode, 1 channel)
156
1 kHz off 2-MHz carrier (16X mode, 16 channel)
161
Input frequency = 2.5 MHz
LNA = 24 dB
159.1
LNA = 18 dB
162.6
LNA = 12 dB
164.4
f1 = 5 MHz, f2 = 5.01 MHz, both tones at –16-dBm amplitude,
16 channels summed up in-phase, CW feedback resistor = 32 Ω
–50
f1 = 5 MHz, f2 = 5.01 MHz, both tones at –16-dBm amplitude,
single channel summed up in-phase, CW feedback resistor = 500 Ω
–60
V
dB
dBc/Hz
dBFS/Hz
dBc
I/Q channel gain
matching
16X mode
±0.04
4X mode
±0.04
I/Q channel phase
matching
16X mode
±0.01
4X mode
±0.01
–50
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V
5
4
Image rejection ratio
16
0.35
35%
CW mixer conversion
loss
DR
MHz
32
VCMOS CMOS input clock
amplitude
CW mixer phase noise
MHz
128
CLKP_16X, CLKM_16X (4X mode)
CLKM_1X, CLKP_1X and CLKM_16X, CLKP_16X
dB
8
CLKP_16X, CLKM_16X (16X mode)
Clock amplitude
(ac-coupled)
nV/√Hz
8
CLKP_1X, CLKM_1X (16X mode)
CWCLK
nV/√Hz
dB
Degrees
dBc
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Electrical Characteristics (continued)
At TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8 = 1.8 V, accoupled with a 0.1-µF capacitor at INP, 15-nF capacitor to ground at INM, no active termination, VCNTLP = VCNTLM = 0 V,
LNA = 18 dB, PGA = 24 dB, LPF filter = 15 MHz, low-noise mode, internal 500-Ω CW feedback resistor, 14-bit ADC
resolution, ADC_CLKP and ADC_CLKM = 50-MHz differential, LVDS mode to capture ADC data, input signal frequency fIN =
5 MHz, and output amplitude VOUT = –1 dBFS, unless otherwise noted. Minimum and maximum values are specified across
the full temperature range.
PARAMETER
TEST CONDITION
MIN
TYP
MAX
UNIT
CW SUMMING AMPLIFIER
Output common-mode
voltage
Internally provided
1.5
Summing amplifier
output
Input-referred voltage
noise
V
4
At 100 Hz
1.6
At 1 kHz
0.9
At 2 kHz to 100 MHz
0.8
VPP
nV/√Hz
Input-referred current
noise
3.75
Unity-gain bandwidth
150
MHz
50
mAPP
Maximum output current
pA/√Hz
ADC SPECIFICATIONS (Clock Input)
Sample rate
14-bit rate
5
65
12-bit rate
5
80
Input clock amplitude
differential
(ADC_CLKP –
ADC_CLKM)
Sine-wave, ac-coupled
LVDS, ac-coupled
0.3
Input clock CMOS
amplitude single-ended
(ADC_CLKP)
High-level input voltage (VIH)
1.5
MSPS
1.5
LVPECL, ac-coupled
1.6
Low-level input voltage (VIL)
VPP
0.3
Input clock duty cycle
35%
50%
V
65%
ADC SPECIFICATIONS (Signal-to-Noise Ratio)
14-bit ratio
SNR
Signal-to-noise ratio
12-bit ratio
Without signal
75
With full-scale signal
72.5
Without signal
dBFS
72
With full-scale signal
69.5
ADC SPECIFICATIONS (Analog Input)
ADC input full-scale
range
2
LVDS rate
VPP
1000
Mbps
POWER DISSIPATION
AVDD_1P8 voltage
1.7
1.8
1.9
V
AVDD_3P3 voltage
3.15
3.3
3.6
V
AVDD_5V voltage
4.75
5
5.25
V
DVDD_1P2 voltage
1.15
1.2
1.25
V
DVDD_1P8 voltage
1.7
1.8
1.9
V
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Electrical Characteristics (continued)
At TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8 = 1.8 V, accoupled with a 0.1-µF capacitor at INP, 15-nF capacitor to ground at INM, no active termination, VCNTLP = VCNTLM = 0 V,
LNA = 18 dB, PGA = 24 dB, LPF filter = 15 MHz, low-noise mode, internal 500-Ω CW feedback resistor, 14-bit ADC
resolution, ADC_CLKP and ADC_CLKM = 50-MHz differential, LVDS mode to capture ADC data, input signal frequency fIN =
5 MHz, and output amplitude VOUT = –1 dBFS, unless otherwise noted. Minimum and maximum values are specified across
the full temperature range.
PARAMETER
TEST CONDITION
MIN
TYP
MAX
ADC in 12-bit resolution,
80 MSPS
143
170
ADC in 14-bit resolution,
65 MSPS
140
ADC in 14-bit resolution,
50 MSPS
136
ADC in 14-bit resolution,
40 MSPS
134
UNIT
POWER DISSIPATION (continued)
TGC low-noise mode, no signal
TGC mode
(Total power dissipation
per channel)
TGC low-noise mode, 500-mVPP input,1% duty cycle
139.5
TGC medium-power mode
104.4
TGC medium-power mode, 500-mVPP input, 1% duty cycle
107.4
TGC low-power mode
93.5
TGC low-power, 500-mVPP input, 1% duty cycle
CW mode
(Total power dissipation
per channel with ADC
and PGA in power-down
state)
CW mode, no signal, ADC shutdown CW mode
96
16X clock = 32 MHz
80
16X clock = 80 MHz
95
CW mode, 16X clock = 80 MHz, CW summing amplifier external feedback
resistance = 33 Ω, 500-mVPP input to all 16 channels, ADC shutdown
203
TGC low-noise mode, no signal
414
TGC medium-power mode, no signal
260
TGC low-power mode, no signal
AVDD_3P3 current
CW mode, no signal
285
16X clock = 80 MHz
285
430
TGC medium-power mode, 500-mVPP input, 1% duty cycle
274
TGC low-power mode, 500-mVPP input, 1% duty cycle
219
CW mode, 16X clock = 80 MHz, 500-mVPP input to all 16 channels
740
TGC low-noise, medium-power, or low-power mode, no signal
CW mode, no signal
64
16X clock = 80 MHz
115
CW mode, 16X clock = 80 MHz, 500-mVPP input to all 16 channels
AVDD_1P8 current
14-bit mode
12-bit mode
DVDD_1P2 current
14-bit mode
12-bit mode
DVDD_1P8 current
14-bit mode
18
57
16X clock = 32 MHz
TGC, low-noise, medium-power, or low-power mode, 500-mVPP input,
1% duty cycle
12-bit mode
112
mW/Ch
467
207
16X clock = 32 MHz
TGC low-noise mode, 500-mVPP input, 1% duty cycle
AVDD_5V current
mW/Ch
mA
80
136
mA
57
160
80 MSPS
170
20 MSPS
120
65 MSPS
160
20 MSPS
120
80 MSPS
110
20 MSPS
50
65 MSPS
95
20 MSPS
52
80 MSPS
100
20 MSPS
85
65 MSPS
95
20 MSPS
85
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337
197
mA
160
mA
132
mA
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Electrical Characteristics (continued)
At TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8 = 1.8 V, accoupled with a 0.1-µF capacitor at INP, 15-nF capacitor to ground at INM, no active termination, VCNTLP = VCNTLM = 0 V,
LNA = 18 dB, PGA = 24 dB, LPF filter = 15 MHz, low-noise mode, internal 500-Ω CW feedback resistor, 14-bit ADC
resolution, ADC_CLKP and ADC_CLKM = 50-MHz differential, LVDS mode to capture ADC data, input signal frequency fIN =
5 MHz, and output amplitude VOUT = –1 dBFS, unless otherwise noted. Minimum and maximum values are specified across
the full temperature range.
PARAMETER
TEST CONDITION
MIN
TYP
MAX
UNIT
POWER-DOWN
Power dissipation in
power-down mode
Partial power-down when PDN_FAST = high (1.8 V)
28
Complete power-down when PDN_GBL = high (1.8 V)
2.2
Power-down response
time
Power-up response time
Partial power-down when PDN_FAST= high (1.8 V) and the device in partial
power-down time for < 500 µs
Complete power-down when PDN_GBL = high (1.8 V)
1
µs
3
µs
2.7
ms
PSMR
Power-supply modulation fIN = 5 MHz, supply tone of 100 mVPP at
ratio
1-kHz frequency
AVDD_3P3
AVDD_5V
–63
PSRR
Power-supply rejection
ratio (3)
AVDD_3P3
–70
AVDD_5V
–70
(3)
Supply tone of 100 mVPP at 1-kHz frequency
mW/Ch
–65
dBc
dBc
The PSRR value in dBc is measured with respect to the supply tone amplitude applied at the device supply (that is, 100 mVPP).
8.6 Digital Characteristics
The dc specifications refer to the condition where the digital outputs are not switching, but are permanently at a valid logic
level 0 or 1. Typical values are at TA = 25°C, minimum and maximum values are across the full temperature range of
TMIN = -40°C to TMAX = 85°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8 =
1.8 V, external differential load resistance between the LVDS output pair, and RLOAD = 100 Ω, unless otherwise noted.
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
LOAD RESISTANCE
External differential load resistance
Between LVDS output pair
Ω
100
CMOS DIGITAL INPUTS (PDN_GBL, PDN_FAST, RESET, SCLK, SDIN, SEN)
VIH
High-level input voltage
1.4
2.1
VIL
Low-level input voltage
0
0.3
V
IIH
High-level input current
100
µA
IIL
Low-level input current
100
µA
Ci
Input capacitance
4
pF
420
mV
1.03
V
V
LVDS DIGITAL OUTPUTS (DOUTPx, DOUTMx) (1)
|VOD|
Output differential voltage
VOS
Output offset voltage
Common-mode voltage of DOUTPx and
DOUTMx
CMOS DIGITAL OUTPUT (SDOUT)
VOH
High-level output voltage
1.4
DVDD_1P8
VOL
Low-level output voltage
DVSS
0.3
zo
Output impedance
(1)
50
V
V
Ω
All LVDS specifications are characterized but are not tested at production.
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8.7 Output Interface Timing
Typical values are at TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8
= 1.8 V, differential ADC clock, LVDS load CLOAD = 5 pF, RLOAD = 100 Ω, 14-bit ADC resolution, and sample rate = 65 MSPS,
unless otherwise noted. Minimum and maximum values are across the full temperature range of TMIN = –40°C to TMAX = 85°C.
MIN
TYP
MAX
UNIT
GENERAL
tAP
Aperture delay (1)
δtAP
Aperture delay variation from device to device
(at same temperature and supply)
tAPJ
Aperture jitter with LVPECL clock as input clock
1.6
ns
±0.5
ns
0.5
ps
15
Cycles
1
ms
Time to valid data after stopping and
restarting the input clock
100
µs
Default after reset (1)
8.5
Low-latency mode
4.5
Time to valid data after exiting
standby mode
(units are in number of ADC_CLKP,
ADC_CLKM cycles)
Wake-up time
Time to valid data after exiting
PDN_GBL mode
ADC TIMING
Cd
ADC latency
ADC clocks
LVDS TIMING (2)
fF
Frame clock frequency (1)
DFRAME
Frame clock duty cycle
NSER
Number of bits serialization of each ADC word
fCLKIN
MHz
50%
12
16
1X output data rate mode
NSER × fCLKIN
1000
2X output data rate mode
2 × NSER × fCLKIN
1000
500
fD
Output rate of
serialized data
fB
Bit clock frequency
fD / 2
DBIT
Bit clock duty cycle
50%
tD
Data bit duration (1)
tPDI
Clock propagation delay (1)
δtPROP
1
Bits
Mbps
MHz
1000 / fD
ns
6 × tD+ 5
ns
Clock propagation delay variation from device to device
(at same temperature and supply)
±2
ns
tORF
DOUT, DCLK, FCLK rise and fall time, transition time
between –100 mV and +100 mV
0.2
ns
tOSU
Minimum serial data, serial clock setup time (1)
tD / 2 – 0.4
ns
tOH
Minimum serial data, serial clock hold time (1)
tD / 2 – 0.4
ns
tDV
Minimum data valid window (3) (1)
tD – 0.65
ns
TX_TRIG TIMING
tTX_TRIG_DEL
Delay between TX_TRIG and TX_TRIGD (4)
tSU_TX_TRIGD
Setup time related to latching TX_TRIGD relative to the
rising edge of the system clock
0.6
ns
tH_TX_TRIGD
Hold time related to latching TX_TRIGD relative to the
rising edge of the system clock
0.4
ns
(1)
(2)
(3)
(4)
(5)
20
0.4 × tCLKIN (5)
0.5
ns
See Figure 1.
All LVDS specifications are characterized but are not tested at production.
The specification for the minimum data valid window is larger than the sum of the minimum setup and hold times because there can be
a skew between the ideal transitions of the serial output data with respect to the transition of the bit clock. This skew can vary across
channels and across devices. A mechanism to correct this skew can therefore improve the setup and hold timing margins. For example,
the LVDS_DCLK_DELAY_PROG control can be used to shift the relative timing of the bit clock with respect to the data.
TX_TRIGD is the internally delayed version of TX_TRIG that gets latched on the rising edge of the ADC clock.
tCLKIN is the ADC clock period in nanoseconds (ns).
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8.8
SBAS687B – FEBRUARY 2015 – REVISED AUGUST 2015
Serial Interface Timing Characteristics
Typical values are at TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, and
DVDD_1P8 = 1.8 V, unless otherwise noted. Minimum and maximum values are across the full temperature range of
TMIN = –40°C to TMAX = 85°C.
MIN
TYP
MAX
UNIT
tSCLK
SCLK period
50
ns
tSCLK_H
SCLK high time
20
ns
tSCLK_L
SCLK low time
20
ns
tDSU
Data setup time
5
ns
tDHO
Data hold time
5
ns
tSEN_SU
SEN falling edge to SCLK rising edge
8
ns
tSEN_HO
Time between last SCLK rising edge to SEN rising edge
8
tOUT_DV
SDOUT delay
ns
12
20
28
ns
Sample N
Input Signal
TAP
Cd Clock
Cycles Latency
Input Clock (CLKIN)
Frequency = fCLKIN
TF
tPDI
Frame Clock (FCLK)
Frequency = fCLKIN
Bit Clock (DCLK)
Frequency = 7 x fCLKIN
Output Data (CHn OUT)
Data Rate = 14 x fCLKIN
1
(12)
0
(13)
13
(0)
12
(1)
11
(2)
10
(3)
9
(4)
8
(5)
7
(6)
6
(7)
5
(8)
4
(9)
3
(10)
2
(11)
1
(12)
0
(13)
13
(0)
12
(1)
11
(2)
10
(3)
9
(4)
8
(5)
7
(6)
6
(7)
5
(8)
4
(9)
3
(10)
2
(11)
1
(12)
0
(13)
13
(0)
13
(0)
12
(1)
11
(2)
10
(3)
9
(4)
8
(5)
7
(6)
6
(7)
5
(8)
4
(9)
3
(10)
2
(11)
1
(12)
0
(13)
13
(0)
12
(1)
Sample N
Sample N-1
Data Bit in MSB-First Mode
Data Bit in LSB-First Mode
D0
DOUT1
D2
D1
D3
D4
Bit Clock (DCLK)
tD
tD
tOH
tOSU
tB
Bit Clock (DCLK)
tDV
tDV
Figure 1. Output Timing Specification
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8.9 Typical Characteristics
At TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8 = 1.8 V, accoupled with a 0.1-µF capacitor at INP, 15-nF capacitor to ground at INM, no active termination, VCNTLP = VCNTLM = 0 V,
LNA = 18 dB, PGA = 24 dB, LPF filter = 15 MHz, low-noise mode, internal 500-Ω CW feedback resistor, 14-bit ADC
resolution, ADC_CLKP and ADC_CLKM = 50-MHz differential, LVDS mode to capture ADC data, input signal frequency fIN =
5 MHz, and output amplitude VOUT = –1 dBFS, unless otherwise noted. Minimum and maximum values are specified across
the full temperature range.
45
45
Low Noise
Low Power
Medium Power
40
35
35
30
30
Gain (dB)
25
20
25
20
15
15
10
10
5
5
0
0
1.1 1.2 1.3 1.4 1.5
0
0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
VCNTL (V)
D002
Across power modes
Figure 2. Gain vs VCNTL
4000
4000
3500
D004
Gain Matching (dB)
D005
Gain Matching (dB)
VCNTL = 0.3 V
0.9
0.8
0.7
0.6
0.5
0.4
-0.8
0.9
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0
0.1
0
-0.1
0
-0.2
500
-0.3
500
-0.4
1000
-0.5
1000
0.3
1500
0.2
1500
2000
0
2000
2500
0.1
2500
-0.6
D003
3000
-0.5
3000
-0.6
3500
-0.7
Number of Occurrences
4500
4500
-0.7
1.1 1.2
Figure 3. Gain vs VCNTL
5000
-0.8
Number of Occurrences
1
Across temperature
-0.1
1
VCNTL (V)
-0.2
0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
-0.3
0
-0.4
Gain (dB)
-40qC
25qC
85qC
40
VCNTL = 0.6 V
Figure 4. Gain Matching Histogram (17472 Channels)
Figure 5. Gain Matching Histogram (17472 Channels)
4000
2500
Number of Occurrences
Number of Occurrences
3500
3000
2500
2000
1500
1000
2000
1500
1000
500
500
Gain Matching (dB)
D006
85
75
65
55
45
35
25
15
5
-5
-15
-25
-35
-45
-55
-65
ADC Output
VCNTL = 0.9 V
D007
VCNTL = 0 V
Figure 6. Gain Matching Histogram (17472 Channels)
22
-75
-85
0.9
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
0
-0.1
-0.2
-0.3
-0.4
-0.5
-0.6
-0.7
0
-0.8
0
Figure 7. Output Offset Histogram (17472 Channels)
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Typical Characteristics (continued)
At TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8 = 1.8 V, accoupled with a 0.1-µF capacitor at INP, 15-nF capacitor to ground at INM, no active termination, VCNTLP = VCNTLM = 0 V,
LNA = 18 dB, PGA = 24 dB, LPF filter = 15 MHz, low-noise mode, internal 500-Ω CW feedback resistor, 14-bit ADC
resolution, ADC_CLKP and ADC_CLKM = 50-MHz differential, LVDS mode to capture ADC data, input signal frequency fIN =
5 MHz, and output amplitude VOUT = –1 dBFS, unless otherwise noted. Minimum and maximum values are specified across
the full temperature range.
12000
10
Open
10000
-10
-20
8000
Phase (q)
Impedance (:)
Open
0
6000
4000
-30
-40
-50
-60
-70
2000
-80
0
0.5
4.5
8.5
12.5
Frequency (MHz)
16.5
-90
0.5
20.5
4.5
D008
Without active termination
16.5
20.5
D009
Without active termination
Figure 8. Input Impedance Magnitude vs Frequency
Figure 9. Input Impedance Phase vs Frequency
550
10
50 :
100 :
200 :
400 :
500
450
400
0
-10
-20
350
Phase (q)
Impedance (:)
8.5
12.5
Frequency (MHz)
300
250
200
-30
-40
-50
-60
150
100
-70
50
-80
0
0
5
10
15
Frequency (MHz)
20
-90
0.5
25
50 :
100 :
200 :
400 :
4.5
D010
Across active termination
8.5
12.5
Frequency (MHz)
16.5
20.5
D011
Across active termination
Figure 10. Input Impedance Magnitude vs Frequency
Figure 11. Input Impedance Phase vs Frequency
5
3
0
0
-3
-5
Amplitude (dB)
Amplitude (dB)
-6
-10
-15
-20
10 MHz
15 MHz
20 MHz
30 MHz
35 MHz
50 MHz
-25
-30
-35
10
20
-15
-18
Register 203[3:2], 205[8] = 01, 1
Register 203[3:2], 205[8] = 01, 0
Register 203[3:2], 205[8] = 00, 0
Register 203[3:2], 205[8] = 11, 0
Register 203[3:2], 205[8] = 10, 0
-21
-24
-27
-40
0
-9
-12
30
40
50
60
Frequency (MHz)
70
80
90
-30
10
D012
Across LPF corner settings
20
30 40 50 70 100
Frequency (kHz)
200
300
500
D013
Across LNA_HPF_PROG (register 203, bits 3-2) and
RED_LNA_HPF_3X (register 205, bit 8)
Figure 12. Full-Channel Amplitude Response vs Frequency
Figure 13. LNA High-Pass Filter Amplitude Response vs
Frequency
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Typical Characteristics (continued)
At TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8 = 1.8 V, accoupled with a 0.1-µF capacitor at INP, 15-nF capacitor to ground at INM, no active termination, VCNTLP = VCNTLM = 0 V,
LNA = 18 dB, PGA = 24 dB, LPF filter = 15 MHz, low-noise mode, internal 500-Ω CW feedback resistor, 14-bit ADC
resolution, ADC_CLKP and ADC_CLKM = 50-MHz differential, LVDS mode to capture ADC data, input signal frequency fIN =
5 MHz, and output amplitude VOUT = –1 dBFS, unless otherwise noted. Minimum and maximum values are specified across
the full temperature range.
5
5
PGA Integrator Enable
PGA Integrator Disable
0
-5
0
Amplitude (dB)
Amplitude (dB)
-10
-15
-20
-25
-5
-30
-10
-35
-40
-45
10
-15
100
Frequency (kHz)
500
0
100
200
300
D014
400 500 600 700
Frequency (kHz)
800
900 1000
D015
With INM capacitor = 1 μF
-144
-146
-148
-150
-152
-154
-156
-158
-160
-162
-164
-166
-168
-170
100
Figure 15. Full-Channel Low Frequency Amplitude
Response vs Frequency
16X Clock Mode
8X Clock Mode
4X Clock Mode
Phase Noise (dBc/Hz)
Phase Noise (dBc/Hz)
Figure 14. Full-Channel High-Pass Filter Amplitude
Response vs Frequency
1k
10k
Offset Frequency (Hz)
50k
-144
-146
-148
-150
-152
-154
-156
-158
-160
-162
-164
-166
-168
-170
100
D017
Figure 17. CW Phase Noise vs Offset Frequency
45
16X Clock Mode
8X Clock Mode
4X Clock Mode
LNA 12 dB
LNA 18 dB
LNA 24 dB
40
Input-Referred Noise (nV—Hz)
Phase Noise (dBc/Hz)
50k
fIN = 2 MHz, across one channel and 16 channels
Figure 16. CW Phase Noise vs Offset Frequency
35
30
25
20
15
10
5
0
1k
10k
Offset Frequency (Hz)
50k
0
D018
fIN = 2 MHz, 16 channels across CW clock modes
Figure 18. CW Phase Noise vs Offset Frequency
24
1k
10k
Offset Frequency (Hz)
D016
fIN = 2 MHz, one channel across CW clock modes
-144
-146
-148
-150
-152
-154
-156
-158
-160
-162
-164
-166
-168
-170
100
Phase Noise 1 Channel
Phase Noise 16 Channels
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0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
VCNTL (V)
1
1.1 1.2
D019
Across LNA gain for low-noise mode
Figure 19. Input-Referred Noise vs VCNTL
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Typical Characteristics (continued)
At TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8 = 1.8 V, accoupled with a 0.1-µF capacitor at INP, 15-nF capacitor to ground at INM, no active termination, VCNTLP = VCNTLM = 0 V,
LNA = 18 dB, PGA = 24 dB, LPF filter = 15 MHz, low-noise mode, internal 500-Ω CW feedback resistor, 14-bit ADC
resolution, ADC_CLKP and ADC_CLKM = 50-MHz differential, LVDS mode to capture ADC data, input signal frequency fIN =
5 MHz, and output amplitude VOUT = –1 dBFS, unless otherwise noted. Minimum and maximum values are specified across
the full temperature range.
50
LNA 12 dB
LNA 18 dB
LNA 24 dB
3
LNA 12 dB
LNA 18 dB
LNA 24 dB
45
Input-Referred Noise (nV—Hz)
Input-Referred Noise (nV—Hz)
3.5
2.5
2
1.5
1
0.5
40
35
30
25
20
15
10
5
0
0
0
0.1
0.2
VCNTL (V)
0.3
0
0.4
0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
VCNTL (V)
D020
Across LNA gain for low-noise mode
D021
Figure 21. Input-Referred Noise vs VCNTL
70
3
LNA 12 dB
LNA 18 dB
LNA 24 dB
2.5
Input-Referred Noise (nV—Hz)
Input-Referred Noise (nV—Hz)
1.1 1.2
Across LNA gain for medium-power mode
Figure 20. Input-Referred Noise vs VCNTL (Zoomed)
2
1.5
1
LNA 12 dB
LNA 18 dB
LNA 24 dB
60
50
40
30
20
10
0
0.5
0
0.1
0.2
VCNTL (V)
0.3
0
0.4
0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
VCNTL (V)
D022
Across LNA gain for medium-power mode
1
1.1 1.2
D023
Across LNA gain for low-power mode
Figure 22. Input-Referred Noise vs VCNTL (Zoomed)
Figure 23. Input-Referred Noise vs VCNTL
230
3.5
LNA 12 dB
LNA 18 dB
LNA 24 dB
3
LNA 12 dB
LNA 18 dB
LNA 24 dB
210
Output-Referred Noise (nV—Hz)
Input-Referred Noise (nV—Hz)
1
2.5
2
1.5
1
190
170
150
130
110
90
70
50
30
0.5
0
0.1
0.2
VCNTL (V)
0.3
0.4
0
0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
VCNTL (V)
D024
Across LNA gain for low-power mode
1
1.1 1.2
D025
Across LNA gain for low-noise mode
Figure 24. Input-Referred Noise vs VCNTL (Zoomed)
Figure 25. Output-Referred Noise vs VCNTL
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Typical Characteristics (continued)
At TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8 = 1.8 V, accoupled with a 0.1-µF capacitor at INP, 15-nF capacitor to ground at INM, no active termination, VCNTLP = VCNTLM = 0 V,
LNA = 18 dB, PGA = 24 dB, LPF filter = 15 MHz, low-noise mode, internal 500-Ω CW feedback resistor, 14-bit ADC
resolution, ADC_CLKP and ADC_CLKM = 50-MHz differential, LVDS mode to capture ADC data, input signal frequency fIN =
5 MHz, and output amplitude VOUT = –1 dBFS, unless otherwise noted. Minimum and maximum values are specified across
the full temperature range.
LNA 12 dB
LNA 18 dB
LNA 24 dB
0
0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
VCNTL (V)
1
360
340
320
300
280
260
240
220
200
180
160
140
120
100
80
60
40
Output-Referred Noise (nV—Hz)
Output-Referred Noise (nV—Hz)
300
280
260
240
220
200
180
160
140
120
100
80
60
40
1.1 1.2
LNA 12 dB
LNA 18 dB
LNA 24 dB
0
0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
VCNTL (V)
D026
Across LNA gain for medium-power mode
1.1 1.2
D027
Across LNA gain for low-power mode
Figure 26. Output-Referred Noise vs VCNTL
Figure 27. Output-Referred Noise vs VCNTL
250
250
Regsiter 203[3:2], 205[8] = 01, 1
Regsiter 203[3:2], 205[8] = 01, 0
Regsiter 203[3:2], 205[8] = 00, 0
Regsiter 203[3:2], 205[8] = 11, 0
Regsiter 203[3:2], 205[8] = 10, 0
225
200
Output-Referred Noise (nV/—Hz)
Output-Referred Noise (nV/—Hz)
1
175
150
125
100
75
0
200
400
600
800 1000
Frequency (kHz)
1200
1400
1600
225
200
175
150
125
100
75
50
250
450
650
850 1050
Frequency (kHz)
D028
Across LNA_HPF_PROG (register 203, bits 3-2) and
RED_LNA_HPF_3X (register 205, bit 8)
1250
1450
1650
D029
INMx capacitor = 1 µF, PGA_HPF_DIS (register 195, bit 4) = 1
Figure 28. Low-Frequency Output-Referred Noise vs
Frequency
Figure 29. Low-Frequency Output-Referred Noise vs
Frequency
180
1.5
Output-Referred Noise (nV/—Hz)
Input-Referred Noise (nV/—Hz)
1.4
1.3
1.2
1.1
1
0.9
0.8
0.7
0.6
0.5
160
140
120
100
80
60
0.4
40
0.3
1
2
3
4
5
6
7
8
Frequency (MHz)
9
10
11
12
Figure 30. Input-Referred Noise vs Frequency
26
1
D030
2
3
4
5
6
7
8
Frequency (MHz)
9
10
11
12
D031
Figure 31. Output-Referred Noise vs Frequency
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Typical Characteristics (continued)
75
75
70
70
SNR (dBFS)
SNR (dBFS)
At TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8 = 1.8 V, accoupled with a 0.1-µF capacitor at INP, 15-nF capacitor to ground at INM, no active termination, VCNTLP = VCNTLM = 0 V,
LNA = 18 dB, PGA = 24 dB, LPF filter = 15 MHz, low-noise mode, internal 500-Ω CW feedback resistor, 14-bit ADC
resolution, ADC_CLKP and ADC_CLKM = 50-MHz differential, LVDS mode to capture ADC data, input signal frequency fIN =
5 MHz, and output amplitude VOUT = –1 dBFS, unless otherwise noted. Minimum and maximum values are specified across
the full temperature range.
65
60
55
65
60
55
24-dB PGA Gain
30-dB PGA Gain
24-dB PGA Gain
30-dB PGA Gain
50
50
0
0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
VCNTL (V)
1
1.1 1.2
0
0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
VCNTL (V)
D032
Low-noise mode across PGA gain
Figure 32. Signal-to-Noise Ratio vs VCNTL
D033
Figure 33. Signal-to-Noise Ratio vs VCNTL
12
Low Noise
Low Power
71
100 :
200 :
400 :
Without Termination
11
10
69
9
Noise Figure (dB)
SNR (dBFS)
1.1 1.2
Low-power mode across PGA gain
73
67
65
63
61
8
7
6
5
4
3
2
59
1
57
0
3
6
9
0
50
12 15 18 21 24 27 30 33 36 39 42
Gain (dB)
D034
Across power modes
100
150
200
250
300
Source Impedence (:)
350
400
D035
LNA = 12 dB, low-noise mode across active termination
Figure 34. Signal-to-Noise Ratio vs Gain
Figure 35. Noise Figure vs Source Impedance
10
12
50 :
100 :
200 :
400 :
Without Termination
10
9
8
50 :
100 :
200 :
400 :
Without Termination
9
8
Noise Figure (dB)
11
Noise Figure (dB)
1
7
6
5
4
7
6
5
4
3
3
2
2
1
1
0
50
100
150
200
250
300
Source Impedence (:)
350
400
0
50
100
D036
LNA = 18 dB, low-noise mode across active termination
Figure 36. Noise Figure vs Source Impedance
150
200
250
300
Source Impedence (:)
350
400
D037
LNA = 24 dB, low-noise mode across active termination
Figure 37. Noise Figure vs Source Impedance
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Typical Characteristics (continued)
At TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8 = 1.8 V, accoupled with a 0.1-µF capacitor at INP, 15-nF capacitor to ground at INM, no active termination, VCNTLP = VCNTLM = 0 V,
LNA = 18 dB, PGA = 24 dB, LPF filter = 15 MHz, low-noise mode, internal 500-Ω CW feedback resistor, 14-bit ADC
resolution, ADC_CLKP and ADC_CLKM = 50-MHz differential, LVDS mode to capture ADC data, input signal frequency fIN =
5 MHz, and output amplitude VOUT = –1 dBFS, unless otherwise noted. Minimum and maximum values are specified across
the full temperature range.
4.5
4.5
Low Noise
Low Power
Medium Power
Low Noise Figure
3.5
Noise Figure (dB)
Noise Figure (dB)
Low Noise
Low Power
Medium Power
Low Noise Figure
3.5
2.5
2.5
1.5
1.5
50
100
150
200
250
300
Source Impedence (:)
350
0.5
50
400
Active termination = 400-Ω across power modes
150
200
250
300
Source Impedence (:)
350
400
D039
Without active termination across power modes
Figure 38. Noise Figure vs Source Impedance
Figure 39. Noise Figure vs Source Impedance
-50
-45
-55
-50
-60
-55
HD3 (dBc)
HD2 (dBc)
100
D038
-65
-70
Low Noise
Low Power
Medium Power
-60
-65
Low Noise
Low Power
Medium Power
-75
-70
-80
-75
1
2
3
4
5
6
7
Frequency (MHz)
8
9
10
1
2
3
D040
VIN = 500 mVPP, VOUT = –1 dBFS across power modes
Figure 40. Second-Order Harmonic Distortion vs Frequency
4
5
6
7
Frequency (MHz)
8
9
10
D041
VIN = 500 mVPP, VOUT = –1 dBFS across power modes
Figure 41. Third-Order Harmonic Distortion vs Frequency
-30
-40
Low Noise
Low Power
Medium Power
-45
-50
Low Noise
Low Power
Medium Power
-40
-60
HD3 (dBc)
HD2 (dBc)
-55
-65
-70
-50
-60
-75
-80
-70
-85
-90
-80
6
12
18
24
Gain (dB)
30
36
LNA = 12 dB, VOUT = –1 dBFS across power modes
Figure 42. Second-Order Harmonic Distortion vs Gain
28
6
12
18
24
Gain (dB)
D042
30
36
D043
LNA = 12 dB, VOUT = –1 dBFS across power modes
Figure 43. Third-Order Harmonic Distortion vs Gain
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Typical Characteristics (continued)
At TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8 = 1.8 V, accoupled with a 0.1-µF capacitor at INP, 15-nF capacitor to ground at INM, no active termination, VCNTLP = VCNTLM = 0 V,
LNA = 18 dB, PGA = 24 dB, LPF filter = 15 MHz, low-noise mode, internal 500-Ω CW feedback resistor, 14-bit ADC
resolution, ADC_CLKP and ADC_CLKM = 50-MHz differential, LVDS mode to capture ADC data, input signal frequency fIN =
5 MHz, and output amplitude VOUT = –1 dBFS, unless otherwise noted. Minimum and maximum values are specified across
the full temperature range.
-40
-30
Low Noise
Low Power
Medium Power
-60
-40
HD3 (dBc)
HD2 (dBc)
-50
-70
Low Noise
Low Power
Medium Power
-80
-50
-60
-70
-90
12
18
24
30
36
-80
12
42
18
24
Gain (dB)
30
36
42
Gain (dB)
LNA = 18 dB, VOUT = –1 dBFS across power modes
D045
LNA = 18 dB, VOUT = –1 dBFS, across power modes
Figure 44. Second-Order Harmonic Distortion vs Gain
Figure 45. Third-Order Harmonic Distortion vs Gain
-30
-40
Low Noise
Low Power
Medium Power
-45
-50
Low Noise
Low Power
Medium Power
-40
-60
HD3 (dBc)
HD2 (dBc)
-55
-65
-70
-50
-60
-75
-80
-70
-85
-90
18
24
30
36
42
-80
18
48
Gain (dB)
24
30
LNA = 24 dB, VOUT = –1 dBFS across power modes
48
D047
Figure 47. Third-Order Harmonic Distortion vs Gain
-54
-54
fIN1 = 2 MHz, fIN2 = 2.01 MHz
fIN1 = 5 MHz, fIN2 = 5.01 MHz
fIN1 = 2 MHz, fIN2 = 2.01 MHz
fIN1 = 5 MHz, fIN2 = 5.01 MHz
-58
IMD3 (dBFS)
-58
IMD3 (dBFS)
42
LNA = 24 dB, VOUT = –1 dBFS across power modes
Figure 46. Second-Order Harmonic Distortion vs Gain
-62
-66
-70
-74
14
36
Gain (dB)
D046
-62
-66
-70
18
22
26
30
Gain (dB)
34
38
42
-74
14
D048
fOUT1 = –1 dBFS, fOUT2 = –21 dBFS
18
22
26
30
Gain (dB)
34
38
42
D049
fOUT1 = –7 dBFS, fOUT2 = –7 dBFS
Figure 48. IMD3 vs Gain
Figure 49. IMD3 vs Gain
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Typical Characteristics (continued)
At TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8 = 1.8 V, accoupled with a 0.1-µF capacitor at INP, 15-nF capacitor to ground at INM, no active termination, VCNTLP = VCNTLM = 0 V,
LNA = 18 dB, PGA = 24 dB, LPF filter = 15 MHz, low-noise mode, internal 500-Ω CW feedback resistor, 14-bit ADC
resolution, ADC_CLKP and ADC_CLKM = 50-MHz differential, LVDS mode to capture ADC data, input signal frequency fIN =
5 MHz, and output amplitude VOUT = –1 dBFS, unless otherwise noted. Minimum and maximum values are specified across
the full temperature range.
-60
-50
VCNTL = 0 V
VCNTL = 0.3 V
VCNTL = 0.6 V
VCNTL = 0.9 V
-55
-65
PSMR (dBc)
PSMR (dBc)
VCNTL = 0 V
VCNTL = 0.3 V
VCNTL = 0.6 V
VCNTL = 0.9 V
-60
-65
-70
-70
-75
-75
5
10
100
Supply Frequency (kHz)
1k
2k
5
10
100
Supply Frequency (kHz)
D050
Across VCNTL
-10
VCNTL = 0 V
VCNTL = 0.3 V
VCNTL = 0.6 V
VCNTL = 0.9 V
-40
VCNTL = 0 V
VCNTL = 0.3 V
VCNTL = 0.6 V
VCNTL = 0.9 V
-20
PSRR wrt Supply Tone (dB)
-30
-50
-60
-70
-80
-30
-40
-50
-60
-70
-80
-90
-90
5
10
100
Supply Frequency (kHz)
1k
2k
5
10
D052
100
Supply Frequency (kHz)
Across VCNTL
1k
2k
D053
Across VCNTL
Figure 52. AVDD Power-Supply Rejection Ratio vs
100-mVPP Supply Noise Frequencies
1.35
18000
1.2
16000
1.05
16000
1.05
14000
0.9
14000
0.9
12000
0.75
12000
0.75
10000
0.6
8000
0.45
6000
0.3
4000
0.15
4000
2000
0
2000
0
-0.15
0
0.5
1
1.5
Time (Ps)
2
2.5
3
Output Code (LSB)
1.35
Output Code
1.2
VCNTL
20000
18000
VCNTL (V)
20000
Figure 53. AVDD_5V Power-Supply Rejection Ratio vs
100-mVPP Supply Noise Frequencies
10000
0.6
8000
0.45
6000
0.3
VCNTL (V)
PSRR wrt Supply Tone (dB)
D051
Figure 51. AVDD_5V Power-Supply Modulation Ratio vs
100-mVPP Supply Noise Frequencies
-20
Output Code (LSB)
2k
Across VCNTL
Figure 50. AVDD Power-Supply Modulation Ratio vs
100-mVPP Supply Noise Frequencies
0.15
0
0
0.2 0.4 0.6 0.8
D054
Figure 54. VCNTL Response vs Time
30
1k
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1
1.2 1.4 1.6 1.8
Time (Ps)
Output Code 0
VCNTL
-0.15
2 2.2 2.4 2.6
D055
Figure 55. VCNTL Response vs Time
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Typical Characteristics (continued)
1.2
1.2
0.6
0.6
Input (V)
Input (V)
At TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8 = 1.8 V, accoupled with a 0.1-µF capacitor at INP, 15-nF capacitor to ground at INM, no active termination, VCNTLP = VCNTLM = 0 V,
LNA = 18 dB, PGA = 24 dB, LPF filter = 15 MHz, low-noise mode, internal 500-Ω CW feedback resistor, 14-bit ADC
resolution, ADC_CLKP and ADC_CLKM = 50-MHz differential, LVDS mode to capture ADC data, input signal frequency fIN =
5 MHz, and output amplitude VOUT = –1 dBFS, unless otherwise noted. Minimum and maximum values are specified across
the full temperature range.
0
-0.6
-0.6
-1.2
-1.2
0
0.5
1
1.5
Time (Ps)
2
2.5
3
0
Figure 56. Pulse Inversion Asymmetrical Positive Input
0.5
1
1.5
Time (Ps)
2
2.5
3
Figure 57. Pulse Inversion Asymmetrical Negative Input
600
10000
Positive Overload
Negative Overload
Average
8000
Positive Overload
Negative Overload
Average
400
Output Code (LSB)
6000
Output Code (LSB)
0
4000
2000
0
-2000
-4000
-6000
200
0
-200
-400
-8000
-600
-10000
0
1
2
3
4
5
6
Time (Ps)
7
8
9
0
10
D058
3
4
5
6
Time (Ps)
7
8
9
10
11
D059
Figure 59. Device Pulse Inversion Output vs Time (Zoomed)
2000
10000
47 nF
15 nF
8000
47 nF
15 nF
1600
6000
1200
4000
800
Output Code (LSB)
Output Code (LSB)
2
VIN = 2 VPP, PRF = 1 kHz, gain = 21 dB
VIN = 2 VPP, PRF = 1 kHz, gain = 21 dB, across pulse inversion
asymmetrical positive and negative input
Figure 58. Device Pulse Inversion Output vs Time
1
2000
0
-2000
-4000
400
0
-400
-800
-6000
-1200
-8000
-1600
-2000
-10000
0
0.5
1
1.5
2
2.5
3
Time (Ps)
3.5
4
4.5
5
1
D060
VIN = large amplitude (50 mVPP) followed by small amplitude
(500 µVPP), across INM capacitor
Figure 60. Overload Recovery Output vs Time
1.5
2
2.5
3
3.5
Time (Ps)
4
4.5
5
D061
VIN = large amplitude (50 mVPP) followed by small amplitude
(500 µVPP), across INM capacitor
Figure 61. Overload Recovery Output vs Time (Zoomed)
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Typical Characteristics (continued)
At TA = 25°C, AVDD_1P8 = 1.8 V, AVDD_3P3 = 3.3 V, AVDD_5V = 5 V, DVDD_1P2 = 1.2 V, DVDD_1P8 = 1.8 V, accoupled with a 0.1-µF capacitor at INP, 15-nF capacitor to ground at INM, no active termination, VCNTLP = VCNTLM = 0 V,
LNA = 18 dB, PGA = 24 dB, LPF filter = 15 MHz, low-noise mode, internal 500-Ω CW feedback resistor, 14-bit ADC
resolution, ADC_CLKP and ADC_CLKM = 50-MHz differential, LVDS mode to capture ADC data, input signal frequency fIN =
5 MHz, and output amplitude VOUT = –1 dBFS, unless otherwise noted. Minimum and maximum values are specified across
the full temperature range.
10
0
Gain (dB)
-10
Normalized K = 0
Normalized K = 1
HPF_CORNER_CHxy = 2
HPF_CORNER_CHxy = 3
HPF_CORNER_CHxy = 4
HPF_CORNER_CHxy = 5
HPF_CORNER_CHxy = 6
HPF_CORNER_CHxy = 7
HPF_CORNER_CHxy = 8
HPF_CORNER_CHxy = 9
HPF_CORNER_CHxy = 10
-20
-30
-40
-50
-60
0
0.2
0.4
0.6
0.8
1
1.2 1.4
Frequency (MHz)
1.6
1.8
2
D062
Across various HPF corner settings
Figure 62. Digital High-Pass Filter Gain Response vs Frequency
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9 Detailed Description
9.1 Overview
The AFE5818 is a highly-integrated, analog front-end (AFE) solution specifically designed for ultrasound systems
in which high performance and higher integration are required. The device integrates a complete time-gaincontrol (TGC) imaging path and a continuous wave Doppler (CWD) path. The device also enables users to select
from a variety of power and noise combinations to optimize system performance. The device contains 16
dedicated channels, each comprising a low-noise amplifier (LNA), voltage-controlled attenuator (VCAT),
programmable gain amplifier (PGA), low-pass filter (LPF), and either a 14-bit or 12-bit analog-to-digital converter
(ADC). At the output of the 16 ADCs is a low-voltage differential signaling (LVDS) serializer to transfer digital
data. In addition, the device also contains a continuous wave (CW) mixer. Multiple features in the device are
suitable for ultrasound applications (such as active termination, individual channel control, fast power-up and
power-down response, programmable clamp voltage control, fast and consistent overload recovery, and digital
processing). Therefore, this device brings premium image quality to ultra-portable, handheld systems all the way
up to high-end ultrasound systems. In addition, the signal chain of the device can handle signal frequencies as
low as 10 kHz and as high as 50 MHz. This broad analog frequency range enables the device to be used in both
sonar and medical applications. See the Functional Block Diagram section for a simplified function block
diagram.
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DVDD_1P8
DVDD_1P2
AVDD_1P8
AVDD_5V
AVDD_3P3
9.2 Functional Block Diagram
VCM
CM_BYP1
Reference Voltage,
Current Generator
CM_BYP2
VHIGH1
VHIGH2
Programmable Active Termination
ACT1
INP1
VCAT
0 dB to
-40 dB
LNA
INM1
LPF
10, 15, 20,
30, 35, and
50 MHz
PGA
24 dB, 30 dB
ADC 1
VNCTL
CW Mixer
LVDS
CW_CH1
DOUTP1
DOUTM1
16x16 CrossPoint SW
CW_CLOCK
DOUTP2
Programmable Active Termination
DOUTM2
INM2
LPF
10, 15, 20,
30, 35, and
50 MHz
PGA
24 dB, 30 dB
ADC 2
VCNTL
CW_CH2
CW Mixer
16x16 CrossPoint SW
CW_CLOCK
LVDS Outputs
VCAT
0 dB to
-40 dB
LNA
LVDS Serializer
Analog Inputs
INP2
Digital Processing (Optional)
ACT2
DOUTP16
DOUTM16
FCLKP
FCLKM
DCLKP
DCLKM
Programmable Active Termination
ACT16
INP16
VCAT
0 dB to
-40 dB
LNA
INM16
LPF
10, 15, 20,
30, 35, and
50 MHz
PGA
24 dB, 30 dB
ADC 16
VCNTL
CW Mixer
CW_CH16
Conversion Clock
16x16 CrossPoint SW
CW_CLOCK
VCNTL
CW_CLOCK
CW Clock
CLKM_16x
Clock
Generator
CW_CH15
CW_CH16
CW_CH1
CW_CH2
VCNTRL Block
CLKP_16x
Serial Interface
SYNC Generator
SDOUT
16 Phase Generator
CLKP_1x
CLKM_1x
SEN
SDIN
SCLK
RESET
PDN_GBL
PDN_FAST
TX_TRIG
ADC_CLKP
ADC_CLKM
VCNTLM
VCNTLP
DVSS
AVSS
Summing Amplifier
CW_IP_OUTP, CW_IP_OUTM,
CW_QP_OUTP, CW_QP_OUTM,
ADC Clock or
System Clock
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9.3 Feature Description
9.3.1 Low-Noise Amplifier
In many high-gain systems, a low-noise amplifier is critical to achieve overall performance. The device uses new
proprietary architecture and a bipolar junction transistor (BJT) input transistor to achieve exceptional low-noise
performance when operating on a low-quiescent current.
9.3.1.1 Input Signal Support
The LNA takes a single-ended input signal and converts it to a differential output signal that is configurable for
programmable gains of 24 dB, 18 dB, and 12 dB. The differential output signal has an input-referred noise of
0.63 nV/√Hz, 0.70 nV/√Hz, and 0.9 nV/√Hz, respectively, across the different gain modes. The LNA supports a
maximum linear differential output swing of 4 VPP across all gain settings. Therefore, depending on the LNA gain,
the maximum linear input swing support changes from 250 mVPP, 500 mVPP, and 1 VPP, for LNA gains of 24 dB,
18 dB, and 12 dB, respectively.
9.3.1.2 Input Circuit
The LNA input pin (INPx) is internally biased at approximately 2.2 V. AC couple the input signal to the INPx pin
with an adequately-sized capacitor, CIN. TI recommends using a 0.1-μF capacitor for CIN. Similarly, the active
termination pin is internally biased at 1.5 V. TI recommends connecting a 1-µF capacitor (CACT) from the active
termination pin (ACTx) to the INP capacitor, as shown in Figure 63.
AFE
CLAMP
CACT
ACTx
CIN
INPx
CBYPASS
INMx
Input
LNAx
Optional
Diodes
DC Offset
Correction
S0498-01
Figure 63. Device Input Circuit
9.3.1.3 LNA High-Pass Filter
To reject an unwanted low-frequency leakage signal from the transducer and to achieve low dc offset drift from
the device, the AFE5818 incorporates a dc offset correction circuit for each amplifier stage; see Figure 63. This
circuit extracts the low-frequency component from the LNA output, which is then fed back to the LNA
complementary input for low-frequency signal rejection. Afterwards, this feedback circuit functions as a high-pass
filter (HPF). The effective corner frequency of the HPF is determined by the CBYPASS capacitor connected at the
INMx pin of the device. The corner frequency is lower with larger CBYPASS capacitors. A large capacitor (such as
1 μF) can be used for setting the low corner frequency (< 2 kHz) of the LNA dc offset correction circuit. For
stable operation, the minimum value of the CBYPASS capacitor that is supported by device is 15 nF. To disable
this HPF, set the LNA_HPF_DIS register bit to 1. Note that disabling this HPF results in a large dc offset at the
device output. Also, for a given INMx capacitor, the corner frequency of the HPF can be programmed using the
LNA_HPF_PROG bit. Table 1 lists the HPF corner frequency for any arbitrary CBYPASS capacitor connected at the
INMx pin across various LNA_HPF_PROG bit settings.
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Feature Description (continued)
Table 1. LNA HPF Corner Frequency
LNA_HPF_PROG (Register 203, Bits 3-2)
HPF CORNER WITH 15-nF CAPACITOR
CONNECTED AT INMx PIN
HPF CORNER WITH CBYPASS CAPACITOR
CONNECTED AT INMx PIN
00
100 kHz
100 kHz × (15 nF / CBYPASS)
01
50 kHz
50 kHz × (15 nF / CBYPASS)
10
200 kHz
200 kHz × (15 nF / CBYPASS)
11
150 kHz
150 kHz × (15 nF / CBYPASS)
The LNA HPF corner frequency can be reduced by 3X by setting the RED_LNA_HPF_3X (register 205, bit 8) bit
to 1. For instance, if the INMx capacitor is 15 nF, the LNA_HPF_PROG bits are set to 01, and
RED_LNA_HPF_3X is set to 1, then the LNA HPF corner frequency is given by 50 kHz / 3 = 16.6 kHz. Figure 28
and Figure 29 illustrate the low-frequency noise for various LNA_HPF_PROG, RED_LNA_HPF_3X, and INM
capacitor combinations.
9.3.1.4 LNA Input Impedance
In ultrasound applications, signal reflection exists as a result of long cables between the transducer and system.
This reflection results in extra ringing added to echo signals in PW mode. This ringing effect can degrade the
axial resolution, which depends on the echo signal length. Therefore, either passive termination or active
termination is preferred if good axial resolution is desired. Figure 64 shows three termination configurations: no
termination, active termination, and passive termination.
Rs
LNA
(a) No Termination
Rf
Rs
LNA
(b) Active Termination
Rs
Rt
LNA
(c) Passive Termination
S0499-01
Figure 64. Termination Configurations
36
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Under the no termination configuration, the input impedance of the device is approximately 6 kΩ (8 KΩ // 20 pF)
at 1 MHz. Passive termination requires an external termination resistor (Rt), which contributes to additional
thermal noise. The LNA supports active termination with programmable values, as shown in Figure 65.
450Ω
900Ω
1800Ω
ACTx
3600Ω
4500Ω
INPx
Input
INMx
LNAx
AFE
S0500-01
Figure 65. Active Termination Implementation
The device has four pre-settings: 50 Ω, 100 Ω, 200 Ω, and 400 Ω, which are configurable through the registers.
Other termination values can be realized by setting the termination switches shown in Figure 65. The
ACT_TERM_IND_RES register (register 196, bits 4-0) is used to enable these switches. The input impedance of
the LNA under the active termination configuration approximately follows Equation 1:
ZIN =
Rf
/ /CIN / /RIN
AnLNA
1+
2
where:
•
RIN (8 kΩ) and CIN (20 pF) are the input resistance and capacitance of the LNA, respectively.
(1)
Table 75 lists the LNA RINs under different LNA gains. System designers can achieve fine tuning for different
probes. Therefore, ZIN is frequency dependent and decreases as frequency increases; see Figure 9. This rollingoff effect does not greatly affect system performance because 2 MHz to 10 MHz is the most commonly-used
frequency range in medical ultrasound applications. Active termination can be applied to both CW and TGC
modes; however, resulting from NF concerns, CW mode can use no termination mode. The flexibility of the
impedance configuration is of great benefit because each ultrasound system includes multiple transducers with
different impedances.
Figure 36, Figure 37, Figure 38, Figure 39, and Figure 40 illustrate the noise frequency (NF) under different
termination configurations. All these NF plots indicate that no termination achieves the best noise figure.
However, active termination adds less noise than passive termination. Thus, termination topology must be
carefully selected based on each scenario in an ultrasound application.
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9.3.1.5 LNA Gain Switch Response
The LNA gain is programmable through the LNA_GAIN_GBL (register 196, bits 14-13) SPI registers. The gain
switching time depends on the SPI speed as well as the LNA gain response time. During switching, glitches can
occur and sometimes appear as artifacts in images. In addition, the signal chain requires approximately 14 µs to
settle after the LNA gain change. Thus, the LNA gain switching may not be preferred when switching time or
settling time for the signal chain is limited. Note that a gain switch also changes the voltage level of clamping
diodes; therefore, the setting time of the clamp circuit must be considered.
9.3.1.6 LNA Noise Contribution
The noise specification is critical for the LNA and determines the dynamic range of the entire system. The device
LNA achieves low power, an exceptionally low-noise voltage of 0.63 nV/√Hz, and a low-current noise of
2.7 pA/√Hz.
Typical ultrasonic transducer impedance (Rs) varies from tens of ohms to several hundreds of ohms. Voltage
noise is the dominant noise in most cases; however, the LNA current noise flowing through the source
impedance (Rs) generates additional voltage noise. Total LNA noise can be computed with Equation 2.
2
2
LNA _ Noise total = VLNAnoise
+ R2s ´ ILNAnoise
(2)
The device achieves a low noise figure (NF) over a wide range of source resistances; see Figure 36, Figure 37,
Figure 38, Figure 39, and Figure 40.
9.3.1.7 LNA Overload Recovery
To avoid any image artifacts in an ultrasound system, the device must offer consistent and fast overload recovery
response. In order to achieve this response, a clamping circuit is used on the active termination path; see
Figure 63 to create a low-impedance path when an overload signal is detected by the device. The clamp circuit
limits large input signals at the LNA inputs and improves the overload recovery performance. The clamp level
can be automatically set to 350 mVPP, 600 mVPP, or 1.15 VPP, depending on the LNA gain settings when the
INPUT_CLAMP_LVL register (register 196, bits 10-9) is set to 00. Other clamp voltages (such as 1.15 VPP, 0.6
VPP, and 1.5 VPP) are also achievable by setting different combinations of the INPUT_CLAMP_LVL bits. This
clamping circuit is also designed to obtain good pulse inversion performance and reduce the affect of
asymmetrical inputs. For very large overload signals (> 6 dB of the linear input signal range), TI recommends
using back-to-back Schottky clamping diodes at the input to limit the amplitude of the input signal.
9.3.2 Voltage-Controlled Attenuator
The voltage-controlled attenuator is designed to have a linear-in-dB attenuation characteristic (that is, the
average attenuation in dB; see Figure 3) that is constant for each equal increment of the control voltage (VCNTL
= VCNTLP – VCNTLM). In the device, a differential control structure is used to reduce common-mode noise.
However, a single-ended control voltage is also supported. A simplified attenuator structure is illustrated in
Figure 66 and Figure 67 for analog and digital structures, respectively.
A1 - A7 Attenuator Stages
Attenuator
Input
RS
Attenuator
Output
Q1
VB
A1
Q2
A1
C1
V1
Q3
A1
C2
V2
Q4
A1
C3
V3
Q5
A1
C4
V4
Q6
A1
C5
V5
Q7
A1
C6
V6
C7
V7
VCNTL
Control
Input
C1 - C8 Clipping Amplifiers
Figure 66. Simplified Voltage-Controlled Attenuator (Analog Structure)
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RS
Attenuator
Input
Attenuator
Output
Q1
Q2
Q3
Q4
Q5
SW5
SW6
Q6
Q7
VB
SW1
SW2
SW3
SW4
SW7
VHIGH
Figure 67. Simplified Voltage-Controlled Attenuator (Digital Structure)
The attenuator is essentially a variable voltage divider that consists of the series input resistor (RS) and seven
shunt field-effect transistors (FETs) placed in parallel and controlled by sequentially activated clipping amplifiers
(A1 through A7). VCNTL is the effective difference between VCNTLP and VCNTLM. Each clipping amplifier can
be understood as a specialized voltage comparator with a soft transfer characteristic and well-controlled output
limit voltage. Reference voltages V1 through V7 are equally spaced over the 0-V to 1.5-V control voltage range.
As control voltage increases through the input range of each clipping amplifier, the amplifier output rises from a
voltage where the FET is nearly off to VHIGH where the FET is completely on. As each FET approaches its onstate and the control voltage continues to rise, the next clipping amplifier and FET combination takes over for the
next portion of the piecewise linear attenuation characteristic. Thus, low control voltages have most of the FETs
turned off, producing minimum signal attenuation. Similarly, high control voltages turn the FETs on, leading to a
maximum signal attenuation. Therefore, each FET functions to decrease the shunt resistance of the voltage
divider formed by RS and the parallel FET network. Even though splitting the control voltage into seven segments
achieves the full attenuation through different setoff transistors, the gain curve across the VCNTL voltage slightly
deviates from the ideal dB-linear curve. The typical ripple is in the order of ±0.5 dB.
The typical gain range for this VCAT is approximately 40 dB, and this gain range is independent of the LNA and
PGA gain settings. The TGC gain curve is inversely proportional to the voltage difference between VCNTLP and
VCNTLM. The maximum attenuation (minimum channel gain) of the TGC gain curve appears at VCNTLP –
VCNTLM = 1.5 V, and minimum attenuation (maximum channel gain) of the TGC gain curve occurs at
VCNTLP – VCNTLM = 0 V.
The total channel gain for an 18-dB LNA gain and a 24-dB PGA gain setting, for different VCNTL values, is
illustrated in Figure 2.
When the device operates in CW mode, the attenuator stage remains connected to the LNA outputs. Therefore,
powering down the VCA is recommended using the PDWN_VCA_PGA (register 197, bit 12) register bit. In this
case, the VCNTLP and VCNTLM voltage does not matter.
9.3.2.1 Digital TGC
Additionally, a digitally-controlled TGC mode is implemented to achieve better phase-noise performance in the
device. The attenuator can be controlled digitally instead of by the analog control voltage, VCNTL. This mode
can be set by the EN_DIG_TGC (register 203, bit 7) register bit. The variable voltage divider is implemented as a
fixed series resistance and a FET is implemented as the shunt resistance. Each FET can be turned on by
connecting the SW[7:1] switches. Turning on each of these switches provides approximately 6 dB of attenuation.
This attenuation can be controlled by the DIG_TGC_ATTENUATION (register 203, bits 6-4) register bits. This
digital control feature can eliminate the noise from the VCNTL circuit and provide better SNR and phase noise for
the TGC path. This digital TGC can be used for PW Doppler or color Doppler modes to achieve better
performance than analog TGC.
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9.3.2.2 Control Voltage Input
As previously mentioned, VCNTLP and VCNTLM can be driven by either a differential or a single-ended signal.
For single-ended operation, VCNTLM can be grounded and VCNTLP can be swept from 0 V to 1.5 V. The TGC
gain profile for the single-ended VCNTL is as shown in Figure 68a. For differentially driving VCNTL, VCNTLP
must always be kept higher than VCNTLM with a typical common-mode of 0.75 V, as shown in Figure 68b.
1.5 V
VCNTLP
VCNTLM = 0 V
X + 40 dB
TGC Gain
X dB
(a) Single-Ended Input at VCNTLP
1.5 V
VCNTLP
0.75 V
VCNTLM
0V
X + 40 dB
TGC Gain
X dB
(b) Differential Inputs at VCNTLP and VCNTLM
Figure 68. VCNTLP and VCNTLM Configurations
The VCNTL pins are high-impedance pins, and the VCNTL pins of multiple devices can be connected in parallel
with no significant loading effect. When the voltage level (VCNTLP, VCNTLM) is above 1.5 V or below 0 V, the
attenuator continues to operate at its maximum attenuation level or minimum attenuation level, respectively.
Limiting the voltage from –0.3 V to 2 V is recommended.
The VCNTL inputs have an approximate bandwidth of 800 kHz. This wide bandwidth, although useful in many
applications (such as fast VCNTL response), can also allow high-frequency noise to modulate the gain control
input and finally affect the Doppler performance. In practice, this modulation can be avoided by additional
external filtering (RVCNTL and CVCNTL) at the VCNTLM and VCNTLP, pins as Figure 104 illustrates. However, the
external filter cutoff frequency cannot be kept too low, which results in a low gain response time. Without an
external filter on the VCNTLP, VCNTLM pins, the gain control response time typically requires less than 1 μs, as
indicated in Figure 54.
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Noise at the VCNTL pins must be low enough to obtain good system performance because this noise is
correlated across channels. Figure 69 shows the allowed noise on the VCNTL pins for different channel systems.
10
16 Channels
32 Channels
64 Channels
128 Channels
192 Channels
9
Noise (nV/—Hz)
8
7
6
5
4
3
2
1
0
1
2 3 4 5 7 10
20 30 50 100 200
Frequency (kHz)
500 1000
5000
D063
Figure 69. Allowed Noise on the VCNTL Signal Across Frequency and Different Channels
Typical VCNTLM and VCNTLP signals are generated by an 8-bit to 12-bit, 10-MSPS, digital-to-analog converter
(DAC) and a differential operation amplifier. TI’s DACs, such as the TLV5626, DAC7821. Differential amplifiers
with output common-mode voltage control (that is, the THS4130 and OPA1632) can connect the DAC to the
VCNTLM and VCNTLP pins. The buffer amplifier can also be configured as an active filter to suppress low
frequency noise. The VCNTLM and VCNTLP circuit achieve low noise in order to prevent the VCNTLM and
VCNTLP noise from being modulated to RF signals. VCNTLM and VCNTLP noise is recommended to be below
25 nV/√Hz at 1 kHz and 5 nV/√Hz at 50 kHz. For more information, see the THS413x data sheet and application
report Design for a Wideband Differential Transimpedance DAC Output (SBAA150).
9.3.2.3 Voltage Attenuator Noise
The voltage-controlled attenuator noise follows a monotonic relationship to the attenuation coefficient. At higher
attenuation the input-referred noise is higher, and vice-versa. The attenuator noise is then amplified by the PGA
and becomes the noise floor at the ADC input. In the high attenuation operating range of the attenuator (that is,
when VCNTL is high), the attenuator input noise can exceed the LNA output noise. The attenuator then becomes
the dominant noise source for the following PGA stage and ADC. Therefore, minimize the attenuator noise
compared to the LNA output noise. The device attenuator is designed for achieving very low noise even at high
attenuation (low channel gain) and realizing better SNR of near-field imaging in ultrasound systems. The inputreferred noise for different attenuations are listed in Table 2.
Table 2. Voltage-Controlled Attenuator Noise vs Attenuation
ATTENUATION (dB)
ATTENUATOR INPUT-REFERRED NOISE
(nV/√Hz)
–40
10.5
–36
10
–30
9
–24
8.5
–18
6
–12
4
–6
3
0
2
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9.3.3 Programmable Gain Amplifier (PGA)
After the voltage-controlled attenuator, a programmable gain amplifier can be configured as 24 dB or 30 dB with
a constant input-referred noise of 1.75 nV/√Hz. The PGA structure consists of a differential voltage-to-current
(V2I) converter with programmable gain, clamping circuits, a transimpedance amplifier (I2V) with a
programmable third-order low-pass filter, and a dc offset correction circuit. The simplified PGA block diagram is
shown in Figure 70.
Voltage Clamp
Current Clamp
To ADC
From Attenuator
I2V
LPF
V2I
Voltage Clamp
Current Clamp
DC Offset
Correction Loop
Figure 70. Simplified Block Diagram of the PGA
9.3.3.1 PGA Clamp
The PGA consists of two clamp circuits, positioned as shown in Figure 70. These clamps limit the amplitude of
the overloaded signal and therefore provide better overload recovery performance.
An input-to-voltage (I2V) block in the PGA supports a maximum output swing of 2 VPP, which means that the
maximum allowed signal amplitude supported at the voltage-to-input (V2I) block input is 125 mVPP (for a PGA
gain = 24 dB) or 62.5 mVPP (for a PGA gain = 30 dB). If the input signal amplitude of the V2I bock is much higher
than the allowable range, then the V2I input can be clamped using a voltage clamp as shown in Figure 70. This
voltage clamp is disabled by default and can be enabled by using the V2I_CLAMP (register 205, bit 13) register
bit.
A current clamp is at the output of the V2I block, as shown in Figure 70, to further limit the overload signal
amplitude. This current clamp can be programmed through the PGA_CLAMP_DIS (register 195, bit 7) and
PGA_CLAMP_LVL (register 195, bit 6) register bits. Note that in low-power and medium-power modes, the
current clamp is disabled for power savings if PGA_CLAMP_DIS (register 195, bit 7) = 0. This current clamp
helps obtain a better overload recovery response. Without enabling this current clamp, at a 0.5-V VCNTL, the
device shows a standard deviation of 4 LSBs at the output signal immediately after the overload. However, with
the current clamp enabled, the standard deviation approaches 3.2 LSBs, meaning that the device requires less
time to reach stable output. Also note that when the PGA output levels are greater than –2 dBFS and the current
clamp is enabled, there is a degradation of approximately 3 dB to 5 dB in HD3 performance.
If the V2I block input is massively overloaded, the output of the I2V block can become saturated even if the
voltage and current clamp described previously is enabled. When the I2V block becomes saturated, higher-order
harmonics are generated that are aliased back to signal bandwidth after sampling. To avoid this undesirable V2I
output saturation, a current clamp can be programmed to –6 dBFs, using the PGA_CLAMP_HALF bit (register
205, bit 15).
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9.3.3.2 Low-Pass Filter (LPF)
The current from the V2I is fed to a programmable transimpedance amplifier, which also functions as a low-pass
filter (LPF). The LPF is designed as a differential, active, third-order filter with Butterworth characteristics and a
typical 18-dB per octave roll-off. Programmable through the serial interface, the –1-dB frequency corner can be
set to 10 MHz, 15 MHz, 20 MHz, 30 MHz, 35 MHz, or 50 MHz. The filter bandwidth is set for all channels
simultaneously. When very low bandwidth is desired (usually when suppressing higher order harmonics to a very
low value), a 5-MHz filtering mode can be enabled using the SUPRESS_HIGHER_HARMONICS (register 205,
bit 14) bit. However, enabling this mode can cause higher gain variation across devices when compared to other
filter corner modes.
9.3.3.3 High-Pass Filter (HPF)
A selectable dc offset correction circuit is implemented in the PGA as well. This correction circuit is similar to the
one used in the LNA. This circuit extracts the dc component of the PGA outputs, which are fed back to the PGA
complimentary inputs for dc offset correction. This dc offset correction circuit also has a high-pass response with
a cutoff frequency of 80 kHz. This HPF is enabled by default and can be disabled by using the PGA_HPF_DIS
(register 195, bit 4) bit.
9.3.3.4 Noise
Low input noise is always preferred in a PGA and its noise contribution must not degrade the ADC SNR too
much after the attenuator. The PGA is designed as a 24-dB or 30-dB gain with a constant input-referred noise of
1.75 nV/√Hz. The LNA noise dominates at minimum attenuation (used for small input signals), and the PGA and
ADC noise dominate at maximum attenuation (large input signals). Thus, a 24-dB PGA gain achieves better SNR
as long as the amplified signals can exceed the noise floor of the ADC.
9.3.4 Analog-to-Digital Converter (ADC)
The device supports a high-performance, 14-bit ADC that achieves 72-dBFS SNR. This ADC ensures excellent
SNR at low-chain gain. The ADC can operate at maximum speeds of 65 MSPS and 80 MSPS, providing a 14-bit
and a 12-bit output, respectively. The low-voltage differential signaling (LVDS) outputs of the ADC enable a
flexible system integration that is desirable for miniaturized systems. In the following sections, full description of
all inputs and outputs of the ADC with different configurations are provided along with suitable examples.
9.3.4.1 System Clock Input
The 16 channels on the device operate from a single clock input. To ensure that the aperture delay and jitter are
the same for all channels, the device uses a clock tree network to generate individual sampling clocks for each
channel. The clock lines for all channels are matched from the source point to the sampling circuit for each of the
16 internal ADCs. The delay variation is described by the aperture delay parameter of the Output Interface
Timing Characteristics table. Variation over time is described by the aperture jitter parameter of the Output
Interface Timing Characteristics table.
This system clock input can be driven differentially (sine wave, LVPECL, or LVDS) or single-ended (LVCMOS).
The device clock input has an internal buffer and clock amplifier (see Figure 71) which is enabled or disabled
automatically, depending on the type of clock provided (auto-detect feature).
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AVDD_1P8
0.7 V
VCM
100 pF
5 kQ
5 kQ
CLKP
6 pF
6 pF
CLKM
Figure 71. Internal Clock Buffer for Differential Clock Mode
If the preferred clocking scheme for the device is single-ended, connect the CLKM pin to ground (in other words,
short CLKM directly to AVSS, as shown in Figure 72). In this case, the auto-detect feature shuts down the
internal clock buffer and the device automatically goes into a single-ended clock input. Connect the single-ended
clock source directly (without decoupling) to the CLKP pin, which is the only device clock input available because
CLKM is connected to ground. Therefore, TI recommends using low-jitter, square signals (LVCMOS levels, 1.8-V
amplitude) to drive the ADC (see technical brief, Clocking High-Speed Data Converters, SLYT075 for further
details).
CMOS Clock Input
CLKP
CLKM
Figure 72. Single-Ended Clock Driving Circuit
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For single-ended sinusoidal clocks, or for differential clocks (such as differential sine wave, LVPECL, LVDS, and
so forth), enable the clock amplifier with the connection scheme shown in Figure 73. The 10-nF capacitor used to
couple the clock input is as shown in Figure 73. This same scheme applies when the clock is single-ended but
the clock amplitude is either small or its edges are not sharp (for instance, with a sinusoidal single-ended clock).
In this case, the input clock signal can be connected with a capacitor to CLKP (as in Figure 73) and connect
CLKM to ground through a capacitor (that is, ac-coupled to AVSS).
If a transformer is used with the secondary coil floating (for instance, to convert from single-ended to differential),
the transformer can be connected directly to the clock inputs without requiring the 10-nF series capacitors.
10 nF
CLKP
Differential Sine Wave
or PECL or LVDS Clock Signal
CLKM
10 nF
Figure 73. Differential Clock Driving Circuit
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9.3.4.2 System Clock Configuration for Multiple Devices
To ensure that the aperture delay and jitter are the same for all channels, the device uses a clock tree network to
generate individual sampling clocks for each channel. For all channels, the clock is matched from the source
point to the sampling circuit of each of the eight internal devices. The variation on this delay is described in the
Aperture Delay parameter of the Output Interface Timing Characteristics table. Variation is described by the
aperture jitter parameter of the Output Interface Timing Characteristics table.
The system clock input can be driven by differential clocks (sine wave, LVPECL, or LVDS) or single-ended
clocks (LVCMOS). In the single-ended case, TI recommends the use of low-jitter square signals (LVCMOS
levels, 1.8-V amplitude). See technical brief, Clocking High-Speed Data Converters, SLYT075 for further details
on the theory.
The jitter cleaners CDCM7005, CDCE72010, or LMK048X series are suitable to generate the system clock and
ensure high performance for the 14-bit device resolution. Figure 74 shows a clock distribution network.
FPGA Clock,
Noisy Clock
n × (5 MHz to 100 MHz)
TI Jitter Cleaner
LMK048X
CDCE72010
CDCM7005
5-MHz to 100-MHz
ADC CLK
CDCLVP1208
LMK0030X
LMK01000
The CDCE72010 has 10
outputs
DUT
DUT
DUT
DUT
DUT
DUT
DUT
DUT
8 Synchronized
DUT System CLKs
Figure 74. System Clock Distribution Network
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9.3.4.3 LVDS Interface
The device supports an LVDS output interface in order to transfer device digital data serially to an FPGA. The
device has a total of 18 LVDS output lines. One of these pairs is a serial data clock, another pair is a data
framing clock, and the remaining 16 pairs are dedicated for data transfer. A graphical representation of the LVDS
output is shown in Figure 75.
LVDS Buffer
DOUTP1
DOUTM1
DOUTP2
DOUTM2
Digital Output
DOUTP16
DOUTM16
DCLKP
DCLKM
Serial Clock
FCLKP
FCLKM
Frame Clock
Figure 75. LVDS Output
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9.3.4.3.1 LVDS Buffer
The equivalent circuit of each LVDS output buffer is shown in Figure 76. The buffer is designed for an output
impedance of 100 Ω (ROUT). The differential outputs can be terminated at the receiver end by a 100-Ω
termination. The buffer output impedance functions like a source-side series termination. By absorbing reflections
from the receiver end, the buffer output impedance helps improve signal integrity. Note that this internal
termination can neither be disabled nor its value changed.
Low
+0.4 V
High
Device
OUTP
0.4 V
High
1.03 V
Low
External
100- Load
ROUT
OUTM
Switch impedance is
nominally 50 (r10%).
Figure 76. LVDS Output Circuit
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9.3.4.3.2 LVDS Data Rate Modes
The LVDS interface supports two data rate modes, as described in this section. Figure 77 shows the
Nomenclatures used in LVDS timing diagrams
DCLKP
Bit Clock
DCLKM
t
t su
h
t
t su
h
CH1 out
DN + 1
Dn
Output Data Pair
Figure 77. LVDS Timing Nomenclature
9.3.4.3.2.1 1X Data Rate Mode
In 1X data rate mode, each LVDS output carries data from a single ADC. Figure 78 and Figure 79 show the
output data, serial clock, and frame clock LVDS lines for the 14-bit and 12-bit 1X mode, respectively.
Input Signal
Sample N
Sample
N+Cd+1
Sample
N+Cd
TA
TA
Cd Clock
Cycles Latency
Input Clock (CLKIN)
Frequency = fCLKIN
T
tPDI
Frame Clock (FCLK)
Frequency = fCLKIN
Bit Clock (DCLK)
Frequency = 7 x fCLKIN
Output Data (CHn OUT)
Data Rate = 14 x fCLKIN
1
(12)
0
(13)
13
(0)
12
(1)
11
(2)
10
(3)
9
(4)
8
(5)
7
(6)
6
(7)
5
(8)
4
(9)
3
(10)
2
(11)
1
(12)
0
(13)
13
(0)
12
(1)
11
(2)
10
(3)
9
(4)
Sample N-Cd
8
(5)
7
(6)
6
(7)
5
(8)
4
(9)
3
(10)
2
(11)
1
(12)
0
(13)
13
(0)
12
(1)
11
(2)
10
(3)
9
(4)
8
(5)
Sample N-1
7
(6)
6
(7)
5
(8)
4
(9)
3
(10)
2
(11)
1
(12)
0
(13)
13
(0)
1
(1
Sample N
Data Bit in MSB-First Mode
13
(0)
Data Bit in LSB-First Mode
(1) K = ADC resolution.
Figure 78. 14-Bit, 1X Data Rate Output Timing Specification
Sample N
Input Signal
TA
Sample
N+Cd+1
Cd Clock Cycles Latency
Input Clock (CLKIN)
Frequency = fCLKIN
tPDI
T
Frame Clock (FCLK)
Frequency = fCLKIN
Bit Clock (DCLK)
Frequency = 6 x fCLKIN
Output Data (CHn OUT)
Data Rate = 12 x fCLKIN
1
(10)
0
(11)
11
(0)
10
(1)
9
(2)
8
(3)
7
(4)
6
(5)
5
(6)
4
(7)
Sample N-Cd
1
(10)
3
(8)
2
(9)
1
(10)
0
(11)
11
(0)
10
(1)
9
(2)
8
(3)
7
(4)
6
(5)
5
(6)
4
(7)
3
(8)
2
(9)
1
(10)
0
(11)
11
(0)
10
(1)
9
(2)
8
(3)
7
(4)
Sample N-1
6
(5)
5
(6)
4
(7)
3
(8)
2
(9)
1
(10)
0
(11)
Sample N
11
(0)
10
(1)
Sample N+1
Data Bit in MSB-First Mode
Data Bit in LSB-First Mode
Figure 79. 12-Bit, 1X Data Rate Output Timing Specification
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9.3.4.3.2.2 2X Data Rate Mode
In 2X data rate mode, only half of the LVDS lines are used to transfer data. Thus, this mode is useful for saving
power when lower sampling frequency ranges permit. This mode is enabled with the LVDS_RATE_2X register bit
(register 1, bit 14). After enabling this mode, the digital data from two ADCs are transmitted with a single LVDS
lane. When compared to the 1X data rate mode, the 2X data rate mode serial clock frequency is doubled, but the
frame clock frequency remains the same (for the same serialization factor and ADC resolution).
When the frame clock is high, data on DOUT1 corresponds to channel 1, DOUT2 corresponds to channel 3, and
so forth. When the frame clock is low, DOUT1 transmits channel 2 data, DOUT2 transmits channel 4 data, and
so forth.
Figure 80 and Figure 81 show a timing diagram for the 14-bit and 12-bit 2X mode, respectively. Channel and
LVDS data line mapping for this mode are listed in Table 3. Note that idle LVDS lines are not powered down by
default. To save power, these lines can be powered down using the corresponding power-down bits
(PDN_LVDSx).
Sample
N+Cd
Input Signal
Sample
N+Cd+1
TA
tPDI
Input Clock (CLKIN)
Frequency = fCLKIN
T
Frame Clock (FCLK)
Frequency = fCLKIN
Bit Clock (DCLK)
Frequency = 14 x fCLKIN
utput Data (CHn OUT)
Data Rate = 28 x fCLKIN
4
(8)
3
(9)
2
(10)
1
(12)
0
(13)
13
(0)
12
(1)
11
(2)
10
(3)
9
(4)
8
(5)
7
(6)
6
(7)
5
(8)
4
(9)
3
(10)
2
(11)
1
(12)
0
(13)
13
(0)
12
(1)
11
(2)
10
(3)
9
(4)
8
(5)
7
(6)
6
(7)
5
(8)
4
(9)
3
(10)
2
(11)
1
(12)
0
(13)
13
(0)
12
(1)
11
(2)
10
(3)
8
(5)
7
(6)
6
(7)
5
(8)
4
(9)
3
(10)
2
(11)
(1
ADC first channel, Sample N+1
ADC second channel, Sample N
ADC first channel, Sample N
9
(4)
Data Bit in MSB-First Mode
13
(0)
Data Bit in LSB-First Mode
Figure 80. 14-Bit, 2X Data Rate Output Timing Specification
Sample
N+Cd
Input Signal
Sample
N+Cd+1
TA
tPDI
Input Clock (CLKIN)
Frequency = fCLKIN
T
Frame Clock (FCLK)
Frequency = fCLKIN
Bit Clock (DCLK)
Frequency = 12 x fCLKIN
Output Data (CHn OUT)
Data Rate = 24 x fCLKIN
4
(7)
3
(8)
2
(9)
1
(10)
0
(11)
11
(0)
10
(1)
9
(2)
8
(3)
7
(4)
6
(5)
5
(6)
4
(7)
3
(8)
ADC first channel, Sample N
1
(10)
2
(9)
1
(10)
0
(11)
11
(0)
10
(1)
9
(2)
8
(3)
7
(4)
6
(5)
5
(6)
4
(7)
3
(8)
ADC second channel, Sample N
2
(9)
1
(10)
0
(11)
11
(0)
10
(1)
9
(2)
8
(3)
7
(4)
7
(4)
6
(5)
5
(6)
4
(7)
3
(8)
2
(9)
1
(10)
0
(11)
11
(0)
10
(1)
ADC first channel, Sample N+1
Data Bit in MSB-First Mode
Data Bit in LSB-First Mode
Figure 81. 12-Bit, 2X Data Rate Output Timing Specification
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Table 3. Channel and ADC Data Line Mapping (2X Rate)
CHANNELS
MAPPING
DOUT1
ADC data for channels 1 and 2
DOUT2
ADC data for channels 3 and 4
DOUT3
ADC data for channels 5 and 6
DOUT4
ADC data for channels 7 and 8
DOUT5
Idle
DOUT6
Idle
DOUT7
Idle
DOUT8
Idle
DOUT9
ADC data for channels 9 and 10
DOUT10
ADC data for channels 11 and 12
DOUT11
ADC data for channels 13 and 14
DOUT12
ADC data for channels 15 and 16
DOUT13
Idle
DOUT14
Idle
DOUT15
Idle
DOUT16
Idle
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9.3.4.4 ADC Register, Digital Processing Description
The ADC has extensive digital processing functionalities that can be used to enhance ADC output performance.
The digital processing blocks are arranged as shown in Figure 82.
ADC 2
Output
Digital Test Patterns
12b, 14b
Final
Digital
Output
MUX
ADC1
Output
Digital Average
Default = No
Digital Gain
Default = 0
Digital HPF
Default = No
12b, 14b
Digital Offset
Default = No
Figure 82. ADC Digital Block Diagram
9.3.4.4.1 Digital Offset
Digital functionality provides for channel offset correction. Setting the DIG_OFFSET_EN bit to 1 enables the
subtraction of the offset value from the ADC output. There are two offset correction modes, as shown in
Figure 83.
DIG_OFFSET_EN
0
Analog
Inputs
ADCx
Bits 13-0
(0s appended as LSBs when in 12-bit resolutions.)
OFFSET_REMOVAL_START_SEL
(Register 4, Bit 14)
OFFSET_REMOVAL_
START_MANUAL
(Register 4, Bit 13)
TX_TRIG Pin
0
Start
MUX
+
AUTO_OFFSET_REMOVAL_
ACC_CYCLES
(Register 4, Bits 12-9)
Accumulator
Bits
29-0
MUX
1
Bits 9-0
OFFSET_CHx
-
Data Output,
Bits 13-0
1
OFFSET_REMOVAL_SELF
(Register 4, Bit 15)
Truncation and
Rounding Data
Bits
Extending Sign
Bit to 14 Bits
Bits 13-0
1
MUX
0
Bits 13-0
Figure 83. Digital Offset Correction Block Diagram
9.3.4.4.1.1 Manual Offset Correction
If the channel offset is known, the appropriate value can be written in the OFFSET_CHx register (bits 13-0, offset
for channel x). The offset value programmed in the OFFSET_CHx register (bits 13-0) subtracts out from the ADC
output. The offset of each of the 16 ADC output channels can be independently programmed. The same offset
value must be programmed into two adjacent offset registers. For instance, when programming the channel 1
offset value 0000011101, write the same offset value of 0000011101 in registers 13 (bits 9-0) and 14 (bits 9-0).
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9.3.4.4.1.2 Auto Offset Correction Mode (Offset Correction using a Built-In Offset Calculation Function)
The auto offset calculation module can be used to calculate the channel offset that is then subtracted from the
ADC output. To enable the auto offset correction mode, set the OFFSET_REMOVAL_SELF bit to 1.
In auto offset correction mode the dc component of the ADC output (assumed to be the channel offset) is
estimated using a digital accumulator. The ADC output sample set used by the accumulator is determined by a
start time or first sample and number of samples to be used. Figure 83 illustrates the options available to
determine the accumulator sample set. A high pulse on the TX_TRIG pin or setting the
OFFSET_REMOVAL_START_MANUAL register can be used to determine the accumulator first sample. To set
the number of samples, the AUTO_OFFSET_REMOVAL_ACC_CYCLES register (bits 12-9) must be
programmed according to Table 4.
If a pulse on the TX_TRIG pin is used to set the first sample, additional flexibility in setting the first sample is
provided. A programmable delay between the TX_TRIG pulse and first sample can be set by writing to the
OFFSET_CORR_DELAY_FROM_TX_TRIG register.
The determined offset value can be read out channel wise. Set the channel number in the
AUTO_OFFSET_REMOVAL_VAL_RD_CH_SEL register and read the offset value for the corresponding channel
in the AUTO_OFFSET_REMOVAL_VAL_RD register.
Table 4. Auto Offset Removal Accumulator Cycles
AUTO_OFFSET_REMOVAL_ACC_CYCLES (Bits 3-0)
NUMBER OF SAMPLES USED FOR OFFSET VALUE
EVALUATION
0
2047
1
127
2
255
3
511
4
1023
5
2045
6
4095
7
8191
8
16383
9
32767
10 to 15
65535
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9.3.4.4.2 Digital Average
The signal-to-noise ratio (SNR) of the signal chain can be further improved by averaging two channels with the
AVG_EN register bit (register 2, bit 11). The way data are transmitted on the digital output lines in this mode is
described in Table 5.
Table 5. Channel and ADC Data Line Mapping (Averaging Enabled)
CHANNELS
MAPPING
DOUT1
Average of channels 1 and 2
DOUT2
Average of channels 3 and 4
DOUT3
Average of channels 5 and 6
DOUT4
Average of channels 7 and 8
DOUT5
Idle
DOUT6
Idle
DOUT7
Idle
DOUT8
Idle
DOUT9
Average of channels 9 and 10
DOUT10
Average of channels 11 and 12
DOUT11
Average of channels 13 and 14
DOUT12
Average of channels 15 and 16
DOUT13
Idle
DOUT14
Idle
DOUT15
Idle
DOUT16
Idle
NOTE
Idle LVDS lines are not powered down by default. To save power, these lines can be
powered down using corresponding power-down bits (PDN_LVDSx).
The serialization factor must be greater than the ADC resolution to obtain SNR
improvement after averaging in 12b resolution.
9.3.4.4.3 Digital Gain
To enable the digital gain block, set DIG_GAIN_EN (register 3, bit 12) to 1. When enabled, the gain value for
channel x (where x is from 1 to 16) can be set with the register bits for the corresponding channel (GAIN_CHx,
bits 15-11). Gain is given as [0 dB + 0.2 dB × GAIN CHx (bits 15-11)]. For instance, if GAIN_CH5 (bits 15-11) =
3, then channel 5 is increased by 0.6-dB gain. GAIN_CHx (bits 15-11) = 31 produces the same effect as
GAIN_CHx (bits 15-11) = 30, which sets the gain of channel x to 6 dB.
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9.3.4.4.4 Digital HPF
To enable the digital high-pass filter (HPF) of channel 1 to 8 and 9 to 16, set the DIG_HPF_EN_CH1-8 (register
21, bit 0) and DIG_HPF_EN_CH9-16 (register 45, bit 0) register bits to 1, respectively.
The HPF_CORNER_CHxy register bits (where xy are 1-4, 5-8, 9-12, or 13-16) control the characteristics of a
digital high-pass transfer function applied to the output data, based on Equation 3. These bits correspond to bits
4-1 in registers 21, 33, 45, and 57, respectively (these register settings describe the value of K). The valid values
of K are 2 to 10. The digital HPF can be used to suppress low-frequency noise. Table 6 shows the cutoff
frequency versus K.
2k
Y(n) =
[x(n) - x(n - 1) + y(n - 1)]
2k + 1
(3)
Table 6. Digital HPF, –1-dB Corner Frequency versus K and fS
CORNER FREQUENCY (kHz)
CORNER FREQUENCY (k)
(HPF_CORNER_CHxy Register)
fS = 40 MSPS
fS = 50 MSPS
fS = 65 MSPS
2
2780
3480
4520
3
1490
1860
2420
4
738
230
1200
5
369
461
600
6
185
230
300
7
111
138
180
8
49
61
80
9
25
30
40
10
12.
15
20
HPF output is mapped to ADC resolution bits either by truncation or a round-off operation. By default, the HPF
output is truncated to map to the ADC resolution. To enable the rounding operation to map the HPF output to the
ADC resolution, set the HPF_ROUND_ENABLE register bit (register 21, bit 5) to 1.
9.3.5 LVDS Synchronization Operation
Different test patterns can be synchronized on the LVDS serialized output lines to help set and program the
FPGA timing that receives the LVDS serial output. Of these test patterns, the ramp, toggle, and pseudo-random
sequence (PRBS) test patterns can be reset or synchronized by providing a synchronization pulse on the
TX_TRIG pin or by setting and resetting a specific register bit. The synchronization pulse on the TX_TRIG pin
must meet the setup and hold time constraints with respect to the system clock, as shown in Figure 84.
t_setup = 3.6 ns
t_hold = 1 ns
System
Clock
TX_TRIG
Figure 84. Setup and Hold Time Constraint for the TX_TRIG Signal
The PRBS_SYNC register bit (register 4, bit 7) can be used to synchronize the PRBS sequence. SCLK must be
synchronous with the system clock and must meet the setup and hold time constraints with respect to the system
clock, as shown in Figure 85.
t_setup = 2.5 ns
t_hold = 5 ns
System
Clock
SCLK
Figure 85. Setup and Hold Time Constraints on SCLK for Using Software, SOFTWARE_RESET, and
RESET Functions
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9.3.6 Continuous-Wave (CW) Beamformer
The continuous-wave Doppler is a key function in mid-end to high-end ultrasound systems. Compared to the
TGC mode, the CW path must handle high dynamic range along with strict phase noise performance. CW
beamforming is often implemented in the analog domain because of the strict requirements. Multiple
beamforming methods are implemented in ultrasound systems, including a passive delay line, active mixer, and
passive mixer. Among these approaches, the passive mixer achieves optimized power and noise. This mixer
satisfies the CW processing requirements (such as wide dynamic range, low phase noise, and accurate gain and
phase matching).
A simplified CW path block diagram and an in-phase or quadrature (I/Q) channel block diagram are illustrated in
Figure 86 and Figure 87, respectively. Each CW channel includes an LNA, a voltage-to-current converter, a
switch-based mixer, a shared summing amplifier with a low-pass filter, and clocking circuits.
NOTE
The local oscillator inputs of the passive mixer are cos (ωt) for the I channel and sin (ωt)
for the Q channel, respectively. Depending on the application-specific CW Doppler
complex FFT processing, swapping the I and Q channels in either the field-programmable
gate array (FPGA) or digital signal processor (DSP) can be required in order to obtain
correct blood flow direction.
All blocks include well-matched, in-phase, quadrature channels to achieve good image frequency rejection as
well as beamforming accuracy. As a result, the image rejection ratio from an I/Q channel is better than –46 dBc,
which is desired in ultrasound systems.
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I-CLK
LNA1
I-Channel
Voltage-to-Current
Converter
Q-Channel
Q-CLK
Sum Amp
with LPF
1 × fcw CLK
I-Channel
Clock Distribution
Circuits
Q-Channel
N × fcw CLK
Sum Amp
with LPF
I-CLK
LNA16
Voltage-to-Current
Converter
I-Channel
Q-Channel
Q-CLK
Figure 86. Simplified Block Diagram of the CW Path
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ACT1
Mixer Clock 1
500
IN1
LNA1
Input 1
INM1
Cext
500
ACT2
Mixer Clock 2
Rint, Rext
500
CW_OUTP
IN2
LNA2
Input 2
CW_AMPINM
10 Ÿ
10 Ÿ
INM2
CW_AMPINP
I2V Sum
Amp
CW_OUTM
500
Rint, Rext
Cext
ACT16
Mixer Clock 16
500
CW I- or Q- Channel Structure
IN16
LNA16
Input 16
INM16
500
NOTE: The 10-Ω to 15-Ω resistors at CW_AMPINM and CW_AMPINP result from the internal device routing and can
create slight attenuation.
Figure 87. A Complete In-Phase or Quadrature-Phase Channel
The CW mixer in the device is passive and switch based; the passive mixer adds less noise than active mixers.
The CW mixer achieves good performance at low power. Figure 88 and the calculations of Equation 4 describe
the principles of the mixer operation. The LO(t) is square-wave based and includes odd harmonic components.
Vi(t)
Vo(t)
LO(t)
Figure 88. Mixer Operation Block Diagram
where:
•
58
Vi(t), Vo(t), and LO(t) are the input, output, and local oscillator (LO) signals for a mixer, respectively.
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From Equation 4, the third- and fifth-order harmonics from the LO can interface with the third- and fifth-order
harmonic signals in the Vi(t) or the noise around the third- and fifth-order harmonics in the Vi(t). Therefore. the
mixer performance is degraded. In order to eliminate this side effect resulting from the square-wave
demodulation, a proprietary harmonic suppression circuit is implemented in the device. The third- and fifth-order
harmonic components from the LO can be suppressed by over 12 dB. Thus, the LNA output noise around the
third- and fifth-order harmonic bands are not down-converted to base band. Hence, a better noise figure is
achieved. The conversion loss of the mixer is approximately –4 dB, which is derived from 20log10 2 / π.
The mixed current outputs of the 16 channels are summed together internally. An internal low-noise operational
amplifier is used to convert the summed current to a voltage output. The internal summing amplifier is designed
to accomplish low power consumption, low noise, and ease of use. CW outputs from multiple devices can be
further combined on the system board to implement a CW beamformer with more than 16 channels.
Multiple clock options are supported in the device CW path. Two CW clock inputs are required: an N × ƒcw clock
and a 1 × ƒcw clock, where ƒcw is the CW transmitting frequency and N can be 16, 8, 4, or 1. The most
convenient system clock solution can be selected for the device. In the 16 × ƒcw and 8 × ƒcw modes, the thirdand fifth-order harmonic suppression feature can be supported. Thus, the 16 × ƒcw and 8 × ƒcw modes achieve
better performance than the 4 × ƒcw and 1 × ƒcw modes.
9.3.6.1 16 × ƒcw Mode
The 16 × ƒcw mode achieves the best phase accuracy compared to other modes. This mode is the default mode
for CW operation. In this mode, 16 × ƒcw and 1 × ƒcw clocks are required. 16 × fcw generates LO signals with 16
accurate phases. Multiple devices can be synchronized by the 1 × ƒcw (that is, LO signals in multiple AFEs can
have the same starting phase). The phase noise spec is critical only for 16X clock. 1X clock is for
synchronization only and doesn’t require low phase noise. Please see the phase noise requirement in the section
of application information.
The top-level clock distribution diagram is shown in Figure 89. Each mixer clock is distributed through a 16 × 16
cross-point switch. The inputs of the cross-point switch are 16 different phases of the 1X clock. TI recommends
aligning the 1 × ƒcw and 16 × ƒcw clocks; see Figure 90.
fIN 16X Clock
INV
D Q
fIN 1X Clock
Fin 1X Clock
16-Phase Generator
1X Clock
Phase 0º
1X Clock
Phase 22.5º
SPI
1X Clock
Phase 292.5º
1X Clock
Phase 315º
1X Clock
Phase 337.5º
16:8 Crosspoint Switch
Mixer 1
1X Clock
Mixer 2
1X Clock
Mixer 3
1X Clock
Mixer 14
1X Clock
Mixer 15
1X Clock
Mixer 16
1X Clock
Figure 89. CW Clock Distribution Scheme
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Figure 90. 1X and 16X CW Clock Timing Diagram
The cross-point switch distributes the clocks with an appropriate phase delay to each mixer. For example, Vi(t) is
a received signal with a delay of (1 / 16) T. Apply a delayed LO(t) to the mixer in order to compensate for the (1 /
16) T delay. Thus, a 22.5⁰ delayed clock, that is 2π / 16 is selected for this channel. The mathematic calculation
is expressed in Equation 5.
é æ
ù
1 ö
Vi(t) = sin êw0 ç t +
÷ + wd t ú = sin [w0 t + 22.5° + wd t ]
ëê è 16 f0 ø
ûú
LO(t) =
é æ
4
1 öù 4
sin êw0 ç t +
÷ ú = sin [w0 t + 22.5°]
16
p
f0 ø ûú p
ëê è
Vo(t) =
2
cos (wd t ) + f (wn t )
p
(5)
Vo(t) represents the demodulated Doppler signal of each channel. When the Doppler signals from N channels
are summed, the signal-to-noise ratio improves. ωd is the Doppler frequency, ωo is the local oscillator frequency,
and ωn represents the high-frequency components that are filtered out.
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9.3.6.2 8 × ƒcw and 4 × ƒcw Modes
The 8 × ƒcw and 4 × ƒcw modes are alternative modes when a higher frequency clock solution (that is, a 16 × ƒcw
clock) is not available in the system. The block diagram of these two modes is shown in Figure 91.
INV
4X, 8X Clock
I/Q CLK
Generator
D Q
1X Clock
LNA2 to 16
In-Phase
CLK
Weight
Summed
In-Phase
Quadrature
CLK
I/V
Weight
LNA1
I/V
Weight
Summed
Quadrature
Weight
Figure 91. 8 × ƒcw and 4 × ƒcw Block Diagram
Good phase accuracy and matching are also maintained. The quadrature clock generator is used to create inphase and quadrature clocks with exactly a 90° phase difference. The only difference between the 8 × ƒcw and 4
× ƒcw modes is the accessibility of the third- and fifth-order harmonic suppression filter. In the 8 × ƒcw mode, the
suppression filter can be supported. In both modes, a (1 / 16) T phase delay resolution is achieved by weighting
the in-phase and quadrature paths correspondingly. For example, if a delay of (1 / 16) T or 22.5° is targeted, the
weighting coefficients must follow Equation 6, assuming Iin and Qin are sin (ω0t) and cos (ω0t), respectively.
æ
1 ö
æ 2p ö
æ 2p ö
Idelayed (t) = Iin cos ç ÷ + Qin sin ç ÷ = Iin ç t +
÷
16
16
16
f0 ø
è ø
è ø
è
æ
1 ö
æ 2p ö
æ 2p ö
Qdelayed (t) = Qin cos ç ÷ - Iin sin ç ÷ = Qin ç t +
÷
è 16 ø
è 16 ø
è 16 f0 ø
(6)
Therefore, after the I/Q mixers, phase delay in the received signals is compensated. The mixer outputs from all
channels are aligned and added linearly to improve the signal-to-noise ratio. TI recommends meeting the timing
between the 1 × fcw clock and 4 × fcw or 8 × fcw clock; see Figure 92.
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Figure 92. 8 × ƒcw and 4 × ƒcw Timing Diagram
9.3.6.3 1 × ƒcw Mode
The 1 × ƒcw mode requires in-phase and quadrature clocks with low phase noise specifications. A block diagram
for this mode is shown in Figure 93. The (1 / 16) T phase delay resolution is also achieved by weighting the inphase and quadrature signals, as described in the 8 × ƒcw and 4 × ƒcw Modes section.
Synchronized
I/Q Clocks
LNA2 to 16
In-Phase
CLK
Weight
Quadrature
CLK
Summed
In-Phase
I/V
Weight
LNA1
Weight
Weight
I/V
Summed
Quadrature
Figure 93. 1 × ƒcw Mode Block Diagram
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9.3.6.4 CW High-Pass Filter
The summing amplifier is implemented in the device to sum and convert 16-channel mixer current outputs to a
differential voltage output. This summing amplifier has five internal gain adjustment resistors that can provide 32
different gain settings; see Table 80. System designers can easily adjust the CW path gain, depending on signal
strength and transducer sensitivity. For any other gain values an external resistor option is supported. The gain
of the summation amplifier is determined by the ratio between the 2000 Ω resistors after the LNA and internal or
external resistor network (Rs). Thus, the matching between these resistors plays a more important role than the
absolute resistor values. Better than 1% matching is achieved on-chip. The absolute resistor tolerance can be
higher, depending on the process variation. If external resistors are used, the gain error between the I/Q
channels or among multiple AFEs can increase. TI recommends using internal resistors to set the gain in order
to achieve better gain matching (across channels and multiple AFEs).
The device provides an extra feature to suppress undesired low-frequency signal presents at the CW output,
which is achieved by implementing an HPF at the CW output using the scheme shown in Figure 94.
ACT1
Mixer Clock 1
500
IN1
Input 1
Rh
LNA1
INM1
Ch
CW_DC_INP
Cs
500
CW_DC_OUTM
ACT2
Mixer Clock 2
Rs
500
IN2
Input 2
10 Ÿ
10 Ÿ
LNA2
INM2
CW_AMPINM
CW_AMPINP
I2V Sum
Amp
500
Rs
CW_OUTP
CW_OUTM
+
2000
2000
HPF
Amp
_
CW Output
CW_DC_INM
CW_DC_OUTP
Ch
ACT16
Cs
Mixer Clock 16
500
Rh
IN16
CW I- or Q-Channel Structure
LNA16
Input 16
INM16
500
Figure 94. CW Summing Amplifier and High-Pass Filter Implementation
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When this feature is enabled, the overall transfer function of the CW summing amplifier across frequency is as
shown in Figure 95.
0
-3
Fc_HPF
Fc_LPF
-6
Gain (dB)
-9
-12
-15
-18
-21
-24
-27
100
1k
10k
Frequency (Hz)
100k
1M
D066
Figure 95. CW Summing Amplifier Transfer Function
The high-pass corner and low-pass corner shown in Figure 95 is given by Equation 7 and Equation 8,
respectively:
Fc_hpf = Rs / (2 × π × Rh × Ch × 2000 Ω)
Fc_lpf = 1 / (2 × π × Rs × Cs)
(7)
(8)
The following rules can be used to calculate the value of different components:
1. Rs is the resistor value determined by how much signal gain is needed.
2. Cs is selected depending upon the value of Fc_lpf.
3. Rh is determined by the amplitude of the undesired low-frequency signal required to be rejected. For
instance, suppose that without enabling the CW HPF feature, the peak-to-peak amplitude of the lowfrequency signal at the CW summing amplifier output is given by Vopp. Then the value of Rh has the
relationship shown in Equation 9. The previous constraint occurs because the CW HPF amplifier output can
only swing up to 4 Vpp.
Rh < 4 × Rs / Vopp
(9)
NOTE
Higher resistance values of Rh provide better noise performance.
4. Ch is the selected value of this capacitor depending upon the value of Fc_hpf.
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An alternative current-summing circuit is shown in Figure 96. However, this circuit only achieves good
performance when a lower noise operational amplifier is available compared to the device internal summing
differential amplifier. This current output mode requires the internal summing amplifier to be powered down
(register 198, bit 9) and Rs set to 0 Ω.
AFE No.X
CW_AMPINP
AFE No.2
ACT1
500
Mixer 1
Clock
CW_AMPINM
Preferably, use an ultra-low noise, fully-differential
amplifier with a high output driving current.
AFE No.1
IN1
Input 1
INM1
LNA1
CM_BYP
500
ACT2
500
Mixer 1
Clock
IN2
Input 2
INM2
CW_AMPINP
LNA2
CW_AMPINM
500
-
+
CM_BYP
CW I or Q Channel Structure
+
-
ACT16
500
IN16
Input 16
INM16
Mixer 1
Clock
LNA16
Ultra-low noise, single-ended amplifiers
are an option as well.
500
Figure 96. CW Circuit With Multiple Devices (Current Output Mode, CM_BYP = 1.5 V)
The CW I/Q channels are well matched internally to suppress image frequency components in the Doppler
spectrum. Use low tolerance components and precise operational amplifiers for achieving good matching in the
external circuits as well.
NOTE
The local oscillator inputs of the passive mixer are cos (ωt) for the I channel and sin (ωt)
for the Q channel, respectively. Depending on the application-specific CW Doppler
complex FFT processing, swapping I/Q channels in the FPGA or DSP may be needed in
order to obtain correct blood flow directions.
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9.3.6.5 CW Clock Selection
The device can accept differential LVDS, LVPECL, and other differential clock inputs as well as a single-ended
CMOS clock. An internally-generated VCM of 2.5 V is applied to CW clock inputs (that is, CLKP_16X, CLKM_16X
and CLKP_1X, CLKM_1X). Because this 2.5-V VCM is different from the one used in standard LVDS or LVPECL
clocks, ac coupling is required between clock drivers and the device CW clock inputs. When the CMOS clock is
used, tie CLKM_1X and CLKM_16X to ground. Common clock configurations are shown in Figure 97.
Appropriate termination is recommended to achieve good signal integrity.
NOTE
The configurations shown in Figure 97 can also be used as a reference for the ADC clock
input.
3.3 V
130 :
3.3 V 0.1 PF
83 :
LMK048x,
CDCM7005,
CDCE7010
AFE
Clocks
0.1 PF
130 :
LVPECL
(a) LVPECL Configuration
100 :
CDCE72010
0.1 PF
0.1 PF
AFE
Clocks
LVDS
(b) LVDS Configuration
C1
100 nF
Clock
Source
0.1 PF
R1
50 :
L1
1 m:
0.1 PF
AFE
Clocks
0.1 PF
(c) Transformer-Based Configuration
CMOS CLK
Driver
AFE
CMOS CLK
CMOS
(d) CMOS Configuration
Figure 97. Clock Configurations
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The combination of the clock noise and the CW path noise can degrade CW performance. The internal clocking
circuit is designed for achieving excellent phase noise required by CW operation. The phase noise of the device
CW path is better than 160 dBc/Hz at a 1-kHz offset. Consequently, the phase noise of the mixer clock inputs
must be better than 160 dBc/Hz.
In the 16, 8, and 4 × ƒcw operations modes, a low-phase noise clock is required for the 16, 8, and 4 × ƒcw clocks
(that is, the CLKP_16X and CLKM_16X pins) in order to maintain good CW phase noise performance. The 1 ×
ƒcw clock (that is, the CLKP_1X and CLKM_1X pins) is only used to synchronize the multiple device chips and is
not used for demodulation. Thus, the 1 × ƒcw clock phase noise is not a concern. However, in the 1 × ƒcw
operation mode, low-phase noise clocks are required for both the CLKP_16X, CLKM_16X and CLKP_1X,
CLKM_1X pins because both are used for mixer demodulation. In general, a higher slew rate clock has lower
phase noise. Thus, clocks with high amplitude and fast slew rate are preferred in CW operation. In the CMOS
clock mode, a 5-V CMOS clock can achieve the highest slew rate.
Clock phase noise can be improved by a divider as long as the divider phase noise is lower than the target
phase noise. The phase noise of a divided clock can be improved approximately by a factor of 20logN dB, where
N is the dividing factor of 16, 8, or 4. If the target phase noise of the mixer LO clock 1 × fcw is 160 dBc/Hz at a 1kHz off the carrier, the 16 × fcw clock phase noise must be better than 160 – 20log16 = 136 dBc/Hz. TI’s jitter
cleaners LMK048x, CDCM7005, and CDCE72010 exceed this requirement and can be selected to work with the
device. In the 4X and 1X modes, higher quality input clocks are expected to achieve the same performance
because N is smaller. Thus, the 16X mode is a preferred mode because this mode reduces the phase noise
requirement for the system clock design. In addition, the phase delay accuracy is specified by the internal clock
divider and distribution circuit.
Note that in the 16X operation mode, the CW operation range is limited to 8 MHz as a result of the 16X clock.
The maximum clock frequency for the 16X clock is 128 MHz. In the 8X, 4X, and 1X modes, higher CW signal
frequencies up to 15 MHz can be supported with a small degradation in performance. For example, the phase
noise is degraded by 9 dB at 15 MHz, compared to 2 MHz.
As the channel number in a system increases, clock distribution becomes more complex. Using one clock driver
output is not preferred to drive multiple AFEs because the clock buffer load capacitance increases by a factor of
N. The section can be used as a reference for the system clock configuration. When clock phase noise is not a
concern (for example, the 1 × ƒcw clock in the 16, 8, and 4 × ƒcw operation modes), one clock driver output can
excite more than one device. Nevertheless, special considerations must be applied for such a clock distribution
network design. Preferably, all clocks are generated from the same clock source in typical ultrasound systems
(such as 16 × ƒcw , 1 × ƒcw clocks, audio ADC clocks, RF ADC clock, pulse repetition frequency signal, frame
clock, and so on). By using the same clock source, interference resulting from clock asynchronization can be
minimized.
9.3.6.6 CW Supporting Circuits
As a general practice in the CW circuit design, in-phase and quadrature channels must be strictly symmetrical by
using well-matched layout and high-accuracy components. In systems, additional high-pass wall filters (20 Hz to
500 Hz) and low-pass audio filters (10 kHz to 100 kHz) with multiple poles are usually needed. Because the CW
Doppler signal ranges from 20 Hz to 20 kHz, noise under this range is critical. Consequently, low-noise audio
operational amplifiers are suitable to build these active filters for CW post-processing (that is, the OPA1632,
OPA2211, or THS4131). More filter design techniques can be found at www.ti.com. The TI active filter design
tool is the WEBENCH® Filter Designer. The filtered audio CW I/Q signals are sampled by audio ADCs and
processed by the DSP or PC. Although CW signal frequency is from 20 Hz to 20 KHz, higher sampling rate
ADCs are still preferred for further decimation and SNR enhancement. Because of the large dynamic range of
CW signals, high-resolution ADCs (≥ 16 bits) are required [such as the ADS8413 (2 MSPS, 16 bits, 92-dBFS
SNR) and the ADS8472 (1 MSPS, 16 bits, 95-dBFS SNR)]. ADCs for in-phase and quadrature-phase channels
must be strictly matched, not only for amplitude matching but also for phase matching in order to achieve the
best I/Q matching. In addition, the in-phase and quadrature ADC channels must be sampled simultaneously.
9.3.6.7 Power Management
Power management plays a critical role to extend battery life and to ensure a long operation time. The device
has a fast and flexible power-up and power-down control that can maximize battery life. The device can be
powered down or up through external pins or internal registers.
This section describes the functionality of different power-down pins and register bits available in the device. The
device can be divided in two major blocks, the VCA and ADC; see Figure 98 and Figure 99.
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AVDD_5V
AVDD_3P3
SBAS687B – FEBRUARY 2015 – REVISED AUGUST 2015
CM_BYP1
CM_BYP2
Reference Voltage,
Current Generator
VHIGH1
Band-Gap Circuit
VHIGH2
One Channel Block
ACT1
INP1
VCAT
0 to -40 dB
LNA
LPF
10, 15, 20,
30, 35 and
50 MHz
PGA
24, 30 dB
INM1
To ADC Channel 1
VCNTL
CW Mixer
CW_CH1
16X16 Cross
Point SW
CW_CLOCK
ACT2
INP2
VCAT
0 to -40 dB
LNA
PGA
24, 30 dB
INM2
LPF
10, 15, 20,
30, 35 and
50 MHz
To ADC Channel 2
LPF
10, 15, 20,
30, 35 and
50 MHz
To ADC Channel 16
VCNTL
Analog Inputs
CW Mixer
CW_CH2
16X16 Cross
Point SW
CW_CLOCK
ACT16
INP16
VCAT
0 to -40 dB
LNA
PGA
24, 30 dB
INM16
VCNTL
CW Mixer
CW_CLOCK
CW_CH16
16X16 Cross
Point SW
VCNTL
CLKP_16x
CLKM_16x
CW_CH15
CW_CH16
CW_CH1
CW_CH2
CW_CLOCK
VCNTRL Block
Serial
Interface
SDOUT
16-Phase
Generator
CW Clock
CLKP_1x
CLKM_1x
SCLK
SEN
RESET
SDIN
PDN_GBL
PDN_FAST
VCNTLM
AVSS
VCNTLP
Summing
Amplifier
CW_IP_OUTP, CW_IP_OUTM,
CW_QP_OUTP, CW_QP_OUTM
Figure 98. VCA Block Diagram
68
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Reference Voltage,
Current Generator
VCM
DVDD_1P8
DVDD_1P2
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AVDD_1P8
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Band-Gap Circuit
ADC1
ADC Analog
ADC Digital
LVDS Data
Serializer and
Buffer
DOUTP1
DOUTM1
ADC Analog
ADC Digital
LVDS Data
Serializer and
Buffer
DOUTP2
DOUTM2
LVDS Data
Serializer and
Buffer
DOUTP16
DOUTM16
ADC2
VCA Output
ADC16
LVDS Outputs
ADC Analog
ADC Digital
FCLKP
FCLKM
LVDS Frame,
Clock
Serializer, and
Buffer
DCLKP
DCLKM
PLL
Serial
Interface
SDOUT
SCLK
SEN
PDN_FAST
PDN_GBL
RESET
SDIN
ADC_CLKP
ADC
Clock
ADC_CLKM
ADC Clock
Buffer
Figure 99. ADC Block Diagram
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9.3.6.7.1 VCA
The VCA consists of the following blocks:
• Band-gap circuit,
• Serial interface,
• Reference voltage and current generator,
• A total of 16 channel blocks (each channel block includes an LNA, VCAT, PGA, LPF, CW mixer, and a 16X16
cross-point switch),
• VCNTRL block,
• Phase generator for CW mode, and
• CW summing amplifier.
Of these VCA blocks, only the band gap and serial interface block cannot be powered down by using powerdown pins or bits. Table 7 lists all the VCA blocks that are powered down using various pin and bit settings.
Table 7. VCA Power-Down Mode Descriptions
NAME
TYPE (Pin or
Register)
LNA
VCAT +
PGA +
LPF
CW
MIXER
16X16 CROSS-POINT
SWITCH
REFERE
NCE
VCNTRL
BLOCK
CW SUMMING
AMPLIFIER +
PHASE
GENERATOR
CHANNEL
PDN_GBL
Pin
Yes (1)
Yes
Yes
Yes
Yes
Yes
Yes
All (2)
GBL_PDWN
Register 197, bit 15
Yes
Yes
Yes
Yes
Yes
Yes
Yes
All
PDN_FAST
Pin
Yes
Yes
Yes
Yes
No
No
Yes
All
FAST_PDWN
Register 197, bit 14
Yes
Yes
Yes
Yes
No
No
Yes
All
PDNCHxx
Register 197, bits 7-0,
register 213, bits 7-0
Yes
Yes
Yes
Yes
No
No
No
Individual
PDWN_LNA
Register 197, bit 13
Yes
No
No
No
No
No
No
All
PDWN_VCA_PGA
Register 197, bit 12
No
Yes
No
No
No
No
No
All
(1)
(2)
Yes = powered down. No = active.
All = all channels are powered down. Individual = only a single channel is powered down, depending upon the corresponding bit.
If more than one bit is simultaneously enabled, then all blocks listed as Yes for each bit setting is powered down.
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9.3.6.7.2 ADC
The ADC consists of the following blocks:
• Band-gap circuit,
• Serial interface,
• Reference voltage and current generator,
• ADC analog block that performs a sampling and conversion,
• ADC digital block that includes all the digital post processing blocks (such as the offset, gain, digital HPF, and so forth),
• LVDS data serializer and buffer that converts the ADC parallel data to a serial stream.
• LVDS frame and clock serializer and buffer,
• PLL (phase-locked loop) that generates a high-frequency clock for both the ADC and serializer.
Of all these blocks, only the band gap and serial interface block cannot be power down using power-down pins or bits. Table 8 lists which blocks in the
ADC are powered down using different pins and bits.
Table 8. Power-Down Modes Description for the ADC
NAME
TYPE (Pin or Register)
ADC
ANALOG
ADC
DIGITAL
LVDS DATA SERIALIZER,
BUFFER
LVDS FRAME AND
CLOCK SERIALIZER,
BUFFER
REFERENCE + ADC
CLOCK BUFFER
PLL
CHANNEL
PDN_GBL
Pin
Yes (1)
Yes
Yes
Yes
Yes
Yes
All (2)
GLOBAL_PDN
Register 1, bit 0
Yes
Yes
Yes
Yes
Yes
Yes
All
PDN_FAST
Pin
Yes
Yes
Yes
No
No
No
All
DIS_LVDS
Register 1, bit 5
No
No
Yes
Yes
No
No
All
PDN_ANA_CHx
Registers 24 (bits 7-4), 36 (bits 7-4),
48 (bits 7-4), and 60 (bits 7-4)
Yes
No
No
No
No
No
Individual
PDN_DIG_CHx
Registers 4 (bits 15-12), 36 (bits 15-12),
48 (bits 15-12), and 60 (bits 15-12)
No
Yes
No
No
No
No
Individual
PDN_LVDSx
Register 24 (bits 11-8), 36 (bits 11-8),
48 (bits 11-8), and 60 (bits 11-8)
No
No
Yes
No
No
No
Individual
(1)
(2)
Yes = powered down. No = active.
All = all channels are powered down. Individual = only a single channel is powered down, depending upon the corresponding bit.
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9.4 Device Functional Modes
9.4.1 ADC Test Pattern Mode
9.4.1.1 Test Patterns
9.4.1.1.1 LVDS Test Pattern Mode
The ADC data coming out of the LVDS outputs can be replaced by different kinds of test patterns. The different
test patterns are described in Table 9.
Table 9. Description of LVDS Test Patterns
TEST
PATTERN
MODE
PROGRAMMING THE MODE
THE SAME PATTERN MUST BE COMMON
TO ALL DATA LINES (DOUT)
THE PATTERN IS SELECTIVELY
REQUIRED ON ONE OR MORE DATA
LINE (DOUT)
TEST PATTERNS
REPLACE (1)
All 0s
Set the mode using PAT_MODES[2:0]
Set PAT_SELECT_IND = 1. To output the
pattern on the DOUTx line, select
PAT_LVDSx[2:0].
Zeros in all bits
(00000000000000)
All 1s
Set the mode using PAT_MODES[2:0]
Set PAT_SELECT_IND = 1. To output the
pattern on the DOUTx line, select
PAT_LVDSx[2:0].
Ones in all bits
(11111111111111)
Deskew
Set the mode using PAT_MODES[2:0]
Set PAT_SELECT_IND = 1. To output the
pattern on the DOUTx line, select
PAT_LVDSx[2:0].
The ADC data are replaced
by alternate 0s and 1s
(01010101010101)
Sync
Set the mode using PAT_MODES[2:0]
Set PAT_SELECT_IND = 1. To output the
pattern on the DOUTx line, select
PAT_LVDSx[2:0].
ADC data are replaced by
half 1s and half 0s
(11111110000000)
Set PAT_SELECT_IND = 1. To output the
pattern on the DOUTx line, select
PAT_LVDSx[2:0].
The word written in the
CUSTOM_PATTERN control
(taken from the MSB side)
replaces ADC data.
(For instance,
CUSTOM_PATTERN =
1100101101011100 and
ADC data =
11001011010111 when the
serialization factor is 14.)
Set PAT_SELECT_IND = 1. To output the
pattern on the DOUTx line, select
PAT_LVDSx[2:0].
The ADC data are replaced
by a word that increments by
1 LSB every conversion clock
starting at negative full-scale,
increments until positive fullscale, and wraps back to
negative full-scale. The step
size of the ramp pattern is
function of ADC resolution
(N) and serialization factor
(S) and is given by 2(S-N).
Custom
Ramp
Set the mode using PAT_MODES[2:0]. Set
the desired custom pattern using the
CUSTOM_PATTERN register control.
Set the mode using PAT_MODES[2:0]
Toggle
Set the mode using PAT_MODES[2:0]
Set PAT_SELECT_IND = 1. To output the
pattern on the DOUTx line, select
PAT_LVDSx[2:0].
The ADC data alternate
between two words that are
all 1s and all 0s. At each
setting of the toggle pattern,
the start word can either be
all 0s or all 1s. (Alternate
between 11111111111111
and 00000000000000.)
PRBS
Set SEL_PRBS_PAT_GBL = 1. Select either
custom or ramp pattern with
PAT_MODES[2:0]. Enable PRBS mode
using PRBS_EN. Select the desired PRBS
mode using PRBS_MODE. Reset the PRBS
generator with PRBS_SYNC.
Set PAT_SELECT_IND = 1. Select either
custom or ramp pattern with
PAT_LVDSx[2:0]. Enable PRBS mode on
DOUTx with the PAT_PRBS_LVDSx control.
Select the desired PRBS mode using
PRBS_MODE. Reset the PRBS generator
with PRBS_SYNC.
A 16-bit pattern is generated
by a 23-bit (or 9-bit) PRBS
pattern generator (taken from
the MSB side) and replaces
the ADC data.
(1)
Shown for a serialization factor of 14.
72
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All patterns listed in Table 9 (except the PRBS pattern) can also be forced on the frame clock output line by
using PAT_MODES_FCLK[2:0]. To force a PRBS pattern on the frame clock, use the SEL_PRBS_PAT_FCLK,
PRBS_EN, and PAT_MODES_FCLK register controls.
The ramp, toggle, and pseudo-random sequence (PRBS) test patterns can be reset or synchronized by providing
a synchronization pulse on the TX_TRIG pin or by setting and resetting a specific register bit.
Figure 100 depicts a block diagram representation of this scheme.
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PAT_MODES[2:0]
PAT_MODES[2:0]
Global
Pattern
ADC1
0
1
PAT_SELECT_IND
0
Serializer
DOUTP1,
DOUTM1
Serializer
DOUTP16,
DOUTM16
1
0
Individual
Pattern for
LVDS1
1
PAT_LVDS1[2:0]
ADC16
0
1
PAT_SELECT_IND
0
1
0
Individual
Pattern for
LVDS16
1
PAT_LVDS16[2:0]
Figure 100. Test Pattern Block Diagram
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9.4.2 Partial Power-Up and Power-Down Mode
The partial power-up and power-down mode is also called fast power-up and power-down mode. The VCA can
be programmed in partial power-down mode either by setting the PDN_FAST pin high or setting the
FAST_PDWN (register 197, bit 14) register bit to 1. Similarly, the ADC can be programmed in this mode by
setting the PDN_FAST pin high. In this mode, most amplifiers in the signal path are powered down and the
internal reference circuits remain active as well as all the data and frame and clock LVDS serializer and buffer.
The partial power-down function allows the device to quickly wake-up from a low-power state. This configuration
ensures that the external capacitors are discharged slowly; thus, a minimum wake-up time is required as long as
the charges on these capacitors are restored. The VCA wake-up response is typically approximately 2 μs or 1%
of the power-down duration, whichever is larger. The longest wake-up time depends on the capacitors connected
at INP and INM, because the wake-up time is the time required to recharge the capacitors to the desired
operating voltages. For instance, 0.1 μF at INP and 15 nF at INM provides a wake-up time of 2.5 ms. For larger
capacitors, this time is longer. The ADC wake-up time is approximately 1 μs. Thus, the device wake-up time is
more dependent on the VCA wake-up time with the assumption that the ADC clock is running for at least 50 μs
before the normal operating mode resumes. The power-down time is instantaneous, less than 1 μs. This fast
wake-up response is desired for portable ultrasound applications in which power savings is critical. The pulse
repetition frequency of an ultrasound system can vary from 50 kHz to 500 Hz, and the imaging depth (that is, the
active period for a receive path) varies from tens of µs to hundreds of μs. The power savings can be quite
significant when a system PRF is low. In some cases, only the VCA is powered down when the ADC runs
normally to ensure minimal interference to the FPGAs; see the Electrical Characteristics table to determine
device power dissipation in partial power-down mode.
9.4.3 Global Power-Down Mode
To achieve the lowest power dissipation, the device can be placed into a complete power-down mode. This
mode is controlled through the GBL_PDWN (for the VCA) or GLOBAL_PDN (for the ADC) registers or the
PDN_GBL pin (for both the VCA and ADC). In complete power-down mode, all circuits (including reference
circuits within the device) are powered down and the capacitors connected to the device are discharged. The
wake-up time depends on the time that the device spends in shutdown mode. 0.1 μF at INP and 15 nF at INM
provide a wake-up time of approximately 2.5 ms.
9.4.4 TGC Configuration
By default, after reset the VCA is configured in TGC mode. Depending upon the system requirements, the device
can be programmed in a suitable power mode using the POW_MODES (register 197, bits 11-10) register bits.
9.4.5 CW Configuration
To configure the device in CW mode, set the CW_TGC_SEL (register 198, bit 9) register bit to 1. To save power,
the voltage-controlled attenuator and programmable gain amplifier in the TGC path can be disabled by setting
the PDWN_VCA_PGA bit (register 197, bit 12) to 1. Also, the ADC can be powered down completely using the
GLOBAL_PDN bit (register 1, bit 0). Usually only half the number of channels in a system are active in the CW
mode. Thus, the individual channel control can power-down unused channels and save power; see Table 7 and
Table 8.
9.4.6 TGC + CW Mode
In systems that require fast switching between the TGC and CW modes, both TGC and CW mode can remain
active simply by setting the CW_TGC_SEL (register 198, bit 9) register bit to 1.
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9.5 Programming
9.5.1 Serial Peripheral Interface (SPI) Operation
Several different device modes can be programmed with the serial peripheral interface (SPI). This interface is
formed by the SEN (serial interface enable), SCLK (serial interface clock), SDIN (serial interface data), and
RESET pins. Inside the device, the SCLK and SDIN pins have a 16-kΩ, pulldown resistor to ground and the SEN
pin has a 16-kΩ, pullup resistor to the DVDD_1P8 supply. Serially shifting bits into the device is enabled when
SEN is low. SDIN serial data are latched at every SCLK rising edge when SEN is active (low). SDIN serial data
are loaded into the register at every 24th SCLK rising edge when SEN is low. If the word length exceeds a
multiple of 24 bits, the excess bits are ignored. Data can be loaded in multiples of 24-bit words within a single
active SEN pulse (an internal counter counts the number of 24 clock groups after the SEN falling edge). The
interface can function with SCLK frequencies from 20 MHz down to low speeds (of a few hertz) and also with a
non-50% SCLK duty cycle. Data are divided into two main portions: the register address (8 bits) and data (16
bits). These portions are loaded on the addressed register. When writing to a register with unused bits, set these
bits to 0. Figure 101 shows this process.
SEN
tSEN_SU
tSCLK_H
Data Latched On
SCLK Rising Edge
tSCLK
tSEN_HO
SCLK
tSCLK_L
tDH
tDSU
SDIN
A7
A6
A5
A4
A3
A2
A1
A0
D15
D14
D13
D12
D11
D10
D9
D8
D7
D6
D5
D4
D3
D2
D1
D0
RESET
Figure 101. Serial Interface Timing Diagram
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Programming (continued)
9.5.1.1 Register Readout
The device includes an option where the contents of the internal registers can be read back. This readback
feature can be useful as a diagnostic test to verify the serial interface communication between the external
controller and the AFE. First, the REG_READ_EN bit (register 0, bit 1) must be set to 1. Then, initiate a serial
interface cycle specifying the address of the register (A[7:0]) whose content must be read. The data bits are don’t
care. The device outputs the contents (bits 15-0) of the selected register on the SDOUT pin. SDOUT has a
typical 20-ns delay (tOUT_DV) from the SCLK falling edge. For lower-speed SCLKs, SDOUT can be latched on the
SCLK rising edge. For higher-speed SCLKs (for example, if the SCLK period is less than 60 ns), latching SDOUT
at the next SCLK falling edge is preferable. The read operation timing diagram is shown in Figure 102 (see the
Serial Interface Timing Characteristics table). In readout mode, the REG_READ_EN bit can be accessed with
SDIN, SCLK, and SEN. To enable serial register writes, set the REG_READ_EN bit back to 0.
The device SDOUT buffer is 3-stated and is only enabled when the REG_READ_EN bit (register 0, bit 1) is
enabled. SDOUT pins from multiple devices can be tied together without any pullup resistors. The
SN74AUP1T04 level shifter can be used to convert 1.8-V logic to 2.5-V or 3.3-V logic, if necessary.
SEN
SCLK
tOUT_DV
SDOUT
SDIN
A7
A6
A5
A4
A3
A2
A1
A0
D15
D14
D13
D12
D11
D10
D9
D8
D7
D6
D5
D4
D3
D2
D1
D0
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
Figure 102. Serial Interface Register, Read Operation
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10 Application and Implementation
NOTE
Information in the following applications sections is not part of the TI component
specification, and TI does not warrant its accuracy or completeness. TI’s customers are
responsible for determining suitability of components for their purposes. Customers should
validate and test their design implementation to confirm system functionality.
10.1 Application Information
The device supports a wide-frequency bandwidth signal in the range of several kHz to several MHz. The device
is a highly-integrated solution that includes a low-noise amplifier (LNA), a voltage-controlled attenuator (VCAT), a
programmable gain amplifier (PGA), an antialiasing filter, an analog-to-digital converter (ADC), and a continuous
wave (CW) mixer. As a result of the device functionality, the device can be used in various applications (such as
in medical ultrasound imaging systems, sonar imaging equipment, radar, and other systems that require a very
large dynamic range).
10.2 Typical Application
Transmitter
1
1 uF
ACT1
SPI
Control
0.1 uF
Channel 1
INP1
T/R Switch
Clamping
Diode
Transmitter
16
AFE 1
LVDS
Receiver
LVDS lines
1 uF
ACT16
0.1 uF
Channel 16
INP16
T/R Switch
64
Channels
Transducer
Array
FPGA
Data
Processing
And
Storage
Clamping
Diode
AFE 4
Transmitter
64
LVDS lines
LVDS
Receiver
1 uF
ACT16
0.1 uF
Channel 64
INP16
Clock
Generator
T/R Switch
Clamping
Diode
Figure 103. Simplified Schematic
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Typical Application (continued)
5 VA
10 PF
N(1) x
AVSS 0.1 PF
N(1) x
AVSS 0.1 PF
1.2 VD
10 PF
N(1) x
AVSS 0.1 PF
1 PF
0.1 PF
1.8 VD
10 PF
N(1) x
DVSS 0.1 PF
N(1) x
DVSS 0.1 PF
DVDD_1P8
DVDD_1P2
AVDD_3P3
AVDD_1P8
INP1
AVDD_5V
0.1 PF
IN CH2
3.3 VA
10 PF
ACT1
1 PF
IN CH1
1.8 VA
10 PF
DOUTP1
DOUTM1
ACT2
DOUTP2
INP2
DOUTM2
10 nF
ADC_CLKP
ADC_CLKM
10 nF
CLKP_16X
DOUTP3, DOUTM3 to DOUTP14, DOUTM14
ACT3, INP3 to ACT14, INP14
AFE5818
Clock Inputs
CLKM_16X
10 nF
DOUTP15
ACT15
1 PF
CLKP_1X
CLKM_1X
DOUTM15
10 nF
DOUTP16
0.1 PF
IN CH15
INP15
DOUTM16
SDOUT
SDIN
DCLKP
ACT16
1 PF
SCLK
0.1 PF
IN CH16
DCLKM
INP16
TX_TRIG
FCLKP
SEN
•15 nF
INM1
•15 nF
INM2
AFE5818
Analog Inputs,
Analog Outputs,
REF and BIAS Decoupling,
LVDS Outputs
INM16
•15 nF
AFE5818
Digital Inputs
FCLKM
Other
AFE5818
Outputs
RESET
RSUM
CW_IP_AMPINP
REXT (optional)
CW_IP_OUTM
CS
CW_IP_AMPINM
REXT (optional)
RSUM
CS
RSUM
PDN_FAST
PDN_GBL
CW_IP_OUTP
To Summing
Amplifier
CW_DC_INM_IP
CH
CW_DC_OUTP_IP
•1 PF
CM_BYP1
Other
AFE5818
Outputs
RSUM
CW_DC_INP_IP
•1 PF
CM_BYP2
•1 PF
VHIGH1
•1 PF
VHIGH2
CH
CW_DC_OUTM_IP
Other
AFE5818
Outputs
RSUM
CW_QP_AMPINP
CW_QP_OUTM
CW_QP_AMPINM
CW_QP_OUTP
CS
REXT (optional)
RSUM
CS
RSUM
To Summing
Amplifier
REXT (optional)
RVCNTL
200 Ÿ
CW_DC_INM_QP
CVCNTL
470 pF
VCNTLP
CW_DC_OUTP_QP
CH
VCNTLP
VCNTLM
VCNTLM
RVCNTL
200 Ÿ
Other
AFE5818
Outputs
RSUM
CW_DC_INP_QP
CVCNTL
470 pF
CW_DC_OUTM_QP
CH
NCs
AVSS
(1)
DVSS
N represents the number of capacitors connected to the supply. Placing at least one capacitor for every three supply
pins is recommended.
Figure 104. Application Circuit
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Typical Application (continued)
10.2.0.2 Design Requirements
Typical requirements for a medical ultrasound imaging system are listed in Table 10.
Table 10. Design Parameters
DESIGN PARAMETER
EXAMPLE VALUES
Signal center frequency
5 MHz
Signal bandwidth
2 MHz
Maximum overloaded signal
1 VPP
Maximum input signal amplitude
100 mVPP
Transducer noise level
1 nV/√Hz
Dynamic range
151 dBc/Hz
Time gain compensation range
40 dB
Total harmonic distortion
40 dBc
10.2.0.3 Detailed Design Procedure
Medical ultrasound imaging is a widely-used diagnostic technique that enables visualization of internal organs,
their size, structure, and blood flow estimation. An ultrasound system uses a focal imaging technique that
involves time shifting, scaling, and intelligently summing the echo energy using an array of transducers to
achieve high imaging performance. The concept of focal imaging provides the ability to focus on a single point in
the scan region. By subsequently focusing at different points, an image is assembled.
See Figure 103 for a simplified schematic of a 64-channel ultrasound imaging system. When initiating an
imaging, a pulse is generated and transmitted from each of the 64 transducer elements. The pulse, now in the
form of mechanical energy, propagates through the body as sound waves, typically in the frequency range of 1
MHz to 15 MHz.
The sound waves weaken rapidly as they travel through the objects being imaged, falling off as the square of the
distance traveled. As the signal travels, portions of the wave front energy are reflected. Signals that are reflected
immediately after transmission are very strong because they are from reflections close to the surface; reflections
that occur long after the transmit pulse are very weak because they are reflecting from deep in the body. As a
result of the limitations on the amount of energy that can be put into the imaging object, the industry developed
extremely sensitive receive electronics. Receive echoes from focal points close to the surface require little, if any,
amplification. This region is referred to as the near field. However, receive echoes from focal points deep in the
body are extremely weak and must be amplified by a factor of 100 or more. This region is referred to as the far
field. In the high-gain (far field) mode, the limit of performance is the sum of all noise sources in the receive
chain.
In high-gain (far field) mode, system performance is defined by its overall noise level, which is limited by the
noise level of the transducer assembly and the receive low-noise amplifier (LNA). However in the low-gain (near
field) mode, system performance is defined by the maximum amplitude of the input signal that the system can
handle. The ratio between noise levels in high-gain mode and the signal amplitude level in low-gain mode is
defined as the dynamic range of the system.
The high integration and high dynamic range of the device make it ideally suited for ultrasound imaging
applications. The device includes an integrated LNA and VCAT (which use the gain that can be changed with
enough time to handle both near- and far-field systems), a low-pass antialiasing filter to limit the noise bandwidth,
an ADC with high SNR performance, and a CW mixer. Figure 104 illustrates an application circuit of the device.
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Use the following steps to design medical ultrasound imaging systems:
1. Use the signal center frequency and signal bandwidth to select an appropriate ADC sampling frequency.
2. Use the time gain compensation range to select the range of the VCNTL signal.
3. Use the transducer noise level and maximum input signal amplitude to select the appropriate LNA gain. The
device input-referred noise level reduces with higher LNA gain. However, higher LNA gain leads to lower
input signal swing support.
4. See Figure 104 to select different passive components for different device pins.
5. See the LNA Input Impedance section to select the appropriate input termination configuration.
6. See the CW Clock Selection section to select the clock configuration for the ADC and CW clocks.
10.2.0.4 Application Curves
0
0
-20
-20
Magnitude (dBFS)
Magnitude (dBFS)
Figure 105 and Figure 106 show the FFT of a device output for VCNTL = 0 V and VCNTL = 0.9 V, respectively,
with an input signal at 5 MHz captured at a sample rate of 50 MHz. Figure 105 shows the spectrum for a far field
imaging scenario with the full Nyquist band, default device settings, and VCNTL = 0 V.Figure 106 shows the
spectrum for a near field imaging scenario for the full Nyquist band with default device settings and VCNTL =
0.9 V.
-40
-60
-80
-40
-60
-80
-100
-100
-120
-120
0
2.5
5
7.5
10 12.5 15 17.5
Frequency (MHz)
20
22.5
25
0
D064
Figure 105. FFT for VCNTL = 0 V
2.5
5
7.5
10 12.5 15 17.5
Frequency (MHz)
20
22.5
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Figure 106. FFT for VCNTL = 0.9 V
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10.3 Do's and Don'ts
Driving the inputs (analog or digital) beyond the power-supply rails. For device reliability, an input must not
go more than 300 mV below the ground pins or 300 mV above the supply pins as suggested in the Absolute
Maximum Ratings table. Exceeding these limits, even on a transient basis, can cause faulty or erratic operation
and can impair device reliability.
Driving the device signal input with an excessively high level signal. The device offers consistent and fast
overload recovery with a 6-dB overloaded signal. For very large overload signals (> 6 dB of the linear input signal
range), TI recommends back-to-back Schottky clamping diodes at the input to limit the amplitude of the input
signal; see the LNA Overload Recovery section for more details.
Driving the VCNTL signal with an excessive noise source. Noise on the VCNTL signal gets directly
modulated with the input signal and causes higher output noise and reduction in SNR performance. Maintain a
noise level for the VCNTL signal as discussed in the Control Voltage Input section.
Using a clock source with excessive jitter, an excessively long input clock signal trace, or having other
signals coupled to the ADC or CW clock signal trace. These situations cause the sampling interval to vary,
causing an excessive output noise and a reduction in SNR performance. For a system with multiple devices, the
clock tree scheme must be used to apply an ADC or CW clock; see the CW Clock Selection section for clock
mismatch between devices, which can lead to latency mismatch and reduction in SNR performance.
LVDS routing length mismatch. The routing length of all LVDS lines routing to the FPGA must be matched to
avoid any timing related issue. For systems with multiple devices, the LVDS serialized data clock (DCLKP,
DCLKM) and the frame clock (FCLKP, FCLKM) of each individual device must be used to deserialize the
corresponding LDVS serialized data (DOUTP, DOUTM).
Failure to provide adequate heat removal. Use the appropriate thermal parameter listed in the Thermal
Information table and an ambient, board, or case temperature in order to calculate device junction temperature. A
suitable heat removal technique must be used to keep the device junction temperature below the maximum limit
of 105°C.
Incorrect register programming. After resetting the device, write register 1, bit 2 = 1 and register 1, bit 4 = 1. If
these bits are not set as specified, the device will not function properly. Furthermore, ADD_OFFSET (register 0,
bit 2) must be used carefully; see the VCA Register Map section.
10.4 Initialization Set Up
After bringing up all the supplies, use the following steps to initialize the device:
1. Apply a hardware reset pulse on the RESET pin with a minimum pulse duration of 100 ns. Note that after
powering up the device, a hardware reset is required.
2. After applying a hardware reset pulse, wait for a minimum time of 100 ns.
3. Set register 1, bits 2 and 4 to 1 using SPI signals.
4. Write any other register settings as required.
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11 Power Supply Recommendations
The device requires a total of five supplies in order to operate properly. These supplies are: AVDD_5V,
AVDD_3P3, AVDD_1P8, DVDD_1P8, and DVDD_1P2. For detailed information regarding the operating voltage
minimum and maximum specifications of different supplies, see the Recommended Operating Conditions table.
11.1 Power Sequencing and Initialization
11.1.1 Power Sequencing
Figure 107 shows the suggested power-up sequencing and reset timing for the device. Note that the DVDD_1P2
supply must rise before the AVDD_1P8 supply. If the AVDD_1P8 supply rises before the DVDD_1P2 supply, the
AVDD_1P8 supply current is eight to 12 times larger than the normal current until the DVDD_1P2 supply reaches
a 1.2-V level.
t1
t2
DVDD_1P2
DVDD_1P8,
AVDD_1P8,
AVDD_3P3,
AVDD_5V
t3
t4
t7
t5
RESET
t6
Device ready for register
write
Device ready for data
conversion
Start of clock
SEN
t8
NOTE: 10 µs < t1 < 50 ms, 10 µs < t2 < 50 ms, t3 > t1, t4 > 10 ms, t5 > 100 ns, t6 > 100 ns, t7 > 4 ADC clock cycles,
and t8 > 100 µs.
Figure 107. Recommended Power-Up Sequencing and Reset Timing Diagram
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12 Layout
12.1 Layout Guidelines
12.1.1 Power Supply, Grounding, and Bypassing
In a mixed-signal system design, the power-supply and grounding design plays a significant role. The device
distinguishes between two different grounds: AVSS (analog ground) and DVSS (digital ground). In most cases
laying out the printed circuit board (PCB) to use a single ground plane is adequate, but in high-frequency or highperformance systems, care must be taken so that this ground plane is properly partitioned between various
sections within the system to minimize interactions between analog and digital circuitry. Alternatively, the digital
supply set consisting of the DVDD_1P8, DVDD_1P2, and DVSS pins can be placed on separate power and
ground planes. For this configuration, tie the AVSS and DVSS grounds together at the power connector in a star
layout. In addition, optical or digital isolators (such as the ISO7240) can completely separate the analog portion
from the digital portion. Consequently, such isolators prevent digital noise from contaminating the analog portion.
Table 11 lists the related circuit blocks for each power supply.
Table 11. Supply versus Circuit Blocks
(1)
POWER SUPPLY
GROUND
CIRCUIT BLOCKS (1)
AVDD_5V
AVSS
Reference voltage and current generator, LNA, VCNTRL block, CW mixer,
CW clock buffer, 16x16 cross-point switch, 16-phase generator
AVDD_3P3
AVSS
Band-gap circuit, reference voltage and current generator, LNA, VCAT,
PGA, LPF, CW summing amplifier, VCA SPI
AVDD_1P8
AVSS
ADC analog, reference voltage and current generator, band-gap circuit,
ADC clock buffer
DVDD_1P8
DVSS
LVDS serializer and buffer, PLL
DVDD_1P2
DVSS
ADC digital, serial interface
See Figure 98 and Figure 99 for further details.
Reference all bypassing and power supplies for the device to their corresponding ground planes. Bypass all
supply pins with 0.1-μF ceramic chip capacitors (size 0603 or smaller). In order to minimize the lead and trace
inductance, the capacitors must be located as close to the supply pins as possible. Where double-sided
component mounting is allowed, these capacitors are best placed directly under the package. In addition, larger
bipolar decoupling capacitors (2.2 µF to 10 μF, effective at lower frequencies) can also be used on the main
supply pins. These components can be placed on the PCB in close proximity (< 0.5 inch or 12.7 mm) to the
device itself.
The device has a number of reference supplies that must be bypassed, such as CM_BYP1, CM_BYP2 and
VHIGH1, VHIGH2. Bypass these pins with at least a 1-μF capacitor; higher value capacitors can be used for
better low-frequency noise suppression. For best results, choose low-inductance ceramic chip capacitors (size
0402, > 1 μF) and placed as close as possible to the device pins.
12.1.2 Board Layout
High-speed, mixed-signal devices are sensitive to various types of noise coupling. One primary source of noise is
the switching noise from the serializer and the output buffer and drivers. For the device, care must be taken to
ensure that the interaction between the analog and digital supplies within the device is kept to a minimal amount.
The extent of noise coupled and transmitted from the digital and analog sections depends on the effective
inductances of each of the supply and ground connections. Smaller effective inductances of the supply and
ground pins result in better noise suppression. For this reason, multiple pins are used to connect each supply
and ground sets. Low inductance properties must be maintained throughout the design of the PCB layout by use
of proper planes and layer thickness.
To avoid noise coupling through supply pins, TI recommends to keep sensitive input pins (such as INM, INP, and
ACT pins) away from the AVDD_3P3 and AVDD_5V planes. For example, do not route the traces or vias
connected to these pins across the AVDD_3P3 and AVDD_5V planes. That is, avoid the power planes under the
INM, INP, and ACT pins.
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In order to maintain proper LVDS timing, all LVDS traces must follow a controlled impedance design. In addition,
all LVDS trace lengths must be equal and symmetrical; TI recommends keeping trace length variations less than
150 mil (0.150 inch or 3.81 mm).
In addition, appropriate delay matching must be considered for the CW clock path, especially in systems with a
high channel count. For example, if the clock delay is half of the 16X clock period, a phase error of 22.5°C can
exist. Thus, the timing delay difference among channels contributes to the beamformer accuracy.
Additional details on the NFBGA PCB layout techniques can be found in the Texas Instruments application
report, MicroStar BGA Packaging Reference Guide (SSYZ015), which can be downloaded from www.ti.com.
12.2 Layout Example
Figure 108 and Figure 109 illustrate example layouts for the top and bottom layers, respectively.
CM_BYP1, CM_BYP2,
VHIGH1, VHIGH2
decapacitors placed
near the device.
INPx, INMx and
ACTx Routing
Differential
Clock Input
Differential
CW Output
Differential
ADC Clock
LVDS
Differential
Routing
Figure 108. Top Layer
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Layout Example (continued)
CM_BYP1, CM_BYP2,
VHIGH1, VHIGH2
decapacitors placed near
the device.
INMx capacitor
placed near
the device.
Different supply decapacitors
placed near the device pins.
Figure 109. Bottom Layer
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Layout Example (continued)
Figure 110 shows a routing example for the ground planes.
Analog Ground
(AVSS) Plane
The INPx, INMx, and ACTx
pin area is isolated from the
ground plane.
ADC Digital Ground
(DVSS) Plane
Figure 110. Ground Plane
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Layout Example (continued)
Figure 111, Figure 112, and Figure 113 illustrate routing examples for different power planes.
The AVDD_1P8
power plane is routed in the
same area as that of analog
ground plane.
The INPx, INMx, and ACTx pin area
is isolated from the ground plane.
ADC Digital Ground
(DVSS) Plane
Figure 111. AVDD_1P8 Power Plane
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Layout Example (continued)
Analog Ground
(AVSS) Plane
The INPx, INMx, and
ACTx pin area is isolated
from the ground plane.
The AVDD_3P3
power plane is routed in the
same area as that of the
analog ground plane.
ADC Digital
Ground
(DVSS) Plane
The DVDD_1P8
power plane is routed in the same area
as that of the digital ground plane.
Figure 112. AVDD_3P3, DVDD_1P8 Power Planes
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Layout Example (continued)
The AVDD_5V
power plane is routed in the same area
as that of the analog ground plane.
The INPx, INMx, and ACTx pin area
is isolated from the ground plane.
The DVDD_1P2
power plane is routed in the same area
as that of the digital ground plane.
Figure 113. AVDD_5V, DVDD_1P2 Power Planes
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13 Register Maps
13.1 Serial Register Map
The device has two voltage-controlled amplifier (VCA) dies and one analog-to-digital converter (ADC) die, as
shown in Figure 114. Figure 114 also describes the channel mapping of VCA dies to the input pins. All dies
share the same SPI control signals (SCLK, SDIN, and SEN). The address space of the programmable registers
for the ADC die is from register 1 to register 60. By default, the address space of the programmable registers for
the VCA dies are shared (that is, both VCA dies have an address space from register 192 to register 205).
Therefore, the ADC and VCA dies can be programmed independently. Because the VCA dies share the same
address space, these dies are programmed together. To program VCA die 1 and VCA die 2 independently, the
address space for these dies must be separated by enabling the ADD_OFFSET bit (register 0, bit 2). All
programmable bits and addresses are listed in this section.
ADC
VCA Die 1
IN2
VCA_IN1
VCA_OUT1
ADC_IN2
DOUT2
IN4
VCA_IN2
VCA_OUT2
ADC_IN4
DOUT4
IN6
VCA_IN3
VCA_OUT3
ADC_IN6
DOUT6
IN8
VCA_IN4
VCA_OUT4
ADC_IN8
DOUT8
IN10
VCA_IN5
VCA_OUT5
ADC_IN10
DOUT10
IN12
VCA_IN6
VCA_OUT6
ADC_IN12
DOUT12
IN14
VCA_IN7
VCA_OUT7
ADC_IN14
DOUT14
IN16
VCA_IN8
VCA_OUT8
ADC_IN16
DOUT16
VCA Die 2
IN1
VCA_IN1
VCA_OUT1
ADC_IN1
DOUT1
IN3
VCA_IN2
VCA_OUT2
ADC_IN3
DOUT3
IN5
VCA_IN3
VCA_OUT3
ADC_IN5
DOUT5
IN7
VCA_IN4
VCA_OUT4
ADC_IN7
DOUT7
IN9
VCA_IN5
VCA_OUT5
ADC_IN9
DOUT9
IN11
VCA_IN6
VCA_OUT6
ADC_IN11
DOUT11
IN13
VCA_IN7
VCA_OUT7
ADC_IN13
DOUT13
VCA_IN8
VCA_OUT8
ADC_IN15
DOUT15
IN15
Device
Figure 114. Channel Mapping: VCA Dies
A reset process is required at the device initialization stage.
NOTE
Initialization can be accomplished with a hardware reset by applying a positive pulse to
the RESET pin. After reset, all ADC and VCA registers are set to 0 (default). Note that
during register programming, all unlisted register bits must be set to 0.
The Global Register is comprised of register 0 and controls both the VCA and ADC die. The ADC Registers
include registers that control the ADC die. The VCA Registers include registers that control the VCA dies (that is,
VCA die 1 and VCA die 2).
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Serial Register Map (continued)
13.1.1 Global Register Map
This section discusses the global register. A register map is available in Table 12.
Table 12. Global Register Map
REGISTER
ADDRESS
REGISTER DATA (1)
DECIMAL
HEX
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
ADD_
OFFSET
REG_READ_
EN
SOFTWARE_
RESET
(1)
The default value of all registers is 0.
13.1.1.1 Description of Global Register
13.1.1.1.1 Register 0 (address = 0h)
Figure 115. Register 0
15
0
W-0h
14
0
W-0h
13
0
W-0h
12
0
W-0h
11
0
W-0h
10
0
W-0h
9
0
W-0h
8
0
W-0h
7
6
5
4
3
2
0
0
0
0
0
ADD_OFFSET
W-0h
W-0h
W-0h
W-0h
W-0h
W-0h
1
REG_READ_
EN
W-0h
0
SOFTWARE_
RESET
W-0h
LEGEND: W = Write only; -n = value
Table 13. Register 0 Field Descriptions
Bit
Field
Type
Reset
Description
0
W
0h
Must write 0
2
ADD_OFFSET
W
0h
0 = Normal operation
1 = Separates the SPI address space of the VCA die 1 and VCA
die 2. Set this bit to 1 to write register addresses 213, 215, 216,
and 217. Otherwise set this bit to 0.
1
REG_READ_EN
W
0h
0 = Register readout mode disabled
1 = Register readout mode enabled; see the Register Readout
section for further details
0
SOFTWARE_RESET
W
0h
0 = Disabled
1 = Enabled (this setting returns the device to a reset state).
This bit is a self-clearing register bit.
15-3
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13.1.2 ADC Register Map
This section discusses the ADC and LVDS registers. A register map is available in Table 14.
Table 14. ADC Register Map
REGISTER DATA (1)
REGISTER ADDRESS
DECIMAL
HEX
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
1
1
0
LVDS_
RATE_2X
0
0
0
0
0
0
0
0
DIS_LVDS
1
0
1
0
GLOBAL_
PDN
2
2
PAT_MODES_FCLK[2:0]
LOW_
LATENCY_
EN
AVG_EN
SEL_PRBS
_PAT_
FCLK
3
3
SER_DATA_RATE
DIG_GAIN
_EN
0
4
4
5
5
7
7
8
8
11
B
13
D
14
15
OFFSET_
REMOVAL
_START_
SEL
OFFEST_
REMOVAL
_START_
MANUAL
OFFSET_CORR_DELAY
_FROM_TX_TRIG[7:6]
AUTO_OFFSET_REMOVAL_ACC_CYCLES[3:0]
OFFSET_CORR_DELAY_FROM_TX_TRIG[5:0]
DIG_
OFFSET_
EN
0
0
0
0
0
0
PAT_
SELECT_
IND
PRBS_
SYNC
PRBS_
MODE
PRBS_EN
MSB_
FIRST
0
0
0
0
0
0
0
0
CHOPPER
_EN
0
0
0
0
0
0
0
ADC_RES
CUSTOM_PATTERN[15:0]
AUTO_OFFSET_REMOVAL_VAL_RD_CH_SEL[4:0]
0
0
0
0
0
0
0
AUTO_OFFSET_REMOVAL_VAL_RD[13:0]
0
0
0
EN_DITHE
R
0
0
0
0
0
0
GAIN_CH1
0
OFFSET_CH1
E
0
0
OFFSET_CH1
F
GAIN_CH2
0
OFFSET_CH2
16
10
0
0
OFFSET_CH2
17
11
GAIN_CH3
0
OFFSET_CH3
18
12
0
0
OFFSET_CH3
19
13
GAIN_CH4
0
OFFSET_CH4
20
14
0
0
21
15
23
17
0
0
0
0
0
0
0
0
18
PDN_DIG_
CH4
PDN_DIG_
CH3
PDN_DIG_
CH2
PDN_DIG_
CH1
PDN_
LVDS4
PDN_
LVDS3
PDN_
LVDS2
PDN_
LVDS1
24
(1)
OFFSET_
REMOVAL
_SELF
SEL_PRBS
_PAT_GBL
PAT_MODES[2:0]
PAT_PRBS
_LVDS1
PAT_PRBS
_LVDS2
PAT_PRBS
_LVDS3
PAT_PRBS
_LVDS4
OFFSET_CH4
PAT_LVDS1[2:0]
HPF_ROU
ND_EN
PAT_LVDS2[2:0]
PAT_LVDS3[2:0]
PDN_ANA_
CH4
PDN_ANA_
CH3
PAT_LVDS4[2:0]
PDN_ANA_
CH2
DIG_HPF_
EN_CH1-4
HPF_CORNER_CH1-4[3:0]
PDN_ANA_
CH1
25
19
GAIN_CH5
0
OFFSET_CH5
26
1A
0
0
OFFSET_CH5
27
1B
GAIN_CH6
0
OFFSET_CH6
28
1C
0
0
OFFSET_CH6
29
1D
GAIN_CH7
0
OFFSET_CH7
30
1E
0
0
OFFSET_CH7
31
1F
GAIN_CH8
0
OFFSET_CH8
32
20
0
0
OFFSET_CH8
INVERT_
LVDS4
INVERT_
LVDS3
0
0
INVERT_
LVDS2
INVERT_
LVDS1
Default value of all registers is 0.
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Table 14. ADC Register Map (continued)
REGISTER DATA (1)
REGISTER ADDRESS
DECIMAL
HEX
15
14
13
12
33
21
PAT_PRBS
_LVDS5
PAT_PRBS
_LVDS6
PAT_PRBS
_LVDS7
PAT_PRBS
_LVDS8
35
23
0
0
0
0
0
0
0
0
36
24
PDN_DIG_
CH8
PDN_DIG_
CH7
PDN_DIG_
CH6
PDN_DIG_
CH5
PDN_
LVDS8
PDN_
LVDS7
PDN_
LVDS6
PDN_
LVDS5
37
25
GAIN_CH9
0
38
26
0
0
OFFSET_CH9
39
27
GAIN_CH10
0
OFFSET_CH10
40
28
0
0
OFFSET_CH10
41
29
GAIN_CH11
0
OFFSET_CH11
42
2A
0
0
OFFSET_CH11
43
2B
GAIN_CH12
0
OFFSET_CH12
44
2C
0
0
OFFSET_CH12
45
2D
47
2F
0
0
0
0
0
0
0
0
48
30
PDN_DIG_
CH12
PDN_DIG_
CH11
PDN_DIG_
CH10
PDN_DIG_
CH9
PDN_
LVDS12
PDN_
LVDS11
PDN_
LVDS10
PDN_
LVDS9
49
31
GAIN_CH13
0
OFFSET_CH13
50
32
0
0
OFFSET_CH13
51
33
GAIN_CH14
0
OFFSET_CH14
52
34
0
0
OFFSET_CH14
53
35
GAIN_CH15
0
OFFSET_CH15
54
36
0
0
OFFSET_CH15
55
37
GAIN_CH16
0
OFFSET_CH16
56
38
0
0
OFFSET_CH16
57
39
59
3B
0
0
0
0
0
0
0
0
60
3C
PDN_DIG_
CH16
PDN_DIG_
CH15
PDN_DIG_
CH14
PDN_DIG_
CH13
PDN_
LVDS16
PDN_
LVDS15
PDN_
LVDS14
PDN_
LVDS13
PDN_ANA_
CH16
PDN_ANA_
CH15
PDN_ANA_
CH14
67
43
0
0
0
0
0
0
0
0
0
0
0
94
PAT_PRBS
_LVDS9
PAT_PRBS
_LVDS13
PAT_PRBS
_LVDS10
PAT_PRBS
_LVDS14
PAT_PRBS
_LVDS11
PAT_PRBS
_LVDS15
11
10
9
8
PAT_LVDS5[2:0]
PAT_PRBS
_LVDS12
6
5
4
PDN_ANA_
CH7
2
1
PAT_LVDS8[2:0]
PDN_ANA_
CH6
PDN_ANA_
CH5
INVERT_
CH8
INVERT_
CH7
0
DIG_HPF_
EN_CH5-8
HPF_CORNER_CH5-8[3:0]
PAT_LVDS7[2:0]
PDN_ANA_
CH8
3
0
0
0
INVERT_
CH6
INVERT_
CH5
OFFSET_CH9
PAT_LVDS9[2:0]
PAT_PRBS
_LVDS16
7
PAT_LVDS6[2:0]
PAT_LVDS10[2:0]
PAT_LVDS13[2:0]
0
PAT_LVDS11[2:0]
PDN_ANA_
CH12
PDN_ANA_
CH11
PAT_LVDS12[2:0]
PDN_ANA_
CH10
PAT_LVDS14[2:0]
PDN_ANA_
CH9
0
PIN_PAT_LVDS15[2:0]
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DIG_HPF_
EN_
CH9-12
HPF_CORNER_CH9-12[3:0]
INVERT_
CH12
INVERT_
CH11
0
0
INVERT_
CH10
INVERT_
CH9
DIG_HPF_
EN_
CH13-16
HPF_CORNER_CH13-16[3:0]
PAT_LVDS16[2:0]
PDN_ANA_
CH13
INVERT_
CH16
INVERT_
CH15
0
0
INVERT_
CH14
INVERT_
CH13
LVDS_DCLK_DELAY_PROG[3:0]
0
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13.1.2.1 Description of ADC Registers
13.1.2.1.1 Register 1 (address = 1h)
Figure 116. Register 1
15
R/W-0h
14
LVDS_RATE_
2X
R/W-0h
7
0
R/W-0h
6
0
R/W-0h
0
13
12
11
10
9
8
0
0
0
0
0
0
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
5
DIS_LVDS
R/W-0h
4
1
W-1h
3
0
R/W-0h
2
1
W-1h
1
0
R/W-0h
0
GLOBAL_PDN
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 15. Register 1 Field Descriptions
Bit
Field
Type
Reset
Description
15
0
R/W
0h
Must write 0
14
LVDS_RATE_2X
R/W
0h
0 = 1x rate; normal operation (default)
1 = 2x rate. This setting combines the data of two LVDS pairs
into a single LVDS pair. This feature can be used when the ADC
clock rate is low; see the LVDS Interface section for further
details.
0
R/W
0h
Must write 0
5
DIS_LVDS
R/W
0h
0 = LVDS interface is enabled (default)
1 = LVDS interface is disabled
4
1
R/W
0h
Must write 1
3
0
R/W
0h
Must write 0
2
1
R/W
0h
Must write 1
1
0
R/W
0h
Must write 0
0
GLOBAL_PDN
R/W
0h
0 = Device operates in normal mode (default)
1 = ADC enters in complete power-down mode
13-6
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13.1.2.1.2 Register 2 (address = 2h)
Figure 117. Register 2
15
14
13
PAT_MODES_FCLK[2:0]
R/W-0h
7
PAT_
MODES[2:0]
R/W-0h
6
SEL_PRBS_
PAT_GBL
R/W-0h
12
LOW_
LATENCY_EN
R/W-0h
AVG_EN
4
5
11
9
R/W-0h
10
SEL_PRBS_
PAT_FCLK
R/W-0h
3
2
1
8
PAT_MODES[2:0]
R/W-0h
0
OFFSET_CORR_DELAY_FROM_TX_TRIG[5:0]
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 16. Register 2 Field Descriptions
Bit
Field
Type
Reset
Description
PAT_MODES_FCLK[2:0]
R/W
0h
These bits enable different test patterns on the frame clock line;
see Table 17 for bit descriptions and to the Test Patterns section
for further details.
12
LOW_LATENCY_EN
R/W
0h
0 = Default latency with digital features supported
1 = Low-latency with digital features bypassed
11
AVG_EN
R/W
0h
0 = No averaging
1 = Enables averaging of two channels to improve signal-tonoise ratio (SNR); see the LVDS Interface section for further
details.
10
SEL_PRBS_PAT_FCLK
R/W
0h
0 = Normal operation
1 = Enables the PRBS pattern to be generated on fCLK; see the
Test Patterns section for further details.
9-7
PAT_MODES[2:0]
R/W
0h
These bits enable different test patterns on the LVDS data lines;
see Table 17 for bit descriptions and to the Test Patterns section
for further details.
SEL_PRBS_PAT_GBL
R/W
0h
0 = Normal operation
1 = Enables the PRBS pattern to be generated; see the Test
Patterns section for further details.
OFFSET_CORR_DELAY_FROM_
TX_TRIG[5:0]
R/W
0h
8-bit register to initiate offset correction after the TX_TRIG input
pulse (each step is equivalent to one sample delay); the
remaining two MSB bits are the
OFFSET_CORR_DELAY_FROM_TX_TRIG[7:6] bits (bits 10-9)
in register 3.
15-13
6
5-0
Table 17. Pattern Mode Bit Description
PAT_MODES[2:0]
96
DESCRIPTION
000
Normal operation
001
Sync (half frame 0, half frame 1)
010
Alternate 0s and 1s
011
Custom pattern
100
All 1s
101
Toggle mode
110
All 0s
111
Ramp pattern
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13.1.2.1.3 Register 3 (address = 3h)
Figure 118. Register 3
15
14
12
11
SER_DATA_RATE
DIG_GAIN_EN
0
R/W-0h
R/W-0h
R/W-0h
4
0
R/W-0h
3
0
R/W-0h
7
0
R/W-0h
6
0
R/W-0h
13
5
0
R/W-0h
10
9
OFFSET_CORR_DELAY_FROM
_TX_TRIG[7:6]
R/W-0h
2
0
R/W-0h
1
0
R/W-0h
8
DIG_
OFFSET_EN
R/W-0h
0
0
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 18. Register 3 Field Descriptions
Bit
Field
Type
Reset
Description
SER_DATA_RATE
R/W
0h
These bits control the LVDS serialization rate.
000 = 12x
001 = 14x
100 = 16x
101, 110, 111, 010, 011 = Unused
12
DIG_GAIN_EN
R/W
0h
0 = Digital gain disabled
1 = Digital gain enabled
11
0
R/W
0h
Must write 0
OFFSET_CORR_DELAY_FROM_
TX_TRIG[7:6]
R/W
0h
8-bit register to initiate offset correction after the TX_TRIG input
pulse (each step is equivalent to one sample delay); the
remaining six LSB bits are the
OFFSET_CORR_DELAY_FROM_TX_TRIG[5:0] bits (bits 5-0) in
register 2.
DIG_OFFSET_EN
R/W
0h
0 = Digital offset subtraction disabled
1 = Digital offset subtraction enabled
0
R/W
0h
Must write 0
15-13
10-9
8
7-0
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13.1.2.1.4 Register 4 (address = 4h)
Figure 119. Register 4
15
OFFSET_
REMOVAL_
SELF
R/W-0h
7
PRBS_
SYNC
R/W-0h
14
13
12
11
10
9
8
0
0
0
0
0
0
PAT_
SELECT_IND
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
6
PRBS_
MODE
R/W-0h
5
4
3
2
1
0
PRBS_EN
MSB_FIRST
0
0
ADC_RES
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 19. Register 4 Field Descriptions
Bit
Field
Type
Reset
Description
15
OFFSET_REMOVAL_SELF
R/W
0h
Auto offset removal mode is enabled when this bit is set to 1
14
OFFSET_REMOVAL_START_SEL
R/W
0h
Enable this bit to initiate offset correction with a pulse at the
TX_TRIG pin, otherwise offset correction is initiated when the
OFFSET_REMOVAL_START_MANUAL bit (bit 13) in register 4
is enabled.
13
OFFSET_REMOVAL_START_
MANUAL
R/W
0h
This bit initiates offset correction manually instead of with a
TX_TRIG pulse
AUTO_OFFSET_REMOVAL_ACC_
CYCLES
R/W
0h
These bits define the number of samples required to generate
an offset in auto offset correction mode
8
PAT_SELECT_IND
R/W
0h
0 = All LVDS output lines have the same pattern, as determined
by the PAT_MODES[2:0] bits (register 2, bits 9-7)
1 = Different test patterns can be sent on different LVDS lines,
depending upon the channel and register; see the Test Patterns
section for further details.
7
PRBS_SYNC
R/W
0h
0 = Normal operation
1 = PRBS generator is in a reset state
6
PRBS_MODE
R/W
0h
0 = 23-bit PRBS generator
1 = 9-bit PRBS generator
5
PRBS_EN
R/W
0h
0 = PRBS sequence generation block disabled
1 = PRBS sequence generation block enabled; see the Test
Patterns section for further details.
4
MSB_FIRST
R/W
0h
0 = The LSB is transmitted first on serialized output data
1 = The MSB is transmitted first on serialized output data
3
0
R/W
0h
Must write 0
2
0
R/W
0h
Must write 0
ADC_RES
R/W
0h
These bits control the ADC resolution.
00 = 12-bit resolution
01 = 14-bit resolution
10, 11 = Unused
12-9
1-0
98
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13.1.2.1.5 Register 5 (address = 5h)
Figure 120. Register 5
15
14
13
12
11
CUSTOM_PATTERN[15:0]
R/W-0h
10
9
8
7
6
5
4
3
CUSTOM_PATTERN[15:0]
R/W-0h
2
1
0
LEGEND: R/W = Read/Write; -n = value after reset
Table 20. Register 5 Field Descriptions
Bit
15-0
Field
Type
Reset
Description
CUSTOM_PATTERN[15:0]
R/W
0h
If the pattern mode is programmed to a custom pattern mode,
then the custom pattern value can be provided by programming
these bits; see the Test Patterns section for further details.
13.1.2.1.6 Register 7 (address = 7h)
Figure 121. Register 7
15
14
13
12
AUTO_OFFSET_REMOVAL_VAL_RD_CH_SEL
R/W-0h
7
0
R/W-0h
6
0
R/W-0h
5
0
R/W-0h
4
0
R/W-0h
11
10
0
R/W-0h
9
0
R/W-0h
8
0
R/W-0h
3
0
R/W-0h
2
0
R/W-0h
1
0
R/W-0h
0
CHOPPER_EN
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 21. Register 7 Field Descriptions
Field
Type
Reset
Description
15-11
Bit
AUTO_OFFSET_REMOVAL_VAL_
RD_CH_SEL
R/W
0h
Write the channel number to read the offset value in auto offset
correction mode for a corresponding channel number (read the
offset value in register 8, bits 13-0)
10-1
0
R/W
0h
Must write 0
CHOPPER_EN
R/W
0h
The chopper can be used to move low-frequency, 1 / f noise to
an fS / 2 frequency.
0 = Chopper disabled
1 = Chopper enabled
0
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13.1.2.1.7 Register 8 (address = 8h)
Figure 122. Register 8
15
0
R/W-0h
14
0
R/W-0h
13
7
6
5
12
11
10
AUTO_OFFSET_REMOVAL_VAL_RD[13:0]
R/W-0h
4
3
AUTO_OFFSET_REMOVAL_VAL_RD[13:0]
R/W-0h
2
9
8
1
0
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 22. Register 8 Field Descriptions
Bit
Field
Type
Reset
Description
15-14
0
R/W
0h
Must write 0
13-0
AUTO_OFFSET_REMOVAL_VAL_
RD
R/W
0h
Read the offset value applied in auto offset correction mode for
a specific channel number as defined in register 7, bits 15-11
13.1.2.1.8 Register 11 (address = Bh)
Figure 123. Register 11
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
EN_DITHER
R/W-0h
10
0
R/W-0h
9
0
R/W-0h
8
0
R/W-0h
7
0
R/W-0h
6
0
R/W-0h
5
0
R/W-0h
4
0
R/W-0h
3
0
R/W-0h
2
0
R/W-0h
1
0
R/W-0h
0
0
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 23. Register 11 Field Descriptions
Bit
15-12
11
10-0
100
Field
Type
Reset
Description
0
R/W
0h
Must write 0
EN_DITHER
R/W
0h
Dither can be used to remove higher-order harmonics.
0 = Dither disabled
1 = Dither enable
Note: Enabling the dither converts higher-order harmonics power
in noise. Thus, enabling this mode removes harmonics but
degrades SNR.
0
R/W
0h
Must write 0
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13.1.2.1.9 Register 13 (address = Dh)
Figure 124. Register 13
15
14
7
6
13
GAIN_CH1
R/W-0h
12
5
4
11
3
10
0
R/W-0h
9
2
1
8
OFFSET_CH1
R/W-0h
0
OFFSET_CH1
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 24. Register 13 Field Descriptions
Bit
Field
Type
Reset
Description
GAIN_CH1
R/W
0h
When the DIG_GAIN_EN bit (register 3, bit 12) is set to 1, then
the digital gain value for channel 1 can be obtained with this
register. For an N value (decimal equivalent of binary) written to
these bits, set the digital gain to N × 0.2 dB.
10
0
R/W
0h
Must write 0
9-0
OFFSET_CH1
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 1 can be obtained with this 10bit register. The offset value is in twos complement format. Write
the same offset value in register 14, bits 9-0.
15-11
13.1.2.1.10 Register 14 (address = Eh)
Figure 125. Register 14
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
7
6
5
4
3
2
1
8
OFFSET_CH1
R/W-0h
0
OFFSET_CH1
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 25. Register 14 Field Descriptions
Bit
15-10
9-0
Field
Type
Reset
Description
0
R/W
0h
Must write 0
OFFSET_CH1
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 1 can be obtained with this 10bit register. The offset value is in twos complement format. Write
the same offset value in register 13, bits 9-0.
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13.1.2.1.11 Register 15 (address = Fh)
Figure 126. Register 15
15
14
7
13
GAIN_CH2
R/W-0h
12
5
4
6
11
3
10
0
R/W-0h
9
2
1
8
OFFSET_CH2
R/W-0h
0
OFFSET_CH2
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 26. Register 15 Field Descriptions
Bit
Field
Type
Reset
Description
GAIN_CH2
R/W
0h
When the DIG_GAIN_EN bit (register 3, bit 12) is set to 1, then
the digital gain value for channel 2 can be obtained with this
register. For an N value (decimal equivalent of binary) written to
these bits, set the digital gain to N × 0.2 dB.
10
0
R/W
0h
Must write 0
9-0
OFFSET_CH2
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 2 can be obtained with this 10bit register. The offset value is in twos complement format. Write
the same offset value in register 16, bits 9-0.
15-11
13.1.2.1.12 Register 16 (address = 10h)
Figure 127. Register 16
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
7
6
5
4
3
2
1
8
OFFSET_CH2
R/W-0h
0
OFFSET_CH2
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 27. Register 16 Field Descriptions
Bit
15-10
9-0
102
Field
Type
Reset
Description
0
R/W
0h
Must write 0
OFFSET_CH2
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 2 can be obtained with this 10bit register. The offset value is in twos complement format. Write
the same offset value in register 15, bits 9-0.
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13.1.2.1.13 Register 17 (address = 11h)
Figure 128. Register 17
15
14
7
6
13
GAIN_CH3
R/W-0h
12
5
4
11
3
10
0
R/W-0h
9
2
1
8
OFFSET_CH3
R/W-0h
0
OFFSET_CH3
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 28. Register 17 Field Descriptions
Bit
Field
Type
Reset
Description
GAIN_CH3
R/W
0h
When the DIG_GAIN_EN bit (register 3, bit 12) is set to 1, then
the digital gain value for channel 3 can be obtained with this
register. For an N value (decimal equivalent of binary) written to
these bits, set the digital gain to N × 0.2 dB.
10
0
R/W
0h
Must write 0
9-0
OFFSET_CH3
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 3 can be obtained with this 10bit register. The offset value is in twos complement format. Write
the same offset value in register 18, bits 9-0.
15-11
13.1.2.1.14 Register 18 (address = 12h)
Figure 129. Register 18
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
7
6
5
4
3
2
1
8
OFFSET_CH3
R/W-0h
0
OFFSET_CH3
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 29. Register 18 Field Descriptions
Bit
15-10
9-0
Field
Type
Reset
Description
0
R/W
0h
Must write 0
OFFSET_CH3
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 3 can be obtained with this 10bit register. The offset value is in twos complement format. Write
the same offset value in register 19, bits 9-0.
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13.1.2.1.15 Register 19 (address = 13h)
Figure 130. Register 19
15
14
7
13
GAIN_CH4
R/W-0h
12
5
4
6
11
3
10
0
R/W-0h
9
2
1
8
OFFSET_CH4
R/W-0h
0
OFFSET_CH4
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 30. Register 19 Field Descriptions
Bit
Field
Type
Reset
Description
GAIN_CH4
R/W
0h
When the DIG_GAIN_EN bit (register 3, bit 12) is set to 1, then
the digital gain value for channel 4 can be obtained with this
register. For an N value (decimal equivalent of binary) written to
these bits, set the digital gain to N × 0.2 dB.
10
0
R/W
0h
Must write 0
9-0
OFFSET_CH4
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 4 can be obtained with this 10bit register. The offset value is in twos complement format. Write
the same offset value in register 20, bits 9-0.
15-11
13.1.2.1.16 Register 20 (address = 14h)
Figure 131. Register 20
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
7
6
5
4
3
2
1
8
OFFSET_CH4
R/W-0h
0
OFFSET_CH4
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 31. Register 20 Field Descriptions
Bit
15-10
9-0
104
Field
Type
Reset
Description
0
R/W
0h
Must write 0
OFFSET_CH4
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 4 can be obtained with this 10bit register. The offset value is in twos complement format. Write
the same offset value in register 19, bits 9-0.
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13.1.2.1.17 Register 21 (address = 15h)
Figure 132. Register 21
15
PAT_PRBS_
LVDS1
R/W-0h
14
PAT_PRBS_
LVDS2
R/W-0h
13
PAT_PRBS_
LVDS3
R/W-0h
12
PAT_PRBS_
LVDS4
R/W-0h
11
7
6
5
HPF_ROUND_
EN
R/W-0h
4
3
PAT_LVDS2[2:0]
R/W-0h
10
9
8
PAT_
LVDS2[2:0]
R/W-0h
1
0
DIG_HPF_EN_
CH1-4
R/W-0h
PAT_LVDS1[2:0]
R/W-0h
2
HPF_CORNER_CH1-4[3:0]
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 32. Register 21 Field Descriptions
Bit
Field
Type
Reset
Description
15
PAT_PRBS_LVDS1
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the PRBS pattern on LVDS output 1 can be enabled with
this bit; see the Test Patterns section for further details.
14
PAT_PRBS_LVDS2
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the PRBS pattern on LVDS output 2 can be enabled with
this bit; see the Test Patterns section for further details.
13
PAT_PRBS_LVDS3
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the PRBS pattern on LVDS output 3 can be enabled with
this bit; see the Test Patterns section for further details.
12
PAT_PRBS_LVDS4
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the PRBS pattern on LVDS output 4 can be enabled with
this bit; see the Test Patterns section for further details.
11-9
PAT_LVDS1[2:0]
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the different pattern on LVDS output 1 can be programmed
with these bits; see Table 33 for bit descriptions.
8-6
PAT_LVDS2[2:0]
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the different pattern on LVDS output 2 can be programmed
with these bits; see Table 33 for bit descriptions.
5
HPF_ROUND_EN
R/W
0h
0 = Rounding in the ADC HPF is disabled. HPF output is
truncated to be mapped to the ADC resolution bits.
1 = HPF output is mapped to the ADC resolution bits by the
round-off operation.
HPF_CORNER_CH1-4[3:0]
R/W
0h
When the DIG_HPF_EN_CH1-4 bit is set to 1, then the digital
HPF characteristic for the corresponding channels can be
programmed by setting the value of k with these bits.
Characteristics of a digital high-pass transfer function applied to
the output data for a given value of k is defined by:
4-1
Y(n) =
2k
2k + 1
[x(n) - x(n - 1) + y(n - 1)]
Note that the value of k can be from 2 to 10 (0010b to 1010b);
see the Digital HPF section for further details.
0
DIG_HPF_EN_CH1-4
R/W
0h
0 = Digital HPF disabled for channels 1 to 4 (default)
1 = Enables digital HPF for channels 1 to 4
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Table 33. Pattern Mode Bit Description
PAT_MODES[2:0]
DESCRIPTION
000
Normal operation
001
Sync (half frame 0, half frame 1)
010
Alternate 0s and 1s
011
Custom pattern
100
All 1s
101
Toggle mode
110
All 0s
111
Ramp pattern
13.1.2.1.18 Register 23 (address = 17h)
Figure 133. Register 23
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
0
R/W-0h
8
0
R/W-0h
7
6
PAT_LVDS3[2:0]
R/W-0h
5
4
3
PAT_LVDS4[2:0]
R/W-0h
2
1
0
R/W-0h
0
0
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 34. Register 23 Field Descriptions
Bit
106
Field
Type
Reset
Description
15-8
0
R/W
0h
Must write 0
7-5
PAT_LVDS3[2:0]
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the different pattern on LVDS output 3 can be programmed
with these bits; see Table 33 for bit descriptions.
4-2
PAT_LVDS4[2:0]
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the different pattern on LVDS output 4 can be programmed
with these bits; see Table 33 for bit descriptions.
1-0
0
R/W
0h
Must write 0
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13.1.2.1.19 Register 24 (address = 18h)
Figure 134. Register 24
15
PDN_DIG_
CH4
R/W-0h
14
PDN_DIG_
CH3
R/W-0h
13
PDN_DIG_
CH2
R/W-0h
12
PDN_DIG_
CH1
R/W-0h
11
10
9
8
PDN_LVDS4
PDN_LVDS3
PDN_LVDS2
PDN_LVDS1
R/W-0h
R/W-0h
R/W-0h
R/W-0h
7
PDN_ANA_
CH4
R/W-0h
6
PDN_ANA_
CH3
R/W-0h
5
PDN_ANA_
CH2
R/W-0h
4
PDN_ANA_
CH1
R/W-0h
3
INVERT_
LVDS4
R/W-0h
2
INVERT_
LVDS3
R/W-0h
1
INVERT_
LVDS2
R/W-0h
0
INVERT_
LVDS1
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 35. Register 24 Field Descriptions
Bit
Field
Type
Reset
Description
15
PDN_DIG_CH4
R/W
0h
0 = Normal operation (default)
1 = Powers down the digital block for channel 4
14
PDN_DIG_CH3
R/W
0h
0 = Normal operation (default)
1 = Powers down the digital block for channel 3
13
PDN_DIG_CH2
R/W
0h
0 = Normal operation (default)
1 = Powers down the digital block for channel2
12
PDN_DIG_CH1
R/W
0h
0 = Normal operation (default)
1 = Powers down the digital block for channel 1
11
PDN_LVDS4
R/W
0h
0 = Normal operation (default)
1 = Powers down LVDS output line 4
10
PDN_LVDS3
R/W
0h
0 = Normal operation (default)
1 = Powers down LVDS output line 3
9
PDN_LVDS2
R/W
0h
0 = Normal operation (default)
1 = Powers down LVDS output line 2
8
PDN_LVDS1
R/W
0h
0 = Normal operation (default)
1 = Powers down LVDS output line 1
7
PDN_ANA_CH4
R/W
0h
0 = Normal operation (default)
1 = Powers down the analog block for channel 4
6
PDN_ANA_CH3
R/W
0h
0 = Normal operation (default)
1 = Powers down the analog block for channel 3
5
PDN_ANA_CH2
R/W
0h
0 = Normal operation (default)
1 = Powers down the analog block for channel 2
4
PDN_ANA_CH1
R/W
0h
0 = Normal operation (default)
1 = Powers down the analog block for channel 1
3
INVERT_LVDS4
R/W
0h
0 = Normal operation (default)
1 = Inverts digital output data sent on LVDS output line 4
2
INVERT_LVDS3
R/W
0h
0 = Normal operation (default)
1 = Inverts digital output data sent on LVDS output line 3
1
INVERT_LVDS2
R/W
0h
0 = Normal operation (default)
1 = Inverts digital output data sent on LVDS output line 2
0
INVERT_LVDS1
R/W
0h
0 = Normal operation (default)
1 = Inverts digital output data sent on LVDS output line 1
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13.1.2.1.20 Register 25 (address = 19h)
Figure 135. Register 25
15
14
7
13
GAIN_CH5
R/W-0h
12
5
4
6
11
3
10
0
R/W-0h
9
2
1
8
OFFSET_CH5
R/W-0h
0
OFFSET_CH5
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 36. Register 25 Field Descriptions
Bit
Field
Type
Reset
Description
GAIN_CH5
R/W
0h
When the DIG_GAIN_EN bit (register 3, bit 12) is set to 1, then
the digital gain value for channel 5 can be obtained with this
register. For an N value (decimal equivalent of binary) written to
these bits, set the digital gain to N × 0.2 dB.
10
0
R/W
0h
Must write 0
9-0
OFFSET_CH5
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 5 can be obtained with this 10bit register. The offset value is in twos complement format. Write
the same offset value in register 26, bits 9-0.
15-11
13.1.2.1.21 Register 26 (address = 1Ah)
Figure 136. Register 26
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
7
6
5
4
3
2
1
8
OFFSET_CH5
R/W-0h
0
OFFSET_CH5
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 37. Register 26 Field Descriptions
Bit
15-10
9-0
108
Field
Type
Reset
Description
0
R/W
0h
Must write 0
OFFSET_CH5
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 5 can be obtained with this 10bit register. The offset value is in twos complement format. Write
the same offset value in register 25, bits 9-0.
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13.1.2.1.22 Register 27 (address = 1Bh)
Figure 137. Register 27
15
14
7
6
13
GAIN_CH6
R/W-0h
12
5
4
11
3
10
0
R/W-0h
9
2
1
8
OFFSET_CH6
R/W-0h
0
OFFSET_CH6
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 38. Register 27 Field Descriptions
Bit
Field
Type
Reset
Description
GAIN_CH6
R/W
0h
When the DIG_GAIN_EN bit (register 3, bit 12) is set to 1, then
the digital gain value for channel 6 can be obtained with this
register. For an N value (decimal equivalent of binary) written to
these bits, set the digital gain to N × 0.2 dB.
10
0
R/W
0h
Must write 0
9-0
OFFSET_CH6
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 6 can be obtained with this 10bit register. The offset value is in twos complement format. Write
the same offset value in register 28, bits 9-0.
15-11
13.1.2.1.23 Register 28 (address = 1Ch)
Figure 138. Register 28
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
7
6
5
4
3
2
1
8
OFFSET_CH6
R/W-0h
0
OFFSET_CH6
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 39. Register 28 Field Descriptions
Bit
15-10
9-0
Field
Type
Reset
Description
0
R/W
0h
Must write 0
OFFSET_CH6
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 6 can be obtained with this 10bit register. The offset value is in twos complement format. Write
the same offset value in register 27, bits 9-0.
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13.1.2.1.24 Register 29 (address = 1Dh)
Figure 139. Register 29
15
14
7
13
GAIN_CH7
R/W-0h
12
5
4
6
11
3
10
0
R/W-0h
9
2
1
8
OFFSET_CH7
R/W-0h
0
OFFSET_CH7
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 40. Register 29 Field Descriptions
Bit
Field
Type
Reset
Description
GAIN_CH7
R/W
0h
When the DIG_GAIN_EN bit (register 3, bit 12) is set to 1, then
the digital gain value for channel 7 can be obtained with this
register. For an N value (decimal equivalent of binary) written to
these bits, set the digital gain to N × 0.2 dB.
10
0
R/W
0h
Must write 0
9-0
OFFSET_CH7
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 7 can be obtained with this 10bit register. The offset value is in twos complement format. Write
the same offset value in register 30, bits 9-0.
15-11
13.1.2.1.25 Register 30 (address = 1Eh)
Figure 140. Register 30
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
7
6
5
4
3
2
1
8
OFFSET_CH7
R/W-0h
0
OFFSET_CH7
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 41. Register 30 Field Descriptions
Bit
15-10
9-0
110
Field
Type
Reset
Description
0
R/W
0h
Must write 0
OFFSET_CH7
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 7 can be obtained with this 10bit register. The offset value is in twos complement format. Write
the same offset value in register 29, bits 9-0.
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13.1.2.1.26 Register 31 (address = 1Fh)
Figure 141. Register 31
15
14
7
6
13
GAIN_CH8
R/W-0h
12
5
4
11
3
10
0
R/W-0h
9
2
1
8
OFFSET_CH8
R/W-0h
0
OFFSET_CH8
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 42. Register 31 Field Descriptions
Bit
Field
Type
Reset
Description
GAIN_CH8
R/W
0h
When the DIG_GAIN_EN bit (register 3, bit 12) is set to 1, then
the digital gain value for channel 8 can be obtained with this
register. For an N value (decimal equivalent of binary) written to
these bits, set the digital gain to N × 0.2 dB.
10
0
R/W
0h
Must write 0
9-0
OFFSET_CH8
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 8 can be obtained with this 10bit register. The offset value is in twos complement format. Write
the same offset value in register 32, bits 9-0.
15-11
13.1.2.1.27 Register 32 (address = 20h)
Figure 142. Register 32
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
7
6
5
4
3
2
1
8
OFFSET_CH8
R/W-0h
0
OFFSET_CH8
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 43. Register 32 Field Descriptions
Bit
15-10
9-0
Field
Type
Reset
Description
0
R/W
0h
Must write 0
OFFSET_CH8
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 16 can be obtained with this
10-bit register. The offset value is in twos complement format.
Write the same offset value in register 31, bits 9-0.
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13.1.2.1.28 Register 33 (address = 21h)
Figure 143. Register 33
15
PAT_PRBS_
LVDS5
R/W-0h
14
PAT_PRBS_
LVDS6
R/W-0h
13
PAT_PRBS_
LVDS7
R/W-0h
12
PAT_PRBS_
LVDS8
R/W-0h
11
7
6
5
4
3
10
9
8
PAT_
LVDS6[2:0]
R/W-0h
1
0
DIG_HPF_EN_
CH5-8
R/W-0h
PAT_LVDS5[2:0]
R/W-0h
2
PAT_LVDS6[2:0]
0
HPF_CORNER_CH5-8[3:0]
R/W-0h
R/W-0h
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 44. Register 33 Field Descriptions
Bit
Field
Type
Reset
Description
15
PAT_PRBS_LVDS5
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the PRBS pattern on LVDS output 5 can be enabled with
this bit; see the Test Patterns section for further details.
14
PAT_PRBS_LVDS6
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the PRBS pattern on LVDS output 6 can be enabled with
this bit; see the Test Patterns section for further details.
13
PAT_PRBS_LVDS7
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the PRBS pattern on LVDS output 7 can be enabled with
this bit; see the Test Patterns section for further details.
12
PAT_PRBS_LVDS8
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the PRBS pattern on LVDS output 8 can be enabled with
this bit; see the Test Patterns section for further details.
11-9
PAT_LVDS5[2:0]
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the different pattern on LVDS output 5 can be programmed
with these bits; see Table 33 for bit descriptions.
8-6
PAT_LVDS6[2:0]
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the different pattern on LVDS output 6 can be programmed
with these bits; see Table 33 for bit descriptions.
0
R/W
0h
Must write 0
HPF_CORNER_CH5-8[3:0]
R/W
0h
When the DIG_HPF_EN_CH5-8 bit is set to 1, then the digital
HPF characteristic for the corresponding channels can be
programmed by setting the value of k with these bits.
Characteristics of a digital high-pass transfer function applied to
the output data for a given value of k is defined by:
5
4-1
Y(n) =
2k
2k + 1
[x(n) - x(n - 1) + y(n - 1)]
Note that the value of k can be from 2 to 10 (0010b to 1010b);
see the Digital HPF section for further details.
0
112
DIG_HPF_EN_CH5-8
R/W
0h
0 = Digital HPF disabled for channels 5 to 8 (default)
1 = Enables digital HPF for channels 5 to 8
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13.1.2.1.29 Register 35 (address = 23h)
Figure 144. Register 35
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
0
R/W-0h
8
0
R/W-0h
7
6
PAT_LVDS7[2:0]
R/W-0h
5
4
3
PAT_LVDS8[2:0]
R/W-0h
2
1
0
R/W-0h
0
0
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 45. Register 35 Field Descriptions
Bit
Field
Type
Reset
Description
15-8
0
R/W
0h
Must write 0
7-5
PAT_LVDS7[2:0]
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the different pattern on LVDS output 7 can be programmed
with these bits; see Table 33 for bit descriptions.
4-2
PAT_LVDS8[2:0]
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the different pattern on LVDS output 8 can be programmed
with these bits; see Table 33 for bit descriptions.
1-0
0
R/W
0h
Must write 0
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13.1.2.1.30 Register 36 (address = 24h)
Figure 145. Register 36
15
PDN_DIG_
CH8
R/W-0h
14
PDN_DIG_
CH7
R/W-0h
13
PDN_DIG_
CH6
R/W-0h
12
PDN_DIG_
CH5
R/W-0h
11
10
9
8
PDN_LVDS8
PDN_LVDS7
PDN_LVDS6
PDN_LVDS5
R/W-0h
R/W-0h
R/W-0h
R/W-0h
7
PDN_ANA_
CH8
R/W-0h
6
PDN_ANA_
CH7
R/W-0h
5
PDN_ANA_
CH6
R/W-0h
4
PDN_ANA_
CH5
R/W-0h
3
INVERT_
CH8
R/W-0h
2
INVERT_
CH7
R/W-0h
1
INVERT_
CH6
R/W-0h
0
INVERT_
CH5
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 46. Register 36 Field Descriptions
114
Bit
Field
Type
Reset
Description
15
PDN_DIG_CH8
R/W
0h
0 = Normal operation (default)
1 = Powers down the digital block for channel 8
14
PDN_DIG_CH7
R/W
0h
0 = Normal operation (default)
1 = Powers down the digital block for channel 7
13
PDN_DIG_CH6
R/W
0h
0 = Normal operation (default)
1 = Powers down the digital block for channel 6
12
PDN_DIG_CH5
R/W
0h
0 = Normal operation (default)
1 = Powers down the digital block for channel 5
11
PDN_LVDS8
R/W
0h
0 = Normal operation (default)
1 = Powers down LVDS output line 8
10
PDN_LVDS7
R/W
0h
0 = Normal operation (default)
1 = Powers down LVDS output line 7
9
PDN_LVDS6
R/W
0h
0 = Normal operation (default)
1 = Powers down LVDS output line 6
8
PDN_LVDS5
R/W
0h
0 = Normal operation (default)
1 = Powers down LVDS output line 5
7
PDN_ANA_CH8
R/W
0h
0 = Normal operation (default)
1 = Powers down the analog block for channel 8
6
PDN_ANA_CH7
R/W
0h
0 = Normal operation (default)
1 = Powers down the analog block for channel 7
5
PDN_ANA_CH6
R/W
0h
0 = Normal operation (default)
1 = Powers down the analog block for channel 6
4
PDN_ANA_CH5
R/W
0h
0 = Normal operation (default)
1 = Powers down the analog block for channel 5
3
INVERT_CH8
R/W
0h
0 = Normal operation (default)
1 = Inverts digital output data sent on LVDS output line 8
2
INVERT_CH7
R/W
0h
0 = Normal operation (default)
1 = Inverts digital output data sent on LVDS output line 7
1
INVERT_CH6
R/W
0h
0 = Normal operation (default)
1 = Inverts digital output data sent on LVDS output line 6
0
INVERT_CH5
R/W
0h
0 = Normal operation (default)
1 = Inverts digital output data sent on LVDS output line 5
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13.1.2.1.31 Register 37 (address = 25h)
Figure 146. Register 37
15
14
7
6
13
GAIN_CH9
R/W-0h
12
5
4
11
3
10
0
R/W-0h
9
2
1
8
OFFSET_CH9
R/W-0h
0
OFFSET_CH9
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 47. Register 37 Field Descriptions
Bit
Field
Type
Reset
Description
GAIN_CH9
R/W
0h
When the DIG_GAIN_EN bit (register 3, bit 12) is set to 1, then
the digital gain value for channel 9 can be obtained with this
register. For an N value (decimal equivalent of binary) written to
these bits, set the digital gain to N × 0.2 dB.
10
0
R/W
0h
Must write 0
9-0
OFFSET_CH9
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 9 can be obtained with this 10bit register. The offset value is in twos complement format. Write
the same offset value in register 38, bits 9-0.
15-11
13.1.2.1.32 Register 38 (address = 26h)
Figure 147. Register 38
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
7
6
5
4
3
2
1
8
OFFSET_CH9
R/W-0h
0
OFFSET_CH9
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 48. Register 38 Field Descriptions
Bit
15-10
9-0
Field
Type
Reset
Description
0
R/W
0h
Must write 0
OFFSET_CH9
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 9 can be obtained with this 10bit register. The offset value is in twos complement format. Write
the same offset value in register 37, bits 9-0.
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13.1.2.1.33 Register 39 (address = 27h)
Figure 148. Register 39
15
14
7
13
GAIN_CH10
R/W-0h
12
5
4
6
11
3
10
0
R/W-0h
9
2
1
8
OFFSET_CH10
R/W-0h
0
OFFSET_CH10
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 49. Register 39 Field Descriptions
Bit
Field
Type
Reset
Description
GAIN_CH10
R/W
0h
When the DIG_GAIN_EN bit (register 3, bit 12) is set to 1, then
the digital gain value for channel 10 can be obtained with this
register. For an N value (decimal equivalent of binary) written to
these bits, set the digital gain to N × 0.2 dB.
10
0
R/W
0h
Must write 0
9-0
OFFSET_CH10
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 10 can be obtained with this
10-bit register. The offset value is in twos complement format.
Write the same offset value in register 40, bits 9-0.
15-11
13.1.2.1.34 Register 40 (address = 28h)
Figure 149. Register 40
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
7
6
5
4
3
2
1
8
OFFSET_CH10
R/W-0h
0
OFFSET_CH10
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 50. Register 40 Field Descriptions
Bit
15-10
9-0
116
Field
Type
Reset
Description
0
R/W
0h
Must write 0
OFFSET_CH10
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 10 can be obtained with this
10-bit register. The offset value is in twos complement format.
Write the same offset value in register 39, bits 9-0.
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13.1.2.1.35 Register 41 (address = 29h)
Figure 150. Register 41
15
14
7
6
13
GAIN_CH11
R/W-0h
12
5
4
11
3
10
0
R/W-0h
9
2
1
8
OFFSET_CH11
R/W-0h
0
OFFSET_CH11
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 51. Register 41 Field Descriptions
Bit
Field
Type
Reset
Description
GAIN_CH11
R/W
0h
When the DIG_GAIN_EN bit (register 3, bit 12) is set to 1, then
the digital gain value for channel 11 can be obtained with this
register. For an N value (decimal equivalent of binary) written to
these bits, set the digital gain to N × 0.2 dB.
10
0
R/W
0h
Must write 0
9-0
OFFSET_CH11
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 11 can be obtained with this
10-bit register. The offset value is in twos complement format.
Write the same offset value in register 42, bits 9-0.
15-11
13.1.2.1.36 Register 42 (address = 2Ah)
Figure 151. Register 42
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
7
6
5
4
3
2
1
8
OFFSET_CH11
R/W-0h
0
OFFSET_CH11
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 52. Register 42 Field Descriptions
Bit
15-10
9-0
Field
Type
Reset
Description
0
R/W
0h
Must write 0
OFFSET_CH11
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 11 can be obtained with this
10-bit register. The offset value is in twos complement format.
Write the same offset value in register 41, bits 9-0.
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13.1.2.1.37 Register 43 (address = 2Bh)
Figure 152. Register 43
15
14
7
13
GAIN_CH12
R/W-0h
12
5
4
6
11
3
10
0
R/W-0h
9
2
1
8
OFFSET_CH12
R/W-0h
0
OFFSET_CH12
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 53. Register 43 Field Descriptions
Bit
Field
Type
Reset
Description
GAIN_CH12
R/W
0h
When the DIG_GAIN_EN bit (register 3, bit 12) is set to 1, then
the digital gain value for channel 12 can be obtained with this
register. For an N value (decimal equivalent of binary) written to
these bits, set the digital gain to N × 0.2 dB.
10
0
R/W
0h
Must write 0
9-0
OFFSET_CH12
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 12 can be obtained with this
10-bit register. The offset value is in twos complement format.
Write the same offset value in register 44, bits 9-0.
15-11
13.1.2.1.38 Register 44 (address = 2Ch)
Figure 153. Register 44
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
7
6
5
4
3
2
1
8
OFFSET_CH12
R/W-0h
0
OFFSET_CH12
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 54. Register 44 Field Descriptions
Bit
15-10
9-0
118
Field
Type
Reset
Description
0
R/W
0h
Must write 0
OFFSET_CH12
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 12 can be obtained with this
10-bit register. The offset value is in twos complement format.
Write the same offset value in register 43, bits 9-0.
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13.1.2.1.39 Register 45 (address = 2Dh)
Figure 154. Register 45
15
PAT_PRBS_
LVDS9
R/W-0h
14
PAT_PRBS_
LVDS10
R/W-0h
13
PAT_PRBS_
LVDS11
R/W-0h
12
PAT_PRBS_
LVDS12
R/W-0h
11
10
7
6
5
4
3
PAT_LVDS10[2:0]
0
HPF_CORNER_CH9-12[3:0]
R/W-0h
R/W-0h
R/W-0h
9
8
PAT_
LVDS10[2:0]
R/W-0h
1
0
DIG_HPF_EN_
CH9-12
R/W-0h
PAT_LVDS9[2:0]
R/W-0h
2
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 55. Register 45 Field Descriptions
Bit
Field
Type
Reset
Description
15
PAT_PRBS_LVDS9
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the PRBS pattern on LVDS output 9 can be enabled with
this bit; see the Test Patterns section for further details.
14
PAT_PRBS_LVDS10
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the PRBS pattern on LVDS output 10 can be enabled with
this bit; see the Test Patterns section for further details.
13
PAT_PRBS_LVDS11
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the PRBS pattern on LVDS output 11 can be enabled with
this bit; see the Test Patterns section for further details.
12
PAT_PRBS_LVDS12
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the PRBS pattern on LVDS output 12 can be enabled with
this bit; see the Test Patterns section for further details.
11-9
PAT_LVDS9[2:0]
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the different pattern on LVDS output 9 can be programmed
with these bits; see Table 33 for bit descriptions.
8-6
PAT_LVDS10[2:0]
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the different pattern on LVDS output 10 can be
programmed with these bits; see Table 33 for bit descriptions.
0
R/W
0h
Must write 0
HPF_CORNER_CH9-12[3:0]
R/W
0h
When the DIG_HPF_EN_CH9-12 bit is set to 1, then the digital
HPF characteristic for the corresponding channels can be
programmed by setting the value of k with these bits.
Characteristics of a digital high-pass transfer function applied to
the output data for a given value of k is defined by:
5
4-1
Y(n) =
2k
2k + 1
[x(n) - x(n - 1) + y(n - 1)]
Note that the value of k can be from 2 to 10 (0010b to 1010b);
see the Digital HPF section for further details.
0
DIG_HPF_EN_CH9-12
R/W
0h
0 = Digital HPF disabled for channels 9 to 12 (default)
1 = Enables digital HPF for channels 9 to 12
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13.1.2.1.40 Register 47 (address = 2Fh)
Figure 155. Register 47
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
0
R/W-0h
8
0
R/W-0h
7
6
PAT_LVDS11[2:0]
R/W-0h
5
4
3
PAT_LVDS12[2:0]
R/W-0h
2
1
0
R/W-0h
0
0
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 56. Register 47 Field Descriptions
Bit
15-18
120
Field
Type
Reset
Description
0
R/W
0h
Must write 0
7-5
PAT_LVDS11[2:0]
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the different pattern on LVDS output 11 can be
programmed with these bits; see Table 33 for bit descriptions.
4-2
PAT_LVDS12[2:0]
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the different pattern on LVDS output 12 can be
programmed with these bits; see Table 33 for bit descriptions.
1-0
0
R/W
0h
Must write 0
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13.1.2.1.41 Register 48 (address = 30h)
Figure 156. Register 48
15
PDN_DIG_
CH12
R/W-0h
14
PDN_DIG_
CH11
R/W-0h
13
PDN_DIG_
CH10
R/W-0h
12
PDN_DIG_
CH9
R/W-0h
11
10
9
8
PDN_LVDS12
PDN_LVDS11
PDN_LVDS10
PDN_LVDS9
R/W-0h
R/W-0h
R/W-0h
R/W-0h
7
PDN_ANA_
CH12
R/W-0h
6
PDN_ANA_
CH11
R/W-0h
5
PDN_ANA_
CH10
R/W-0h
4
PDN_ANA_
CH9
R/W-0h
3
INVERT_
CH12
R/W-0h
2
INVERT_
CH11
R/W-0h
1
INVERT_
CH10
R/W-0h
0
INVERT_
CH9
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 57. Register 48 Field Descriptions
Bit
Field
Type
Reset
Description
15
PDN_DIG_CH12
R/W
0h
0 = Normal operation (default)
1 = Powers down the digital block for channel 12
14
PDN_DIG_CH11
R/W
0h
0 = Normal operation (default)
1 = Powers down the digital block for channel 11
13
PDN_DIG_CH10
R/W
0h
0 = Normal operation (default)
1 = Powers down the digital block for channel 10
12
PDN_DIG_CH9
R/W
0h
0 = Normal operation (default)
1 = Powers down the digital block for channel 9
11
PDN_LVDS12
R/W
0h
0 = Normal operation (default)
1 = Powers down LVDS output line 12
10
PDN_LVDS11
R/W
0h
0 = Normal operation (default)
1 = Powers down LVDS output line 11
9
PDN_LVDS10
R/W
0h
0 = Normal operation (default)
1 = Powers down LVDS output line 10
8
PDN_LVDS9
R/W
0h
0 = Normal operation (default)
1 = Powers down LVDS output line 9
7
PDN_ANA_CH12
R/W
0h
0 = Normal operation (default)
1 = Powers down the analog block for channel 12
6
PDN_ANA_CH11
R/W
0h
0 = Normal operation (default)
1 = Powers down the analog block for channel 11
5
PDN_ANA_CH10
R/W
0h
0 = Normal operation (default)
1 = Powers down the analog block for channel 10
4
PDN_ANA_CH9
R/W
0h
0 = Normal operation (default)
1 = Powers down the analog block for channel 9
3
INVERT_CH12
R/W
0h
0 = Normal operation (default)
1 = Inverts digital output data sent on LVDS output line 12
2
INVERT_CH11
R/W
0h
0 = Normal operation (default)
1 = Inverts digital output data sent on LVDS output line 11
1
INVERT_CH10
R/W
0h
0 = Normal operation (default)
1 = Inverts digital output data sent on LVDS output line 10
0
INVERT_CH9
R/W
0h
0 = Normal operation (default)
1 = Inverts digital output data sent on LVDS output line 9
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13.1.2.1.42 Register 49 (address = 31h)
Figure 157. Register 49
15
14
7
13
GAIN_CH13
R/W-0h
12
5
4
6
11
3
10
0
R/W-0h
9
2
1
8
OFFSET_CH13
R/W-0h
0
OFFSET_CH13
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 58. Register 49 Field Descriptions
Bit
Field
Type
Reset
Description
GAIN_CH13
R/W
0h
When the DIG_GAIN_EN bit (register 3, bit 12) is set to 1, then
the digital gain value for channel 13 can be obtained with this
register. For an N value (decimal equivalent of binary) written to
these bits, set the digital gain to N × 0.2 dB.
10
0
R/W
0h
Must write 0
9-0
OFFSET_CH13
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 13 can be obtained with this
10-bit register. The offset value is in twos complement format.
Write the same offset value in register 50, bits 9-0.
15-11
13.1.2.1.43 Register 50 (address = 32h)
Figure 158. Register 50
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
7
6
5
4
3
2
1
8
OFFSET_CH13
R/W-0h
0
OFFSET_CH13
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 59. Register 50 Field Descriptions
Bit
15-10
9-0
122
Field
Type
Reset
Description
0
R/W
0h
Must write 0
OFFSET_CH13
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 13 can be obtained with this
10-bit register. The offset value is in twos complement format.
Write the same offset value in register 49, bits 9-0.
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13.1.2.1.44 Register 51 (address = 33h)
Figure 159. Register 51
15
14
7
6
13
GAIN_CH14
R/W-0h
12
5
4
11
3
10
0
R/W-0h
9
2
1
8
OFFSET_CH14
R/W-0h
0
OFFSET_CH14
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 60. Register 51 Field Descriptions
Bit
Field
Type
Reset
Description
GAIN_CH14
R/W
0h
When the DIG_GAIN_EN bit (register 3, bit 12) is set to 1, then
the digital gain value for channel 14 can be obtained with this
register. For an N value (decimal equivalent of binary) written to
these bits, set the digital gain to N × 0.2 dB.
10
0
R/W
0h
Must write 0
9-0
OFFSET_CH14
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 14 can be obtained with this
10-bit register. The offset value is in twos complement format.
Write the same offset value in register 52, bits 9-0.
15-11
13.1.2.1.45 Register 52 (address = 34h)
Figure 160. Register 52
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
7
6
5
4
3
2
1
8
OFFSET_CH14
R/W-0h
0
OFFSET_CH14
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 61. Register 52 Field Descriptions
Bit
15-10
9-0
Field
Type
Reset
Description
0
R/W
0h
Must write 0
OFFSET_CH14
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 14 can be obtained with this
10-bit register. The offset value is in twos complement format.
Write the same offset value in register 51, bits 9-0.
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13.1.2.1.46 Register 53 (address = 35h)
Figure 161. Register 53
15
14
7
13
GAIN_CH15
R/W-0h
12
5
4
6
11
3
10
0
R/W-0h
9
2
1
8
OFFSET_CH15
R/W-0h
0
OFFSET_CH15
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 62. Register 53 Field Descriptions
Bit
Field
Type
Reset
Description
GAIN_CH15
R/W
0h
When the DIG_GAIN_EN bit (register 3, bit 12) is set to 1, then
the digital gain value for channel 15 can be obtained with this
register. For an N value (decimal equivalent of binary) written to
these bits, set the digital gain to N × 0.2 dB.
10
0
R/W
0h
Must write 0
9-0
OFFSET_CH15
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 15 can be obtained with this
10-bit register. the offset value is in twos complement format.
Write the same offset value in register 54, bits 9-0.
15-11
13.1.2.1.47 Register 54 (address = 36h)
Figure 162. Register 54
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
7
6
5
4
3
2
1
8
OFFSET_CH15
R/W-0h
0
OFFSET_CH15
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 63. Register 54 Field Descriptions
Bit
15-10
9-0
124
Field
Type
Reset
Description
0
R/W
0h
Must write 0
OFFSET_CH15
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 15 can be obtained with this
10-bit register. the offset value is in twos complement format.
Write the same offset value in register 53, bits 9-0.
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13.1.2.1.48 Register 55 (address = 37h)
Figure 163. Register 55
15
14
7
6
13
GAIN_CH16
R/W-0h
12
5
4
11
3
10
0
R/W-0h
9
2
1
8
OFFSET_CH16
R/W-0h
0
OFFSET_CH16
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 64. Register 55 Field Descriptions
Bit
Field
Type
Reset
Description
GAIN_CH16
R/W
0h
When the DIG_GAIN_EN bit (register 3, bit 12) is set to 1, then
the digital gain value for channel 16 can be obtained with this
register. For an N value (decimal equivalent of binary) written to
these bits, set the digital gain to N × 0.2 dB.
10
0
R/W
0h
Must write 0
9-0
OFFSET_CH16
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 16 can be obtained with this
10-bit register. the offset value is in twos complement format.
Write the same offset value in register 56, bits 9-0.
15-11
13.1.2.1.49 Register 56 (address = 38h)
Figure 164. Register 56
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
7
6
5
4
3
2
1
8
OFFSET_CH16
R/W-0h
0
OFFSET_CH16
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 65. Register 56 Field Descriptions
Bit
15-10
9-0
Field
Type
Reset
Description
0
R/W
0h
Must write 0
OFFSET_CH16
R/W
0h
When the DIG_OFFSET_EN bit (register 3, bit 8) is set to 1,
then the offset value for channel 16 can be obtained with this
10-bit register. the offset value is in twos complement format.
Write the same offset value in register 55, bits 9-0.
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13.1.2.1.50 Register 57 (address = 39h)
Figure 165. Register 57
15
PAT_PRBS_
LVDS13
R/W-0h
14
PAT_PRBS_
LVDS14
R/W-0h
13
PAT_PRBS_
LVDS15
R/W-0h
12
PAT_PRBS_
LVDS16
R/W-0h
11
10
7
6
5
4
3
PAT_LVDS14[2:0]
0
HPF_CORNER_CH25-32[3:0]
R/W-0h
R/W-0h
R/W-0h
9
8
PAT_
LVDS14[2:0]
R/W-0h
1
0
DIG_HPF_EN_
CH25-32
R/W-0h
PAT_LVDS13[2:0]
R/W-0h
2
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 66. Register 57 Field Descriptions
Bit
Field
Type
Reset
Description
15
PAT_PRBS_LVDS13
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the PRBS pattern on LVDS output 13 can be enabled with
this bit; see the Test Patterns section for further details.
14
PAT_PRBS_LVDS14
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the PRBS pattern on LVDS output 14 can be enabled with
this bit; see the Test Patterns section for further details.
13
PAT_PRBS_LVDS15
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the PRBS pattern on LVDS output 15 can be enabled with
this bit; see the Test Patterns section for further details.
12
PAT_PRBS_LVDS16
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the PRBS pattern on LVDS output 16 can be enabled with
this bit; see the Test Patterns section for further details.
11-9
PAT_LVDS13[2:0]
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the different pattern on LVDS output 13 can be
programmed with these bits; see Table 33 for bit descriptions.
8-6
PAT_LVDS14[2:0]
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the different pattern on LVDS output 14 can be
programmed with these bits; see Table 33 for bit descriptions.
0
R/W
0h
Must write 0
HPF_CORNER_CH13-16[3:0]
R/W
0h
When the DIG_HPF_EN_CH13-16 bit is set to 1, then the digital
HPF characteristic for the corresponding channels can be
programmed by setting the value of k with these bits.
Characteristics of a digital high-pass transfer function applied to
the output data for a given value of k is defined by:
5
4-1
Y(n) =
2k
2k + 1
[x(n) - x(n - 1) + y(n - 1)]
Note that the value of k can be from 2 to 10 (0010b to 1010b);
see the Digital HPF section for further details.
0
126
DIG_HPF_EN_CH13-16
R/W
0h
0 = Digital HPF disabled for channels 13 to 16 (default)
1 = Enables digital HPF for channels 13 to 16
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13.1.2.1.51 Register 59 (address = 3Bh)
Figure 166. Register 59
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
0
R/W-0h
8
0
R/W-0h
7
6
PIN_PAT_LVDS15[2:0]
R/W-0h
5
4
3
PAT_LVDS16[2:0]
R/W-0h
2
1
0
R/W-0h
0
0
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 67. Register 59 Field Descriptions
Bit
Field
Type
Reset
Description
15-8
0
R/W
0h
Must write 0
7-5
PAT_LVDS15[2:0]
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the differentpattern on LVDS output 15 can be programmed
with these bits; see Table 33 for bit descriptions.
4-2
PAT_LVDS16[2:0]
R/W
0h
When the PAT_SELECT_IND bit (register 4, bit 8) is set to 1,
then the different pattern on LVDS output 16 can be
programmed with these bits; see Table 33 for bit descriptions.
1-0
0
R/W
0h
Must write 0
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13.1.2.1.52 Register 60 (address = 3Ch)
Figure 167. Register 60
15
PDN_DIG_
CH16
R/W-0h
14
PDN_DIG_
CH15
R/W-0h
13
PDN_DIG_
CH14
R/W-0h
12
PDN_DIG_
CH13
R/W-0h
11
10
9
8
PDN_LVDS16
PDN_LVDS15
PDN_LVDS14
PDN_LVDS13
R/W-0h
R/W-0h
R/W-0h
R/W-0h
7
PDN_ANA_
CH16
R/W-0h
6
PDN_ANA_
CH15
R/W-0h
5
PDN_ANA_
CH14
R/W-0h
4
PDN_ANA_
CH13
R/W-0h
3
INVERT_
CH16
R/W-0h
2
INVERT_
CH15
R/W-0h
1
INVERT_
CH14
R/W-0h
0
INVERT_
CH13
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 68. Register 60 Field Descriptions
128
Bit
Field
Type
Reset
Description
15
PDN_DIG_CH16
R/W
0h
0 = Normal operation (default)
1 = Powers down the digital block for channel 16
14
PDN_DIG_CH15
R/W
0h
0 = Normal operation (default)
1 = Powers down the digital block for channel 15
13
PDN_DIG_CH14
R/W
0h
0 = Normal operation (default)
1 = Powers down the digital block for channel 14
12
PDN_DIG_CH13
R/W
0h
0 = Normal operation (default)
1 = Powers down the digital block for channel 13
11
PDN_LVDS16
R/W
0h
0 = Normal operation (default)
1 = Powers down LVDS output line 16
10
PDN_LVDS15
R/W
0h
0 = Normal operation (default)
1 = Powers down LVDS output line 15
9
PDN_LVDS14
R/W
0h
0 = Normal operation (default)
1 = Powers down LVDS output line 14
8
PDN_LVDS13
R/W
0h
0 = Normal operation (default)
1 = Powers down LVDS output line 13
7
PDN_ANA_CH16
R/W
0h
0 = Normal operation (default)
1 = Powers down the analog block for channel 16
6
PDN_ANA_CH15
R/W
0h
0 = Normal operation (default)
1 = Powers down the analog block for channel 15
5
PDN_ANA_CH14
R/W
0h
0 = Normal operation (default)
1 = Powers down the analog block for channel 14
4
PDN_ANA_CH13
R/W
0h
0 = Normal operation (default)
1 = Powers down the analog block for channel 13
3
INVERT_CH15
R/W
0h
0 = Normal operation (default)
1 = Inverts digital output data sent on LVDS output line 16
2
INVERT_CH16
R/W
0h
0 = Normal operation (default)
1 = Inverts digital output data sent on LVDS output line 15
1
INVERT_CH14
R/W
0h
0 = Normal operation (default)
1 = Inverts digital output data sent on LVDS output line 14
0
INVERT_CH13
R/W
0h
0 = Normal operation (default)
1 = Inverts digital output data sent on LVDS output line 13
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13.1.2.1.53 Register 67 (address = 43h)
Figure 168. Register 67
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
7
0
R/W-0h
6
0
R/W-0h
5
0
R/W-0h
4
11
0
R/W-0h
10
0
R/W-0h
3
2
LVDS_DCLK_DELAY_PROG[3:0]
R/W-0h
9
0
R/W-0h
8
0
R/W-0h
1
0
0
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 69. Register 67 Field Descriptions
Bit
Field
Type
Reset
Description
15-5
0
R/W
0h
Must write 0
4-1
LVDS_DCLK_DELAY_PROG[3:0]
R/W
0h
The LVDS DCLK output delay is programmable with 110-ps
steps. Delay values are in twos complement format. Increasing
the positive delay increases setup time and reduces hold time,
and vice-versa for the negative delay.
0000 = No delay
0001 = 110 ps
0010 = 220 ps
…
1110 = –220 ps
1111 = –110ps
…
0
R/W
0h
Must write 0
0
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13.1.3 VCA Register Map
This section discusses the VCA registers. A register map is available in Table 70.
Table 70. VCA Register Map
REGISTER DATA (1)
REGISTER ADDRESS
DECIMAL
130
15
14
PGA_GAIN
12
11
0
6
0
PGA_
CLAMP_
LVL
5
4
0
PGA_HPF_
DIS
3
2
1
0
PDCH3/4
PDCH1/2
LNA_GAIN
_IND_EN
197
C5
GBL_
PDWN
FAST_
PDWN
198
C6
0
CW_HPF_
EN
199
C7
CW_MIX_PH_CH7/8
CW_MIX_PH_CH5/6
CW_MIX_PH_CH3/4
CW_MIX_PH_CH1/2
200
C8
CW_MIX_PH_CH15/16
CW_MIX_PH_CH13/14
CW_MIX_PH_CH11/12
CW_MIX_PH_CH9/10
201
C9
PDWN_
VCA_
PGA
CW_HPF_FB_RES
LNA_GAIN_CH13/14
0
7
PGA_
CLAMP_
DIS
C4
LNA_GAIN_CH15/16
LNA_HPF_
DIS
0
8
196
PDWN_
LNA
0
9
0
LNA_GAIN_GBL
0
10
C3
CB
0
13
195
203
(1)
HEX
INPUT_CLAMP_LVL
ACT_
TERM_
EN
GBL_ACTIVE_TERM
ACT_
TERM_
IND_RES_
EN
POW_MODES
LOW_NF
0
PDCH
15/16
PDCH
13/14
PDCH
11/12
CW_CLK_MODE
DIS_CW_
AMP
CW_TGC_
SEL
0
1X_CLK_
BUF_
MODE
16X_CLK_
BUF_
MODE
LNA_GAIN_CH11/12
LNA_GAIN_CH9/10
LNA_GAIN_CH7/8
LPF_PROG
ACT_TERM_IND_RES
PDCH9/10
PDCH7/8
CW_SUM_AMP_GAIN
LNA_GAIN_CH5/6
LNA_GAIN_CH3/4
0
0
0
0
0
0
0
0
EN_DIG_
TGC
V2I_
CLAMP
0
0
0
0
RED_LNA_
HPF_3X
0
0
0
0
0
PDWN_
LNA_
DIE2
PDWN_
VCA_
PGA_DIE2
LOW_NF_
DIE2
0
PDCH15
PDCH13
PDCH11
PDCH9
PDCH7
DIG_TGC_ATTENUATION
205
CD
PGA_
CLAMP_
HALF
SUPRESS
_HIGHER_
HAR
MONICS
213
D5
GBL_
PDWN_
DIE2
FAST_
PDWN_
DIE2
215
D7
CW_MIX_PH_CH7
CW_MIX_PH_CH5
CW_MIX_PH_CH3
216
D8
CW_MIX_PH_CH15
CW_MIX_PH_CH13
CW_MIX_PH_CH11
217
D9
LNA_GAIN_CH15
LNA_GAIN_CH13
POW_MODES_DIE2
LNA_GAIN_CH11
LNA_GAIN_CH9
LNA_GAIN_CH7
PDCH5/6
LNA_HPF_PROG
LNA_GAIN_CH5
LNA_GAIN_CH1/2
0
0
0
0
0
PDCH5
PDCH3
PDCH1
CW_MIX_PH_CH1
CW_MIX_PH_CH9
LNA_GAIN_CH3
LNA_GAIN_CH1
The default value of all registers is 0.
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13.1.3.1 Description of VCA Registers
13.1.3.1.1 Register 195 (address = C3h)
Table 71. Register 195
15
0
R/W-0h
14
0
R/W-0h
13
PGA_GAIN
R/W-0h
12
0
R/W-0h
11
0
R/W-0h
10
0
R/W-0h
9
0
R/W-0h
8
0
R/W-0h
7
PGA_CLAMP_
DIS
R/W-0h
6
PGA_CLAMP_
LVL
R/W-0h
5
4
3
2
1
0
0
PGA_HPF_DIS
LPF_PROG
R/W-0h
R/W-0h
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value after reset
Table 72. Register 195 Field Descriptions
Bit
15-14
13
12-8
Field
Type
Reset
Description
0
R/W
0h
Must write 0
PGA_GAIN
R/W
0h
0 = PGA gain set to 24 dB
1 = PGA gain set to 30 dB
0
R/W
0h
Must write 0
7
PGA_CLAMP_DIS
R/W
0h
When POW_MODES (register 197, bits 11-10) is 01 or 10:
0 = Disables the PGA current clamp circuit
1 = Enables the PGA current clamp circuit before the PGA
outputs
When POW_MODES (register 197, bits 11-10) is 00:
0 = Enables the PGA current clamp circuit
1 = Disables the PGA current clamp circuit before the PGA
outputs
PGA_CLAMP_LVL (register 195, bit 6) determines the current
clamp level.
6
PGA_CLAMP_LVL
R/W
0h
0 = –2 dBFS
1 = 0 dBFS
Note that the current clamp circuit ensures that the PGA output
is in the linear range. For example, at a 0-dBFS setting, the PGA
output HD3 worsens by 3 dB at a –2-dBFS ADC input. In normal
operation, the current clamp function can be set as 0 dBFS.
5
0
R/W
0h
Must write 0
4
PGA_HPF_DIS
R/W
0h
0 = PGA high-pass filter enabled
1 = PGA high-pass filter disabled
LPF_PROG
R/W
0h
These bits program the cutoff frequency of the antialiasing lowpass filter.
0000 = 15 MHz
0100 = 20 MHz
0101 = 35 MHz
0110 = 30 MHz
0111 = 50 MHz
1000 = 10 MHz
All other bit combinations are not applicable
3-0
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13.1.3.1.2 Register 196 (address = C4h)
Table 73. Register 196
15
LNA_GAIN_
IND_EN
R/W-0h
14
7
6
13
12
11
10
LNA_GAIN_GBL
LNA_HPF_DIS
0
INPUT_CLAMP_LVL
R/W-0h
R/W-0h
R/W-0h
4
3
GBL_ACTIVE_TERM
R/W-0h
5
ACT_TERM_
IND_RES_EN
R/W-0h
9
R/W-0h
2
1
8
ACT_TERM_
EN
R/W-0h
0
ACT_TERM_IND_RES
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value
Table 74. Register 196 Field Descriptions
Bit
Field
Type
Reset
Description
15
LNA_GAIN_IND_EN
R/W
0h
0 = Disabled
1 = LNA individual channel control enabled
See register 201 and register 217 for details.
LNA_GAIN_GBL
R/W
0h
00
01
10
11
12
LNA_HPF_DIS
R/W
0h
0 = LNA high-pass filter enabled
1 = LNA high-pass filter disabled
11
0
R/W
0h
Must write 0
INPUT_CLAMP_LVL
R/W
0h
00
01
10
11
ACT_TERM_EN
R/W
0h
0 = Active termination disabled
1 = Active termination enabled
GBL_ACTIVE_TERM
R/W
0h
00 = 50 Ω
01 = 100 Ω
10 = 200 Ω
11 = 400 Ω
Note that the device adjusts resistor mapping (register 196, bits
4-0) automatically. 50-Ω active termination is not supported in
the 12-dB LNA setting. Instead, 00 represents high-impedance
mode when LNA gain is 12 dB.
ACT_TERM_IND_RES_EN
R/W
0h
0 = Disabled
1 = Internal active termination individual resistor control enabled
ACT_TERM_IND_RES
R/W
0h
To enable this bit, ensure that ACT_TERM_IND_RES_EN
(register 196, bit 5) is 1. For further details, see Table 75.
14-13
10-9
8
7-6
5
4-0
132
= 18 dB
= 24 dB
= 12 dB
= Reserved
= Auto setting
= 1.5 VPP
= 1.15 VPP
= 0.6 VPP
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Table 75. ACT_TERM_IND_RES (1) (Register 196, Bits 4-0) versus LNA Input Impedances
ACT_TERM_IND_RES (Register 196, Bits 4-0)
(1)
BIT SETTINGS
LNA = 12 dB
LNA = 18 dB
LNA = 24 dB
00000
High-Z
High-Z
High-Z
00001
150 Ω
90 Ω
50 Ω
00010
300 Ω
180 Ω
100 Ω
00011
100 Ω
60 Ω
33 Ω
00100
600 Ω
360 Ω
200 Ω
00101
120 Ω
72 Ω
40 Ω
00110
200 Ω
120 Ω
66.67 Ω
00111
86 Ω
51 Ω
29 Ω
01000
1200 Ω
720 Ω
400 Ω
01001
133 Ω
80 Ω
44 Ω
01010
240 Ω
144 Ω
80 Ω
01011
92 Ω
55 Ω
31 Ω
01100
400 Ω
240 Ω
133 Ω
01101
109 Ω
65 Ω
36 Ω
01110
171 Ω
103 Ω
57 Ω
01111
80 Ω
48 Ω
27 Ω
10000
1500 Ω
900 Ω
500 Ω
10001
136 Ω
82 Ω
45 Ω
10010
250 Ω
150 Ω
83 Ω
10011
94 Ω
56 Ω
31 Ω
10100
429 Ω
257 Ω
143 Ω
10101
111 Ω
67 Ω
37 Ω
10110
176 Ω
106 Ω
59 Ω
10111
81 Ω
49 Ω
27 Ω
11000
667 Ω
400 Ω
222 Ω
11001
122 Ω
73 Ω
41 Ω
11010
207 Ω
124 Ω
69 Ω
11011
87 Ω
52 Ω
29 Ω
11100
316 Ω
189 Ω
105 Ω
11101
102 Ω
61 Ω
34 Ω
11110
154 Ω
92 Ω
51 Ω
11111
76 Ω
46 Ω
25 Ω
Total device input impedance is given by the parallel combination of the mentioned active termination resistance and a passive
resistance of 15 kΩ.
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13.1.3.1.3 Register 197 (address = C5h)
Table 76. Register 197
15
14
13
11
R/W-0h
12
PDWN_VCA_
PGA
R/W-0h
GBL_PDWN
FAST_PDWN
PDWN_LNA
R/W-0h
R/W-0h
7
PDCH15/16
R/W-0h
6
PDCH13/14
R/W-0h
10
9
8
POW_MODES
LOW_NF
0
5
PDCH11/12
R/W-0h
4
PDCH9/10
R/W-0h
3
PDCH7/8
R/W-0h
R/W-0h
R/W-0h
R/W-0h
1
PDCH3/4
R/W-0h
0
PDCH1/2
R/W-0h
2
PDCH5/6
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value
Table 77. Register 197 Field Descriptions
Bit
Field
Type
Reset
Description
15
GBL_PDWN
R/W
0h
0 = Normal operation
1 = When ADD_OFFSET is set to 0, the LNA, VCAT, and PGA are completely
powered down (slow wake response) for both VCA dies 1 and 2
When ADD_OFFSET is set to 1, the LNA, VCAT, and PGA are completely
powered down (slow wake response) for only VCA die 1.
This bit can overwrite FAST PDWN (register 197, bit 14). Note that enabling this
bit does not power-down the ADC. This bit only powers down the VCA dies.
14
FAST_PDWN
R/W
0h
0 = Normal operation
1 = When ADD_OFFSET set to 0, the LNA, VCAT, and PGA are partially
powered down (fast wake response) for both VCA dies 1 and 2
When ADD_OFFSET set to 1, the LNA, VCAT, and PGA are partially powered
down (fast wake response) for only VCA die 1.
Note that enabling this bit does not power-down the ADC. This bit only powers
down the VCA dies.
13
PDWN_LNA
R/W
0h
0 = Normal operation
1 = When ADD_OFFSET is set to 0, only the LNA is powered down for both
VCA dies 1 and 2
When ADD_OFFSET is set to 1, only the LNA is powered down for VCA die 1.
12
PDWN_VCA_PGA
R/W
0h
0 = Normal operation
1 = When ADD_OFFSET is set to 0, the VCAT and PGA are powered down for
both VCA dies 1 and 2
When ADD_OFFSET set to 1, the VCAT and PGA are powered down for only
VCA die 1.
POW_MODES
R/W
0h
00 = Low-noise mode
01 = Set to low-power mode; at 30-dB PGA the total chain gain can slightly
change
10 = Set to medium-power mode; at 30-dB PGA the total chain gain can slightly
change
11 = Reserved
When ADD_OFFSET is set to 0, the device performs an operation as this
POW_MODES section describes on both VCA dies 1 and 2.
When ADD_OFFSET is set to 1, the device performs an operation as this
POW_MODES section describes only on VCA die 1.
9
LOW_NF
R/W
0h
This mode can be used to improve the noise figure for high-impedance probes.
To write to this register, ensure that POW MODES (register 197, bits 11-10) =
00.
0 = Disable low-noise figure mode
1 = When ADD_OFFSET is set to 0, the low-noise figure mode is enabled on
both VCA dies 1 and 2
When ADD_OFFSET set to 1, the low-noise figure mode is enabled only on
VCA die 1.
8
0
R/W
0h
Must write 0
7
PDCH15/16
R/W
0h
0 = Default
1 = When ADD_OFFSET is 0, channels 15 and 16 are powered down; when
ADD_OFFSET is 1, only channel 16 is powered down
This bit only powers down the channel of the VCA die (that is, LNA + VCA +
PGA). This bit does not affect the ADC channel.
11-10
134
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Table 77. Register 197 Field Descriptions (continued)
Bit
Field
Type
Reset
Description
6
PDCH13/14
R/W
0h
0 = Default
1 = When ADD_OFFSET is 0, channels 13 and 14 are powered down; when
ADD_OFFSET is 1, only channel 14 is powered down
This bit only powers down the channel of the VCA die (that is, LNA + VCA +
PGA). This bit does not affect the ADC channel.
5
PDCH11/12
R/W
0h
0 = Default
1 = When ADD_OFFSET is 0, channels 11 and 12 are powered down; when
ADD_OFFSET is 1, only channel 12 is powered down
This bit only powers down the channel of the VCA die (that is, LNA + VCA +
PGA). This bit does not affect the ADC channel.
4
PDCH9/10
R/W
0h
0 = Default
1 = When ADD_OFFSET is 0, channels 9 and 10 are powered down; when
ADD_OFFSET is 1, only channel 10 is powered down
This bit only powers down the channel of the VCA die (that is, LNA + VCA +
PGA). This bit does not affect the ADC channel.
3
PDCH7/8
R/W
0h
0 = Default
1 = When ADD_OFFSET is 0, channels 7 and 8 are powered down; when
ADD_OFFSET is 1, only channel 8 is powered down
This bit only powers down the channel of the VCA die (that is, LNA + VCA +
PGA). This bit doesn’t have any impact on ADC channel.
2
PDCH5/6
R/W
0h
0 = Default
1 = When ADD_OFFSET is 0, channels 5 and 6 are powered down; when
ADD_OFFSET is 1, only channel 6 is powered down
This bit only powers down the channel of the VCA die (that is, LNA + VCA +
PGA). This bit does not affect the ADC channel.
1
PDCH3/4
R/W
0h
0 = Default
1 = When ADD_OFFSET is 0, channels 3 and 4 are powered down; when
ADD_OFFSET is 1, only channel 4 is powered down
This bit only powers down the channel of the VCA die (that is, LNA + VCA +
PGA). This bit does not affect the ADC channel.
0
PDCH1/2
R/W
0h
0 = Default
1 = When ADD_OFFSET is 0, channels 1 and 2 are powered down; when
ADD_OFFSET is 1, only channel 2 is powered down
This bit only powers down the channel of the VCA die (that is, LNA + VCA +
PGA). This bit does not affect the ADC channel.
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13.1.3.1.4 Register 198 (address = C6h)
Table 78. Register 198
15
0
R/W-0h
14
CW_HPF_EN
R/W-0h
7
0
6
1X_CLK_BUF_
MODE
R/W-0h
R/W-0h
13
12
CW_HPF_FB_RES
R/W-0h
5
16X_CLK_BUF
_MODE
R/W-0h
4
11
10
CW_CLK_MODE
R/W-0h
3
9
DIS_CW_AMP
R/W-0h
8
CW_TGC_SEL
R/W-0h
1
0
2
CW_SUM_AMP_GAIN
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value
Table 79. Register 198 Field Descriptions
Bit
Field
Type
Reset
Description
15
0
R/W
0h
Must write 0
14
CW_HPF_EN
R/W
0h
0 = Normal operation
1 = Enables CW output high-pass filter
13-12
CW_HPF_FB_RES
R/W
0h
If CW_HPF_EN = 1 then the value of the CW high-pass filter feedback
resistor is given by:
00 = 400 Ω
01 = 133 Ω
10 = 80 Ω
11 = 57 Ω
If CW_HPF_EN = 0 then these bits are ignored and the feedback path
remains open.
11-10
CW_CLK_MODE
R/W
0h
00 = 16X mode
01 = 8X mode
10 = 4X mode
11 = 1X mode
9
DIS_CW_AMP
R/W
0h
0 = CW summing amplifier enabled
1 = CW summing amplifier disabled
Note that this bit is only effective in CW mode.
8
CW_TGC_SEL
R/W
0h
0 = TGC mode
1 = CW mode
Note that the VCAT and PGA still function in CW mode. Power-down the
VCAT and PGA separately with PDWN_VCA_PGA (register 197, bit 12).
7
0
R/W
0h
Must write 0
6
1X_CLK_BUF_MODE
R/W
0h
0 = Accepts CMOS clock
1 = Accepts differential clock
5
16X_CLK_BUF_MODE
R/W
0h
0 = Accepts differential clock
1 = Accepts CMOS clock
4-0
CW_SUM_AMP_GAIN
R/W
0h
These bits select the feedback resistor for the CW amplifier, as per Table 75.
Table 80. CW Summing Amplifier Feedback Resistor
136
REGISTER 198
(Bits 4-0)
FEEDBACK RESISTOR
REGISTER 198
(Bits 4-0)
FEEDBACK RESISTOR
REGISTER 198
(Bits 4-0)
FEEDBACK RESISTOR
00000
Open
01011
111 Ω
10110
153 Ω
00001
250 Ω
01100
333 Ω
10111
95 Ω
00010
250 Ω
01101
142 Ω
11000
666 Ω
00011
125 Ω
01110
142 Ω
11001
181 Ω
00100
500 Ω
01111
90 Ω
11010
181 Ω
00101
166 Ω
10000
2000 Ω
11011
105 Ω
00110
166 Ω
10001
222 Ω
11100
285 Ω
00111
100 Ω
10010
222 Ω
11101
133 Ω
01000
1000 Ω
10011
117 Ω
11110
133 Ω
01001
200 Ω
10100
400 Ω
11111
87 Ω
01010
200 Ω
10101
153 Ω
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13.1.3.1.5 Register 199 (address = C7h)
Table 81. Register 199
15
14
13
CW_MIX_PH_CH[7/8]
R/W-0h
12
11
10
9
CW_MIX_PH_CH[5/6]
R/W-0h
8
7
6
5
CW_MIX_PH_CH[3/4]
R/W-0h
4
3
2
1
CW_MIX_PH_CH[1/2]
R/W-0h
0
LEGEND: R/W = Read/Write; W = Write only; -n = value
Table 82. Register 199 Field Descriptions
Bit
Field
Type
Reset
Description
15-12
CW_MIX_PH_CH[7/8]
R/W
0h
These bits control the CW mixer phase. Writing N to these bits
sets the corresponding channel phase to N × 22.5°. Where, N =
0 to 15; see Table 83 for further details.
The functionality of these bits depends upon the value of the
ADD_OFFSET bit. When the ADD_OFFSET bit is set to 0,
setting bits 15-12 programs the CW phase of channels 7 and 8.
When the ADD_OFFSET bit is set to 1, setting bits 15-12
programs the CW phase of only channel 8.
11-8
CW_MIX_PH_CH[5/6]
R/W
0h
These bits control the CW mixer phase. Writing N to these bits
sets the corresponding channel phase to N × 22.5°. Where, N =
0 to 15; see Table 83 for further details.
The functionality of these bits depends upon the value of the
ADD_OFFSET bit. When the ADD_OFFSET bit is set to 0,
setting bits 11-8 programs the CW phase of channels 5 and 6.
When the ADD_OFFSET bit is set to 1, setting bits 11-8
programs the CW phase of only channel 6.
7-4
CW_MIX_PH_CH[3/4]
R/W
0h
These bits control the CW mixer phase. Writing N to these bits
sets the corresponding channel phase to N × 22.5°. Where, N =
0 to 15; see Table 83 for further details.
The functionality of these bits depends upon the value of the
ADD_OFFSET bit. When the ADD_OFFSET bit is set to 0,
setting bits 7-4 programs the CW phase of channels 3 and 4.
When the ADD_OFFSET bit is set to 1, setting bits 7-4
programs the CW phase of only channel 4.
3-0
CW_MIX_PH_CH[1/2]
R/W
0h
These bits control the CW mixer phase. Writing N to these bits
sets the corresponding channel phase to N × 22.5°. Where, N =
0 to 15; see Table 83 for further details.
The functionality of these bits depends upon the value of the
ADD_OFFSET bit. When the ADD_OFFSET bit is set to 0,
setting bits 3-0 programs the CW phase of channels 1 and 2.
When the ADD_OFFSET bit is set to 1, setting bits 3-0
programs the CW phase of only channel 2.
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Table 83. CW Mixer Phase Delay versus Register Settings
138
BIT SETTINGS
CW_MIX_PH_CHX, CW_MIX_PH_CHY PHASE SHIFT
0000
0
0001
22.5°
0010
45°
0011
67.5°
0100
90°
0101
112.5°
0110
135°
0111
157.5°
1000
180°
1001
202.5°
1010
225°
1011
247.5°
1100
270°
1101
292.5°
1110
315°
1111
337.5°
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13.1.3.1.6 Register 200 (address = C8h)
Table 84. Register 200
15
14
13
CW_MIX_PH_CH[15/16]
R/W-0h
12
11
10
9
CW_MIX_PH_CH[13/14]
R/W-0h
8
7
6
5
CW_MIX_PH_CH[11/12]
R/W-0h
4
3
2
1
CW_MIX_PH_CH[9/10]
R/W-0h
0
LEGEND: R/W = Read/Write; W = Write only; -n = value
Table 85. Register 200 Field Descriptions
Bit
Field
Type
Reset
Description
15-12
CW_MIX_PH_CH[15/16]
R/W
0h
These bits control the CW mixer phase. Writing N to these bits sets
the corresponding channel phase to N × 22.5°. Where, N = 0 to 15;
see Table 83 for further details.
The functionality of these bits depends upon the value of the
ADD_OFFSET bit. When the ADD_OFFSET bit is set to 0, setting
bits 15-12 programs the CW phase of channels 15 and 16.
When the ADD_OFFSET bit is set to 1, setting bits 15-12 programs
the CW phase of only channel 16.
11-8
CW_MIX_PH_CH[13/14]
R/W
0h
These bits control the CW mixer phase. Writing N to these bits sets
the corresponding channel phase to N × 22.5°. Where, N = 0 to 15;
see Table 83 for further details.
The functionality of these bits depends upon the value of the
ADD_OFFSET bit. When the ADD_OFFSET bit is set to 0, setting
bits 11-8 programs the CW phase of channels 13 and 14.
When the ADD_OFFSET bit is set to 1, setting bits 11-8 programs
the CW phase of only channel 14.
7-4
CW_MIX_PH_CH[11/12]
R/W
0h
These bits control the CW mixer phase. Writing N to these bits sets
the corresponding channel phase to N × 22.5°. Where, N = 0 to 15;
see Table 83 for further details.
The functionality of these bits depends upon the value of the
ADD_OFFSET bit. When the ADD_OFFSET bit is set to 0, setting
bits 7-4 programs the CW phase of channels 11 and 12.
When the ADD_OFFSET bit is set to 1, setting bits 7-4 programs
the CW phase of only channel 12.
3-0
CW_MIX_PH_CH[9/10]
R/W
0h
These bits control the CW mixer phase. Writing N to these bits sets
the corresponding channel phase to N × 22.5°. Where, N = 0 to 15;
see Table 83 for further details.
The functionality of these bits depends upon the value of the
ADD_OFFSET bit. When the ADD_OFFSET bit is set to 0, setting
bits 3-0 programs the CW phase of channels 9 and 10.
When the ADD_OFFSET bit is set to 1, setting bits 3-0 programs
the CW phase of only channel 10.
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13.1.3.1.7 Register 201 (address = C9h)
Table 86. Register 201
15
14
LNA_GAIN_CH[15/16]
R/W-0h
13
12
LNA_GAIN_CH[13/14]
R/W-0h
11
10
LNA_GAIN_CH[11/12]
R/W-0h
9
8
LNA_GAIN_CH[9/10]
R/W-0h
7
6
LNA_GAIN_CH[7/8]
R/W-0h
5
4
LNA_GAIN_CH[5/6]
R/W-0h
3
2
LNA_GAIN_CH[3/4]
R/W-0h
1
0
LNA_GAIN_CH[1/2]
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value
Table 87. Register 201 Field Descriptions
Bit
Field
Type
Reset
Description
15-14
LNA_GAIN_CH[15/16]
R/W
0h
To enable this bit, ensure that LNA_GAIN_IND_EN (register
196, bit 15) is 1.
00 = 18 dB
01 = 24 dB
10 = 12 dB
11 = Do not use
The functionality of this bit depends on the ADD_OFFSET bit.
When ADD_OFFSET is 0, the gain of channels 15 and 16 are
programmed; when ADD_OFFSET is 1, only the gain of channel
16 is programmed.
13-12
LNA_GAIN_CH[13/14]
R/W
0h
To enable this bit, ensure that LNA_GAIN_IND_EN (register
196, bit 15) is 1.
00 = 18 dB
01 = 24 dB
10 = 12 dB
11 = Do not use
The functionality of this bit depends on the ADD_OFFSET bit.
When ADD_OFFSET is 0, the gain of channels 13 and 14 are
programmed; when ADD_OFFSET is 1, only the gain of channel
14 is programmed.
11-10
LNA_GAIN_CH[11/12]
R/W
0h
To enable this bit, ensure that LNA_GAIN_IND_EN (register
196, bit 15) is 1.
00 = 18 dB
01 = 24 dB
10 = 12 dB
11 = Do not use
The functionality of this bit depends on the ADD_OFFSET bit.
When ADD_OFFSET is 0, the gain of channels 11 and 12 are
programmed; when ADD_OFFSET is 1, only the gain of channel
12 is programmed.
9-8
LNA_GAIN_CH[9/10]
R/W
0h
To enable this bit, ensure that LNA_GAIN_IND_EN (register
196, bit 15) is 1.
00 = 18 dB
01 = 24 dB
10 = 12 dB
11 = Do not use
The functionality of this bit depends on the ADD_OFFSET bit.
When ADD_OFFSET is 0, the gain of channels 9 and 10 are
programmed; when ADD_OFFSET is 1, only the gain of channel
10 is programmed.
140
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Table 87. Register 201 Field Descriptions (continued)
Bit
Field
Type
Reset
Description
7-6
LNA_GAIN_CH[7/8]
R/W
0h
To enable this bit, ensure that LNA_GAIN_IND_EN (register
196, bit 15) is 1.
00 = 18 dB
01 = 24 dB
10 = 12 dB
11 = Do not use
The functionality of this bit depends on the ADD_OFFSET bit.
When ADD_OFFSET is 0, the gain of channels 7 and 8 are
programmed; when ADD_OFFSET is 1, only the gain of channel
8 is programmed.
5-4
LNA_GAIN_CH[5/6]
R/W
0h
To enable this bit, ensure that LNA_GAIN_IND_EN (register
196, bit 15) is 1.
00 = 18 dB
01 = 24 dB
10 = 12 dB
11 = Do not use
The functionality of this bit depends on the ADD_OFFSET bit.
When ADD_OFFSET is 0, the gain of channels 5 and 6 are
programmed; when ADD_OFFSET is 1, only the gain of channel
6 is programmed.
3-2
LNA_GAIN_CH[3/4]
R/W
0h
To enable this bit, ensure that LNA_GAIN_IND_EN (register
196, bit 15) is 1.
00 = 18 dB
01 = 24 dB
10 = 12 dB
11 = Do not use
The functionality of this bit depends on the ADD_OFFSET bit.
When ADD_OFFSET is 0, the gain of channels 3 and 4 are
programmed; when ADD_OFFSET is 1, only the gain of channel
4 is programmed.
1-0
LNA_GAIN_CH[1/2]
R/W
0h
To enable this bit, ensure that LNA_GAIN_IND_EN (register
196, bit 15) is 1.
00 = 18 dB
01 = 24 dB
10 = 12 dB
11 = Do not use
The functionality of this bit depends on the ADD_OFFSET bit.
When ADD_OFFSET is 0, the gain of channels 1 and 2 are
programmed; when ADD_OFFSET is 1, only the gain of channel
2 is programmed.
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13.1.3.1.8 Register 203 (address = CBh)
Table 88. Register 203
15
0
R/W-0h
14
0
R/W-0h
13
0
R/W-0h
12
0
R/W-0h
7
EN_DIG_TGC
R/W-0h
6
5
DIG_TGC_ATTENUATION
R/W-0h
4
11
0
R/W-0h
10
0
R/W-0h
3
2
LNA_HPF_PROG
R/W-0h
9
0
R/W-0h
8
0
R/W-0h
1
0
R/W-0h
0
0
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value
Table 89. Register 203 Field Descriptions
Bit
Field
Type
Reset
Description
0
R/W
0h
Must write 0
EN_DIG_TGC
R/W
0h
0 = Disable digital TGC attenuator
1 = Enable digital TGC attenuator
6-4
DIG_TGC_ATTENUATION
R/W
0h
When EN_DIG_TGC (register 203, bit 7) is set to 1, then the
digital attenuation in the TGC path is programmed as follows:
000 = 0-dB attenuation
001 = 6-dB attenuation
010 = 12-dB attenuation
011 = 18-dB attenuation
100 = 24-dB attenuation.
101 = 30-dB attenuation
110 = 36-dB attenuation
111 = 42-dB attenuation
3-2
LNA_HPF_PROG
R/W
0h
00
01
10
11
1-0
0
R/W
0h
Must write 0
15-8
7
142
= 100 kHz
= 50 kHz
= 200 kHz
= 150 kHz with 0.015 µF on INMx
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13.1.3.1.9 Register 205 (address = CDh)
Table 90. Register 205
15
13
12
11
10
9
8
V2I_CLAMP
0
0
0
0
RED_LNA_
HPF_3X
R/W-0h
14
SUPRESS_
HIGHER_
HARMONICS
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
R/W-0h
7
0
R/W-0h
6
0
R/W-0h
5
0
R/W-0h
4
0
R/W-0h
3
0
R/W-0h
2
0
R/W-0h
1
0
R/W-0h
0
0
R/W-0h
PGA_CLAMP_
HALF
LEGEND: R/W = Read/Write; W = Write only; -n = value
Table 91. Register 205 Field Descriptions
Bit
Field
Type
Reset
Description
15
PGA_CLAMP_HALF
R/W
0h
0 = Disables –6-dB PGA clamp
1 = Enables a –6-dB PGA clamp setting (that is, the PGA output
HD3 worsens by 3 dB at a –6-dBFS ADC input). The actual
PGA output is reduced to approximately 1.5 VPP. As a result, the
device low-pass filter (LPF) is not saturated and can suppress
harmonic signals better at the PGA output. Resulting from the
reduction of the PGA output, the ADC output dynamic range is
affected.
14
SUPRESS_HIGHER_HARMONICS
R/W
0h
0 = Disables a 1st-order, 5-MHz LPF filter
1 = Enables a 1st-order, 5-MHz LPF filter to suppress signals >
5 MHz or high-order harmonics
13
V2I_CLAMP
R/W
0h
0 = Disables V2I clamp in the PGA
1 = Enables V2I clamp in the PGA
0
R/W
0h
Must write 0
RED_LNA_HPF_3X
R/W
0h
0 = The LNA HPF corner frequency is given as per the
LNA_HPF_PROG bit description
1 = The LNA HPF corner frequency reduces by 3x as per the
LNA_HPF_PROG bit description.
For example, if LNA_HPF_PROG = 01 and RED_LNA_HPF_3X
= 1, then the LNA HPF corner is given by the equation 50 kHz /
3 = 16.6 kHz.
0
R/W
0h
Must write 0
12-9
8
7-0
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13.1.3.1.10 Register 213 (address = D5h)
Table 92. Register 213
15
GBL_PDWN_
DIE2
R/W-0h
14
FAST_PDWN_
DIE2
R/W-0h
13
PDWN_LNA_
DIE2
R/W-0h
12
PDWN_VCA_
PGA_DIE2
R/W-0h
7
PDCH15
R/W-0h
6
PDCH13
R/W-0h
5
PDCH11
R/W-0h
4
PDCH9
R/W-0h
11
10
POW_MODES_DIE2
R/W-0h
3
PDCH7
R/W-0h
2
PDCH5
R/W-0h
9
LOW_NF_
DIE2
R/W-0h
8
R/W-0h
1
PDCH3
R/W-0h
0
PDCH1
R/W-0h
0
LEGEND: R/W = Read/Write; W = Write only; -n = value
Table 93. Register 213 Field Descriptions
Bit
Field
Type
Reset
Description
15
GBL_PDWN_DIE2
R/W
0h
0 = Normal operation
1 = When ADD_OFFSET is set to 1, the LNA, VCAT, and PGA
are completely powered down (slow wake response) for only
VCA die 2.
Note that enabling this bit does not power-down the ADC. This
bit only powers down VCA dies.
14
FAST_PDWN_DIE2
R/W
0h
0 = Normal operation
1 = When ADD_OFFSET set to 1, the LNA, VCAT, and PGA
partially powered down (fast wake response) for only VCA die 2.
Note that enabling this bit does not power-down the ADC. This
bit only powers down VCA dies.
13
PDWN_LNA_DIE2
R/W
0h
0 = Normal operation
1 = When ADD_OFFSET is set to 1, only the LNA is powered
down for VCA die 2.
12
PDWN_VCA_PGA_DIE2
R/W
0h
0 = Normal operation
1 = When ADD_OFFSET set to 1, the VCAT and PGA are
powered down for only VCA die 2.
POW_MODES_DIE2
R/W
0h
00 = Low-noise mode
01 = Set to low-power mode. At 30-dB PGA, the total chain gain
may slightly change.
10 = Set to medium-power mode. At 30-dB PGA, the total chain
gain may slightly change.
11 = Reserved
When ADD_OFFSET set to 1, the device performs an operation
as described in this POW_MODES_DIE2 section only on die 2.
9
LOW_NF_DIE2
R/W
0h
This mode can be used to improve the noise figure for highimpedance probes. To write to this register, set POW
MODES_DIE2 (register 213, bits 11-10) = 00.
0 = Disable the low-noise figure mode
1 = When ADD_OFFSET set to 1, the low-noise figure mode is
enabled on only on VCA die 2.
8
0
R/W
0h
Must write 0
7
PDNCH15
R/W
0h
0 = Default
1 = When ADD_OFFSET is 1, channel 15 is powered down
This bit powers down the channel of the VCA die only (that is,
LNA + VCA + PGA). This bit does not affect the ADC channel.
6
PDNCH13
R/W
0h
0 = Default
1 = When ADD_OFFSET is 1, channel 13 is powered down
This bit powers down the channel of the VCA die only (that is,
LNA + VCA + PGA). This bit does not affect the ADC channel.
5
PDNCH11
R/W
0h
0 = Default
1 = When ADD_OFFSET is 1, channel 11 is powered down
This bit powers down the channel of the VCA die only (that is,
LNA + VCA + PGA). This bit does not affect the ADC channel.
4
PDNCH9
R/W
0h
0 = Default
1 = When ADD_OFFSET is 1, channel 9 is powered down
This bit powers down the channel of the VCA die only (that is,
LNA + VCA + PGA). This bit does not affect the ADC channel.
11-10
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Table 93. Register 213 Field Descriptions (continued)
Bit
Field
Type
Reset
Description
3
PDNCH7
R/W
0h
0 = Default
1 = When ADD_OFFSET is 1, channel 7 is powered down
This bit powers down the channel of the VCA die only (that is,
LNA + VCA + PGA). This bit does not affect the ADC channel.
2
PDNCH5
R/W
0h
0 = Default
1 = When ADD_OFFSET is 1, channel 5 is powered down
This bit powers down the channel of the VCA die only (that is,
LNA + VCA + PGA). This bit does not affect the ADC channel.
1
PDNCH3
R/W
0h
0 = Default
1 = When ADD_OFFSET is 1, channel 3 is powered down
This bit powers down the channel of the VCA die only (that is,
LNA + VCA + PGA). This bit does not affect the ADC channel.
0
PDNCH1
R/W
0h
0 = Default
1 = When ADD_OFFSET is 1, channel 1 is powered down
This bit powers down the channel of the VCA die only (that is,
LNA + VCA + PGA). This bit does not affect the ADC channel.
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13.1.3.1.11 Register 215 (address = D7h)
Table 94. Register 215
15
14
13
CW_MIX_PH_CH7
R/W-0h
12
11
10
9
CW_MIX_PH_CH5
R/W-0h
8
7
6
5
CW_MIX_PH_CH3
R/W-0h
4
3
2
1
CW_MIX_PH_CH1
R/W-0h
0
LEGEND: R/W = Read/Write; W = Write only; -n = value
Table 95. Register 215 Field Descriptions
Bit
Field
Type
Reset
Description
15-12
CW_MIX_PH_CH[7]
R/W
0h
These bits control the CW mixer phase. Writing N to these bits
sets the corresponding channel phase to N × 22.5°.
Where, N = 0 to 15; see Table 83 for further details.
When the ADD_OFFSET bit is set to 1, setting bits 15-12
programs the CW phase of channel 7.
11-8
CW_MIX_PH_CH[5]
R/W
0h
These bits control the CW mixer phase. Writing N to these bits
sets the corresponding channel phase to N × 22.5°.
Where, N = 0 to 15; see Table 83 for further details.
When the ADD_OFFSET bit is set to 1, setting bits 11-8
programs the CW phase of channel 5.
7-4
CW_MIX_PH_CH[3]
R/W
0h
These bits control the CW mixer phase. Writing N to these bits
sets the corresponding channel phase to N × 22.5°.
Where, N = 0 to 15; see Table 83 for further details.
When the ADD_OFFSET bit is set to 1, setting bits 7-4
programs the CW phase of channel 3.
3-0
CW_MIX_PH_CH[1]
R/W
0h
These bits control the CW mixer phase. Writing N to these bits
sets the corresponding channel phase to N × 22.5°.
Where, N = 0 to 15; see Table 83 for further details.
When the ADD_OFFSET bit is set to 1, setting bits 3-0
programs the CW phase of channel 1.
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13.1.3.1.12 Register 216 (address = D8h)
Table 96. Register 216
15
14
13
CW_MIX_PH_CH15
R/W-0h
12
11
10
9
CW_MIX_PH_CH13
R/W-0h
8
7
6
5
CW_MIX_PH_CH11
R/W-0h
4
3
2
1
CW_MIX_PH_CH9
R/W-0h
0
LEGEND: R/W = Read/Write; W = Write only; -n = value
Table 97. Register 216 Field Descriptions
Bit
Field
Type
Reset
Description
15-12
CW_MIX_PH_CH[15]
R/W
0h
These bits control the CW mixer phase. Writing N to these bits
sets the corresponding channel phase to N × 22.5°.
Where, N = 0 to 15; see Table 83 for further details.
When the ADD_OFFSET bit is set to 1, setting bits 15-12
programs the CW phase of channel 15.
11-8
CW_MIX_PH_CH[13]
R/W
0h
These bits control the CW mixer phase. Writing N to these bits
sets the corresponding channel phase to N × 22.5°.
Where, N = 0 to 15; see Table 83 for further details.
When the ADD_OFFSET bit is set to 1, setting bits 11-8
programs the CW phase of channel 13.
7-4
CW_MIX_PH_CH[11]
R/W
0h
These bits control the CW mixer phase. Writing N to these bits
sets the corresponding channel phase to N × 22.5°.
Where, N = 0 to 15; see Table 83 for further details.
When the ADD_OFFSET bit is set to 1, setting bits 7-4
programs the CW phase of channel 11.
3-0
CW_MIX_PH_CH[9]
R/W
0h
These bits control the CW mixer phase. Writing N to these bits
sets the corresponding channel phase to N × 22.5°.
Where, N = 0 to 15; see Table 83 for further details.
When the ADD_OFFSET bit is set to 1, setting bits 3-0
programs the CW phase of channel 9.
13.1.3.1.13 Register 217 (address = D9h)
Table 98. Register 217
15
14
LNA_GAIN_CH15
R/W-0h
13
12
LNA_GAIN_CH13
R/W-0h
11
10
LNA_GAIN_CH11
R/W-0h
9
8
LNA_GAIN_CH9
R/W-0h
7
6
LNA_GAIN_CH7
R/W-0h
5
4
LNA_GAIN_CH5
R/W-0h
3
2
LNA_GAIN_CH3
R/W-0h
1
0
LNA_GAIN_CH1
R/W-0h
LEGEND: R/W = Read/Write; W = Write only; -n = value
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Table 99. Register 217 Field Descriptions
Field
Type
Reset
Description
15-14
Bit
LNA_GAIN_CH[15]
R/W
0h
To enable this bit, set LNA_GAIN_IND_EN (register 196, bit
D15) to 1.
00 = 18 dB
01 = 24 dB
10 = 12 dB
11 = Do not use
When ADD_OFFSET is 1, the gain of channel 15 is
programmed.
13-12
LNA_GAIN_CH[13]
R/W
0h
To enable this bit, set LNA_GAIN_IND_EN (register 196, bit
D15) to 1.
00 = 18 dB
01 = 24 dB
10 = 12 dB
11 = Do not use
When ADD_OFFSET is 1, the gain of channel 13 is
programmed.
11-10
LNA_GAIN_CH[11]
R/W
0h
To enable this bit, set LNA_GAIN_IND_EN (register 196, bit
D15) to 1.
00 = 18 dB
01 = 24 dB
10 = 12 dB
11 = Do not use
When ADD_OFFSET is 1, the gain of channel 11 is
programmed.
9-8
LNA_GAIN_CH[9]
R/W
0h
To enable this bit, set LNA_GAIN_IND_EN (register 196, bit
D15) to 1.
00 = 18 dB
01 = 24 dB
10 = 12 dB
11 = Do not use
When ADD_OFFSET is 1, the gain of channel 9 is programmed.
7-6
LNA_GAIN_CH[7]
R/W
0h
To enable this bit, set LNA_GAIN_IND_EN (register 196, bit
D15) to 1.
00 = 18 dB
01 = 24 dB
10 = 12 dB
11 = Do not use
When ADD_OFFSET is 1, the gain of channel 7 is programmed.
5-4
LNA_GAIN_CH[5]
R/W
0h
To enable this bit, set LNA_GAIN_IND_EN (register 196, bit
D15) to 1.
00 = 18 dB
01 = 24 dB
10 = 12 dB
11 = Do not use
When ADD_OFFSET is 1, the gain of channel 5 is programmed.
3-2
LNA_GAIN_CH[3]
R/W
0h
To enable this bit, set LNA_GAIN_IND_EN (register 196, bit
D15) to 1.
00 = 18 dB
01 = 24 dB
10 = 12 dB
11 = Do not use
When ADD_OFFSET is 1, the gain of channel 3 is programmed.
1-0
LNA_GAIN_CH[1]
R/W
0h
To enable this bit, set LNA_GAIN_IND_EN (register 196, bit
D15) to 1.
00 = 18 dB
01 = 24 dB
10 = 12 dB
11 = Do not use
When ADD_OFFSET is 1, the gain of channel 1 is programmed.
148
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14 Device and Documentation Support
14.1 Documentation Support
14.1.1 Related Documentation
AFE5816 Data Sheet, SBAS688
MicroStar BGA Packaging Reference Guide, SSYZ015
Clocking High-Speed Data Converters, SLYT075
Design for a Wideband Differential Transimpedance DAC Output, SBAA150
TI Active Filter Design Tool, WEBENCH® Filter Designer
CDCM7005 Data Sheet, SCAS793
CDCE72010 Data Sheet, SCAS858
TLV5626 Data Sheet, SLAS236
DAC7821 Data Sheet, SBAS365
THS413x Data Sheet, SLOS318
OPA1632 Data Sheet, SBOS286
LMK048x Data Sheet, SNAS489
OPA2211 Data Sheet, SBOS377
ADS8413 Data Sheet, SLAS490
ADS8472 Data Sheet, SLAS514
ADS8881 Data Sheet, SBAS547
SN74AUP1T04 Data Sheet, SCES800
UCC28250 Data Sheet,SLUSA29
ISO7240 Data Sheet, SLLS868
14.2 Trademarks
All trademarks are the property of their respective owners.
14.3 Electrostatic Discharge Caution
These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
14.4 Export Control Notice
Recipient agrees to not knowingly export or re-export, directly or indirectly, any product or technical data (as
defined by the U.S., EU, and other Export Administration Regulations) including software, or any controlled
product restricted by other applicable national regulations, received from disclosing party under nondisclosure
obligations (if any), or any direct product of such technology, to any destination to which such export or re-export
is restricted or prohibited by U.S. or other applicable laws, without obtaining prior authorization from U.S.
Department of Commerce and other competent Government authorities to the extent required by those laws.
14.5 Glossary
SLYZ022 — TI Glossary.
This glossary lists and explains terms, acronyms, and definitions.
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15 Mechanical, Packaging, and Orderable Information
The following pages include mechanical, packaging, and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and revision of
this document. For browser-based versions of this data sheet, refer to the left-hand navigation.
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15.1 Tray Information
Figure 169. Tray Diagram, Section 1
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Tray Information (continued)
Figure 170. Tray Diagram, Section 2
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PACKAGING INFORMATION
Orderable Device
Status
(1)
AFE5818ZBV
ACTIVE
Package Type Package Pins Package
Drawing
Qty
NFBGA
ZBV
289
126
Eco Plan
Lead/Ball Finish
MSL Peak Temp
(2)
(6)
(3)
Pb-Free
(RoHS)
SNAGCU
Level-3-260C-168 HR
Op Temp (°C)
Device Marking
(4/5)
-40 to 85
AFE5818
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3)
MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
(4)
There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5)
Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
(6)
Lead/Ball Finish - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead/Ball Finish values may wrap to two lines if the finish
value exceeds the maximum column width.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 1
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Addendum-Page 2
IMPORTANT NOTICE
Texas Instruments Incorporated and its subsidiaries (TI) reserve the right to make corrections, enhancements, improvements and other
changes to its semiconductor products and services per JESD46, latest issue, and to discontinue any product or service per JESD48, latest
issue. Buyers should obtain the latest relevant information before placing orders and should verify that such information is current and
complete. All semiconductor products (also referred to herein as “components”) are sold subject to TI’s terms and conditions of sale
supplied at the time of order acknowledgment.
TI warrants performance of its components to the specifications applicable at the time of sale, in accordance with the warranty in TI’s terms
and conditions of sale of semiconductor products. Testing and other quality control techniques are used to the extent TI deems necessary
to support this warranty. Except where mandated by applicable law, testing of all parameters of each component is not necessarily
performed.
TI assumes no liability for applications assistance or the design of Buyers’ products. Buyers are responsible for their products and
applications using TI components. To minimize the risks associated with Buyers’ products and applications, Buyers should provide
adequate design and operating safeguards.
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