12-Bit, 2.6 GSPS/2.5 GSPS/2.0 GSPS,
1.3 V/2.5 V Analog-to-Digital Converter
Data Sheet AD9625
Rev. C Document Feedbac
k
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FEATURES
12-bit 2.5 GSPS ADC, no missing codes
SFDR = 79 dBc, AIN up to 1 GHz at −1 dBFS, 2.5 GSPS
SFDR = 77 dBc, AIN up to 1.8 GHz at −1 dBFS, 2.5 GSPS
SNR = 57.6 dBFS, AIN up to 1 GHz at −1 dBFS, 2.5 GSPS
SNR = 57 dBFS, AIN up to 1.8 GHz at −1 dBFS, 2.5 GSPS
Noise spectral density = −149.5 dBFS/Hz at 2.5 GSPS
Differential analog input: 1.2 V p-p
Differential clock input
3.2 GHz analog input bandwidth, full power
High speed 6- or 8-lane JESD204B serial output at 2.6 GSPS
Subclass 1: 6.5 Gbps at 2.6 GSPS
Two independent decimate by 8 or decimate by 16 filters
with 10-bit NCOs
Supply voltages: 1.3 V, 2.5 V
Serial port control
Flexible digital output modes
Built-in selectable digital test patterns
Timestamp feature
Conversion error rate < 10−15
APPLICATIONS
Spectrum analyzers
Military communications
Radar
High performance digital storage oscilloscopes
Active jamming/antijamming
Electronic surveillance and countermeasures
FUNCTIONAL BLOCK DIAGRAM
A
VDD
A
GND DRVDD DRGND
CMOS DIGITAL
INPUT/OUTPUT
DDC
fS
/8 OR
fS
/16
DIGITAL INTERFACE
AND CONTROL
CONTROL
REGISTERS
VIN+
VIN–
VCM
SYSREF±
CLK±
RBIAS_EXT
ADC
CORE
REFERENCE
CLOCK
MANAGEMENT
SDIO SCLK CSB
FD
SERDOUT[0]±
SERDOUT[1]±
SERDOUT[2]±
SERDOUT[3]±
SERDOUT[4]±
SERDOUT[5]±
SERDOUT[6]±
SERDOUT[7]±
SYNCINB±
DIVCL
RSTB
IRQ
AD9625
JESD204B
INTERFACE
CMOS
DIGITAL
INPUT/
OUTPUT
LVDS
DIGITAL
INPUT/
OUTPUT
11814-001
Figure 1.
GENERAL DESCRIPTION
The AD9625 is a 12-bit monolithic sampling analog-to-digital
converter (ADC) that operates at conversion rates of up to
2.6 giga samples per second (GSPS). This product is designed
for sampling wide bandwidth analog signals up to the second
Nyquist zone. The combination of wide input bandwidth, high
sampling rate, and excellent linearity of the AD9625 is ideally
suited for spectrum analyzers, data acquisition systems, and a
wide assortment of military electronics applications, such as
radar and electronic countermeasures.
The analog input, clock, and SYSREF± signals are differential
inputs. The JESD204B-based high speed serialized output is
configurable in a variety of one-, two-, four-, six-, or eight-lane
configurations. The product is specified over the industrial
temperature range of −40°C to +85°C, measured at the case.
PRODUCT HIGHLIGHTS
1. High performance: exceptional SFDR in high sample rate
applications, direct RF sampling, and on-chip reference.
2. Flexible digital data output formats based on the JESD204B
specification.
3. Control path SPI interface port that supports various
product features and functions, such as data formatting,
gain, and offset calibration values.
AD9625* PRODUCT PAGE QUICK LINKS
Last Content Update: 02/23/2017
COMPARABLE PARTS
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EVALUATION KITS
2 AD9625 ADC’s running at 2.5GSPS with an effective
sampling rate of 5GSPS
AD9625 Evaluation and Synchronization
AD9625 Evaluation Board
ADA4961 & AD9625 Analog Signal Chain Evaluation and
Converter Synchronization
ADL5567 & AD9625 Analog Signal Chain Evaluation and
ADF4355-2 Wideband Synthesizer with VCO
DOCUMENTATION
Data Sheet
AD9625: 12-Bit, 2.6 GSPS/2.5 GSPS/2.0 GSPS, 1.3 V/2.5 V
Analog-to-Digital Converter Data Sheet
User Guides
AD-FMCADC2-EBZ FMC Board User Guide
TOOLS AND SIMULATIONS
Visual Analog
AD9625 AMI Model
REFERENCE MATERIALS
Informational
JESD204 Serial Interface
Press
2.6-GHz A/D Converter in High-Reliability Package Meets
Specific Sample Rate and Dynamic Range Requirements
of Aerospace/Defense Applications
Analog Devices Unveils 2.5-GSPS A/D Converter, Driver
Amplifier and Rapid Prototyping FMC Module
Global Leader in Converter Technology Releases
Industry’s Highest Performing 2-GSPS Data Converter
New PLLs Deliver Widest Frequency Range Coverage and
Lowest VCO Phase Noise in a Single Device
Technical Articles
A Test Method for Synchronizing Multiple GSPS
Converters
Designing High Speed Analog Signal Chains from DC to
Wideband
MS-2660: Understanding Spurious-Free Dynamic Range in
Wideband GSPS ADCs
MS-2670-1: The Demand for Digital: Challenges and
Solutions for High Speed Analog-to-Digital Converters
and Radar Systems
MS-2672: JESD204B Subclasses - Part 1: An Introduction to
JESD204B Subclasses and Deterministic Latency
MS-2677: JESD204B Subclasses - Part 2: Subclass 1 vs.
Subclass 2 System Considerations
MS-2702: Gigasample ADCs Run Fast to Solve New
Challenges
MS-2708: GSPS Data Converters to the Rescue for
Electronics Surveillance and Warfare Systems
MS-2714: Understanding Layers in the JESD204B
Specificaton: A High Speed ADC Perspective, Part 1
MS-2728: Demystifying the Conversion Error Rate of High
Speed ADCs
MS-2735: Maximizing the Dynamic Range of Software-
Defined Radio
Taming the Wideband Conundrum with RF Sampling
ADCs
DESIGN RESOURCES
AD9625 Material Declaration
PCN-PDN Information
Quality And Reliability
Symbols and Footprints
DISCUSSIONS
View all AD9625 EngineerZone Discussions.
SAMPLE AND BUY
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TECHNICAL SUPPORT
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number.
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AD9625 Data Sheet
Rev. C | Page 2 of 72
TABLE OF CONTENTS
Features .............................................................................................. 1
Applications ....................................................................................... 1
Functional Block Diagram .............................................................. 1
General Description ......................................................................... 1
Product Highlights ........................................................................... 1
Revision History ............................................................................... 3
Specifications ..................................................................................... 4
DC Specifications ......................................................................... 4
AC Specifications .......................................................................... 5
Digital Specifications ................................................................... 6
Switching Specifications .............................................................. 7
Timing Specifications .................................................................. 7
Absolute Maximum Ratings ............................................................ 9
Thermal Characteristics .............................................................. 9
ESD Caution .................................................................................. 9
Pin Configuration and Function Descriptions ........................... 10
Typical Performance Characteristics ........................................... 16
AD9625-2.0 ................................................................................. 17
AD9625-2.5 ................................................................................. 20
AD9625-2.6 ................................................................................. 24
Equivalent Test Circuits ................................................................. 27
Theory of Operation ...................................................................... 28
ADC Architecture ...................................................................... 28
Fast Detect ................................................................................... 28
Gain Threshold Operation ........................................................ 28
Test Modes ................................................................................... 29
Analog Input Considerations ........................................................ 30
Differential Input Configurations ............................................ 30
Using the ADA4961 ................................................................... 30
DC Coupling ............................................................................... 32
Clock Input Considerations ...................................................... 32
Digital Downconverters (DDC) ................................................... 33
Frequency Synthesizer and Mixer ............................................ 33
Numerically Controlled Oscillator .......................................... 33
High Bandwidth Decimator ..................................................... 33
Low Bandwidth Decimator ....................................................... 36
Digital Outputs ............................................................................... 37
Introduction to the JESD204B Interface ................................. 37
Functional Overview ................................................................. 37
JESD204B Link Establishment ................................................. 39
Physical Layer Output ................................................................ 43
Scrambler ..................................................................................... 43
Tail Bits ........................................................................................ 43
DDC Modes (Single and Dual) ................................................ 43
CheckSum ................................................................................... 44
8-Bit/10-Bit Encoder Control ................................................... 44
Initial Lane Alignment Sequence (ILAS) ................................ 44
Lane Synchronization ................................................................ 45
JESD204B Application Layers .................................................. 48
Frame Alignment Character Insertion .................................... 51
Thermal Considerations ............................................................ 51
Power Supply Considerations ................................................... 51
Serial Port Interface (SPI) .............................................................. 52
Configuration Using the SPI ..................................................... 52
Hardware Interface ..................................................................... 52
Memory Map .................................................................................. 53
Reading the Memory Map Register ......................................... 53
Memory Map Registers ............................................................. 53
Applications Information .............................................................. 71
Design Guidelines ...................................................................... 71
Power and Ground Recommendations ................................... 71
Clock Stability Considerations ................................................. 71
SPI Port ........................................................................................ 71
Outline Dimensions ....................................................................... 72
Ordering Guide .......................................................................... 72
Data Sheet AD9625
Rev. C | Page 3 of 72
REVISION HISTORY
9/2016—Rev. B to Rev. C
Changes to ADC Output Control Bits on JESD204B Samples
Section .............................................................................................. 45
Changes to Table 94 ........................................................................ 67
Changes to Table 110 and Table 111 ............................................. 69
Changes to Table 113 and Table 114 ............................................. 70
Changes to the Clock Stability Considerations Section ............. 71
Changes to Ordering Guide ........................................................... 72
5/2015—Rev. A to Rev. B
Added AD9625-2.6 ....................................................... Throughout
Change to Figure 1 ............................................................................ 1
Changes to Table 1 ............................................................................ 4
Changes to Table 2 ............................................................................ 5
Change to Figure 5 .......................................................................... 10
Added Endnote 1, Table 8 .............................................................. 11
Added Endnote 2, Table 9 .............................................................. 13
Added AD9625-2.6 Section ........................................................... 24
Changes to Figure 61 and Figure 63 ............................................. 27
Changes to Table 11 ........................................................................ 30
Added Using the ADA4961 Section ............................................. 30
Added Figure 77; Renumbered Sequentially, Figure 78,
Figure 79, and Figure 80 ................................................................. 31
Changes to Table 12 ........................................................................ 34
Changes to Low Bandwidth Decimator Section and Table 13 ..... 36
Changes to Table 28 ........................................................................ 54
Changes to Table 107 ...................................................................... 69
Changes to Ordering Guide ........................................................... 72
9/2014—Rev. 0 to Rev. A
Added AD9625-2.5 ....................................................... Throughout
Changes to Features and General Description Sections .............. 1
Changes to Table 1 ............................................................................ 4
Changes to Table 2 ............................................................................ 5
Changes to Table 3 ............................................................................ 6
Changes to Table 4 ............................................................................ 7
Changes to Figure 3 and Figure 4 .................................................... 8
Changes to Table 6 ............................................................................ 9
Changes to Pin K4; Figure 5, Table 8, and Table 9 ...................... 10
Added Typical Performance Characteristics Summary and
Changes to Typical Performance Characteristics ....................... 16
Changes to Figure 45, Figure 49, and Figure 50; Added
Figure 51 to Figure 54 ..................................................................... 23
Changes to Gain Threshold Operation Section .......................... 24
Changes to Analog Input Considerations Section ...................... 26
Changes to Digital Downconverters (DDC) Section ................. 28
Added Figure 68 .............................................................................. 32
Changes to Data Streaming Section; Added Link Setup
Parameters Section .......................................................................... 33
Changes to Digital Outputs, Timing, and Controls Section and
Table 15 ............................................................................................. 34
Changes to Table 16 and Table 17 ................................................. 35
Added Table 18 ................................................................................ 36
Added Multichip Synchronization Using SYSREF± Timestamp,
Six Lane Output Mode, and SYSREF± Setup and Hold IRQ
Sec tions ............................................................................................. 39
Added IRQ Guardband Delays (SYSREF± Setup and Hold)
Section .............................................................................................. 40
Added Using Rising/Falling Edges of CLK to Latch SYSREF±
Section .............................................................................................. 41
Changes to Configuration Using the SPI Section ....................... 46
Changes to Transfer Register Map Section, Table 26, and
Table 27 ............................................................................................. 47
Changes to Table 28, Table 29, and Table 30 ............................... 48
Changes to Table 33 and Table 34 ................................................. 49
Changes to Table 53 ........................................................................ 52
Changes to Table 54 ........................................................................ 52
Changes to Table 58 ........................................................................ 54
Changes to Table 71 ........................................................................ 56
Changes to Table 79 and Table 80 ................................................. 57
Changes to Table 81, Table 82, Table 83, Table 84, Table 85, and
Table 86 ............................................................................................. 58
Changes to Table 89 ........................................................................ 59
Changes to Table 92 and Table 93 ................................................. 60
Changes to Table 94, Table 97, and Table 98 ............................... 61
Changes to Table 101 and Table 106 ............................................. 62
Added Table 107 and Table 108 ..................................................... 63
Added Table 115 and Table 116 ..................................................... 64
Added Applications Information Section .................................... 65
Changes to Ordering Guide ........................................................... 66
5/2014—Revision 0: Initial Version
AD9625 Data Sheet
Rev. C | Page 4 of 72
SPECIFICATIONS
DC SPECIFICATIONS
AVDD1 = DVDD1 = DRVDD1 = 1.3 V, AVDD2 = DVDD2 = DRVDD2 = 2.5 V, specified maximum sampling rate, 1.2 V internal
reference, AIN = −1.0 dBFS, default SPI settings, dc-coupled output data, unless otherwise noted.
Table 1.
Parameter
Test Conditions/
Comments Temperature1
AD9625-2.0 AD9625-2.5 AD9625-2.6
Unit Min Typ Max Min Typ Max Min Typ Max
RESOLUTION 12 12 12 Bits
ACCURACY
No Missing Codes Full Guaranteed Guaranteed Guaranteed
Offset Error Full −7 ±0.5 +6.4 −7 ±0.5 +6.4 −8.5 ±0.5 +7.0 LSB
Gain Error Full −8 +8 −10.8 +14.2 −13.8 +20.9 %FSR
Differential Nonlinearity
(DNL)
Full −0.7 ±0.3 +0.7 −0.5 ±0.3 +0.7 −0.6 ±0.3 +0.7 LSB
Integral Nonlinearity (INL) Full −3.6 ±0.9 +3.6 −2.1 ±1.0 +2.1 −2.7 ±1.0 +2.3 LSB
ANALOG INPUTS
Differential Input
Voltage Range Internal VREF = 1.2 V Full 1.1 1 1 V p-p
Resistance 25°C 100 100 100 Ω
Capacitance 25°C 1.5 1.5 1.5 pF
Internal Common-Mode
Voltage (VCM)
Full 492 525 563 492 525 563 492 525 563 mV
Analog Full-Power
Bandwidth2 Internal termination 25°C 3.2 3.2 3.2 GHz
Input Referred Noise 25°C 2 2 2 LSBRMS
POWER SUPPLIES
AVDD1 Full 1.26 1.3 1.32 1.26 1.3 1.32 1.26 1.3 1.32 V
AVDD2 Full 2.4 2.5 2.6 2.4 2.5 2.6 2.4 2.5 2.6 V
DRVDD1 Full 1.26 1.3 1.32 1.26 1.3 1.32 1.26 1.3 1.32 V
DRVDD2 Full 2.4 2.5 2.6 2.4 2.5 2.6 2.4 2.5 2.6 V
DVDD1 Full 1.26 1.3 1.32 1.26 1.3 1.32 1.26 1.3 1.32 V
DVDD2 Full 2.4 2.5 2.6 2.4 2.5 2.6 2.4 2.5 2.6 V
DVDDIO Full 2.4 2.5 3.3 2.4 2.5 3.3 2.4 2.5 3.3 V
SPI_VDDIO Full 2.4 2.5 3.3 2.4 2.5 3.3 2.4 2.5 3.3 V
IAVDD1 Full
1120 1222 1250 1351 1267 1390 mA
IAVDD2 Full
383 460 427 491 432 492 mA
IDRVDD1 Full
456 470 476 518 497 544 mA
IDRVDD2 Full
9 10 9 10
9 10 mA
IDVDD1 Full
410 430 425 473 441 503 mA
IDVDD2 Full <1 <1 <1 mA
IDVDDIO Full <1 <1 <1 mA
ISPI_VDDIO Full <1 <1 <1 mA
Power Dissipation Eight lane mode Full 3.48 3.8 3.90 4.2 4.0 4.3 W
Power-Down Dissipation 125 3.8 125 125 mW
1 Full temperature range is −40°C to +85°C measured at the case (TC).
2 See Figure 75 and Figure 76 for networks.
Data Sheet AD9625
Rev. C | Page 5 of 72
AC SPECIFICATIONS
AVDD1 = DVDD1 = DRVDD1 = 1.3 V, AVDD2 = DVDD2 = DRVDD2 = 2.5 V, specified maximum sampling, 1.2 V internal reference,
AIN = −1.0 dBFS, sample clock input = 1.65 V p-p differential, default SPI settings, unless otherwise noted.
Table 2.
Parameter
Test Conditions/
Comments Temperature1
AD9625-2.0 AD9625-2.5 AD9625-2.6
Unit Min Typ Max Min Typ Max Min Typ Max
SPEED GRADE 2.0 2.5 2.6 GSPS
ANALOG INPUT Full scale Full 1.1 1.2 1.1 V p-p
NOISE DENSITY 25°C −149.0 −149.5 −150.0 dBFS/Hz
SIGNAL-TO-NOISE RATIO
(SNR)
fIN = 100 MHz 25°C 59.5 58.3 58.1 dBFS
fIN = 500 MHz 25°C 59.4 58.0 58.0 dBFS
fIN = 1000 MHz 25°C 59.0 57.6 57.5 dBFS
fIN = 1800 MHz Full 55.4 58.2 54.1 57.0 55.0 56.6 dBFS
SIGNAL-TO-NOISE AND
DISTORTION (SINAD)
fIN = 100 MHz 25°C 58.4 57.2 57.0 dBc
fIN = 500 MHz 25°C 58.4 57.0 56.9 dBc
fIN = 1000 MHz 25°C 58.0 56.5 56.4 dBc
fIN = 1800 MHz Full 54.1 57.2 53.1 55.9 53.9 55.6 dBc
EFFECTIVE NUMBER OF
BITS (ENOB)
fIN = 100 MHz 25°C 9.4 9.2 9.2 Bits
fIN = 500 MHz 25°C 9.4 9.2 9.2 Bits
fIN = 1000 MHz 25°C 9.3 9.1 9.1 Bits
fIN = 1800 MHz 25°C 9.2 9.0 8.9 Bits
SPURIOUS FREE
DYNAMIC RANGE
(SFDR)
Including second or
thrid harmonic
fIN = 100 MHz 25°C 80 77 80.5 dBc
fIN = 500 MHz 25°C 81 76 79.6 dBc
fIN = 1000 MHz 25°C 80 79 77.3 dBc
fIN = 1800 MHz Full 67 76 70 77 65 75.4 dBc
WORST OTHER SPUR Excluding second or
third harmonic
fIN = 100 MHz 25°C −80 −77 −81 dBc
fIN = 500 MHz 25°C −86 −76 −83 dBc
fIN = 1000 MHz 25°C −83 −82 −80 dBc
fIN = 1800 MHz Full −85 −73 −78 −70
−78.0 −66.0 dBc
TWO-TONE
INTERMODULATION
DISTORTION (IMD)
At −7 dBFS per tone
fIN1 = 728.5 MHz, fIN2 =
731.5 MHz
25°C
−82.8 −81.2 −78.3 dBc
fIN1 = 1805.5 MHz, fIN2 =
1808.5 MHz
25°C
−77.6 −76.3 −77.7 dBc
1 Full temperature range is −40°C to +85°C measured at the case (TC).
AD9625 Data Sheet
Rev. C | Page 6 of 72
DIGITAL SPECIFICATIONS
AVDD1 = DVDD1 = DRVDD1 = 1.3 V, AVDD2 = DVDD2 = DRVDD2 = 2.5 V, specified maximum sampling rate, 1.2 V internal
reference, AIN = −1.0 dBFS, default SPI settings, unless otherwise noted.
Table 3.
Parameter Temperature1 Min Typ Max Unit
CLOCK INPUTS (CLK+, CLK−)
Differential Input Voltage Full 500 1800 mV p-p
Common-Mode Input Voltage Full 0.88 V
Input Resistance (Differential) Full 40
Input Capacitance Full 1.5 pF
SYSREF INPUTS (SYSREF+, SYSREF−)
Differential Input Voltage Full 500 1800 mV p-p
Common-Mode Input Voltage Full 0.88 V
Input Resistance (Differential) Full 40
Input Capacitance Full 1.5 pF
LOGIC INPUTS (SDIO, SCLK, CSB)
Logic Compliance CMOS
Voltage
Logic 1 Full 0.8 × SPI_DVDDIO V
Logic 0 Full 0.5 V
Input Resistance Full 30
Input Capacitance Full 0.5 pF
SYNCB+/SYNCB− INPUT
Logic Compliance Full LVDS
Input Voltage
Differential Full 250 1200 mV p-p
Common Mode Full 1.2 V
Input Resistance (Differential) Full 100 Ω
Input Capacitance Full 2.5 pF
LOGIC OUTPUT (SDIO)
Logic Compliance CMOS
Voltage
Logic 1 (IOH = 800 μA) Full 0.8 × SPI_VDDIO V
Logic 0 (IOL = 50 μA) Full 0.3 V
DIGITAL OUTPUTS (SERDOUT[x]±)
Compliance Full CML
Output Voltage
Differential Full 360 700 800 mV p-p
Offset Full DRVDD/2 mV p-p
Differential Return Loss (RLDIFF)2 25°C 8 dB
Common-Mode Return Loss (RLCM) 25°C 6 dB
Differential Termination Impedance 25°C 100 Ω
RESET (RSTB)
Voltage
Logic 1 Full 0.8 × DVDDIO V
Logic 0 Full 0.5 V
Input Resistance (Differential) Full 20
Input Capacitance Full 2.5 pF
FAST DETECT (FD), PWDN, AND INTERRUPT (IRQ)
Logic Compliance CMOS
Voltage
Logic 1 Full 0.8 × DVDDIO V
Logic 0 Full 0.5 V
Input Resistance (Differential) Full 20
Input Capacitance Full 2.5 pF
1 Full temperature range is −40°C to +85°C measured at the case (TC).
2 Differential and common-mode return loss measured from 100 MHz to 0.75 × baud rate.
Data Sheet AD9625
Rev. C | Page 7 of 72
SWITCHING SPECIFICATIONS
AVDD1 = DVDD1 = DRVDD1 = 1.3 V, AVDD2 = DVDD2 = DRVDD2 = 2.5 V, specified maximum sampling rate, 1.2 V internal
reference, AIN = −1.0 dBFS, default SPI settings, unless otherwise noted.
Table 4.
Parameter Test Conditions/Comments Temperature1 Min Typ Max Unit
CLOCK (CLK)
Maximum Clock Rate Full 2600 MSPS
Minimum Clock Rate Full 3302 MSPS
Clock Pulse Width High Full 50 ± 5 % duty cycle
Clock Pulse Width Low Full 50 ± 5 % duty cycle
SYSREF (SYSREF±)3
Setup Time (tSU_SR) 25°C +200 ps
Hold Time (tH_SR) 25°C −100 ps
FAST DETECT OUTPUT (FD)
Latency Full 82 Clock cycles
OUTPUT PARAMETERS (SERDOUT[x]±)
Rise Time 25°C 70 ps
Fall Time 25°C 70 ps
Pipeline Latency Eight lane mode 25°C 226 Clock cycles
SYNCB± Falling Edge to First K.28 Characters 25°C 4 Multiframes
CGS Phase K.28 Characters Duration 25°C 1 Multiframes
Differential Termination Resistance 25°C 100 Ω
APERTURE
Delay Full 200 ps
Uncertainty (Jitter) Full 80 fS rms
Out-of-Range Recovery Time Full 2 Clock cycles
1 Full temperature range is −40°C to +85°C measured at the case (TC).
2 Must use a two-lane, generic output lane configuration for minimum sample rate. For more information, see the lane table in the JESD204B specification document.
3 SYSREF± setup and hold times are defined with respect to the rising SYSREF± edge and rising clock edge. Positive setup time leads the clock edge. Negative hold time
also leads the clock edge.
TIMING SPECIFICATIONS
Table 5.
Parameter Test Conditions/Comments Min Typ Max Unit
SPI TIMING REQUIREMENTS
tDS Setup time between the data and the rising edge of SCLK 2 ns
tDH Hold time between the data and the rising edge of SCLK 2 ns
tCLK Period of the SCLK 40 ns
tS Setup time between CSB and SCLK 2 ns
tH Hold time between CSB and SCLK 2 ns
tHIGH Minimum period that SCLK should be in a logic high state 10 ns
tLOW Minimum period that SCLK should be in a logic low state 10 ns
tEN_SDIO Time required for the SDIO pin to switch from an input to an
output relative to the SCLK falling edge
10 ns
tDIS_SDIO Time required for the SDIO pin to switch from an output to an
input relative to the SCLK rising edge
10 ns
AD9625 Data Sheet
Rev. C | Page 8 of 72
Timing Diagrams
11814-202
CLK+
CLK–
SYSREF+
SYSREF–
t
SU_SR
t
H_SR
Figure 2. SYSREF± Setup and Hold Timing
DON’T CARE
DON’T CAREDON’T CARE
DON’T CARE
SDIO
SCLK
CSB
t
S
t
DS
t
DH
t
HIGH
t
LOW
t
CLK
t
H
R/W W1W0A12A11A10A9A8A7 D5D4D3D2D1D0
11814-203
Figure 3. Serial Port Interface Timing Diagram (MSB First)
S
ERDOUT0±
N – 225
N – 226
N – 224 N – 1
SAMPLE N
N + 1
CLK+
CLK–
CLK+
CLK–
S
ERDOUT7±
ANALOG
INPUT
SIGNAL
SAMPLE N – 226
ENCODED INTO 2
8-BIT/10-BIT SYMBOL
SAMPLE N – 225
ENCODED INTO 2
8-BIT/10-BIT SYMBOL
SAMPLE N – 224
ENCODED INTO 2
8-BIT/10-BIT SYMBOL
11814-204
Figure 4. Data Output Timing for Eight Lane Mode
Data Sheet AD9625
Rev. C | Page 9 of 72
ABSOLUTE MAXIMUM RATINGS
Table 6.
Parameter Rating
Electrical
AVDD1 to AGND −0.3 V to +1.32 V
AVDD2 to AGND −0.3 V to +2.75 V
DRVDD1 to DRGND −0.3 V to +1.32 V
DRVDD2 to DRGND −0.3 V to +2.75 V
DVDD1 to DGND −0.3 V to +1.32 V
DVDD2 to DGND −0.3 V to +2.75 V
DVDDIO to DGND −0.3 V to +3.63 V
SPI_VDDIO to DGND −0.3 V to +3.63 V
AGND to DRGND −0.3 V to +0.3 V
VIN± to AGND −0.3 V to AVDD1 + 0.2 V
VCM to AGND −0.3 V to AVDD1 + 0.2 V
VMON to AGND −0.3 V to AVDD1 + 0.2 V
CLK± to AGND −0.3 V to AVDD1 + 0.2 V
SYSREF± to AGND −0.3 V to AVDD1 + 0.2 V
SYNCINB± to DRGND −0.3 V to DRVDD2 + 0.2 V
SCLK to DRGND −0.3 V to SPI_VDDIO + 0.2 V
SDIO to DRGND −0.3 V to SPI_VDDIO + 0.2 V
IRQ to DRGND −0.3 V to DVDDIO + 0.2 V
RSTB to DRGND −0.3 V to DVDDIO + 0.2 V
CSB to DRGND −0.3 V to SPI_VDDIO + 0.2 V
FD to DRGND −0.3 V to DVDDIO + 0.2 V
DIVCLK± to DRGND −0.3 V to DRVDD2 + 0.2 V
SERDOUT[x]± to DRGND −0.3 V to DRVDD1 + 0.2 V
Environmental
Storage Temperature Range −60°C to +150°C
Operating Case Temperature Range −40°C to +85°C
(measured at case)
Maximum Junction Temperature 110°C
Stresses at or above those listed under Absolute Maximum
Ratings may cause permanent damage to the product. This is a
stress rating only; functional operation of the product at these
or any other conditions above those indicated in the operational
section of this specification is not implied. Operation beyond
the maximum operating conditions for extended periods may
affect product reliability.
THERMAL CHARACTERISTICS
The following characteristics are for a 4-layer and 10-layer
printed circuit board (PCB).
Table 7. Thermal Resistance
PCB TA (°C)
θJA
(°C/W)
ΨJT
(°C/W)
ΨJB
(°C/W)
θJC
(°C/W)
4-Layer 85.0 18.7 0.61 6.1 1.4
10-Layer 85.0 11.5 0.61 4.1 N/A1
1 N/A means not applicable.
ESD CAUTION
AD9625 Data Sheet
Rev. C | Page 10 of 72
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
AGND
AGND
AGND
DVDD1
DGND
DVDD1
DGND
DVDD1
DGND
DVDD1
DGND
DRGND
DRVDD1
DRVDD1
A
B
C
D
E
F
G
H
J
K
L
M
N
P
DNC
AGND
AGND
AGND
DVDD1
DGND
DVDD1
DGND
DVDD1
DGND
DVDD1
DRGND
SERDOUT
[7]+
SERDOUT
[7]–
AGND
AGND
AGND
DVDD1
DGND
DVDD1
DGND
DVDD1
DGND
RSTB
SYNCINB–
DRGND
SERDOUT
[6]+
SERDOUT
[6]–
AVDD1
AGND
AGND
DNC
DVDD2
SPI_VDDIO
CSB
SCLK
SDIO
PWDN
SYNCINB+
DRGND
SERDOUT
[5]+
SERDOUT
[5]–
AGND
AVDD1
AGND
AGND
VMON
DVDDIO
DVDDIO
IRQ
FD
AGND
DGND
DRGND
SERDOUT
[4]+
SERDOUT
[4]–
AVDD2
AGND
AVDD1
AGND
AGND
AGND
AGND
AGND
RBIAS_EXT
AGND
DGND
DRGND
DRVDD1
DRVDD1
VCM
AVDD2
AGND
AVDD1
AVDD1
AVDD1
AVDD1
AVDD1
AVDD1
AGND
DGND
DRGND
SERDOUT
[3]+
SERDOUT
[3]–
AGND
AGND
AVDD2
AVDD2
AVDD2
AVDD2
AVDD2
AVDD2
AVDD2
AGND
DGND
DRGND
SERDOUT
[2]+
SERDOUT
[2]–
VIN+
AGND
AGND
AGND
AGND
AGND
AGND
AGND
AGND
AGND
DGND
DRGND
SERDOUT
[1]+
SERDOUT
[1]–
VIN–
AGND
AGND
AGND
AGND
AGND
AGND
AGND
AGND
AGND
DNC
DRGND
SERDOUT
[0]+
SERDOUT
[0]–
AGND
AGND
AVDD2
AVDD2
AVDD2
AVDD2
AVDD2
AVDD2
AVDD2
AGND
DNC
DRVDD1
DRVDD1
DRVDD1
VM_BYP
AVDD2
AGND
AVDD1
AVDD1
AVDD1
AVDD1
AVDD1
AVDD1
AGND
DNC
REXT
VP_BYP
DRGND
AVDD2
AGND
AGND
AVDD1
AGND
AGND
AGND
AGND
AGND
AGND
AGND
DRGND
DRVDD2
DIVCLK–
AVDD2
1234567891011121314
AGND
AVDD1
AVDD1
AGND
CLK+
CLK
AGND
SYSREF+
SYSREF–
AGND
DRGND
DRVDD2
DIVCLK+
A
D9625
TOP VIEW
(Not to Scale)
NOTES
1. DNC = DO NOT CONNECT. DO NOT CONNECT TO THIS PIN. LEAVE THIS PIN FLOATING.
11814-009
Figure 5. Pin Configuration
Data Sheet AD9625
Rev. C | Page 11 of 72
Table 8. Pin Function Descriptions (By Pin Number)
Pin No. Mnemonic Type Description
A1 to A3 AGND Ground ADC Analog Ground. These pins connect to the analog ground plane.
A4 AVDD1 Power ADC Analog Power Supply (1.30 V).
A5 AGND Ground ADC Analog Ground. This pin connects to the analog ground plane.
A6 AVDD2 Power ADC Analog Power Supply (2.50 V).
A7 VCM Output Analog Input, Common Mode (0.525 V).
A8 AGND Ground ADC Analog Ground. This pin connects to the analog ground plane.
A9 VIN+ Input Differential Analog Input, True.
A10 VIN− Input Differential Analog Input, Complement.
A11 AGND Ground ADC Analog Ground. This pin connects to the analog ground plane.
A12 VM_BYP Input Voltage Bypass.
A13 AVDD2 Power ADC Analog Power Supply (2.50 V).
A14 AVDD2 Power ADC Analog Power Supply (2.50 V).
B1 to B4 AGND Ground ADC Analog Ground. These pins connect to the analog ground plane.
B5 AVDD1 Power ADC Analog Power Supply (1.30 V).
B6 AGND Ground ADC Analog Ground. This pin connects to the analog ground plane.
B7 AVDD2 Power ADC Analog Power Supply (2.50 V).
B8 to B11 AGND Ground ADC Analog Ground. These pins connect to the analog ground plane.
B12 AVDD2 Power ADC Analog Power Supply (2.50 V).
B13, B14 AGND Ground ADC Analog Ground. These pins connect to the analog ground plane.
C1 to C5 AGND Ground ADC Analog Ground. These pins connect to the analog ground plane.
C6 AVDD1 Power ADC Analog Power Supply (1.30 V).
C7 AGND Ground ADC Analog Ground. This pin connects to the analog ground plane.
C8 AVDD2 Power ADC Analog Power Supply (2.50 V).
C9, C10 AGND Ground ADC Analog Ground. These pins connect to the analog ground plane.
C11 AVDD2 Power ADC Analog Power Supply (2.50 V).
C12, C13 AGND Ground ADC Analog Ground. These pins connect to the analog ground plane.
C14 AVDD1 Power ADC Analog Power Supply (1.30 V).
D1 to D3 DVDD1 Power ADC Digital Power Supply (1.30 V).
D4 DNC N/A1 Do Not Connect. Do not connect to this pin. Leave this pin floating.
D5, D6 AGND Ground ADC Analog Ground. These pins connect to the analog ground plane.
D7 AVDD1 Power ADC Analog Power Supply (1.30 V).
D8 AVDD2 Power ADC Analog Power Supply (2.50 V).
D9, D10 AGND Ground ADC Analog Ground. These pins connect to the analog ground plane.
D11 AVDD2 Power ADC Analog Power Supply (2.50 V).
D12 to D14 AVDD1 Power ADC Analog Power Supply (1.30 V).
E1 to E3 DGND Ground Digital Control Ground Supply. These pins connect to the digital ground plane.
E4 DVDD2 Power ADC Digital Power Supply (2.5 V).
E5 VMON Output CTAT Voltage Monitor Output.
E6 AGND Ground ADC Analog Ground. This pin connects to the analog ground plane.
E7 AVDD1 Power ADC Analog Power Supply (1.30 V).
E8 AVDD2 Power ADC Analog Power Supply (2.50 V).
E9, E10 AGND Ground ADC Analog Ground. These pins connect to the analog ground plane.
E11 AVDD2 Power ADC Analog Power Supply (2.50 V).
E12 AVDD1 Power ADC Analog Power Supply (1.30 V).
E13, E14 AGND Ground ADC Analog Ground. These pins connect to the analog ground plane.
F1 to F3 DVDD1 Power ADC Digital Power Supply (1.30 V).
F4 SPI_VDDIO Power SPI Digital Power Supply (2.50 V).
F5 DVDDIO Power Digital I/O Power Supply (2.50 V).
F6 AGND Ground ADC Analog Ground. This pin connects to the analog ground plane.
F7 AVDD1 Power ADC Analog Power Supply (1.30 V).
F8 AVDD2 Power ADC Analog Power Supply (2.50 V).
F9, F10 AGND Ground ADC Analog Ground. These pins connect to the analog ground plane.
AD9625 Data Sheet
Rev. C | Page 12 of 72
Pin No. Mnemonic Type Description
F11 AVDD2 Power ADC Analog Power Supply (2.50 V).
F12 AVDD1 Power ADC Analog Power Supply (1.30 V).
F13 AGND Ground ADC Analog Ground. This pin connects to the analog ground plane.
F14 CLK+ Input ADC Clock Input, True.
G1 to G3 DGND Ground Digital Control Ground Supply. These pins connect to the digital ground plane.
G4 CSB Input SPI Chip Select CMOS Input. Active low.
G5 DVDDIO Power Digital I/O Power Supply (2.50 V).
G6 AGND Ground ADC Analog Ground. This pin connects to the analog ground plane.
G7 AVDD1 Power ADC Analog Power Supply (1.30 V).
G8 AVDD2 Power ADC Analog Power Supply (2.50 V).
G9, G10 AGND Ground ADC Analog Ground. These pins connect to the analog ground plane.
G11 AVDD2 Power ADC Analog Power Supply (2.50 V).
G12 AVDD1 Power ADC Analog Power Supply (1.30 V).
G13 AGND Ground ADC Analog Ground. This pin connects to the analog ground plane.
G14 CLK− Input ADC Clock Input, Complement.
H1 to H3 DVDD1 Power ADC Digital Power Supply (1.30 V).
H4 SCLK Input SPI Serial Clock CMOS Input.
H5 IRQ Output Interrupt Request Output Signal.
H6 AGND Ground ADC Analog Ground. This pin connects to the analog ground plane.
H7 AVDD1 Power ADC Analog Power Supply (1.30 V).
H8 AVDD2 Power ADC Analog Power Supply (2.50 V).
H9, H10 AGND Ground ADC Analog Ground. These pins connect to the analog ground plane.
H11 AVDD2 Power ADC Analog Power Supply (2.50 V).
H12 AVDD1 Power ADC Analog Power Supply (1.30 V).
H13, H14 AGND Ground ADC Analog Ground. These pins connect to the analog ground plane.
J1 to J3 DGND Ground Digital Control Ground Supply. These pins connect to the digital ground plane.
J4 SDIO I/O SPI Serial Data CMOS Input/Output; Scan Output 1.
J5 FD Output Fast Detect Output. This pin requires an external 10 kΩ resistor connected to ground.
J6 RBIAS_EXT Input Reference Bias. This pin requires an external 10 kΩ resistor connected to ground.
J7 AVDD1 Power ADC Analog Power Supply (1.30 V).
J8 AVDD2 Power ADC Analog Power Supply (2.50 V).
J9, J10 AGND Ground ADC Analog Ground. These pins connect to the analog ground plane.
J11 AVDD2 Power ADC Analog Power Supply (2.50 V).
J12 AVDD1 Power ADC Analog Power Supply (1.30 V).
J13 AGND Ground ADC Analog Ground. This pin connects to the analog ground plane.
J14 SYSREF+ Input System Reference Chip Synchronization, True.
K1 to K2 DVDD1 Power ADC Digital Power Supply (1.30 V).
K3 RSTB Input Chip Digital Reset, Active Low.
K4 PWDN Input Power-down.
K5 to K13 AGND Ground ADC Analog Ground. These pins connect to the analog ground plane.
K14 SYSREF− Input System Reference Chip Synchronization, Complement.
L1 DGND Ground Digital Control Ground Supply. This pin connects to the digital ground plane.
L2 DNC N/A1 Do Not Connect. Do not connect to this pin. Leave this pin floating.
L3 SYNCINB− Input Synchronization, Complement.
L4 SYNCINB+ Input Synchronization, True. SYNCINB LVDS input (active low, true).
L5 to L9 DGND Ground Digital Control Ground Supply. These pins connect to the digital ground plane.
L10 to L12 DNC N/A1 Do Not Connect. Do not connect to these pins. Leave these pins floating.
L13, L14 AGND Ground ADC Analog Ground. These pins connect to the analog ground plane.
M1 to M10 DRGND Ground Digital Driver Ground Supply. These pins connect to the digital driver ground plane.
M11 DRVDD1 Power Power Supply (1.3 V) Reference Clock Divider, VCO, and Synthesizer.
M12 REXT Input External Resistor, 10 kΩ to Ground.
M13, M14 DRGND Ground Digital Driver Ground Supply. This pin connects to the digital driver ground plane.
Data Sheet AD9625
Rev. C | Page 13 of 72
Pin No. Mnemonic Type Description
N1 DRVDD1 Power Serial Digital Power Supply (1.3 V).
N2 SERDOUT[7]+ Output Lane 7 CML Output Data, True.
N3 SERDOUT[6]+ Output Lane 6 CML Output Data, True.
N4 SERDOUT[5]+ Output Lane 5 CML Output Data, True.
N5 SERDOUT[4]+ Output Lane 4 CML Output Data, True.
N6 DRVDD1 Power Serial Digital Power Supply (1.3 V).
N7 SERDOUT[3]+ Output Lane 3 CML Output Data, True.
N8 SERDOUT[2]+ Output Lane 2 CML Output Data, True.
N9 SERDOUT[1]+ Output Lane 1 CML Output Data, True.
N10 SERDOUT[0]+ Output Lane 0 CML Output Data, True.
N11 DRVDD1 Power Serial Digital Power Supply (1.3 V).
N12 VP_BYP Input Voltage Bypass.
N13, N14 DRVDD2 Power Power Supply (2.5 V) Reference Clock Divider for SYNCINB±, DIVCLK±.
P1 DRVDD1 Power Serial Digital Power Supply (1.3 V).
P2 SERDOUT[7]− Output Lane 7 CML Output Data, Complement.
P3 SERDOUT[6]− Output Lane 6 CML Output Data, Complement.
P4 SERDOUT[5]− Output Lane 5 CML Output Data, Complement.
P5 SERDOUT[4]− Output Lane 4 CML Output Data, Complement.
P6 DRVDD1 Power Serializer Digital Power Supply (1.30 V).
P7 SERDOUT[3]− Output Lane 3 CML Output Data, Complement.
P8 SERDOUT[2]− Output Lane 2 CML Output Data, Complement.
P9 SERDOUT[1]− Output Lane 1 CML Output Data, Complement.
P10 SERDOUT[0]− Output Lane 0 CML Output Data, Complement.
P11 DRVDD1 Power Serializer Digital Power Supply (1.30 V).
P12 DRGND Ground Digital Driver Ground Supply. This pin connects to the digital driver ground plane.
P13 DIVCLK− Output Divide-by-4 Reference Clock LVDS, Complement.
P14 DIVCLK+ Output Divide-by-4 Reference Clock LVDS, True.
1 N/A means not applicable.
Table 9. Pin Function Descriptions (By Function)1
Pin No. Mnemonic Type Description
General Power and Ground Supply Pins
A1 to A3, A5, A8, A11, B1 to B4, B6, B8 to B11,
B13, B14, C1 to C5, C7, C9, C10, C12, C13, D5,
D6, D9, D10, E6, E9, E10, E13, E14, F6, F9, F10,
F13, G6, G9, G10, G13, H6, H9, H10, H13, H14,
J9, J10, J13, K5 to K13, L13, L14
AGND Ground
ADC Analog Ground. These pins connect to the analog
ground plane.
J6 RBIAS_EXT Input
Reference Bias. This pin requires an external 10 kΩ resistor
connected to ground.
Clock Pins
F14 CLK+ Input ADC Clock Input, True.
G14 CLK− Input ADC Clock Input, Complement.
ADC Analog Power and Ground Supplies Pins
A6, A13, A14, B7, B12, C8, C11, D8, D11, E8,
E11, F8, F11, G8, G11, H8, H11, J8, J11
AVDD2 Power ADC Analog Power Supply (2.50 V).
A4, B5, C6, C14, D7, D12 to D14, E7, E12, F7,
F12, G7, G12, H7, H12, J7, J12
AVDD1 Power ADC Analog Power Supply (1.30 V).
A12 VM_BYP Input Voltage Bypass.
A1 to A3, A5, A8, A11, B1 to B4, B6, B8 to B11,
B13, B14, C1 to C5, C7, C9, C10, C12, C13,D5,
D6, D9, D10, E6, E9, E10, E13, E14, F6, F9, F10,
F13, G6, G9, G10, G13, H6, H9, H10, H13, H14,
J9, J10, J13, K5 to K13, L13, L14
AGND Ground
ADC Analog Ground. These pins connect to the analog
ground plane.
AD9625 Data Sheet
Rev. C | Page 14 of 72
Pin No. Mnemonic Type Description
ADC Analog Input and Outputs Pins
A9 VIN+ Input Differential Analog Input, True.
A10 VIN− Input Differential Analog Input, Complement.
A7 VCM Output Analog Input, Common Mode (0.525 V).
E5 VMON Output CTAT Voltage Monitor Output (Diode Temperature Sensor).
JESD204B High Speed Power and Ground Pins
N1, N6, N11, P1, P6, P11 DRVDD1 Power Serial Digital Power Supply (1.3 V).
M1 to M10, M13, M14, P12 DRGND Ground Digital Driver Ground Supply. These pins connect to the
digital driver ground plane.
N13, N14 DRVDD2 Power Power Supply (2.5 V) Reference Clock Divider, SYNCINB±,
DIVCLK±.
M11 DRVDD1 Power
Power Supply (1.3 V) Reference Clock Divider, VCO, and
Synthesizer.
N12 VP_BYP Input Voltage Bypass.
L2 DNC N/A2 Do Not Connect. Do not connect to this pin.
JESD204B High Speed Serial I/O Pins
J14 SYSREF+ Input System Reference Chip Synchronization, True.
K14 SYSREF− Input System Reference Chip Synchronization, Complement.
L4 SYNCINB+ Input Synchronization, True. SYNCINB LVDS input (active low, true).
L3 SYNCINB− Input
Synchronization, Complement. SYNCINB LVDS input (active
low, complement).
N10 SERDOUT[0]+ Output Lane 0 CML Output Data, True.
P10 SERDOUT[0]− Output Lane 0 CML Output Data, Complement.
N9 SERDOUT[1]+ Output Lane 1 CML Output Data, True.
P9 SERDOUT[1]− Output Lane 1 CML Output Data, Complement.
N8 SERDOUT[2]+ Output Lane 2 CML Output Data, True.
P8 SERDOUT[2]− Output Lane 2 CML Output Data, Complement.
N7 SERDOUT[3]+ Output Lane 3 CML Output Data, True.
P7 SERDOUT[3]− Output Lane 3 CML Output Data, Complement.
N5 SERDOUT[4]+ Output Lane 4 CML Output Data, True.
P5 SERDOUT[4]− Output Lane 4 CML Output Data, Complement.
N4 SERDOUT[5]+ Output Lane 5 CML Output Data, True.
P4 SERDOUT[5]− Output Lane 5 CML Output Data, Complement.
N3 SERDOUT[6]+ Output Lane 6 CML Output Data, True.
P3 SERDOUT[6]− Output Lane 6 CML Output Data, Complement.
N2 SERDOUT[7]+ Output Lane 7 CML Output Data, True.
P2 SERDOUT[7]− Output Lane 7 CML Output Data, Complement.
P14 DIVCLK+ Output Divide-by-4 Reference Clock LVDS, True.
P13 DIVCLK− Output Divide-by-4 Reference Clock LVDS, Complement.
Digital Supply and Ground Pins
D1 to D3, F1 to F3, H1 to H3, K1 to K2 DVDD1 Power ADC Digital Power Supply (1.3 V).
F5, G5 DVDDIO Power Digital I/O Power Supply (2.5 V).
F4 SPI_VDDIO Power SPI Digital Power Supply (2.5 V).
E4 DVDD2 Power ADC Digital Power Supply (2.5 V).
E1 to E3, G1 to G3, J1 to J3, L1, L5 to L9 DGND Ground Digital Control Ground Supply. These pins connect to the
digital ground plane.
D4 DNC N/A2 Do Not Connect. Do not connect to this pin. Leave this pin
floating.
Digital Control Pins
K3 RSTB Input Chip Digital Reset, Active Low.
K4 PWDN Input Power-down for the AD9625.
M12 REXT Input External Resistor, 10 kΩ to Ground.
G4 CSB Input SPI Chip Select CMOS Input. Active low.
H4 SCLK Input SPI Serial Clock CMOS Input.
Data Sheet AD9625
Rev. C | Page 15 of 72
Pin No. Mnemonic Type Description
J4 SDIO I/O SPI Serial Data CMOS Input/Output.
J5 FD Output
Fast Detect Output. This pin requires an external 10 kΩ
resistor connected to ground.
H5 IRQ Output Interrupt Request Output Signal.
L10 to L12 DNC N/A2 Do Not Connect. Do not connect to these pins. Leave these
pins floating.
1 Note that when pins are relevant to multiple categories, they are repeated in Table 9. Pins may not appear in alphanumeric order within Table 9.
2 N/A means not applicable.
AD9625 Data Sheet
Rev. C | Page 16 of 72
TYPICAL PERFORMANCE CHARACTERISTICS
100
40
45
50
55
60
65
70
80
90
95
75
85
SNR/SFDR (dB)
SNR (dBFS), 240MHz
SFDR (dBc), 240MHz
SNR (dBc), 1821MHz
SFDR (dBc), 1821MHz
11814-330
300
2500
2300
2100
1900
1700
1500
1300
1100
900
700
500
SAMPLE RATE (MSPS)
Figure 6. SNR/SFDR vs. Sample Rate
1300
1200
1100
1000
900
800
700
600
500
400
300
200
100
0
4.5
2.0
2.5
3.0
3.5
4.0
300
2500
2300
2100
1900
1700
1500
1300
1100
900
700
500
CURRENT (mA)
POWER (W)
SAMPLE RATE (MSPS)
I
DVDD2
, I
DRVDD2
I
DRVDD1
TOTAL
POWER
I
AVDD1
I
DVDD1
I
AVDD2
11814-322
TWO LANE
MODE
FOUR LANE
MODE
EIGHT LANE
MODE
Figure 7. Current and Power vs. Sample Rate: Two Lane, Four Lane, and Eight
Lane Output Modes
0
–9
–8
–7
–6
–5
–4
–3
–2
–1
10 50001000100
AMPLITUDE (dBFS)
INPUT FREQUENCY (MHz)
11814-326
Figure 8. Full Power Input Bandwidth (Input Network in Figure 76 Used
>2 GHz, Input Network in Figure 75 Used <2 GHz)
1.0
0.9
0.8
0.7
0.6
0.5
–50 –25 0 25 50 75 100 125
VMON (V)
JUNCTION TEMPERATURE (°C)
11814-344
Figure 9. VMON Output Voltage vs. Junction Temperature VMON (V) =
−0.0013 × TEMP(C) + 0.8675
Data Sheet AD9625
Rev. C | Page 17 of 72
AD9625-2.0
For the AD9625-2.0 model, the full-scale range used is 1.1 V.
0
–120
–100
–80
–60
–40
–20
0 200 400 600 800 1000
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2000MSPS
3010MHz AT –1.0dBFS
SNR = 56.2dBFS
SFDR = 73.1dBc
11814-308
Figure 10. FFT Plot at 2.0 GSPS, fIN = 3010 MHz at AIN (SFDR = 73.1 dBc,
SNR = 56.2 dBFS) (Input Network in Figure 76 Used)
0
–120
–100
–80
–60
–40
–20
0 1000800600400200
11814-104
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2000MSPS
1807.3MHz AT –1dBFS
SNR = 58.12dBFS
SFDR = 75.5dBc
Figure 11. FFT Plot at 2.0 GSPS, fIN = 1807.3 MHz at AIN (SFDR = 75.5 dBc,
SNR = 58.12 dBFS)
0
–120
–100
–80
–60
–40
–20
0 1000800600400200
11814-105
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2000MSPS
730.3MHz AT –1dBFS
SNR = 59.19dBFS
SFDR = 80.9dBc
Figure 12. FFT Plot at 2.0 GSPS, fIN = 730.3 MHz at AIN (SFDR = 80.9 dBc,
SNR = 59.19 dBFS)
0
–120
–100
–80
–60
–40
–20
0 1000800600400200
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2000MSPS
310.3MHz AT –1dBFS
SNR = 59.6dBFS
SFDR = 82.2dBc
11814-106
Figure 13. FFT Plot at 2.0 GSPS, fIN = 310.3 MHz at AIN (SFDR = 82.2 dBc,
SNR = 59.6 dBFS)
100
90
80
70
60
50
40
30
20
10
0
–90 –80 –70 –60 –50 –40 –30 –20 –10 0
11814-108
SNR/SFDR (dB)
AMPLITUDE (dB)
SFDR (dBFS)
SNR (dBFS)
SFDR (dBc)
SNR (dB)
Figure 14. SNR/SFDR vs. Analog Input Amplitude at 2.0 GSPS,
fIN = 241.1 MHz at AIN
100
90
80
70
60
50
40
30
20
10
0
–90 –80 –70 –60 –50 –40 –30 –20 –10 0
11814-109
SNR/SFDR (dB)
AMPLITUDE (dB)
SFDR (dBFS)
SNR (dBFS)
SFDR (dBc)
SNR (dB)
Figure 15. SNR/SFDR vs. Analog Input Amplitude at 2.0 GSPS,
fIN = 1811.3 MHz at AIN
AD9625 Data Sheet
Rev. C | Page 18 of 72
120
100
80
60
40
20
0
–90 –80 –70 –60 –50 –40 –30 –20 –10 0
11814-112
SFDR (dB)
AMPLITUDE (dBFS)
IMD3 (dBFS)
SFDR (dBFS)
SFDR (dBc)
Figure 16. Two Tone SFDR and IMD3 vs. Analog Input Amplitude at 2.0 GSPS
at 1800 MHz AIN
120
100
80
60
40
20
0
–90 –80 –70 –60 –50 –40 –30 –20 –10 0
11814-215
SFDR (dB)
AMPLITUDE (dBFS)
IMD3 (dBFS)
SFDR (dBFS)
SFDR (dBc)
Figure 17. Two Tone SFDR and IMD3 vs. Analog Input Amplitude at 2.0 GSPS
at 230 MHz AIN
5.0
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
MORE N – 4 N – 2 N MOREN + 4N + 2
11814-114
HITS (Millions)
BINS
Figure 18. Input Referred Noise Histogram with 2.0 GSPS
90
85
80
75
70
65
60
55
50
100 300 500 700 900 1100 1300 1500 1700 1900
SNR/SFDR (dB)
ANALOG INPUT FREQUENCY (MHz)
SFDR (dBc)
SNR (dBFS)
+90°C
+25°C
–55°C
11814-113
Figure 19. SNR/SFDR vs. Analog Input Frequency at Different Temperatures
at 2.0 GSPS
0
–120
–100
–80
–60
–40
–20
0 1000800600400200
11814-219
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2000MSPS
f
IN1
= 1805.5MHz AT –7.0dBFS
f
IN2
= 1808.5MHz AT –7.0dBFS
SFDR = 78.117dBc
Figure 20. Two Tone FFT Plot at 2.0 GSPS, fIN1 = 1805.5 MHz and
fIN2 = 1808.5 MHz at AIN, −7.0 dBFS (SFDR = 78.117 dBc)
0
–120
–100
–80
–60
–40
–20
0 1000800600400200
11814-220
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2000MSPS
f
IN1
= 728.5MHz AT –7.0dBFS
f
IN2
= 731.5MHz AT –7.0dBFS
SFDR = 80.98dBc
Figure 21. Two Tone FFT Plot at 2.0 GSPS, fIN1 = 728.5 MHz and
fIN2 = 731.5 MHz at AIN, −7.0 dBFS (SFDR = 80.98 dBc)
Data Sheet AD9625
Rev. C | Page 19 of 72
0
–120
–100
–80
–60
–40
–20
0 1000800600400200
11814-221
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2000MSPS
f
IN1
= 228.5MHz AT –7.0dBFS
f
IN2
= 231.5MHz AT –7.0dBFS
SFDR = 80.76dBc
Figure 22. Two Tone FFT Plot at 2.0 GSPS, fIN1 = 228.5 MHz and
fIN2 = 231.5 MHz at AIN, −7.0 dBFS (SFDR = 80.76 dBc)
0.5
–0.5
–0.4
–0.3
–0.2
–0.1
0
0.1
0.2
0.3
0.4
–1 4095307120471023
11814-222
DNL (LSB)
CODES
Figure 23. Differential Nonlinearity (DNL), ±0.2 LSB at 2.0 GSPS
0.6
–0.6
–0.4
–0.2
0
0.2
0.4
0 4096307220481024
11814-223
INL (LSB)
CODES
Figure 24. Integral Nonlinearity (INL), ±0.4 LSB at 2.0 GSPS
AD9625 Data Sheet
Rev. C | Page 20 of 72
AD9625-2.5
For the AD9625-2.5 model, full-scale range used is 1.2 V.
0
–120
–100
–80
–60
–40
–20
0 250 500 750 1000 1250
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2500MSPS
1816.7MHz AT –1.0dBFS
SNR = 57.1dBFS
SFDR = 80.35dBc
11814-306
Figure 25. FFT Plot at 2.5 GSPS, fIN = 1816.7 MHz at AIN (SFDR = 80.35 dBc,
SNR = 57.1 dBFS)
0
–120
–100
–80
–60
–40
–20
0 250 500 750 1000 1250
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2500MSPS
730.3MHz AT –1.0dBFS
SNR = 57.8dBFS
SFDR = 77.1dBc
11814-307
Figure 26. FFT Plot at 2.5 GSPS, fIN = 730.3 MHz at AIN (SFDR = 77.1 dBc,
SNR = 57.8 dBFS)
0
–120
–100
–80
–60
–40
–20
0 250 500 750 1000 1250
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2500MSPS
115.05MHz AT –1.0dBFS
SNR = 58.1dBFS
SFDR = 78.4dBc
11814-309
Figure 27. FFT Plot at 2.5 GSPS, fIN = 115.05 MHz at AIN (SFDR = 78.4 dBc,
SNR = 58.1 dBFS)
0
–120
–100
–80
–60
–40
–20
0 250 500 750 1000 1250
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2500MSPS
2990.11MHz AT –1.0dBFS
SNR = 55.3dBFS
SFDR = 70.6dBc
11814-310
Figure 28. FFT Plot at 2.5 GSPS, fIN = 2990.11 MHz at AIN (SFDR = 70.6 dBc,
SNR = 55.3 dBFS) (Input Network in Figure 75 Used)
140
–150
–148
–146
–144
–142
0 1000 2000 3000 4000 5000 6000
NOISE SPECTRAL DENSITY (dBFS/Hz)
INPUT FREQUENCY (MHz)
11814-311
Figure 29. Noise Specrtal Density (NSD) vs. AIN at 2.5 GSPS (Input Network in
Figure 76 Used <2 GHz, Input Network in Figure 75 Used >2 GHz)
100
90
80
70
60
50
40
30
20
10
0
–90 –80 –70 –60 –50 –40 30 –20 –10 0
SNR/SFDR (dB)
AMPLITUDE (dB)
SFDR (dBFS)
SNR (dBFS)
SFDR (dBc)
SNR (dB)
11814-320
Figure 30. SNR/SFDR vs. Analog Input Amplitude at 2.5 GSPS, fIN = 241 MHz
at AIN
Data Sheet AD9625
Rev. C | Page 21 of 72
100
90
80
70
60
50
40
30
20
10
0
–90 –80 –70 –60 –50 –40 –30 –20 –10 0
SNR/SFDR (dB)
AMPLITUDE (dB)
SFDR (dBFS)
SNR (dBFS)
SFDR (dBc)
SNR (dB)
11814-321
Figure 31. SNR/SFDR vs. Analog Input Amplitude at 2.5 GSPS, fIN = 1811 MHz
at AIN
60
48
49
50
51
52
53
54
55
56
57
58
59
0 30002500200015001000500
SNR (dBFS)
INPUT FREQUENCY (MHz)
–40°C +25°C
+85°C
11814-323
Figure 32. SNR at 2.5 GSPS vs. Temperature (Input Network in Figure 76 Used
<2 GHz, Input Network in Figure 75 Used >2 GHz)
85
40
45
50
55
60
65
70
75
80
0 30002500200015001000500
SFDR (dBc)
INPUT FREQUENCY (MHz)
–40°C
+25°C
+85°C
11814-324
Figure 33. SFDR at 2.5 GSPS vs. Temperature (Input Network in Figure 76
Used <2 GHz, Input Network in Figure 75 Used >2 GHz)
120
0
100
80
60
40
20
–90 –10–20–30–40–50–60–70–80
SFDR (dB)
AMPLITUDE (dBFS)
IMD3 (dBFS)
SFDR (dBFS)
SFDR (dBc)
11814-327
Figure 34. Two Tone SFDR and IMD3 vs. Analog Input Amplitude at 2.5 GSPS
at 1800 MHz AIN
120
0
100
80
60
40
20
–90 –10–20–30–40–50–60–70–80
SFDR (dB)
AMPLITUDE (dBFS)
IMD3 (dBFS)
SFDR (dBFS)
SFDR (dBc)
11814-328
Figure 35. Two Tone SFDR and IMD3 vs. Analog Input Amplitude at 2.5 GSPS
at 230 MHz AIN
120
0
100
80
60
40
20
–90 –10–20–30–40–50–60–70–80
SFDR (dB)
AMPLITUDE (dBFS)
IMD3 (dBFS)
SFDR (dBFS)
SFDR (dBc)
11814-329
Figure 36. Two Tone SFDR and IMD3 vs. Analog Input Amplitude at 2.5 GSPS
at 730 MHz AIN
AD9625 Data Sheet
Rev. C | Page 22 of 72
85
40
45
50
55
60
65
70
75
80
100 60001000
SFDR (dBc)
ANALOG INPUT FREQUENCY (MHz)
11814-331
Figure 37. SFDR vs. AIN Frequency at 2.5 GSPS (Input Network in Figure 76
Used <2 GHz, Input Network in Figure 75 used >2 GHz)
4.0
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
MORE N – 4N – 6 N – 2 N MOREN + 4 N + 6N + 2
HITS (Millions)
CODE
11814-333
Figure 38. Input Referred Noise Histogram with 2.5 GSPS
0.5
–0.5
–0.4
–0.3
–0.2
–0.1
0
0.1
0.2
0.3
0.4
0 4096307220481024
DNL (LSB)
CODES
11814-341
Figure 39. Differential Nonlinearity (DNL), ±0.3 LSB at 2.5 GSPS
59
48
49
50
51
52
53
54
55
57
58
56
100 60001000
SNR (dBFS)
ANALOG INPUT FREQUENCY (MHz)
11814-332
Figure 40. SNRFS vs. AIN Frequency at 2.5 GSPS (Input Network in Figure 76
Used <2 GHz, Input Network in Figure 75 Used >2 GHz)
0
–120
–100
–80
–60
–40
–20
0 250 500 750 1000 1250
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2500MSPS
f
IN1
= 1808.5MHz AT –7.0dBFS
f
IN2
= 1805.5MHz AT –7.0dBFS
SFDR = 75.9dBc
11814-334
Figure 41. Two Tone FFT Plot at 2.5 GSPS, fIN1 = 1808.5 MHz and
fIN2 = 1805.5 MHz at AIN, −7.0 dBFS (SFDR = 75.9 dBc)
0
–120
–100
–80
–60
–40
–20
0 250 500 750 1000 1250
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2500MSPS
f
IN1
= 728.5MHz AT –7.0dBFS
f
IN2
= 731.5MHz AT –7.0dBFS
SFDR = 79.3dBc
11814-335
Figure 42. Two Tone FFT Plot at 2.5 GSPS, fIN1 = 728.5 MHz and
fIN2 = 731.5 MHz at AIN, −7.0 dBFS (SFDR = 79.3 dBc)
Data Sheet AD9625
Rev. C | Page 23 of 72
0
–120
–100
–80
–60
–40
–20
0 250 500 750 1000 1250
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2500MSPS
f
IN1
= 228.5MHz AT –7.0dBFS
f
IN2
= 231.5MHz AT –7.0dBFS
SFDR = 76.7dBc
11814-336
Figure 43. Two Tone FFT Plot at 2.5 GSPS, fIN1 = 228.5 MHz and
fIN2 = 231.5 MHz at AIN, −7.0 dBFS (SFDR = 76.7 dBc)
1.5
–1.5
–1.0
–0.5
0
0.5
1.0
0 4096307220481024
INL (LSB)
CODES
11814-343
Figure 44. Integral Nonlinearity (INL), ±1.0 LSB at 2.5 GSPS
AD9625 Data Sheet
Rev. C | Page 24 of 72
AD9625-2.6
For the AD9625-2.6 model, full-scale range used is 1.1 V.
0
–90
–105
–120
–75
–60
–45
–30
–15
0150
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2600MSPS
1820.825MHz AT –1dBFS
SNR = 55.556dB
SFDR = 76.47dBc
300 450 600 750 900 1050 1200
11814-506
Figure 45. FFT Plot at 2.6 GSPS, fIN = 1820.825 MHz at AIN
(SFDR = 76.47 dBc, SNR = 55.556 dB)
0
–90
–105
–120
–75
–60
–45
–30
–15
0150
AMPLITUDE (dBFS)
FREQUENCY (MHz)
300 450 600 750 900 1050 1200
11814-503
2600MSPS
729.028MHz AT –1dBFS
SNR = 56.766dB
SFDR = 78.248dBc
Figure 46. FFT Plot at 2.6 GSPS, fIN = 729.028 MHz at AIN
(SFDR = 78.248 dB, SNR = 56.766)
0
–90
–105
–120
–75
–60
–45
–30
–15
0 150
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2600MSPS
113.940MHz AT –1dBFS
SNR = 57.159dB
SFDR = 81.161dBc
300 450 600 750 900 1050 1200
11814-500
Figure 47. FFT Plot at 2.6 GSPS, fIN = 113.940 MHz at AIN (SFDR = 81.161,
SNR = 57.159)
100
90
80
70
60
50
40
30
20
10
0
–90 –80 –70 –60 –50 –40 –30 –20 –10 0
SNR/SFDR (dB)
AMPLITUDE (dB)
SNR (dBFS)
SFDR (dBFS)
SFDR (dBc)
SNR (dB)
11814-513
Figure 48. SNR/SFDR vs. Analog Input Amplitude at 2.6 GSPS,
fIN = 1811 MHz at AIN
100
90
80
70
60
50
40
30
20
10
0
–90 –80 –70 –60 –50 –40 –30 –20 –10 0
SNR/SFDR (dB)
AMPLITUDE (dB)
SNR (dBFS)
SFDR (dBFS)
SFDR (dBc)
SNR (dB)
11814-512
Figure 49. SNR/SFDR vs. Analog Input Amplitude at 2.6 GSPS,
fIN = 241 MHz at AIN
48
49
50
51
52
53
54
SNR (dBFS)
INPUT FREQUENCY (MHz)
55
56
57
58
59
0 400 800 1200 1600 2000
–40°C
+25°C
+85°C
11814-515
Figure 50. SNR vs. Temperature at 2.6 GSPS
Data Sheet AD9625
Rev. C | Page 25 of 72
0
10
20
30
40
50
60
SFDR (dBFS)
INPUT FREQUENCY (MHz)
70
80
90
100
0 400 800 1200 1600 2000
–40°C
+25°C +85°C
11814-516
Figure 51. SFDR vs. Temperature at 2.6 GSPS
120
0
100
80
60
40
20
–90 –10–20–30–40–50–60–70–80
SFDR/IMD3 (dB)
AMPLITUDE (dBFS)
IMD3 (dBFS)
SFDR (dBFS)
SFDR (dBc)
11814-517
Figure 52. Two Tone SFDR and IMD3 vs. Analog Input Amplitude at
2.6 GSPS at 230 MHz AIN
120
0
100
80
60
40
20
–90 –10–20–30–40–50–60–70–80
SFDR/IMD3 (dB)
AMPLITUDE (dBFS)
IMD3 (dBFS)
SFDR (dBFS)
SFDR (dBc)
11814-518
Figure 53. Two Tone SFDR and IMD3 vs. Analog Input Amplitude at
2.6 GSPS at 730 MHz AIN
120
0
100
80
60
40
20
–90 –10–20–30–40–50–60–70–80
SFDR/IMD3 (dB)
AMPLITUDE (dBFS)
IMD3 (dBFS)
SFDR (dBFS)
SFDR (dBc)
11814-519
Figure 54. Two Tone SFDR and IMD3 vs. Analog Input Amplitude at
2.6 GSPS at 1807 MHz AIN
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
MORE
N – 6
N – 5
N – 4
N – 3
N – 2
N – 1
N
BINS
N + 1
N + 2
N + 3
N + 4
N + 5
N + 6
MORE
HITS (Millions)
11814-514
Figure 55. Input Referred Noise Histogram with 2.6 GSPS
0
–120
–100
–80
–60
–40
–20
0 800 1000 1200 1400600400200
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2600MSPS
f
IN1
= 794.5MHz AT –7.0dBFS
f
IN2
= 791.5MHz AT –7.0dBFS
SFDR = 79.154dBc
11814-511
Figure 56. Two Tone FFT Plot at 2.6 GSPS AIN = 1807 MHz
AD9625 Data Sheet
Rev. C | Page 26 of 72
0
–120
–100
–80
–60
–40
–20
0 800 1000 1200 1400600400200
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2600MSPS
f
IN1
= 728.5MHz AT –7.0dBFS
f
IN2
= 731.5MHz AT –7.0dBFS
SFDR = 78.362dBc
11814-510
Figure 57. Two Tone FFT Plot at 2.6 GSPS AIN = 730 MHz
0
–120
–100
–80
–60
–40
–20
0 800 1000 1200 1400600400200
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2600MSPS
f
IN1
= 231.5MHz AT –7.0dBFS
f
IN2
= 228.5MHz AT –7.0dBFS
SFDR = 78.117dBc
11814-509
Figure 58. Two Tone FFT Plot at 2.6 GSPS AIN = 230 MHz
0.5
–0.5
–0.4
–0.3
–0.2
–0.1
0
0.1
0.2
0.3
0.4
0 4096307220481024
DNL (LSB)
CODES
11814-507
Figure 59. Differential Nonlinearity (DNL) at 2.6 GSPS
1.2
–1.2
–0.8
–0.4
0
0.4
0.8
0 4096307220481024
INL (LSB)
CODES
11814-508
Figure 60. Integral Nonlinearity (INL) at 2.6 GSPS
Data Sheet AD9625
Rev. C | Page 27 of 72
EQUIVALENT TEST CIRCUITS
150.6pF
500.2pF0.5pF 0.2pF
VDD
A
IN
V
CM
890nH
11814-010
Figure 61. Equivalent Analog Input Circuit
VDD
1k
VDD
SCLK
11814-011
Figure 62. Equivalent SCLK Circuit
2pF
DVDD
2k
1k
11814-012
Figure 63. Equivalent VMON Temperature Sensor Circuit (DVDD)
AVDD
CLK+
AVDD
CLK–
0.88V
AVDD
20k20k
11814-013
Figure 64. Equivalent Clock Input Circuit
30k
ESD
PROTECTED
ESD
PROTECTED
1k
DVDD
CSB
11814-015
Figure 65. Equivalent CSB/PWDN Input Circuit
DIVCLK
DRVDD DRVDD
11814-150
Figure 66. Equivalent DIVCLK Output Circuit (DRVDD)
DRGND
DRGND
DATA+
DATA–
DRVDD
DRVDD
OUTPUT
DRIVER
EMPHASIS/SWING
CONTROL (SPI)
11814-400
Figure 67. Digital Outputs
11814-153
DVDD2
DVDD2
SYNCINB–
200
DVDD2
SYNCINB+
200
100
Figure 68. Equivalent SYNCINB± Input
30k
ESD
PROTECTED
ESD
PROTECTED
1k
DRVDD
DRVDD
SDI
SDIO
SDO
11814-401
Figure 69. Equivalent SDIO Circuit
AVDD
SYSREF+
AVDD
SYSREF–
0.9V
AVDD
20k20k
11814-014
Figure 70. Equivalent SYSREF± Input Circuit
AD9625 Data Sheet
Rev. C | Page 28 of 72
THEORY OF OPERATION
ADC ARCHITECTURE
The AD9625 is a pipelined ADC. The pipelined architecture
permits the first stage to operate on a new input sample and the
remaining stages to operate on the preceding samples. Sampling
occurs on the rising edge of the clock.
Each stage of the pipeline, excluding the last, consists of a low
resolution flash ADC connected to a switched capacitor digital-
to-analog converter (DAC) and an interstage residue amplifier
(MDAC). The residue amplifier magnifies the difference between
the reconstructed DAC output and the flash input for the next
stage in the pipeline. One bit of redundancy is used in each stage
to facilitate digital correction of flash errors. The last stage simply
consists of a flash ADC.
The input stage contains a differential sampling circuit that can
be ac- or dc-coupled in differential or single-ended modes. The
output staging block aligns the data, corrects errors, and passes
the data to the output buffers. The output buffers are powered
from a separate supply, allowing adjustment of the output drive
current.
Synchronization capability is provided to allow synchronized
timing between multiple devices.
FAST DETECT
The fast detect block within the AD9625 generates a fast
detection bit (FD), which, when used with variable gain
amplifier front-end blocks, reduces the gain and prevents the
ADC input signal levels from exceeding the converter range.
Figure 71 shows the rapidity by which the detection bit is
programmable using an upper threshold, lower threshold,
and dwell time.
The FD bit is set when the absolute value of the input signal
exceeds the programmable upper threshold level. The FD bit
clears only when the absolute value of the input signal drops
below the lower threshold level for greater than the programmable
dwell time, thereby providing hysteresis and preventing the FD
bit from excessive toggling.
GAIN THRESHOLD OPERATION
For best performance, the AD9625 needs an input signal to
perform internal calibration. This signal needs to exceed a set
threshold that is established through register settings. The
threshold prohibits background calibration updates for small
signal amplitudes. The threshold for gain calibration is enabled
by default.
Threshold Operation
The absolute value of every sample is accumulated to produce
an average voltage estimate.
When the calibration has run for its predetermined number of
samples, the voltage estimate is compared to the data set threshold.
If the voltage estimate is greater than the threshold, the cali-
bration coefficients update; otherwise, no update occurs.
Threshold Format
The threshold registers are all 16-bit registers loaded via the SPI
one byte at a time. The threshold values range from 0 to 16,384,
corresponding to a voltage range of 0.0 V to 1.2 V (full scale).
The calibration threshold range is 0 to 16,384 (0x00 to 0x4000,
hexadecimal) and represents the average magnitude of the
input. For example, to set the threshold so that a −6 dBFS input
sine wave sits precisely at the threshold requires a threshold
setting of
16,384 × 20
6
10
×
2 ≥ 5228
UPPER THRESHOLD
LOWER THRESHOLD
FD
DWELL TIME
TIMER RESET BY
RISE ABOVE LT
TIMER COMPLETES BEFORE
SIGNAL RISES ABOVE LT
DWELL TIME
11814-016
Figure 71. Fast Detection Bit
Data Sheet AD9625
Rev. C | Page 29 of 72
TEST MODES
ADC CORE
FRAMER
SERALIZER OUTPUT
JESD204B TEST PATTERNS
10 BIT
SPI REGISTER 0x061
BITS[5:4] = 01 AND
BITS[3:0] 0000
JESD204B
TEST PATTERNS
16 BIT
SPI REGISTER 0x061
BITS[5:4] = 00
AND BITS[3:0] 0000
JESD204B
SAMPLE
CONSTRUCTION
ADC TEST PATTERNS
12 BIT
SPI REGISTER 0x00D
BITS[3:0] 0000
TAIL
BITS
FRAME
CONSTRUCTION
8b/10b
ENCODER
SCRAMBLER
(OPTIONAL)
11814-018
Figure 72. Test Modes
Table 10. Flexible Output Test Modes from SPI Register 0x00D
Output Test
Mode Bit
Sequence Pattern Name
Digital Output Word 1
(Default Twos Complement
Format)
Digital Output Word 2 (Default Twos
Complement Format)
Subject to
Data Format
Select
0000 Off (default) Not applicable Not applicable Yes
0001 Midscale short 0000 0000 0000 = Word 1 Yes
0010 Positive full scale 0111 1111 1111 = Word 1 Yes
0011 Negative full scale 1000 0000 0000 = Word 1 Yes
0100 Alternating checkerboard 1010 1010 1010 0101 0101 0101 No
0101 PN sequence long Not applicable Not applicable Yes
0111 One-/zero-word toggle 1111 1111 1111 0000 0000 0000 No
1000 User test mode User data from
Register 0x019 to
Register 0x020
User data from Register 0x019 to
Register 0x020
Yes
1111 Ramp output N N + 1 No
AD9625 Data Sheet
Rev. C | Page 30 of 72
ANALOG INPUT CONSIDERATIONS
The AD9625 has a differential analog input, which is optimized
to provide superior wideband performance and must be driven
differentially. For best dynamic performance, the source
impedances driving VIN+ and VIN− should be matched such
that common-mode settling errors are symmetrical. Mismatch
between VIN+ and VIN− introduces undesired distortion. A
wideband transformer, balun, or amplifier can provide the
differential analog inputs for applications that require a single-
ended to differential conversion.
DIFFERENTIAL INPUT CONFIGURATIONS
Optimum performance is achieved while driving the AD9625
in a differential input configuration. A passive input configura-
tion can be used with a single to differential balun at the analog
input to the AD9625. Because the AD9625 does not make use
of an internal input buffer, an external network needs to be
designed to reduce bandwidth peaking and minimize kickback
from the ADC sampling capacitor.
Small series resistors (R3 and R4) limit input bandwidth, but can
be installed to further improve performance. Choose the input
network components such that its equivalent impedance, in
parallel with the 100  input impedance of the AD9625, is
matched to the output impedance of the balun or amplifier.
Using a larger value for R3 and R4 suppresses the input
kickback from the sampling capacitor seen at the input to the
AD9625. However, the tradeoff is a lower usable input
bandwidth and an increase in the amount of signal power
needed to drive into the network for the AD9625 to sample a
full-scale signal.
Series isolation resistors (R5 and R6) are recommended to
reduce bandwidth peaking and minimize kickback from the
ADC sampling capacitor. Table 11 lists the front-end
requirements.
AD9625
AVDD
VCM
DRVDD
R5
R6
R3
R4
0.1µF
0.1µF
R1
R2
11814-024
Figure 73. Recommended Front-End Network
Table 11. Recommended Front-End Components
Component Component Value
R1 33 Ω to 50 Ω (termination)
R2 33 Ω to 50 Ω (termination)
R3 0 Ω to 33 Ω (lower for higher bandwidth)
R4 0 Ω to 33 Ω (lower for higher bandwidth)
R5 33 Ω
R6 33 Ω
AD9625
AVDD
VCM
DRVDD
33
33
0.1µF
0.1µF
50
50
1.5pF
0.1µF
100
0.1µF
ANALOG
INPUT
INPUT
Z = 50ADC INTERNAL
INPUT Z
11814-359
Figure 74. Input Network Example for Passive Balun with High Bandwidth
AD9625
25
25
33
33
0.1µ
0.1µF
33
33
100
INTERNAL
0.1µF
EXTERNAL
BALUN/AMP
11814-360
Figure 75. Input Network Example for Passive Balun and >2 GHz ADC
Bandwidth
AD9625
33
33
25
25
0.1µ
0.1µF
33
33
100
INTERNAL
0.1µF
EXTERNAL
BALUN/AMP
11814-361
Figure 76. Input Network Example for Passive Balun and <2 GHz ADC
Bandwidth
USING THE ADA4961
As an alternative to using only a passive differential balun input
for wideband applications, the ADA4961 differential amplifier
driver can be used (see Figure 80).
The ADA4961 is a high performance BiCMOS RF differential
gain amplifier (DGA) optimized for driving heavy loads out to
2.0 GHz and beyond. It typically achieves −90 dBc IMD3
performance at 500 MHz and −85 dBc at 1.5 GHz. e device
also exhibits very low output noise (6.8 nV/√Hz). Together,
these performance numbers result in an SFDR of 133 dB/Hz
at 1.5 GHz.
The ADA4961 has an internal differential input impedance of
100  and a differential dynamic output impedance of 50 ,
eliminating the need for external termination resistors. The
digital adjustability provides for 1 dB resolution, thus
optimizing SNR for input levels spanning 21 dB.
Data Sheet AD9625
Rev. C | Page 31 of 72
Figure 80 uses a 1:2 impedance transformer to provide the
100  input impedance of the ADA4961 with a matched input.
The open collector outputs of the ADA4961 are biased through
the two 560 nH inductors. The two 0.1 µF capacitors on the
outputs decouple the 5 V inductor voltage from the input
common-mode voltage of the ADA4961. The two 50 
resistors in parallel with the 100  input impedance of the
AD9625 provide the 50  load to the ADA4961, whose gain
is load dependent. The 2 nH inductors and the 1.5 pF internal
capacitance of the AD9625 constitute a 1 GHz low-pass filter to
−1 dB. The two 10  isolation resistors suppress any switching
currents from the AD9625 sample-and-hold circuitry. The
circuit depicted in Figure 80 provides variable gain, isolation,
filtering and source matching for the AD9625. By using this
circuit with the ADA4961 in a gain of 15 dB (maximum gain)
an SNRFS of 55 dB and an SFDR performance of 77 dBc are
achieved with a 1 GHz input as shown in Figure 80.
0
–120
–100
–80
–60
–40
–20
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2500MSPS
1003.8MHz AT –1.0dBFS
SNR = 53.83dB
SFDR = 77.354dBc
11814-363
0 150
5
23
6+
300 450 600 750 900 1050 1200
4
Figure 77. Measured Single-Tone Performance of the Circuit Shown in
Figure 80 for a 1 GHz Input Signal Using Maximum Gain (15 dB)
The two-tone 1 GHz IMD of two 0.55 V p-p signals have an
SFDR of greater than 75 dBc, as shown in Figure 78.
0
–120
–100
–80
–60
–40
–20
AMPLITUDE (dBFS)
FREQUENCY (MHz)
2500MSPS
f
IN1
= 1022.3MHz AT –7.0dBFS
f
IN2
= 1012.3MHz AT –7.0dBFS
SFDR = 75.8dBc
11814-364
0 150
F2 – F1 F1 + F2
2F2 + F1
2F1 + F2 2F1 – F2
2F2 – F1
300 450 600 750 900 1050 1200
Figure 78. Measured Two-Tone Performance of the Circuit Shown in
Figure 80 for a 1 GHz input Signal Using Maximum Gain (15 dB)
10
–25
–20
–15
–10
–5
0
5
10 100 1000 10000
AMPLITUDE (dB)
FREQUENCY (MHz)
11814-365
Figure 79. Measured Frequency Response of the AD9625 Interface with
ADA4961 Depicted in Figure 80
AD9625
VCM
10
10
50
50
1.5pF 100
MARKI
BAL-0006GSMG
1:2
+
VIN+
VIN–
2nH
2nH
0.1µF
0.1µF
0.1µF
0.1µF
5.0V
0.5nH
5.0V
5.0V
0.5nH
DIGITAL
INTERFACE
ADA4961
50
BANDPASS
FILTER
AC
11814-362
Figure 80. Configuration for Driving the AD9625 with ADA4961
AD9625 Data Sheet
Rev. C | Page 32 of 72
DC COUPLING
The AD9625 can operate using a dc-coupled input configura-
tion. The differential analog common-mode input signal would
need to be referenced to the VCM output of the AD9625.
CLOCK INPUT CONSIDERATIONS
For optimum performance, drive the AD9625 sample clock
inputs (CLK+ and CLK−) with a differential signal. This
signal is typically ac-coupled to the CLK+ and CLK− pins via a
transformer or capacitors. These pins are biased internally and
require no additional biasing.
Clock Jitter Considerations
High speed, high resolution ADCs are sensitive to the quality of the
clock input. The degradation in SNR at a given input frequency
(fA) due only to aperture jitter (tJ) can be calculated by
SNR = 20 × log 10(1/(2 × π × fA × tJ))
In this equation, the rms aperture jitter represents the root-
mean-square of all jitter sources, including the clock input,
analog input signal, and ADC aperture jitter specifications. IF
undersampling applications are particularly sensitive to jitter
(see Figure 81).
130
120
110
100
90
80
70
60
50
40
30
10 100 1000 10000
SNR (dB)
ANALOG INPUT FREQUENCY (MHz)
12.5
f
S
25
f
S
50
f
S
100
f
S
200
f
S
400
f
S
800
f
S
11814-366
Figure 81. Ideal SNR vs. Analog Input Frequency and Jitter
In cases where aperture jitter may affect the dynamic range of
the AD9625, treat the clock input as an analog signal. To avoid
modulating the clock signal with digital noise, separate power
supplies for clock drivers from the ADC output driver supplies.
Low jitter, crystal-controlled oscillators make the best clock
sources. If the clock is generated from another type of source (by
gating, dividing, or other methods), it should be retimed by the
original clock at the last step. Refer to the AN-501 Application
Note and the AN-756 Application Note for more information
about jitter performance as it relates to ADCs.
Clock Duty Cycle Considerations
Typical high speed ADCs use both clock edges to generate a
variety of internal timing signals. As a result, these ADCs may
be sensitive to clock duty cycle. Commonly, a 5% tolerance is
required on the clock duty cycle to maintain dynamic performance
characteristics.
Data Sheet AD9625
Rev. C | Page 33 of 72
DIGITAL DOWNCONVERTERS (DDC)
SYNTHESIZERNCO
12-BIT ADC
@ 2.0GSPS
DECIMATION
BY 8
GAIN SELECT:
0dB, 6dB, 12dB, 18dB
MODE SELECT:
96MHz OR 192MHz BW
MIXER
MIXER
8 × 12-BIT
@ 250MHz
DECIMATION
BY 8
DECIMATION
BY 2
8 × 13-BIT
@ 250MHz
8 × 12-BIT
@ 250MHz
8 × 13-BIT
@ 250MHz
16-BIT @ 250MHz
16-BIT
@ 125MHz
16-BIT
@ 125MHz
I-PHASE
16-BIT @ 250MHz
Q-PHASE
TUNER SELECT:
–1.0GHz TO +1.0GHz
GAIN SELECT:
0dB, 6dB,
12dB, 18dB
TO
FRAMER
TO
FRAMER
11814-019
Figure 82. Digital Downconverter Block Diagram Operating at 2.0 GSPS
The AD9625 architecture includes two DDCs, each designed to
extract a portion of the full digital spectrum captured by the
ADC. Each tuner consists of an independent frequency synthesizer
and quadrature mixer; a chain of low-pass filters for rate conversion
follows these components. Assuming a sampling frequency of
2.500 GSPS, the frequency synthesizer (10-bit NCO) allows for
1024 discrete tuning frequencies, ranging from −1.2499 GHz to
+1.2500 GHz, in steps of 2500/1024 = 2.44 MHz. The low-pass
filters allow for two modes of decimation.
A high bandwidth mode, 240 MHz wide (from −120 MHz
to +120 MHz), sampled at 2.5 GHz/8 = 312.5 MHz for the
I and Q branches separately. The 16-bit samples from the I
and Q branches are transmitted through a dedicated
JESD204B interface.
A low bandwidth mode, 120 MHz wide (from −60 MHz to
+60 MHz), sampled at 2.5 GHz/16 = 156.25 MHz for the I
and Q branches separately. The 16-bit samples from the I
and Q branches are transmitted through a dedicated
JESD204B interface.
By design, all of the blocks operate at a single clock frequency of
2.5 GHz/8 = 312.5 MHz.
Each filter stage includes a gain control block that is programmable
by the user. The gain varies from 0 dB to 18 dB, in steps of 6 dB,
and the gain is applied before final scaling and rounding. The
gain control feature may be useful in cases where the tuner
filters out a strong out-of-band interferer, leaving a weak
in-band signal.
FREQUENCY SYNTHESIZER AND MIXER
For a sampling rate of 2.500 GHz, the synthesizer (10-bit
NCO) outputs one of 1024 possible complex frequencies from
−1.249 GHz to +1.250 GHz. The synthesizer employs the direct
digital synthesis technique, using look-up sine tables and a
phase accumulator. The user specifies the tuner frequency by
writing to a 10-bit phase increment register.
NUMERICALLY CONTROLLED OSCILLATOR
Each DDC has a 10-bit oscillator that is synthesized and mixed
with the ADC output data. The 10-bit phase can be tuned for
each DDC based on the value used in its NCO registers. The
phase for DDC0 is located with Register 0x132 and Register 0x131.
The phase for DDC1 is located with Register 0x13A and
Register 0x139. The NCO output frequency for DDC0 =
(decimal(Register 0x132[1:0]; Register 0x131[7:0]) × fS)/1024. The
NCO output frequency for DDC1 = (decimal(Register 0x13A[1:0];
Register 0x139[7:0]) × fS)/1024.
HIGH BANDWIDTH DECIMATOR
The first filter stage is designed for a rate reduction factor of 8,
yielding a sample rate of 2.500 GHz/8 = 312.5 MHz. To achieve
a combination of low complexity and low clock rate, the DDC
employs a decimate-by-8 polyphase fuse filter that receives
eight 13-bit samples from the mixer block at every clock cycle.
The block design provides user specified gain control, from 0 dB to
18 dB in steps of 6 dB. The gain is applied before final scaling
and rounding to 16 bits.
AD9625 Data Sheet
Rev. C | Page 34 of 72
10
–100
–90
–80
–70
–60
–50
–40
–30
–20
0
–10
f
S
/2
MAGNITUDE (dB)
FREQUENCY (MHz)
11814-020
Figure 83. Magnitude Response of the Decimate-by-8 Polyphase Fuse Filter
Filter performance is shown in Figure 83 and Figure 84. The
filter yields an effective bandwidth of 120 MHz, with a transition
band of 156.5 MHz − 120 MHz = 36.5 MHz. Therefore, the
two-sided complex bandwidth of the filter is 240 MHz.
A rejection ratio of 85 dB ensures that the seven aliases that fold
back into the pass band yield an SNR of 85 dB − 10log10(7) =
76.5 dB, which ensures that the aliases remain sufficiently below
the noise floor of the input signal. The pass-band ripple is
±0.05 dB, as shown in Figure 84.
0.25
–0.20
–0.15
–0.10
–0.05
0
0.05
0.10
0.15
0.20
012010080604020
MAGNITUDE (dB)
FREQUENCY (MHz)
11814-021
Figure 84. Magnitude Ripple in the High Bandwidth Pass Band
The high bandwidth decimator has a filter architecture that
consists of a 142 tap delay line. The coefficients are 17 bits each
and are listed in Table 12.
Table 12. Filter Tap Coefficients for High Bandwidth
Decimator
Tap Number Coefficient
1 −38
2 −57
3 −92
4 −132
5 −172
6 −204
7 −219
8 −207
9 −162
10 −79
11 +43
12 +196
13 +369
14 +540
15 +685
16 +780
17 +800
18 +727
19 +554
20 +289
21 −48
22 −420
23 −778
24 −1069
25 −1238
26 −1242
27 −1055
28 −677
29 −135
30 +513
31 +1186
32 +1785
33 +2210
34 +2372
35 +2209
36 +1698
37 +869
38 −200
39 −1382
40 −2516
41 −3425
42 −3945
43 −3944
44 −3353
45 −2179
46 −519
47 +1446
48 +3467
49 +5250
50 +6496
51 +6945
Data Sheet AD9625
Rev. C | Page 35 of 72
Tap Number Coefficient
52 +6412
53 +4831
54 +2276
55 −1031
56 −4725
57 −8330
58 −11304
59 −13098
60 −13222
61 −11306
62 −7160
63 −808
64 +7498
65 +17281
66 +27882
67 +38515
68 +48340
69 +56550
70 +62451
71 +65536
72 +65536
73 +62451
74 +56550
75 +48340
76 +38515
77 +27882
78 +17281
79 +7498
80 −808
81 −7160
82 −11306
83 −13222
84 −13098
85 −11304
86 −8330
87 −4725
88 −1031
89 +2276
90 +4831
91 +6412
92 +6945
93 +6496
94 +5250
95 +3467
96 +1446
97 −519
98 −2179
99 −3353
100 −3944
101 −3945
102 −3425
103 −2516
104 −1382
Tap Number Coefficient
105 −200
106 +869
107 +1698
108 +2209
109 +2372
110 +2210
111 +1785
112 +1186
113 +513
114 −135
115 −677
116 −1055
117 −1242
118 −1238
119 −1069
120 −778
121 −420
122 −48
123 +289
124 +554
125 +727
126 +800
127 +780
128 +685
129 +540
130 +369
131 +196
132 +43
133 −79
134 −162
135 −207
136 −219
137 −204
138 −172
139 −132
140 −92
141 −57
142 −38
AD9625 Data Sheet
Rev. C | Page 36 of 72
LOW BANDWIDTH DECIMATOR
Use the second filter stage in the optional low bandwidth mode
only. It achieves an additional rate reduction factor of 2, yielding a
final sample rate of 2.500 GHz/16 = 156.25 MHz. The internal
architecture of the low bandwidth decimation filter is similar to
that of a high bandwidth decimator. Moreover, for ease of
physical design, the block operates at 312.5 MHz, a result of
which both the I- and Q-phases can share the filter engine.
The performance of the low bandwidth decimation filter is
shown in Figure 85 and Figure 86. The filter yields an effective
bandwidth of 60 MHz, with a transition band of 81.25 MHz −
60 MHz = 21.25 MHz. Thus, the two sided, complex bandwidth
of the filter is 120 MHz. A rejection ratio of 85 dB ensures that
the alias region folds back well below the noise floor of the
input signal.
As with the high bandwidth filter, this block provides user
specified gain control, from 0 dB to 18 dB, in steps of 6 dB. The
gain is applied before final quantization at the output of the low
bandwidth decimation filter to 16 bits.
10
–100
–90
–80
–70
–60
–50
–40
–30
–20
–10
0
0 16014012010080604020
MAGNITUDE (dB)
FREQUENCY (MHz)
11814-022
Figure 85. Magnitude Response of Decimate-by-2 Filter
–0.2
–0.1
0
0.1
0.2
0.3
0.4
0605040302010
MAGNITUDE (dB)
FREQUENCY (MHz)
11814-023
Figure 86. Magnitude Ripple in the Low Bandwidth Pass Band
The low bandwidth decimator has a filter architecture that
consists of a 31 tap delay line. The coefficients are 17 bits each
and are listed in Table 13.
Table 13. Filter Tap Coefficients for Low Bandwidth
Decimator
Tap Number Coefficient
1 +126
2 +312
3 −16
4 −859
5 −628
6 +1217
7 +1428
8 −1944
9 −3227
10 +2511
11 +6302
12 −3099
13 −13075
14 +3441
15 +43442
16 +65536
17 +43442
18 +3441
19 −13075
20 −3099
21 +6302
22 +2511
23 −3227
24 −1944
25 +1428
26 +1217
27 −628
28 −859
29 −16
30 +312
31 +126
Data Sheet AD9625
Rev. C | Page 37 of 72
DIGITAL OUTPUTS
INTRODUCTION TO THE JESD204B INTERFACE
The AD9625 digital output complies with the JEDEC Standard
No. JESD204B, Serial Interface for Data Converters. JESD204B is
a protocol to link the AD9625 to a digital processing device
over a serial interface up to and above 6.5 Gbps link speeds. The
benefits of the JESD204B interface over LVDS include a reduction
in required board area for data interface routing, and enabling
smaller packages for converter and logic devices. The AD9625
supports one, two, four, six, or eight output lanes.
The JESD204B data transmit block assembles the parallel data
from the ADC into frames and uses 8-bit/10-bit encoding as
well as optional scrambling to form serial output data. Lane
synchronization is supported using special characters during
the initial establishment of the link. Additional data that is used
to maintain synchronization is embedded in the data stream
thereafter. A JESD204B receiver is required to complete the
serial link. For additional details on the JESD204B interface,
users are encouraged to refer to the JESD204B standard.
The AD9625 JESD204B transmit block maps to two digital
down converters for the outputs of the ADC over a link. A
link can be configured to use up to eight JESD204B lanes.
The JESD204B specification refers to a number of parameters
to define the link, and these parameters must match between
the JESD204B transmitter (AD9625 output) and receiver
(FPGA, ASIC, or logic device).
Table 14 describes the JESD204B interface nomenclature (the
terms, converter device and link, are used interchangeably in
the specification).
Table 14. JESD204B Interface Nomenclature
Symbol Description
S Samples transmitted per single converter per frame cycle
M Number of converters per converter device (link)
L Number of lanes per converter device (link)
N Converter resolution
N' Total number of bits per sample
CF Number of control words per frame clock cycle per
converter device (link)
CS Number of control bits per conversion sample
K Number of frames per multiframe
HD High density mode
F Octets per frame
C Control bit (overrange, timestamp)
T Tail bit
The AD9625 adheres to the JESD204B draft specification,
which provides a high speed, serial, embedded clock interface
standard for data converters and logic devices. It is designed as
an MCDA-ML, Subclass 1 device that uses the SYSREF± input
signal for multichip synchronization and deterministic latency.
This design adheres to the following basic JESD204B link config-
uration parameters:
M = 1 (single converter, always for AD9625)
L = 1 to 8 (up to eight lanes)
S = 4 (four samples per JESD204B frame)
F = 1, 2, 4, 8 (up to 8 octets per frame)
N’ = 12, 16 (12- or 16-bit JESD204B word size)
HD = 0, 1 (high density mode, sample span multiple lanes)
FUNCTIONAL OVERVIEW
The block diagram in Figure 87 shows the flow of data through
the JESD204B hardware from the sample input to the physical
output. The processing can be divided into layers that are
derived from the OSI model widely used to describe the
abstraction layers of communications systems. These are the
transport layer, data link layer, and physical layer (serializer).
Each of these layers are described in detail in the following
sections.
Transport Layer
The transport layer handles packing the data (consisting of
samples and optional control bits) into 8-bit words that are sent
to the data link layer. The transport layer is controlled by rules
derived from the link configuration data. It packs data according to
the rules, adding tail bits to fill gaps when required.
Data Link Layer
The data link layer is responsible for the low level functions of
passing data across the link. These include optionally scrambling
the data, handling the synchronization process for characters,
frames, and lanes across the links, encoding 8-bit data-words
into 10-bit characters, and inserting appropriate control
characters into the data output. The data link layer is also
responsible for sending the initial lane alignment sequence
(ILAS), which contains the link configuration data, used by
the receiver (Rx) to verify the settings in the transport layer.
Physical Layer
The physical layer consists of the high speed circuitry clocked at
the serial clock rate. The physical layer includes the serialization
circuits and the high speed drivers.
SAMPLE
CONSTRUCTION
FRAME
CONSTRUCTION SCRAMBLER
ALIGNMENT
CHARACTER
GENERATION
8-BIT/10-BIT
ENCODER
CROSSBAR
MUX SERIALIZER OUTPUT
PROCESSED
SAMPLES
FROM ADC
DATA LINK
LAYER
TRANSPORT
LAYER
PHYSICAL
LAYER
11814-242
Figure 87. Data Flow
AD9625 Data Sheet
Rev. C | Page 38 of 72
abcde fgh i jabcde fgh i jfgh i j abcde fgh i jabcde fgh i j
abcde fgh i jabcde fgh i jfgh i j abcde fgh i jabcde fgh i j
abcde fgh i jabcde fgh i jfgh i j abcde fgh i jabcde fgh i j
abcde fgh i jabcde fgh i jfgh i j abcde fgh i jabcde fgh i j
abcde fgh i jabcde fgh i jfgh i j abcde fgh i jabcde fgh i j
abcde fgh i jabcde fgh i jfgh i j abcde fgh i jabcde fgh i j
abcde fgh i jabcde fgh i jfgh i j abcde fgh i jabcde fgh i j
abcde fgh i jabcde fgh i jfgh i j abcde fgh i jabcde fgh i j
JESD204B INTERFACE
M = 1; L = 8; N = 12; N' = 16; CF = 0; CS = 0; CS = 0...4; K = 32; HD = 1; F = 1
400ps MIN (2.5GHz)
CLK+
(ENCODE CLOCK)
LANE A±
@ 6.25Gbps
LANE B±
@ 6.25Gbps
LANE C±
@ 6.25Gbps
LANE D±
@ 6.25Gbps
LANE
@ 6.25Gbps
LANE F±
@ 6.25Gbps
LANE G±
@ 6.25Gbps
LANE H±
@ 6.25Gbps
SAMPLE N + 3 [3:0],
CTTTT
SAMPLE N + 7 [3:0],
CTTTT
SAMPLE N + 11 [3:0],
CTTTT
SAMPLE N + 15 [3:0],
CTTTT
SAMPLE N + 2 [3:0],
CTTTT
SAMPLE N + 6 [3:0],
CTTTT
SAMPLE N + 10 [3:0],
CTTTT
SAMPLE N + 14 [3:0],
CTTTT
SAMPLE N + 1 [3:0],
CTTTT
SAMPLE N + 5 [3:0],
CTTTT
SAMPLE N + 9 [3:0],
CTTTT
SAMPLE N + 13 [3:0],
CTTTT
SAMPLE N [3:0],
CTTTT
SAMPLE N + 4 [3:0],
CTTTT
SAMPLE N + 8 [3:0],
CTTTT
SAMPLE N + 12 [3:0],
CTTTT
SAMPLE N + 3 [11:4] SAMPLE N + 7 [11:4] SAMPLE N + 11 [11:4] SAMPLE N + 15 [11:4]
SAMPLE N + 2 [11:4] SAMPLE N + 6 [11:4] SAMPLE N + 10 [11:4] SAMPLE N + 14 [11:4]
SAMPLE N + 1 [11:4] SAMPLE N + 5 [11:4] SAMPLE N + 9 [11:4] SAMPLE N + 13 [11:4]
SAMPLE N [11:4] SAMPLE N + 4 [11:4] SAMPLE N + 8 [11:4] SAMPLE N + 12 [11:4]
F = 1 OCTETS F = 1 OCTETS F = 1 OCTETS F = 1 OCTETS
11814-373
Figure 88. JESD204B Lane Data Mapping
Data Sheet AD9625
Rev. C | Page 39 of 72
JESD204B LINK ESTABLISHMENT
The AD9625 JESD204B Tx interface operates in Subclass 1 as
defined in the JEDEC Standard No. 204B-July 2011 specification.
It is divided into the following steps: code group synchronization,
initial lane alignment sequence, and data streaming.
Code Group Synchronization (CGS) and SYNCINB±
CGS is the process where the JESD204B receiver finds the
boundaries between the 10-bit characters in the stream of data.
During the CGS phase, the JESD204B transmit block transmits
/K28.5/ characters. The receiver (external logic device) must
locate the /K28.5/ characters in its input data stream using clock
and data recovery (CDR) techniques.
The receiver issues a synchronization request by activating the
SYNCINB± pins of the AD9625. The JESD204B Tx begins
sending /K28.5/ characters until the next LMFC boundary.
When the receiver has synchronized, it waits for the correct
reception of at least four consecutive /K28.5/ symbols. It then
deactivates SYNCINB±. The AD9625 then transmits an initial
lane alignment sequence (ILAS) on the following LMFC
boundary.
For more information on the code group synchronization
phase, refer to the JEDEC Standard No. 204B-July 2011, Section
5.3.3.1.
The SYNCINB± pin operation can be controlled by SPI. The
SYNCINB± signal is a differential LVDS mode signal by default,
but it can also be driven single ended. For more information on
configuring the SYNCINB± pin operation, refer to the Memory
Map section.
Initial Lane Alignment Sequence (ILAS)
The ILAS phase follows the CGS phase and begins on the next
LMFC boundary. The ILAS consists of four mulitframes, with
an /R/ character marking the beginning and an /A/ character
marking the end. The ILAS begins by sending an /R/ character
followed by 0 to 255 ramp data for one multiframe. On the
second multiframe, the link configuration data is sent starting
with the third character. The second character is a /Q/ character
to confirm that the link configuration data follows. All
undefined data slots are filled with ramp data. The ILAS
sequence is never scrambled.
The ILAS sequence construction is shown in Figure 90. The
four multiframes include the following:
Multiframe 1: begins with an /R/ character (K28.0) and
ends with an /A/ character (K28.3).
Multiframe 2: begins with an /R/ character followed by a
/Q/ [K28.4] character, followed by link configuration
parameters over 14 configuration octets and ends with an /A/
character. Many of the parameter values are of the notation of
the value, −1.
Multiframe 3: this is the same as Multiframe 1.
Multiframe 4: this is the same as Multiframe 1.
Data Streaming
After the initial lane alignment sequence is complete, the user
data is sent. In a usual frame, all characters are user data.
However, to monitor the frame clock and multiframe clock
synchronization, there is a mechanism for replacing characters
with /F/ or /A/ alignment characters when the data meets
certain conditions. These conditions are different for unscrambled
and scrambled data. The scrambling operation is enabled by
default but may be disabled using SPI.
For scrambled data, any 0xFC character at the end of a frame is
replaced by an /F/, and any 0x7C character at the end of a
multiframe is replaced with an /A/. The JESD204B Rx checks
for /F/ and /A/ characters in the received data stream and
verifies that they only occur in the expected locations. If an
unexpected /F/ or /A/ character is found, the receiver handles
the situation by using dynamic realignment or activating the
SYNCINB± signal for more than four frames to initiate a
resynchronization. For unscrambled data, if the final character
of two subsequent frames is equal, the second character is
replaced with an /F/ if it is at the end of a frame, and an /A/ if it
is at the end of a multiframe.
Insertion of alignment characters may be modified using SPI.
The frame alignment character insertion is enabled by default.
More information on the link controls is available in the
Memory Map section, Register 0x062.
Link Setup Parameters
The following steps demonstrate how to configure the AD9625
JESD204B interface and the output:
1. Disable the lanes before changing configuration.
2. Select one quick configuration option.
3. Configure the detailed options.
4. Check FCHK, checksum of JESD204B interface parameters.
5. Set additional digital output configuration options.
6. Reenable the required lane(s).
7. Before modifying the JESD204B link parameters, disable
the link and hold it in reset.
8-Bit/10-Bit Encoder
The 8-bit/10-bit encoder converts 8-bit octets into 10-bit
characters and inserts control characters into the stream when
needed. The control characters used in JESD204B are shown in
Table 15. The 8-bit/10-bit encoding allows the signal to be dc
balanced by using the same number of ones and zeros.
The 8-bit/10-bit interface has options that may be controlled via
SPI. These operations include bypass, invert or mirror. These
options are intended to be a troubleshooting tool for the
verification of the digital front end (DFE).
AD9625 Data Sheet
Rev. C | Page 40 of 72
Digital Outputs, Timing, and Controls
The AD9625 physical layer consists of drivers that are defined in
the JEDEC Standard No. 204B-July 2011. The differential digital
outputs are powered up by default. The drivers utilize a
dynamic 100  internal termination to reduce unwanted
reflections.
Place a 100 Ω differential termination resistor at each receiver
input to result in a nominal 300 mV p-p swing at the receiver
(see Figure 89). Alternatively, single-ended 50 Ω termination
can be used. When single-ended termination is used, the termi-
nation voltage should be DRVDD/2; otherwise, 0.1 F ac coupling
capacitors can be used to terminate to any single-ended voltage.
The AD9625 digital outputs can interface with custom ASICs
and FPGA receivers, providing superior switching performance
in noisy environments. Single point-to-point network topologies
are recommended with a single differential 100  termination
resistor placed as close to the receiver inputs as possible.
OR
SERDOUT[x]+
DRVDD
V
RXCM
SERDOUT[x]–
OUTPUT SWING = 300mV p-p
0.1µF
100
5050
0.1µF
RECEIVER
V
CM
= V
RXCM
100
DIFFERENTIAL
TRACE PAIR
11814-243
Figure 89. AC-Coupled Digital Output Termination Example
If there is no far end receiver termination, or if there is poor
differential trace routing, timing errors may result. To avoid
such timing errors, it is recommended that the trace length be
less than six inches, and that the differential output traces be
close together and at equal lengths.
De-Emphasis
De-emphasis enables the receiver eye diagram mask to be met
in conditions where the interconnect insertion loss does not
meet the JESD204B specification. The de-emphasis feature
should only be used when the receiver is unable to recover the
clock due to excessive insertion loss. Under normal conditions,
it is disabled to conserve power. Additionally, enabling and
setting too high a de-emphasis value on a short link may cause
the receiver eye diagram to fail. Using the de-emphasis setting
may increase EMI. See the Memory Map section for details.
KKRD DARD DARD DADDARQC CD
END OF
MULTIFRAME
START OF
USER DATA
START OF LINK
CONFIGURATION
DATA
START OF
ILAS
11814-132
Figure 90. Initial Lane Alignment Sequence
Table 15. AD9625 Control Characters Used in JESD204B
Abbreviation Control Symbol 8-Bit Value
10-Bit Value
RD (Running
Disparity) = −1
10-Bit Value
RD (Running
Disparity) = +1 Description
/R/ /K28.0/ 000 11100 001111 0100 110000 1011 Start of multiframe
/A/ /K28.3/ 011 11100 001111 0011 110000 1100 Lane alignment
/Q/ /K28.4/ 100 11100 001111 0010 110000 1101 Start of link configuration data
/K/ /K28.5/ 101 11100 001111 1010 110000 0101 Group synchronization
/F/ /K28.7/ 111 11100 001111 1000 110000 0111 Frame alignment
Data Sheet AD9625
Rev. C | Page 41 of 72
Table 16. JESD204B Mode of Operation (M = 1, S = 4, N' = 16, Unless Otherwise Noted)
Quick
Configuration
Value Description1
Lanes
(L)
Octets/
Frame (F)
Sample Clock Rate
Sample Clock
Multiplier
JESD204B Lane Rate
Minimum
MSPS
Maximum
MSPS
Minimum
Mbps
Maximum
Mbps
0x02 Generic 2 4 330 650 10 3300 6500
0x04 Generic 4 2 650 1300 5 3250 6500
0x06 Generic (N' = 12) 6 1 1300 2500 2.5 3250 6250
0x08 Generic 8 1 1300 2500 2.5 3250 6250
0x42 fS × 8 2 4 406 813 8 3250 6500
0x44 fS × 4 4 2 813 1625 4 3250 6500
0x48 fS × 2 8 1 1625 2500 2 3250 5000
0x81 Single DDC, high BW 1 8 650 1300 5 3250 6500
0x82 Single DDC, high BW 2 4 1300 2500 2.5 3250 6250
0x91 Single DDC, low BW 1 8 1300 2500 2.5 3250 6250
0xC1 Dual DDC, high BW 1 8 330 650 10 3300 6500
0xC2 Dual DDC, high BW 2 4 650 1300 5 3250 6500
0xC4 Dual DDC, high BW 4 2 1300 2500 2.5 3250 6250
0xE1 Dual DDC, mixed BW 1 8 330 650 10 3300 6500
0xE2 Dual DDC, mixed BW 2 4 650 1300 5 3250 6500
0xE4 Dual DDC, mixed BW 4 2 1300 2500 2.5 3250 6250
0xD1 Dual DDC, low BW 1 8 650 1300 5 3250 6500
0xD2 Dual DDC, low BW 2 4 1300 2500 2.5 3250 6250
1 DDC means digital downconverter, BW means bandwidth, fS × x means sample rate multiplied by an integer (where x is an integer: 2, 4, 8).
Table 17. JESD204B Logical Lane Mapping
Quick
Configuration
Value Description
Lanes
(L)
Logical
Lane 0
Logical
Lane 1
Logical
Lane 2
Logical
Lane 3
Logical
Lane 4
Logical
Lane 5
Logical
Lane 6
Logical
Lane 7
0x02 Generic 2 S[N],
S[N + 1]
S[N + 2],
S[N + 3]
Off Off Off Off Off Off
0x04 Generic 4 S[N] S[N + 1] S[N + 2] S[N + 3] Off Off Off Off
0x06 Generic
(N' = 12)
6 SMSB[N], SLSB[N], SMSB[N + 1], SLSB[N + 1], SMSB[N + 2], SLSB[N + 2], SMSB[N + 3], SLSB[N + 3] Off Off
0x08 Generic 8 SMSB[N] SLSB[N] SMSB[N + 1] SLSB[N + 1] SMSB[N + 2] SLSB[N + 2] SMSB[N + 3] SLSB[N + 3]
0x42 fS × 8 2 See Figure 104, fS × 2 mode application layer (transmit)
0x44 fS × 4 4 See Figure 104, fS × 2 mode application layer (transmit)
0x48 fS × 2 8 SMSB[N], SLSB[N], SMSB[N + 1], SLSB[N + 1], SMSB[N + 2], SLSB[N + 2], SMSB[N + 3], SLSB[N + 3], SMSB[N + 4], SLSB[N + 4];
see Figure 104, fS × 2 mode application layer (transmit)
0x81 Single DDC,
high BW
1 I0[N],
Q0[N],
I0[N + 1],
Q0[N + 1]
Off Off Off Off Off Off Off
0x82 Single DDC,
high BW
2 I0[N],
Q0[N]
I0[N+1],
Q0[N+1]
Off Off Off Off Off Off
0x91 Single DDC,
low BW
1 I0[N],
Q0[N],
I0[N + 1],
Q0[N + 1]
Off Off Off Off Off Off Off
0xC1 Dual DDC,
high BW
1 I0[N],
Q0[N],
I1[N],
Q1[N]
Off Off Off Off Off Off Off
0xC2 Dual DDC,
high BW
2 I0[N],
Q0[N]
I1[N],
Q1[N]
Off Off Off Off Off Off
0xC4 Dual DDC,
high BW
4 I0[N] Q0[N] I1[N] Q1[N] Off Off Off Off
0xE1 Dual DDC,
mixed BW
1 I0[N],
Q0[N],
I1[N],
Q1[N]
Off Off Off Off Off Off Off
0xE2 Dual DDC,
mixed BW
2 I0[N],
Q0[N]
I1[N],
Q1[N]
Off Off Off Off Off Off
AD9625 Data Sheet
Rev. C | Page 42 of 72
Quick
Configuration
Value Description
Lanes
(L)
Logical
Lane 0
Logical
Lane 1
Logical
Lane 2
Logical
Lane 3
Logical
Lane 4
Logical
Lane 5
Logical
Lane 6
Logical
Lane 7
0xE4 Dual DDC,
mixed BW
4 I0[N] Q0[N] I1[N] Q1[N] Off Off Off Off
0xD1 Dual DDC,
low BW
1 I0[N],
Q0[N],
I1[N],
Q1[N]
Off Off Off Off Off Off Off
0xD2 Dual DDC,
low BW
2 I0[N],
Q0[N]
I1[N],
Q1[N]
Off Off Off Off Off Off
Table 18. Typical Current Consumption per ADC Mode (Unused Output Lanes are Powered Down)
Quick
Configuration
Value Mode
Lanes
(L)
Sample Rate
(MSPS)
Typical Current Consumption (A)
IAVDD1 I
AVDD2 I
DRVDD1 I
DRVDD2 I
DVDD1 I
DVDD2 Total Power (W)
0x02 Generic, two lane 2 650 0.7 0.3 0.2 0.0 0.1 0.0 2.1
0x04 Generic, four lane 4 1300 0.9 0.3 0.3 0.0 0.2 0.0 2.6
0x06 Generic, six lane 6 2600 1.2 0.4 0.4 0.0 0.4 0.0 3.4
0x08 Generic, eight lane 8 2600 1.2 0.4 0.5 0.0 0.4 0.0 3.9
0x42 fS × 8 2 813 0.7 0.4 0.2 0.0 0.2 0.0 2.3
0x44 fS × 4 4 1625 1.0 0.4 0.3 0.0 0.3 0.0 3.0
0x48 fS × 2 8 2600 1.2 0.4 0.5 0.0 0.4 0.0 3.8
0x81 Single DDC high BW, one lane 1 1300 0.9 0.4 0.1 0.0 0.3 0.0 2.7
0x82 Single DDC high BW, two lane 2 2600 1.2 0.4 0.2 0.0 0.6 0.0 3.6
0x91 Single DDC low BW, one lane 1 2600 1.2 0.4 0.1 0.0 0.6 0.0 3.5
0xC1 Dual DDC high BW, one lane 1 650 0.7 0.4 0.1 0.0 0.2 0.0 2.3
0xC2 Dual DDC high BW, two lane 2 1300 0.9 0.4 0.2 0.0 0.5 0.0 2.9
0xC4 Dual DDC high BW, four lane 4 2600 1.2 0.4 0.3 0.0 0.8 0.0 4.0
0xE1 Dual DDC mixed BW, one lane 1 650 0.7 0.4 0.1 0.0 0.2 0.0 2.3
0xE2 Dual DDC mixed BW, two lane 2 1300 0.9 0.4 0.2 0.0 0.5 0.0 2.9
0xE4 Dual DDC mixed BW, four lane 4 2600 1.2 0.4 0.3 0.0 0.8 0.0 4.0
0xD1 Dual DDC low BW, one lane 1 1300 0.9 0.4 0.1 0.0 0.4 0.0 2.8
0xD2 Dual DDC low BW, two lane 2 2600 1.2 0.4 0.2 0.1 0.8 0.0 4.0
Data Sheet AD9625
Rev. C | Page 43 of 72
PHYSICAL LAYER OUTPUT
400
–400
–300
–200
–100
0
100
200
300
–150 –100 –50 0 50 100 150
VOLTAGE (mV)
TIME (ps)
11814-026
Figure 91. Recovered Data Eye of JESD204B Lane at 6.25 Gbps
1
1
–2
1
–4
1
–6
1
–8
1
–10
1
–12
1
–14
–0.5 –0.4 –0.3 0.2 –0.1 0 0.1 0.2 0.3 0.4 0.5
BE
R
UI
11814-027
Figure 92. Bathtub Plot of JESD204B Output at 6.25 Gbps
180
160
140
120
100
80
60
40
20
0
–15 –10 –5 0 5 10 15
HITS
TIME (ps)
11814-028
Figure 93. Time Interval Histogram Error of JESD204B Output at 6.25 Gbps
SCRAMBLER
The scrambler polynomial is 1 + x14 + x15. The scrambler enable
bit is located in Register 0x06E[7].
Setting Bit 7 to 0 disables the scrambler.
Setting Bit 7 to 1 enables the scrambler.
TAIL BITS
The tail bit, PN generator, is located in Register 0x05F[6].
Setting Bit 6 to 0 disables the tail bit generator.
Setting Bit 6 to 1 enables the tail bit generator.
DDC MODES (SINGLE AND DUAL)
The AD9625 contains two separate DDCs that can digitally
downconvert real ADC output data into I/Q decimated data
at a reduced bandwidth. This feature is useful when the full
bandwidth supplied by the 2.6 GSPS converter is not needed.
Figure 94 shows a simplified block diagram of the DDC blocks
as they traverse through the AD9625. Because all JESD204B
frames contain four samples (S = 4), the output from the DDCs
must also output four samples. Table 19 shows the remapping of
I/Q samples to converter samples for the JESD204B interface,
specific to the AD9625.
When in mixed bandwidth mode, DDC 0 is always in high
bandwidth mode and DDC 1 is always in low bandwidth mode.
To match the data throughput of the high bandwidth mode, the
low bandwidth samples are repeated twice in mixed bandwidth
mode. Table 20 lists the four frames of data for both DDC 0
(high bandwidth mode) and DDC 1 (low bandwidth mode).
AD9625 Data Sheet
Rev. C | Page 44 of 72
I0
Q0
I1
Q1
LOGICAL LANE 0 (L0)
LOGICAL LANE 1 (L1)
LOGICAL LANE 2 (L2)
LOGICAL LANE 3 (L3)
16
16
16
16
LOGICAL LANE 4 (L4)
LOGICAL LANE 5 (L5)
LOGICAL LANE 6 (L6)
LOGICAL LANE 7 (L7)
REMAP
I/Q TO
CONVERTER
SAMPLES
SAMPLE [N]
SAMPLE [N + 1]
SAMPLE [N + 2]
SAMPLE [N + 3]
48
ADC
JESD204X
INTERFACE
(M = 1; L = 8; S = 4;
F = 1; N = 16; N' = 16;
CF = 0; SCR = 0, 1;
HD = 1;
K = SEE SPECS)
12-BIT ADC
SAMPLES [N]
THROUGH [N + 3]
DCC 0DCC 1
11814-029
Figure 94. DDC Mapping
Table 19. DDC Remap I/Q to Converter Samples
Application Mode Sample[N] Sample[N + 1] Sample[N + 2] Sample[N + 3]
Single DDC I0[N] Q0[N] I0[N + 1] Q0[N + 1]
Dual DDCs I0[N] Q0[N] I1[N] Q1[N]
Table 20. DDC Mixed Bandwidth Mode
JESD204B Frame Number Sample[N] Sample[N + 1] Sample[N + 2] Sample[N + 3]
Frame 0 I0[N] Q0[N] I1[N] Q1[N]
Frame 1 I0[N + 1] Q0[N + 1] I1[N] Q1[N]
Frame 2 I0[N + 2] Q0[N + 2] I1[N + 1] Q1[N + 1]
Frame 3 I0[N + 3] Q0[N + 3] I1[N + 1] Q1[N + 1]
CHECKSUM
The JESD204B checksum value is sent with the configuration
parameters during the initial lane alignment sequence. Disabling
the checksum is primarily for debug purposes only.
8-BIT/10-BIT ENCODER CONTROL
The 8-bit/10-bit encoder must be controlled in the following
manner:
The bypass 8-bit/10-bit encoder is controlled by
Register 0x60, Bit 2 (0 = 8-bit/10-bit enabled; 1 =
8-bit/10-bit bypassed).
The invert 10-bit encoder is controlled by Register 0x060,
Bit 1 (0 = normal; 1 = invert).
The mirror 10-bit encoder is controlled by Register 0x060,
Bit 0 (0 = normal; 1 = mirrored).
The inversion of the 10-bit values allows the user to swap the
true/complement differential pins swapped on the boards. For
details about Register 0x060, see the Memory Map Register
section.
INITIAL LANE ALIGNMENT SEQUENCE (ILAS)
The AD9625 must support three different ILAS modes that are
controlled using Bits[3:2] in Register 0x05F as follows:
00: disabled
01: enabled
10: reserved
11: always on test mode
When enabled, the device must also support the capability to
repeat the ILAS using Bits[7:0] in Register 0x062 to determine
the number of times ILAS is repeated (0 = repeat 0 times, ILAS
runs one time only, 1 = repeat one time, ILAS runs twice, and
so forth). Because the number of frames per multiframe is
determined by the value of K, the total number of frames
transmitted during the initial lane alignment sequence is
4 × (K + 1) × (ILAS_COUNT + 1)
where the value of K is defined in Register 0x070, Bits[4:0].
Note that only values divisible by four can be used.
For details about Register 0x05F and Register 0x062, see the
Memory Map Register section.
Data Sheet AD9625
Rev. C | Page 45 of 72
LANE SYNCHRONIZATION
Lane synchronization is defined by Register 0x05F, Bit 4 (0 =
disabled, 1 = enabled). For more information, see the Memory
Map Register section.
Multichip Synchronization Using SYSREF± Timestamp
The SYSREF± pin in the AD9625 can also be used as a
timestamp of data as it passes through the ADC and out the
JESD204B interface. This can be accomplished in two ways:
Replace the least significant converter bit with the
synchronous low to high captured SYSREF± signal. If
the AD9625 were configured as a 12-bit converter, this
would effectively reduce it to a 11-bit converter. This is
accomplished by setting Register 0x03A[7] = 1 in the
register map.
Use the extra output JESD204B control bits to insert the
synchronous low to high captured SYSREF± signal. These
extra control bits are only available while in the JESD204B
generic two, four, and eight lane modes. The generic six lane
mode does not support control bits as both N and N’ = 12.
Six Lane Output Mode
The full data output bandwidth of the eight lane mode can
alternately by output using a six lane mode. This is achieved by
using an N’ = 12 in the six lane mode vs. N’ = 16 in the eight
lane mode for N = 12 ADC data.
The benefit of using the six lane mode is that only six lanes of
output data are needed instead of eight lanes and two output
data lanes can be powered down. A drawback of the six lane
mode is that because there is full efficiency of the link for N =
N’ = 12, there is no spare bandwidth available for control bits.
Therefore, control bit timestamping using SYSREF± cannot be
used in the six lane mode. The LSB of the 12-bit ADC data can
be substituted to output the SYSREF± timestamp.
N – 1 N + 1
N + 2 N + 3
N
AIN
ENCODE
CLK
SYSREF
AD9625
PIPELINE
LATENCY
N – 1
N
N + 1
N + 2
N + 3
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
SYSREF
CO NTR OL BIT
12-BIT ADC
SAMPLES 4- BIT CONT ROL
AND TAIL BITS
SAMPLES
11814-480
Figure 95. A SYSREF± Control Bit Can Be Used to Mark the Same Analog
Sample that is Coincident with a Sampled SYSREF± Edge by CLK±
ADC Output Control Bits on JESD204B Samples
When N' = 16 and the ADC resolution is 12, there are four
spare bits available per sample. Two of these spare bits can be
used as control bits, depending on the configuration options.
The control bits are set in Register 0x072, Bits[7:6]. (CS means
control bits per sample.)
00: no control bits sent per sample (CS = 0).
01: one control bit sent per sample, overrange bit enabled,
(CS = 1).
10: two control bits sent per sample, overrange and time
stamped SYSREF± control bit (marks the sample of a rising
edge seen on the SYSREF± pin), (CS = 2). Use of the
SYSREF± control bit (CS = 2) time stamps a particular
analog sample that is seen coincident with a rising signal
on the SYSREF± pins. See the Register 0x08A description to
disable the LMFC JESD204B alignment for timestamping.
SYSREF± Setup and Hold IRQ
The differential SYSREF± inputs to AD9625 are critical for
JESD204B deterministic latency and sample timestamping. At
a 2.5 GSPS sample rate, the clock period is only 400 ps in
duration from which to accurately latch a SYSREF± edge to
meet setup and hold time to the sample clock. Therefore, it is
important to know the location of the SYSREF± edge relative to
the sampling edge of the encode clock. To help identify the
SYSREF± edge location within the clock period, the AD9625
provides a setup and hold time edge detector circuit to provide
feedback to the system for SYSREF± timing skew and other
alignment procedures. This is a fine timing detector (<1 clock
cycle) and does not provide useful information if coarse timing
(>1 clock cycle) skew adjustment is needed on SYSREF±.
The AD9625 provides an interrupt request (IRQ) bit that
identifies either a setup or a hold time error for the SYSREF±
edge relative to the sampling clock. The error indicates that the
SYSREF± edge is present within the designated time window.
There is a default detector window for both the actual setup and
hold time, with each being nominally 35 ps in time. This error
flag can be identified internal to the AD9625 IRQ register or the
status can be sent externally via the IRQ pin, provided that the
appropriate interrupts are masked or enabled as desired.
A SYSREF± edge located in either the setup or hold violation
window causes ambiguity as to whether the event latchs on
CLK±[N] or CLK±[N + 1]. As a best practice, the SYSREF± edge
must be earlier than both the setup and hold violation windows so
that a deterministic clock can be used to latch SYSREF±.
CLK+
SYSREF–
S
YSREF+
CLK–
SETUP IRQ ERROR
11814-481
Figure 96. SYSREF± Edge Falls Within the Actual Setup Time Window and
Triggers an IRQ Error
AD9625 Data Sheet
Rev. C | Page 46 of 72
CLK+
SYSREF–
S
YSREF+
CLK–
HOLD IR Q ERROR
11814-482
Figure 97. SYSREF± Edge Falls Within the Actual Hold Time Window and
Triggers an IRQ Error
IRQ Guardband Delays (SYSREF± Setup and Hold)
Additional guardband delays can be added to each of the default
setup and hold time windows. This yields more information to
the system about the placement of the SYSREF± edge within the
clock period and help identify the proximity of the SYSREF± edge
to the actual setup and hold time windows. With a default
setting of 00b for both setup and hold, each has seven
additional settings to increase the guardband timing feedback
information.
There are 3 bits that define the SYSREF± setup time guardband
located in Register 0x13C[7:5]. There are 3 bits that define the
SYSREF± hold time guardband located in Register 0x13B[7:5].
A setting of 000b for either is the default of no additional timing
guardband, with just the actual setup and hold time window
used as the IRQ.
The IRQ flag for the SYSREF± setup window is in Register
0x100[2], while the IRQ flag for the SYSREF± hold window is
in Register 0x100[3]. The IRQ flag mask for the SYSREF± setup
window is in Register 0x101[2], while the IRQ flag mask for the
SYSREF± hold window is in Register 0x101[3].
After each IRQ alert, the status needs to be cleared, as it does
not automatically clear itself, even if the alert conditions are no
longer valid. For either the SYSREF± setup or hold IRQ alert,
the status is cleared using Register 0x03A[6]. Setting Register
0x03A[6] = 1 clears and hold the IRQ in a reset value of 0. To
allow IRQ flags pertaining to SYSREF± again, set Register
0x03A[6] = 0.
CLK+
SYSREF–
S
YSREF+
CLK–
111
110
101
100
011
010
001
000
000
001
010
011
100
101
110
111
SETUP AND
GUARDB AND T I M E HOLD AND
GUARD BAND T I M E
SETUP G UA RDBAND
IRQ DELAYS HOLD GU ARDBAN D
IRQ DELAYS
11814-483
Figure 98. SYSREF± Edge Falls Within the Guardbanded Setup Time Window
and Triggers an IRQ Error
In Figure 98, the SYSREF± edge meets the default setup and
hold time of the clock, but would trigger an IRQ event only if
certain setup time guardband delays were used. For this figure,
all of the setup guardband delays that would place the SYSREF±
crossing edge between it and the dotted black line would incur
an IRQ event equal to 1. All other settings would be 0. Because
there is no edge in the hold guardband delays, those would all
be 0 if they were set.
Table 21. IRQ Outcomes for All Setup or Hold Guardband
Settings for the Case in Figure 98
Setting/IRQ Setup Hold
000 0 0
001 0 0
010 0 0
011 0 0
100 1 0
101 1 0
110 1 0
111 1 0
CLK+
SYSREF–
S
YSREF+
CLK–
111
110
101
100
011
010
001
000
000
001
010
011
100
101
110
111
SETUP AND
GUARDB AND T I M E HOLD AND
GUARD BAND T I M E
SETUP G UA RDBAND
IRQ DELAYS HOL D GUARDBAND
IRQ DELAYS
11814-484
Figure 99. SYSREF± Edge Falls Within the Guardbanded Hold Time Window
and Triggers an IRQ Error
In Figure 99, the SYSREF± edge misses the default setup and
hold time of the clock, but would trigger an IRQ event only if
certain hold time guardband delays were used. For this figure,
all of the hold guardband delays that would place the SYSREF±
crossing edge between it and the dotted black line would incur
an IRQ event equal to 1. All other settings would be 0. Because
there is no edge in the setup guardband delays, those would all
be 0 if they were set.
Table 22. IRQ Outcomes for All Setup or Hold Guardband
Settings Using the Case in Figure 99
Setting/IRQ Setup Hold
000 0 0
001 0 0
010 0 0
011 0 0
100 0 1
101 0 1
110 0 1
111 0 1
Data Sheet AD9625
Rev. C | Page 47 of 72
In the case where the encode clock used for the AD9625 is
sufficiently fast (>1.75 GSPS), the guardband delays for the
earliest setup and latest hold condition starts to overlap in time
due to the fast clock period. This case occurs when the encode
clock period is smaller than 16× the nominal delay guardband
window of 35 ps or (1/fS < 16 × 35 ps). The earliest setup guard-
band delays from clock N can overlap with the latest guardband
delays from CLK±[N + 1]. When this is the case, a SYSREF±
edge located in one of these overlapped guardband delays
triggers an IRQ event for both the setup and hold detection.
While it is possible to make use of this information, it is
suggested to limit the number of valid settings to no more
than 5 (100b) and below when sampling above 1.75 GSPS to
avoid this situation.
CLK+
SYSREF–
S
YSREF+
CLK–
111
110
101
100
011
010
001
000
000
001
010
011
HOLD AND
GUARDBAND TIME [N]
SETUP AND
GUARDBAND TIME [N + 1]
HOLD GUARDBAND
[N] IRQ DELAYS
SETUP GUARDBAND
[N +1] IRQ DELAYS
010
001
000
000
001
010
011
100
101
110
111 OVERLAP
CLK±[N] CLK±[N + 1]
11814-485
Figure 100. SYSREF± Edge Falls Within Both the Latest Hold Time
Guardbanded of CLK±[N] and the Earliest Setup Time Guardband of
CLK±[N + 1] and Triggers an IRQ Error
Table 23. IRQ Outcomes for All Setup or Hold Guardband
Settings Using the Case in Figure 100
Setting/IRQ Setup Hold
000 0 0
001 0 0
010 0 0
011 0 0
100 0 0
101 0 0
110 0 0
111 1 1
As a secondary use, the SYSREF± edge detector can also alert
the system about phase shift drift between SYSREF± and CLK
due to temperature or supply changes. For example, a conservative
guardband setting could be used, such that an IRQ status of 0
would be seen in ideal conditions. If timing drifts were significant
enough to trigger the IRQ, the system would take action to
adjust the skew of the SYSREF± to CLK accordingly to reestablish
an IRQ of 0.
CLK+
SYSREF–
SYSREF+
CLK–
111
110
101
100
011
010
001
000
000
001
010
011
100
101
110
111
SETUP AND
GUARDBAND TIME
HOLD AND
GUARDBAND TIME
SETUP GUARDBAND
IRQ DELAYS
HOLD GUARDBAND
IRQ DELAYS
1
1814
-
486
Figure 101. SYSREF± Edge Changes Phase Relative to the Encode Clock,
Which can be Detected When the Edge Crosses Through the Guardband
Setup Time
Table 24. IRQ Outcomes for all Setup or Hold Guardband
Settings Using the Case in Figure 101
Setting/IRQ Setup Hold Setting/IRQ Setup Hold
000 0 0 000 0 0
001 0 0 001 0 0
010 0 0 010 1 0
011 0 0 011 1 0
100 1 0 100 1 0
101 1 0 101 1 0
110 1 0 110 1 0
111 1 0 111 1 0
Using Rising/Falling Edges of the CLK to Latch SYSREF±
The SYSREF± signal can be latched on either the rising or
falling edge of the encode clock, based on the value of register
0x03A[3] = 0 (latch on rising edge) or 0x03A[3] = 1 (latch on
falling edge). This does not impact the analog input, which is
always sampled on the rising edge of the encode clock. For
sampling SYSREF±, the falling edge encode capture of CLK±[N]
precedes the rising edge encode capture of CLK±[N], both
corresponding to the same analog sample.
AD9625 Data Sheet
Rev. C | Page 48 of 72
For synchronous sampling of multiple converters using
SYSREF±, it may be possible to have a scenario shown in
Figure 102. This case uses a SYSREF± capture with the falling
edge of the encode clock first to test the SYSREF± position
using the edge detection window. The three ADC’s each receive
a SYSREF± input that may be skewed in time due to board trace
length or source variance. For ADC[0] SYSREF± meets setup/
hold to CLK±[N], ADC[1] misses setup/hold to CLK±[N], and
ADC[2] is indeterminate as it falls within the setup/hold window
and may be latched by either CLK±[N] or CLK±[N + 1].
CLK+
CLK–
SYSREF–
S
YSREF+
SYSREF–
S
YSREF+
SYSREF–
S
YSREF+
ADC[0]
ADC[1]
ADC[2]
CLK±[N]
FALLING
CLK±[N + 1]
FALLING
CLK±[N]
RISING
?
11814-487
Figure 102. SYSREF± Case From Three ADCs Having Various Phase Delays
Relative to the Falling Edge of the Encode Clock and is Latched on Different
Sample Clock Edges CLK±[N] or CLK±[N + 1]
As a solution to this case, the SYSREF± capture edge can be
changed from falling to rising, which is still captured to the
analog sample from CLK±[N]. When this is done, all three
ADC’s now meet the setup/hold time for the rising edge capture
of CLK±[N].
CLK+
CLK–
SYSREF–
S
YSREF+
SYSREF–
S
YSREF+
SYSREF–
S
YSREF+
ADC[0]
ADC[1]
ADC[2]
CLK±[N]
FALLING
CLK±[N + 1]
FALLING
CLK±[N]
RISING
11814-488
Figure 103. Changing the Latching Edge to Rising for All Three ADCs,
SYSREF± Can Now be Aligned to CLK±[N]
Test Modes
Bits[5:4] in Register 0x061 control the JESD204B interface test
injection points.
00: 16-bit test generation data injected at the sample input
to the link.
01: 10-bit test generation data injected at the output of the
8-bit/10-bit encoder (at the input to PHY).
10: 8-bit test generation data injected at the input of the
scrambler.
11: reserved.
Bits[3:0] in Register 0x061 determine the type of test patterns
that are injected, as follows:
0000: normal operation (test mode disabled).
0001: alternating checkerboard.
0010: 1/0 word toggle.
0011: PN sequence: long (x23 + x18 + 1).
0101: continuous/repeat user test mode; most significant
bits from 16-bit user pattern (1, 2, 3, 4) are placed on the
output for one clock cycle and then repeated. (Output user
pattern: 1, 2, 3, 4, 1, 2, 3, 4, 1, 2, 3, 4, ….)
0110: single user test mode; most significant bits from the
16-bit user pattern (1, 2, 3, 4) placed on the output for one
clock cycle and then outputs all zeros. (Output user
pattern: 1, 2, 3, 4, then output all zeros.)
0111: Ramp output (dependent on test injection point and
number of bits, N).
1000: modified RPAT test sequence.
1001: unused.
1010: JSPAT test sequence.
1011: JTSPAT test sequence.
1100 to 1111: unused.
JESD204B APPLICATION LAYERS
The AD9625 supports the following application layer modes via
Register 0x063[3:0]:
0100: fS × x mode which supports line rates at integer
multiples of the sample rates
1000: single DDC mode, high bandwidth mode (only
DDC 0 used)
1001: single DDC mode, low bandwidth mode (only
DDC 0 used)
1010 to 1011: unused
1100: dual DDC mode, high bandwidth mode (both
DDC 0 and DDC 1 used)
1101: dual DDC mode, low bandwidth mode (both DDC 0
and DDC 1 used)
1110: dual DDC mode, mixed bandwidth mode (DDC 0
high bandwidth mode, DDC 1 low bandwidth mode,
samples repeated)
Data Sheet AD9625
Rev. C | Page 49 of 72
fS × 2, fS × 4, fS × 8 Modes
The JESD204B low multiplier mode application layer adds a
rate conversion on top of a JESD204B transmitter/receiver with
the following configuration parameters: M = 1; L = 8; S = 4;
F = 1; N = 16; N' = 16; CS = 0; CF = 0; SCR = 0, 1; HD = 1;
K = reference JESD204B specification.
In this mode, there are five actual samples per frame and
scrambling can be optionally enabled in the JESD204B
interface. The transmit portion of the low multiplier mode
JESD204B application layer is shown in Figure 104.
The first step in this application layer is where 12-bit ADC
samples are divided into six bytes.
To allow the line rate of the JESD204B interface to map directly
into an integer of the converter sample rate, a four to five rate
conversion takes place to group the 12-bit ADC samples into
blocks of five samples. During this rate conversion, for every
five 12-bit ADC sample, an extra user defined, 4-bit nibble is
appended to create a 64-bit frame. Next, the 64-bit low multi-
plier frame maps into the four 16-bit JESD204B samples. The
most significant 16-bits of the 64-bit low multiplier frame map
to the oldest 16-bit JESD204B sample and the least significant
16-bits of the 64-bit low multiplier frame map to the most
recent 16-bit JESD204B sample.
The receive portion of the fS × 2 JESD204B application layer is
shown in Figure 105.
ADC SAMPLE N
(12 BITS)
ADC
JESD SAMPLE N
(16 BITS)
APPLICATION
LAYER
DATA LINK,
TRANSPORT,
AND PHY LAYERS
f
S
× 2 APPLICATION LAYER (TRANSMIT)
4/5 RATE EXCHANGE
ADC CONVERTER SAMPLE N
(N = 8, 10, OR 12 BITS)
CONTROL BITS FOR SAMPLE N
(CS = 0, 2 OR 4 BITS)
ADC CONVERTER SAMPLE N + 1
(N = 8, 10 OR 12 BITS)
CONTROL BITS FOR SAMPLE N + 1
(CS = 0, 2 OR 4 BITS)
ADC CONVERTER SAMPLE N + 2
(N = 8, 10 OR 12 BITS)
CONTROL BITS FOR SAMPLE N + 2
(CS = 0, 2 OR 4 BITS)
ADC CONVERTER SAMPLE N + 3
(N = 8, 10 OR 12 BITS)
CONTROL BITS FOR SAMPLE N + 3
(CS = 0, 2 OR 4 BITS)
LANE 0
S[N][15:0]
S[N + 1][15:0]
S[N + 2][15:0]
S[N + 3][15:0]
LANE 1
LANE 2
LANE 3
LANE 4
LANE 5
LANE6
LANE 7
USER DEFINED
(FSYNC[3:0])
ADC SAMPLE N + 1
(12 BITS)
ADC SAMPLE N + 2
(12 BITS)
ADC SAMPLE N + 3
(12 BITS)
48 BITS
@
f
S
/4
64 BITS
@
f
S
/5
64 BITS
@
f
S
/5
ADC SAMPLE N
(12 BITS)
ADC SAMPLE N + 1
(12 BITS)
ADC SAMPLE N + 2
(12 BITS)
ADC SAMPLE N + 3
(12 BITS)
ADC SAMPLE N + 4
(12 BITS)
(4 BITS)
S[N][11:0], S[N + 1][11:8]
(16 BITS)
S[N + 1][7:0], S[N + 2][11:4]
(16 BITS)
S[N + 2][3:0], S[N + 3][11:0]
(16 BITS)
S[N + 4][11:0], UD[3:0]
(16 BITS)
JESD SAMPLE N + 1
(16 BITS)
JESD SAMPLE N + 2
(16 BITS)
JESD SAMPLE N + 3
(16 BITS)
JESD204B FRAMER + PHY
(M = 1; L = 8; S = 4; F = 1; N = 16; N' = 16; CF = 0; SCR = 0, 1; HD = 1; K = SEE SPEC
11814-032
Figure 104. fS × 2 Mode Application Layer (Transmit)
AD9625 Data Sheet
Rev. C | Page 50 of 72
APPLICATION
LAYER
DATA LINK,
TRANSPORT,
AND PHY LAYERS
f
S
× 2 APPLICATION LAYER (RECEIVE)
4/5 RATE EXCHANGE
CUSTOMER APPLICATION
ADC CONVERTER SAMPLE N
(N = 8, 10, OR 12 BITS)
CONTROL BITS FOR SAMPLE N
(CS = 0, 2 OR 4 BITS)
ADC CONVERTER SAMPLE N + 1
(N = 8, 10 OR 12 BITS)
CONTROL BITS FOR SAMPLE N + 1
(CS = 0, 2 OR 4 BITS)
ADC CONVERTER SAMPLE N + 2
(N = 8, 10 OR 12 BITS)
CONTROL BITS FOR SAMPLE N + 2
(CS = 0, 2 OR 4 BITS)
ADC CONVERTER SAMPLE N + 3
(N = 8, 10 OR 12 BITS)
CONTROL BITS FOR SAMPLE N + 3
(CS = 0, 2 OR 4 BITS)
LANE 0
S[N][15:0]
S[N + 1][15:0]
S[N + 2][15:0]
S[N + 3][15:0]
LANE 1
LANE 2
LANE 3
LANE 4
LANE 5
LANE6
LANE 7
USER
DEFINED
ADC SAMPLE N
(12 BITS)
ADC SAMPLE N + 1
(12 BITS)
ADC SAMPLE N + 2
(12 BITS)
ADC SAMPLE N + 3
(12 BITS)
4
8 BIT
S
@f
S
/4
64 BIT
S
@f
S
/5
64 BIT
S
@f
S
/5
ADC SAMPLE N
(12 BITS)
ADC SAMPLE N + 1
(12 BITS)
ADC SAMPLE N + 2
(12 BITS)
ADC SAMPLE N + 3
(12 BITS)
ADC SAMPLE N + 4
(12 BITS)
(4 BITS)
S[N][11:0], S[N + 1][11:8]
(16 BITS)
S[N + 1][7:0], S[N + 2][11:4]
(16 BITS)
S[N + 2][3:0], S[N + 3][11:0]
(16 BITS)
S[N + 4][11:0], UD[3:0]
(16 BITS)
JESD SAMPLE N
(16 BITS)
JESD SAMPLE N + 1
(16 BITS)
JESD SAMPLE N + 2
(16 BITS)
JESD SAMPLE N + 3
(16 BITS)
JESD204B FRAMER + PHY
(M = 1; L = 8; S = 4; F = 1; N = 16; N' = 16; CF = 0; SCR = 0, 1; HD = 1; K = SEE SPEC
11814-033
Figure 105. fS × 2 Application Layer (Receive)
Data Sheet AD9625
Rev. C | Page 51 of 72
FRAME ALIGNMENT CHARACTER INSERTION
Frame alignment character insertion (FACI) is defined in the
register map (see the Memory Map Register section). Disable
FACI only when it is used as a test feature.
The FACI disable bit is located in Register 0x05F, Bit 1. Use the
following settings:
Setting Bit 1 to 0 = FACI enabled
Setting Bit 1 to 1 = FACI disabled
THERMAL CONSIDERATIONS
Because of the high power nature of the device, it is critical to
provide airflow and/or install a heat sink when operating at a
high temperature. This ensures that the maximum case
temperature does not exceed 85°C.
POWER SUPPLY CONSIDERATIONS
The AD9625 must be powered by the following two supplies:
AVDD1 = DVDD1 = DRVDD1 = 1.3 V, AVDD2 = DVDD2 =
DRVDD2 = 2.5 V. An optional DVDDIO and SPI_DVDDIO
may be required at 2.5 V.
For applications requiring an optimal high power efficiency
and low noise performance, it is recommended that ADP2386
switching regulator is used to convert the 12 V input rail into
two intermediate rails (2.1 V and 3.6 V). These intermediate
rails are then postregulated by very low noise, low dropout (LDO)
regulators (ADP1740, ADP7104, and ADP125). Figure 106
shows the recommended method.
ADP1740
LDO
ADP1740
LDO
ADP1740
LDO
ADP1740
LDO
ADP125
LDO
ADP125
LDO
ADP2386
BUCK
REGULATOR
2.1V
ADP2386
BUCK
REGULATOR
3.6V
1.3V: AVDD1
2.5V: AVDD2
1.3V: DRVDD1
1.3V: DVDD1
2.5V: DRVDD2
2.5V: DVDDIO
2.5V: SPI_DVDDIO
2.5V: DVDD2
12V
INPU
T
11814-054
Figure 106. Power Supply Recommendation
AD9625 Data Sheet
Rev. C | Page 52 of 72
SERIAL PORT INTERFACE (SPI)
The AD9625 SPI allows the user to configure the converter for
specific functions or operations through a structured register
space provided inside the ADC. The SPI gives the user added
flexibility and customization, depending on the application.
Addresses are accessed via the serial port and can be written to
or read from via the port. Memory is organized into bytes that
can be further divided into fields. These fields are documented
in the Memory Map section.
CONFIGURATION USING THE SPI
Three pins define the SPI of this ADC: the SCLK pin, the SDIO
pin, and the CSB pin (see Table 25). The SCLK (serial clock) pin is
used to synchronize the read and write data presented from/to the
ADC. The SDIO (serial data input/output) pin is a dual-purpose
pin that allows data to be sent and read from the internal ADC
memory map registers. The CSB (chip select bar) pin is an active
low control that enables or disables the read and write cycles.
Table 25. Serial Port Interface Pins
Pin Function
SCLK Serial Clock. The serial shift clock input, which is used to
synchronize serial interface, reads and writes.
SDIO Serial Data Input/Output. A dual-purpose pin that
typically serves as an input or an output, depending on
the instruction being sent and the relative position in the
timing frame.
CSB Chip Select Bar. An active low control that gates the read
and write cycles.
The falling edge of CSB, in conjunction with the rising edge of
SCLK, determines the start of the framing.
Other modes involving the CSB pin are available. The CSB pin
can be held low indefinitely, which permanently enables the
device; this is called streaming. The CSB pin can stall high
between bytes to allow for additional external timing. When
CSB is tied high, SPI functions are placed in a high impedance
mode. This mode turns on any SPI pin secondary functions.
All data is composed of 8-bit words. The first bit of each individual
byte of serial data indicates whether a read or write command is
issued. This allows the SDIO pin to change direction from an
input to an output.
In addition to word length, the instruction phase determines
whether the serial frame is a read or write operation, allowing
the serial port to be used both to program the chip and to read
the contents of the on-chip memory. If the instruction is a read
operation, performing a read causes the SDIO pin to change
direction from an input to an output at the appropriate point in
the serial frame.
Data can be sent in MSB first mode or in LSB first mode. MSB
first is the default on power-up and can be changed via the SPI
port configuration register.
HARDWARE INTERFACE
The pins described in Table 25 comprise the physical interface
between the user programming device and the serial port of the
AD9625. The SCLK pin and the CSB pin function as inputs when
using the SPI interface. The SDIO pin is bidirectional, functioning
as an input during write phases and as an output during read.
The SPI interface is flexible enough to be controlled by either
FPGAs or microcontrollers. One method for SPI configuration
is described in detail in the AN-812 Application Note,
Microcontroller-Based Serial Port Interface (SPI) Boot Circuit.
Do not activate the SPI port during periods when the full dynamic
performance of the converter is required. Because the SCLK signal,
the CSB signal, and the SDIO signal are typically asynchronous
to the ADC clock, noise from these signals can degrade converter
performance. If the on-board SPI bus is used for other devices, it
may be necessary to provide buffers between this bus and the
AD9625 to prevent these signals from transitioning at the converter
inputs during critical sampling periods.
Data Sheet AD9625
Rev. C | Page 53 of 72
MEMORY MAP
READING THE MEMORY MAP REGISTER
Each row in the memory map register contains eight bit
locations. The memory map is roughly divided into three
sections: the chip configuration registers (Address 0x000 to
Address 0x002); the transfer register (Address 0x0FF); and the
ADC functions registers, including setup, control, and test
(Address 0x008 to Address 0x13A).
The memory map register tables provide the default hexadecimal
value for each hexadecimal address that is listed.
The column with the heading, Bit 7 (MSB), is the start of the
default hexadecimal value given. For example, Address 0x14,
the output mode register, has a hexadecimal default value of
0x01. This means that Bit 0 = 1, and the remaining bits are 0s.
This setting is the default output format value, which is twos
complement. For more information on this function and others,
see the AN-877 Application Note, Interfacing to High Speed
ADCs via SPI.
Open and Reserved Locations
All address and bit locations are not currently supported for this
device. Unused bits of a valid address location should be written
with 0s. Writing to these locations is required only when a
portion of an address location is open. If the entire address
location is open, this address location should not be written.
Default Values
After the AD9625 is reset, critical registers are loaded with
default values. The default values for the registers are given in
the memory map register tables.
Logic Levels
An explanation of logic level terminology follows:
“Bit is set” is synonymous with “bit is set to Logic 1” or
“writing Logic 1 for the bit.
Clear a bit” is synonymous with “bit is set to Logic 0” or
“writing Logic 0 for the bit.
Transfer Register Map
Register addresses for the AD9625 are shadowed. Register
writes do not affect device operation until a transfer command
is issued by writing 0x01 to Address 0x0FF, thereby setting the
transfer bit. This allows the registers to update internally and
simultaneously when the transfer bit is set. The internal update
occurs when the transfer bit is set, and then the bit automati-
cally clears.
MEMORY MAP REGISTERS
Address and bit locations that are not included in Table 26
through Table 116 are not currently supported for this device.
Table 26. SPI Configuration Register, Address 0x000 (Default = 0x18)
Bit No. Access Bit Description
7 Unused.
6 RW SPI least significant bit (LSB) first.
1: LSB shifted first for all SPI operations. For multibyte SPI operations, the addressing increments
automatically.
0: most significant bit (MSB) shifted first for all SPI operations. For multibyte SPI operations, the
addressing decrements automatically.
5 RW Self clearing soft reset.
1: reset the SPI registers (self clearing).
0: do nothing.
4 R 13-bit addressing enabled.
3 R 13-bit addressing enabled.
2 RW Self clearing soft reset.
1: reset the SPI registers(self clearing).
0: do nothing.
1 RW SPI LSB first.
1: LSB shifted first for all SPI operations. For multibyte SPI operations, the addressing increments
automatically.
0: MSB shifted first for all SPI operations. For multibyte SPI operations, the addressing decrements
automatically.
0 Unused Unused.
Table 27. Chip ID Register, Address 0x001 (Default = 0x41)
Bit No. Access Bit Description
[7:0] R Chip ID.
AD9625 Data Sheet
Rev. C | Page 54 of 72
Table 28. Chip Grade Register, Address 0x002 (Default = 0x14)
Bit No. Access Bit Description
[7:6] Unused.
[5:4] R Chip ID/speed grade.
11: 2.6 GSPS.
10: 2.5 GSPS.
01: 2.0 GSPS.
[3:0] Unused.
Table 29. Power Control Mode Register, Address 0x008 (Default = 0x80)
Bit No. Access Bit Description
7 Reserved.
6 Reserved.
5 Reserved.
[4:2] Reserved.
[1:0] RW Chip power modes.
00: normal mode (power-up).
01: Power-down.
10: standby mode; digital datapath clocks disabled, JESD204B interface enabled, outputs enabled.
11: digital datapath reset mode; digital data path clocks enabled, digital data path held in reset, JESD204B interface held
in reset, outputs enabled.
Table 30. PLL Status Register, Address 0x00A (Default = 0x00)
Bit No. Access Bit Description
7 RO PLL locked status bit.
0: PLL is unlocked.
1: PLL is locked.
[6:0] Reserved.
Table 31. ADC Test Control Register, Address 0x00D (Default = 0x00)
Bit No. Access Bit Description
7 RW ADC datapath user test mode control. Note that these bits are only used when Register 0x00D, Bits[3:0] is in user input
mode (Register 0x00D[3:0] = 1000); otherwise, they are ignored.
0: continuous/repeat pattern mode. Place each user pattern (1, 2, 3, 4) on the output for one clock cycle and then repeat.
(Output user pattern: 1, 2, 3, 4, 1, 2, 3, 4, 1, 2, 3, 4, …)
1: single pattern mode. Place each user pattern (1, 2, 3, 4) on the output for one clock cycle and then output all zeros.
(Output user pattern: 1, 2, 3, 4, then output all zeros.)
6 Unused.
5 RW ADC long psuedo random number test generator reset.
0: long PN enabled.
1: long PN held in reset.
4 RW Unused.
[3:0] RW ADC data output test generation mode.
0000: off, normal operation.
0001: midscale short.
0010: positive full scale.
0011: negative full scale.
0100: alternating checkerboard.
0101: PN sequence, long.
0110: unused.
0111: one-/zero-word toggle.
1000: user test mode. Used with Register 0x00D[7] and user pattern (1, 2, 3, 4) registers.
1001 to 1110: unused.
1111: ramp output.
Data Sheet AD9625
Rev. C | Page 55 of 72
Table 32. Data Path Customer Offset Register, Address 0x010 (Default = 0x00)
Bit No. Access Bit Description
[7:6] Unused.
[5:0] RW Digital datapath offset. Twos complement offset adjustment aligned with least converter resolution.
011111: +31.
011110: +30.
000001: +1.
000000: 0.
111111: −1.
100001: −31.
100000: −32.
Table 33. Output Mode Register, Address 0x014 (Default = 0x01)
Bit No. Access Bit Description
[7:5] Unused.
4 RW Chip output disable. Bit 4 enables and disables the digital outputs from the ADC.
0: enable.
1: disable.
3 Unused.
2 RW Digital ADC sample invert.
0: ADC sample data is not inverted.
1: ADC sample data is inverted.
[1:0] RW Digital ADC data format select (DFS). Note that the use of the muxed SDIO pin to control Register 0x014[1:0] is not
supported on the AD9625.
00: offset binary.
01: twos complement (default).
10: reserved.
11: reserved.
Table 34. Serializer Output Adjust, Register, Address 0x015 (Default = 0x54)
Bit No. Access Bit Description
7 RW Serializer output polarity selection.
0: normal, not inverted.
1: output driver polarity inverted.
[6:5] RW Serializer output emphasis amplitude control.
00: 0 mV de-emphasis differential peak to peak.
01: 160 mV de-emphasis differential peak to peak.
10: 80 mV de-emphasis differential peak to peak.
11: 40 mV de-emphasis differential peak to peak.
[4:0] RW Reserved.
Table 35. User Test Pattern 1 LSB Register, Address 0x019 (Default = 0x00)
Bit No. Access Bit Description
[7:0] RW
User Test Pattern 1 least significant byte. Note that these bits are used only when Register 0x00D, Bits[3:0] is in user
input mode (Register 0x00D[3:0] = 1000), or when Register 0x061, Bits[3:0] is in the scrambler or 10-bit test modes
(Register 0x061[3:0] = 0100 to 0111). Otherwise, these bits are ignored.
Table 36. User Test Pattern 1 MSB Register, Address 0x01A (Default = 0x00)
Bit No. Access Bit Description
[7:0] RW
User Test Pattern 1 most significant byte. Note that these bits are used only when Register 0x00D, Bits[3:0] is in user
input mode (Register 0x00D[3:0] = 1000). Otherwise, these bits are ignored.
AD9625 Data Sheet
Rev. C | Page 56 of 72
Table 37. User Test Pattern 2 LSB Register, Address 0x01B (Default = 0x00)
Bit No. Access Bit Description
[7:0] RW User Test Pattern 2 least significant byte. Note that these bits are used only when Register 0x00D, Bits[3:0] is in user
input mode (Register 0x00D[3:0] = 1000). Otherwise, these bits are ignored.
Table 38. User Test Pattern 2 MSB Register, Address 0x01C (Default = 0x00)
Bit No. Access Bit Description
[7:0] RW User Test Pattern 2 most significant byte. Note that these bits are used only when Register 0x00D, Bits[3:0] is in user
input mode (Register 0x00D[3:0] = 1000). Otherwise, these bits are ignored.
Table 39. User Test Pattern 3 LSB Register, Address 0x01D (Default = 0x00)
Bit No. Access Bit Description
[7:0] RW User Test Pattern 3 least significant byte. Note that these bits are used only when Register 0x00D, Bits[3:0] is in user
input mode (Register 0x00D[3:0] = 1000). Otherwise, these bits are ignored.
Table 40. User Test Pattern 3 MSB Register, Address 0x01E (Default = 0x00)
Bit No. Access Bit Description
[7:0] RW User Test Pattern 3 most significant byte. Note that these bits are used only when Register 0x00D, Bits[3:0] is in user
input mode (Register 0x00D[3:0] = 1000). Otherwise, these bits are ignored.
Table 41. User Test Pattern 4 LSB Register, Address 0x01F (Default = 0x00)
Bit No. Access Bit Description
[7:0] RW User Test Pattern 4 least significant byte. Note that these bits are used only when Register 0x00D, Bits[3:0] is in user
input mode (Register 0x00D[3:0] = 1000). Otherwise, these bits are ignored.
Table 42. User Test Pattern 4 MSB Register, Address 0x020 (Default = 0x00)
Bit No. Access Bit Description
[7:0] RW User Test Pattern 4 most significant byte. Note that these bits are used only when Register 0x00D, Bits[3:0] is in user
input mode (Register 0x00D[3:0] = 1000). Otherwise, these bits are ignored.
Table 43. Synthesizer PLL Control Register, Address 0x021 (Default = 0x00)
Bit No. Access Bit Description
[7:5] Unused.
4 RW 1: force power-down of VCO LDO.
3 RW Reserved for future use.
[2:0] Unused.
Table 44. ADC Analog Input Control Register, Address 0x02C (Default = 0x00)
Bit No. Access Bit Description
[7:3] Unused.
2 RW Set function on VMON pin.
0: unused.
1: allows external reference on VMON pin.
[1:0] Unused.
Table 45. SYSREF± Control Register, Address 0x03A (Default = 0x00)
Bit No. Access Bit Description
7 RW SYSREF± status bit replaces the LSB from the converter.
0: normal mode.
1: SYSREF± status bit replaces the LSB.
6 RW SYSREF± status bit flag reset. To use the flags, Register 0x03A, Bit 1 must be set to high.
0: normal flag operation.
1: SYSREF± status bit flags held in reset.
5 Unused.
Data Sheet AD9625
Rev. C | Page 57 of 72
Bit No. Access Bit Description
4 RW SYSREF± transition selection.
0: SYSREF± is valid on low to high transitions using selected CLK edge.
1: SYSREF± is valid on high to low transitions using selected CLK edge.
3 RW SYSREF± capture edge selection.
0: captured on rising edge of CLK input.
1: captured on falling edge of CLK input.
2 RW SYSREF± next mode.
0: continuous mode.
1: next SYSREF± mode: uses the next valid edge only of the SYSREF± pin. Subsequent edges of the SYSREF± pin are
ignored. When the next system reference is found, Bit 1 of Register 0x03A clears.
1 RW SYSREF± pins enable.
0: SYSREF± disabled.
1: SYSREF± enabled. When Register 0x03A, Bit 2 = 1, only the next valid edge of the SYSREF± pins is used. Subsequent
edges of the SYSREF± pin are ignored.
0 Unused.
Table 46. Fast Detect Control Register, Address 0x045 (Default = 0x00)
Bit No. Access Bit Description
[7:4] Unused.
3 RW Force the fast detect output pin.
0: normal operation of fast detect pin.
1: force a value on the fast detect pin (see Bit 2 in this table, Table 46).
2 RW The fast detect output pin is set to the value in this bit (Register 0x045[2]) when the output is forced.
1 Unused.
0 RW Enable fast detect on the corrected ADC data.
0: fine fast detect disabled.
1: fine fast detect enabled.
Table 47. Fast Detect Upper Threshold Register, Address 0x047 (Default = 0x00)
Bit No. Access Bit Description
[7:0] RW These bits are the LSBs of the fast detect upper threshold. These eight LSBs of the programmable 12-bit upper threshold
are compared to the fine ADC magnitude.
Table 48. Fast Detect Upper Threshold Register, Address 0x048 (Default = 0x00)
Bit No. Access Bit Description
[7:4] Unused.
[3:0] RW These bits are the MSBs of the fast detect upper threshold. These four MSBs of the programmable 12-bit upper
threshold are compared to the fine ADC magnitude.
Table 49. Fast Detect Lower Threshold Register, Address 0x049 (Default = 0x00)
Bit No. Access Bit Description
[7:0] RW These bits are the LSBs of the fast detect lower threshold. These eight LSBs of the programmable 12-bit lower threshold
are compared to the fine ADC magnitude.
Table 50. Fast Detect Lower Threshold Register, Address 0x04A (Default = 0x00)
Bit No. Access Bit Description
[7:4] Unused.
[3:0] RW MSBs of the fast detect lower threshold. These four MSBs of the programmable 12-bit lower threshold are compared to
the fine ADC magnitude.
Table 51. Fast Detect Dwell Time Counter Threshold Register, Address 0x04B (Default = 0x00)
Bit No. Access Bit Description
[7:0] RW These bits are the LSBs of the fast detect dwell time counter target. This is the value for a 16-bit counter that determines
the length of time that the ADC data must remain below the lower threshold before the FD pin reset to 0.
AD9625 Data Sheet
Rev. C | Page 58 of 72
Table 52. Fast Detect Dwell Time Counter Threshold Register, Address 0x04C (Default = 0x00)
Bit No. Access Bit Description
[7:0] RW These bits are the MSBs of the fast detect dwell time counter target. This is the value for a 16-bit counter that
determines the length of time that the ADC data must remain below the lower threshold before the FD pin resets to 0.
Note that the fast detect (FD) pin deasserts after the ADC codes stay below the lower target for the number of samples
indicated by the value in Register 0x04C[7:0].
Table 53. JESD204B Quick Configuration Register, Address 0x05E (Default = 0x00)
Bit No. Access Bit Description
[7:0] RW JESD204B serial quick configuration (self clearing). This register is self clearing and does not control anything in the
AD9625 directly; it only changes the value of the other JESD240B registers that control the chip. Because this register is
self clearing, it always returns to 000 after each write. To use the quick configuration feature, write to this register first,
then, if there are any changes that need to be made to any of the following settings, write to the other JESD204B
registers.
0x00: configuration determined by other registers. Because the register is self clearing, it always returns to this value
after each write.
0x01: reserved.
0x02: Generic Two Lane Configuration Register 0x063[3:0] = 0x0; Register 0x06E[4:0] = 0x1; Register 0x072[4:0] = 0xB;
Register 0x073[4:0] = 0xF.
0x04: Generic Four Lane Configuration Register 0x063[3:0] = 0x0; Register 0x06E[4:0] = 0x3; Register 0x072[4:0] = 0xB;
Register 0x073[4:0] = 0xF.
0x06: Generic Six Lane Configuration Register 0x063[3:0] = 0x0; Register 0x06E[4:0] = 0x5; Register 0x072[4:0] = 0xB;
Register 0x073[4:0] = 0xB.
0x08: Generic Eight Lane Configuration Register 0x063[3:0] = 0x0; Register 0x06E[4:0] = 0x7; Register 0x072[4:0] = 0xB;
Register 0x073[4:0] = 0xF.
0x42: reserved.
0x44: reserved.
0x48: fS × 2 mode, eight lanes. Register 0x063[3:0] = 0x4; Register 0x06E[4:0] = 0x7; Register 0x072[4:0] = 0xF;
Register 0x073[4:0] = 0xF.
0x81: 1 DDC (high BW), one lane. Register 0x063[3:0] = 0x8; Register 0x06E[4:0] = 0x0; Register 0x072[4:0] = 0xF;
Register 0x073[4:0] = 0xF.
0x82: 1 DDC (high BW), two lanes. Register 0x063[3:0] = 0x8; Register 0x06E[4:0] = 0x1; Register 0x072[4:0] = 0xF;
Register 0x073[4:0] = 0xF.
0x91: 1 DDC (low BW), one lane. Register 0x063[3:0] = 0x9; Register 0x06E[4:0] = 0x0; Register 0x072[4:0] = 0xF;
Register 0x073[4:0] = 0xF.
0xC1: 2 DDCs (high BW), one lane. Register 0x063[3:0] = 0xC; Register 0x06E[4:0] = 0x0; Register 0x072[4:0] = 0xF;
Register 0x073[4:0] = 0xF.
0xC2: 2 DDCs (high BW), two lanes. Register 0x063[3:0] = 0xC; Register 0x06E[4:0] = 0x1; Register 0x072[4:0] = 0xF;
Register 0x073[4:0] = 0xF.
0xC4: 2 DDCs (high BW), four lanes. Register 0x063[3:0] = 0xC; Register 0x06E[4:0] = 0x3; Register 0x072[4:0] = 0xF;
Register 0x073[4:0] = 0xF.
0xD1: 2 DDCs (low BW), one lane. Register 0x063[3:0] = 0xD; Register 0x06E[4:0] = 0x0; Register 0x072[4:0] = 0xF;
Register 0x073[4:0] = 0xF.
0xD2: 2 DDCs (low BW), two lanes. Register 0x063[3:0] = 0xD; Register 0x06E[4:0] = 0x1; Register 0x072[4:0] = 0xF;
Register 0x073[4:0] = 0xF.
0xE1: 2 DDCs (mixed BW), one lane. Register 0x063[3:0] = 0xE; Register 0x06E[4:0] = 0x0; Register 0x072[4:0] = 0xF;
Register 0x073[4:0] = 0xF.
0xE2: 2 DDCs (mixed BW), two lanes. Register 0x063[3:0] = 0xE; Register 0x06E[4:0] = 0x1; Register 0x072[4:0] = 0xF;
Register 0x073[4:0] = 0xF.
0xE4: 2 DDCs (mixed BW), four lanes. Register 0x063[3:0] = 0xE; Register 0x06E[4:0] = 0x3; Register 0x072[4:0] = 0xF;
Register 0x073[4:0] = 0xF.
All other values have no effect.
Data Sheet AD9625
Rev. C | Page 59 of 72
Table 54. JESD204B Link Control Register 1, Address 0x05F (Default = 0x14)
Bit No. Access Bit Description
7 Unused.
6 RW
JESD204B serial tail bit, PN, enable. Note that the following equation can be used to determine the number of PN bits
sent per sample = N' − N – CS (the number of control bits per sample).
0: serial tail bit, PN, disabled. Unused extra tail bits are padded with zeros.
1: serial tail bit, PN, enabled. Unused extra tail bits are padded with a pseudo random number sequence from a 31-bit
LFSR (see JESD204B 5.1.4).
5 RW JESD204B serial test sample enable.
0: JESD204B test samples disabled.
1: JESD204B test samples enabled. The transport layer test sample sequence (as specified in JESD204B Section 5.1.6.2) is
sent on all link lanes.
4 RW
JESD204B serial lane synchronization enable. Note that the frame character insertion must be enabled (Register 0x05F[1] = 0)
to enable lane synchronization.
0: lane synchronization disabled. Both sides do not perform lane synchronization; frame alignment character insertion
always uses /K28.7/ control characters (see JESD204B 5.3.3.4).
1: lane synchronization enabled. Both sides perform lane sync; frame alignment character insertion uses either /K28.3/
or /K28.7/ control characters (see JESD204B 5.3.3.4).
[3:2] RW JESD204B serial initial lane alignment sequence mode.
00: initial lane alignment sequence disabled (JESD204B 5.3.3.5).
01: initial lane alignment sequence enabled (JESD204B 5.3.3.5).
10: reserved.
11: initial lane alignment sequence always on test mode; the JESD204B data link layer test mode (where repeated lane
alignment sequence, as specified in JESD204B section 5.3.3.9.2) is sent on all lanes.
1 RW JESD204B serial frame alignment character insertion (FACI) disable.
0: frame alignment character insertion enabled (JESD204B 5.3.3.4).
1: frame alignment character insertion disabled. Note that this is for debug only (JESD204B 5.3.3.4).
0 RW
JESD204B serial transmit link power-down (active high). Note that the JESD204B transmitter link must be powered
down while changing any of the link configuration bits.
0: JESD204B serial transmit link enabled. Transmission of the /K28.5/ characters for code group synchronization is
controlled by the SYNCINB± pins.
1: JESD204B serial transmit link powered down (held in reset and clock gated).
Table 55. JESD204B Link Control Register 2, Address 0x060 (Default = 0x00)
Bit No. Access Bit Description
[7:6] RW JESD204B serial synchronization mode.
00: normal mode.
01: reserved.
10: SYNCINB± active mode. SYNCINB± pins are active: force code group synchronization.
11: SYNCINB± pins disabled.
5 RW JESD204B serial synchronization pin invert.
0: SYNCINB± pins not inverted.
1: SYNCINB± pins inverted.
[4:3] Unused.
2 RW JESD204B Serial 8-bit/10-bit bypass (test mode only).
0: 8-bit/10-bit enabled.
1: 8-bit/10-bit bypassed (most significant two bits are 0).
1 RW
JESD204B 10-bit serial transmit bit invert. Note that in the event that the CML signals are reversed in a system board
layout, this bit effectively inverts the differential outputs from the PHY.
0: normal.
1: invert the a, b, c, d, e, f, g, h, i, j bits.
0 RW JESD204B 10-bit serial transmit bit mirror.
0: 10-bit serial bits are not mirrored. Transmit bit order is alphabetical: a, b, c, d, e, f, g, h, i, j.
1: 10-bit serial bits are mirrored. Transmit bit order is alphabetically reversed: j, i, h, g, f, e, d, c, b, a.
AD9625 Data Sheet
Rev. C | Page 60 of 72
Table 56. JESD204B Link Control Register 3, Address 0x061 (Default = 0x00)
Bit No. Access Bit Description
7 RW JESD204B checksum disable.
0: checksum enabled in the link configuration parameter. Normal operation.
1: checksum disabled in the link configuration parameter (set to zero). For testing purposes only.
6 RW JESD204B checksum mode.
0: checksum is the sum of all 8-bit registers in the link configuration fields.
1: checksum is the sum of all individual link configuration fields (LSB aligned).
[5:4] RW JESD204B serial test generation input selection.
00: 16-bit test generation data injected at the sample input to the link.
01: 10-bit test generation data injected at the output of the 8-bit/10-bit encoder (at the input to PHY).
10: 8-bit test generation data injected at the input of the scrambler.
11: reserved.
[3:0] RW JESD204B serial test generation mode.
0000: normal operation (test mode disabled).
0001: alternating checkerboard.
0010: 1/0 word toggle.
0011: PN sequence (long).
0100: unused.
0101: continuous/repeat user test mode. The most significant bits from the user pattern (1, 2, 3, 4) are placed on the
output for one clock cycle and then repeated (the output user pattern is 1, 2, 3, 4, 1, 2, 3, 4, 1, 2, 3, 4, …).
0110: single user test mode. The most significant bits from the user pattern (1, 2, 3, 4) are placed on the output for one
clock cycle and then output all zeros (the output user pattern is 1, 2, 3, 4, and then outputs all zeros).
0111: ramp output.
1000: modified RPAT test sequence (10-bit value).
1001: unused.
1010: JSPAT test sequence (10-bit value).
1011: JTSPAT test sequence (10-bit value).
1100 to 1111: unused.
Table 57. JESD204B Link Control Register 4, Address 0x062 (Default 0x00)
Bit No. Access Bit Description
[7:0] RW Initial lane alignment sequence repeat count. Bits[7:0] specify the number of times the initial lane alignment sequence
repeats. For ADCs, the JESD204B specification states that the initial lane alignment sequence always spans four multiframes
(JESD204B 5.3.3.5). Because Register 0x070, Bits[4:0] determine the number of frames per multiframe, the total number of
frames transmitted during the initial lane alignment sequence = 4 × (Register 0x070[4:0] + 1) × (Register 0x062[7:0] + 1).
Table 58. JESD204B Link Control Register 5, Address 0x063 (Default = 0x80)
Bit No. Access Bit Description
7 Reserved
[6:4] Reserved
[3:0] RW JESD204B application layer mode. DDC bandwidth modes are as follows: high bandwidth, decimate by 8 (effective output
bandwidth = fS/10) and low bandwidth, decimate by 16 (effective output bandwidth = fS/20).
0000: generic (no application layer used).
0001: unused.
0010: unused.
0011: unused.
0100: fS × x mode (where x is an integer: 2, 4, 8).
0101 to 0111: unused.
1000: single DDC mode (high bandwidth mode (only DDC0 used).
1001: single DDC mode (low bandwidth mode (only DDC0 used).
1010 to 1011: unused.
1100: dual DDC mode, high bandwidth mode (both DDC 0 and DDC 1 used).
1101: dual DDC mode, low bandwidth mode (both DDC 0 and DDC 1 used).
1110: dual DDC mode, mixed bandwidth mode (DDC 0 high bandwidth mode, DDC 1 low bandwidth mode, samples
repeated).
1111: unused.
Data Sheet AD9625
Rev. C | Page 61 of 72
Table 59. JESD204B Configuration Register, Address 0x064 (Default = 0x00)
Bit No. Access Bit Description
[7:0] RW JESD204B serial device identification (DID) number.
Table 60. JESD204B Configuration Register, Address 0x065 (Default = 0x00)
Bit No. Access Bit Description
[7:4] Unused.
[3:0] RW JESD204B serial bank identification (BID) number (extension to DID).
Table 61. JESD204B Configuration Register, Address 0x066 (Default = 0x00)
Bit No. Access Bit Description
[7:5] Unused.
[4:0] RW JESD204B serial lane identification (LID) number for Lane 0.
Table 62. JESD204B Configuration Register, Address 0x067 (Default = 0x01)
Bit No. Access Bit Description
[7:5] Unused.
[4:0] RW JESD204B serial lane identification (LID) number for Lane 1.
Table 63. JESD204B Configuration Register, Address 0x068 (Default = 0x02)
Bit No. Access Bit Description
[7:5] Unused.
[4:0] RW JESD204B serial lane identification (LID) number for Lane 2.
Table 64. JESD204B Configuration Register, Address 0x069 (Default = 0x03)
Bit No. Access Bit Description
[7:5] Unused.
[4:0] RW JESD204B serial lane identification (LID) number for Lane 3.
Table 65. JESD204B Configuration Register, Address 0x06A (Default = 0x04)
Bit No. Access Bit Description
[7:5] Unused.
[4:0] RW JESD204B serial lane identification (LID) number for Lane 4.
Table 66. JESD204B Configuration Register, Address 0x06B (Default = 0x05)
Bit No. Access Bit Description
[7:5] Unused.
[4:0] RW JESD204B serial lane identification (LID) number for Lane 5.
Table 67. JESD204B Configuration Register, Address 0x06C (Default = 0x06)
Bit No. Access Bit Description
[7:5] Unused.
[4:0] RW JESD204B serial lane identification (LID) number for Lane 6.
Table 68. JESD204B Configuration Register, Address 0x06D (Default = 0x07)
Bit No. Access Bit Description
[7:5] Unused.
[4:0] RW JESD204B serial lane identification (LID) number for Lane 7.
Table 69. JESD204B Configuration Register, Address 0x06E (Default = 0x87)
Bit No. Access Bit Description
7 RW JESD204B serial scrambler mode.
0: JESD204B scrambler disabled (SCR = 0).
1: JESD204B scrambler enabled (SCR = 1).
[6:5] Unused.
AD9625 Data Sheet
Rev. C | Page 62 of 72
Bit No. Access Bit Description
[4:0] RW JESD204B serial lane control (L = Register 0x06E[4:0] + 1).
0: one lane per link (L = 1).
1: two lanes per link (L = 2).
2: unused.
3: four lanes per link (L = 4).
4: unused.
5: six lanes per link (L = 6).
6: unused.
7: eight lanes per link (L = 8).
8 to 31: unused.
Table 70. JESD204B Configuration Register, Address 0x06F (Default = 0x00)
Bit No. Access Bit Description
[7:0] RO JESD204B number of octets per frame (F = Register 0x06F[7:0] + 1). These bits are calculated using the
following equation:
F = (N)/(2 × L)
The following are valid values of F:
M = 1, S = 4, N' = 16, L = 1, F = 8.
M = 1, S = 4, N' = 16, L = 2, F = 4.
M = 1, S = 4, N' = 16, L = 4, F = 2.
M = 1, S = 4, N' = 12, L = 6, F = 1.
M = 1, S = 4, N' = 16, L = 8, F = 1 (default).
Table 71. JESD204B Configuration Register, Address 0x070 (Default = 0x1F)
Bit No. Access Bit Description
[7:5] Unused.
[4:0] RW JESD204B number of frames per multiframe (K = Register 0x070[4:0] + 1). Only those values that are divisible
by four can be used.
Table 72. JESD204B Configuration Register, Address 0x071 (Default = 0x00)
Bit No. Access Bit Description
[7:0] RO JESD204B number of converters per link/device.
0: link connected to one ADC (M = 1).
1 to 255: unused.
Table 73. JESD204B Configuration Register, Address 0x072 (Default = 0x0B)
Bit No. Access Bit Description
[7:6] RW JESD204B number of control bits per sample (CS, based on the JESD204B specification).
00: no control bits sent per sample (CS = 0).
01: one control bit sent per sample, overrange bit enabled (CS = 1).
10: two control bits sent per sample, overrange + timestamp SYSREF bit (CS = 2).
11: reserved.
5 Unused.
[4:0] RW JESD204B converter resolution (N = Register 0x072[4:0] + 1).
0x00 to 0x06: reserved.
0x07 to 0x09: reserved.
0x0A: reserved.
0x0B: N = 12-bit ADC converter resolution.
0x0C to 0x0E: reserved.
0x0F: N = 16-bit ADC converter resolution.
0x10 to 0x1F: reserved.
Data Sheet AD9625
Rev. C | Page 63 of 72
Table 74. JESD204B Configuration Register, Address 0x073 (Default = 0x2F)
Bit No. Access Bit Description
[7:5] RW JESD204B device subclass version.
0x0: Subclass 0.
0x1: Subclass 1 (default).
0x2: Subclass 2 (not supported).
0x3: undefined.
[4:0] RW JESD204B total number of bits per sample (N' = Register 0x073[4:0] + 1).
0x0 to 0xA: unused.
0xB: N' = 12 (L must be equal to 6).
0xC to 0xE: unused.
0xF: N' = 16 (L must be equal to 1, 2, 4, or 8).
Table 75. JESD204B Configuration Register, Address 0x074 (Default = 0x23)
Bit No. Access Bit Description
[7:5] RW JESD204B version.
0x0: JESD204A. SYNCINB± pins input are internally gated by the frame clock. SYNCINB± must be low for at least
two frame clock cycles to be interpreted as a synchronization request.
0x1: JESD204B. SYNCINB± pins input are internally gated by the local multiframe clock. SYNCINB± must be low
for at least four frame clock cycles to be interpreted as a synchronization request.
0x2 to 0x7: undefined.
[4:0] RO JESD204B samples per converter frame cycle (S = Register 0x074[4:0] + 1). These are read-only bits. For the
AD9625, S must be equal to 4 (Register 0x074[4:0] = 3).
Table 76. JESD204B Configuration Register, Address 0x075 (Default = 0x80)
Bit No. Access Bit Description
7 RO JESD204B high density (HD) format. This is a read-only bit.
0: HD format disabled.
1: HD format enabled. High density mode is automatically enabled based on the values of N' and L.
The values of HD for the AD9625 are as follows:
N' = 16, L = 1, HD = 0.
N' = 16, L = 2, HD = 0.
N' = 16, L = 4, HD = 0.
N' = 12, L = 6, HD = 1.
N' = 16, L = 8, HD = 1 (default).
[6:5] Unused.
[4:0] RO JESD204B Number of control words per frame clock cycle per link (CF). These are read-only bits. For the AD9625,
CF must equal 0 (Register 0x075[4:0] = 0).
Table 77. JESD204B Configuration Register, Address 0x076 (Default = 0x00)
Bit No. Access Bit Description
[7:0] RW JESD204B Serial Reserved Field 1.
Table 78. JESD204B Configuration Register, Address 0x077 (Default = 0x00)
Bit No. Access Bit Description
[7:0] RW JESD204B Serial Reserved Field 2.
Table 79. JESD204B Configuration Register, Address 0x078 (Default = 0xC3)
Bit No. Access Bit Description
[7:0] RO JESD204B serial checksum value for Lane 0. This value is automatically calculated The value = (the sum of all link
configuration parameters for Lane 0) Modulus 256. Checksum is enabled/disabled using Register 0x061, Bit 7.
Table 80. JESD204B Configuration Register, Address 0x079 (Default = 0xC4)
Bit No. Access Bit Description
[7:0] RO JESD204B serial checksum value for Lane 1. This value is automatically calculated. The value = (the sum of all link
configuration parameters for Lane 1) Modulus 256. Checksum is enabled/disabled using Register 0x061, Bit 7.
AD9625 Data Sheet
Rev. C | Page 64 of 72
Table 81. JESD204B Configuration Register, Address 0x07A (Default = 0xC5)
Bit No. Access Bit Description
[7:0] RO JESD204B serial checksum value for Lane 2. This value is automatically calculated. The value = (the sum of all link
configuration parameters for Lane 2) Modulus 256. Checksum is enabled/disabled using Register 0x061, Bit 7.
Table 82. JESD204B Configuration Register, Address 0x07B (Default = 0xC6)
Bit No. Access Bit Description
[7:0] RO JESD204B serial checksum value for Lane 3. This value is automatically calculated. The value = (the sum of all link
configuration parameters for Lane 3) Modulus 256. Checksum is enabled/disabled using Register 0x061, Bit 7.
Table 83. JESD204B Configuration Register, Address 0x07C (Default = 0xC7)
Bit No. Access Bit Description
[7:0] RO JESD204B serial checksum value for Lane 4. This value is automatically calculated. The value = (the sum of all link
configuration parameters for Lane 4) Modulus 256. Checksum is enabled/disabled using Register 0x061, Bit 7.
Table 84. JESD204B Configuration Register, Address 0x07D (Default = 0xC8)
Bit No. Access Bit Description
[7:0] RO JESD204B serial checksum value for Lane 5. This value is automatically calculated. The value = (the sum of all link
configuration parameters for Lane 5) Modulus 256. Checksum is enabled/disabled using Register 0x061, Bit 7.
Table 85. JESD204B Configuration Register, Address 0x07E (Default = 0xC9)
Bit No. Access Bit Description
[7:0] RO JESD204B serial checksum value for Lane 6. This value is automatically calculated. The value = (the sum of all link
configuration parameters for Lane 6) Modulus 256. Checksum is enabled/disabled using Register 0x061, Bit 7.
Table 86. JESD204B Configuration Register, Address 0x07F (Default = 0xCA)
Bit No. Access Bit Description
[7:0] RO JESD204B serial checksum value for Lane 6. This value is automatically calculated. The value = (the sum of all link
configuration parameters for Lane 6) Modulus 256. Checksum is enabled/disabled using Register 0x061, Bit 7.
Table 87. JESD204B Lane Power-Down Register, Address 0x080 (Default = 0x00)
Bit No. Access Bit Description
7 RW Physical Lane H power-down.
0: Lane H enabled.
1: Lane H powered down.
6 RW Physical Lane G power-down.
0: Lane G enabled.
1: Lane G powered down.
5 RW Physical Lane F power-down.
0: Lane F enabled.
1: Lane F powered down.
4 RW Physical Lane E power-down.
0: Lane E enabled.
1: Lane E powered down.
3 RW Physical Lane D power-down.
0: Lane D enabled.
1: Lane D powered down.
2 RW Physical Lane C power-down.
0: Lane C enabled.
1: Lane C powered down.
1 RW Physical Lane B power-down.
0: Lane B enabled.
1: Lane B powered down.
0 RW Physical Lane A power-down.
0: Lane A enabled.
1: Lane A powered down.
Data Sheet AD9625
Rev. C | Page 65 of 72
Table 88. JESD204B Lane Control Register 1, Address 0x082 (Default = 0x10)
Bit No. Access Bit Description
7 Unused.
[6:4] RW Physical Lane B assignment.
000: Logical Lane 0.
001: Logical Lane 1 (default).
010: Logical Lane 2.
011: Logical Lane 3.
100: Logical Lane 4.
101: Logical Lane 5.
110: Logical Lane 6.
111: Logical Lane 7.
3 Unused.
[2:0] RW Physical Lane A assignment.
000: Logical Lane 0 (default).
001: Logical Lane 1.
010: Logical Lane 2.
011: Logical Lane 3.
100: Logical Lane 4.
101: Logical Lane 5.
110: Logical Lane 6.
111: Logical Lane 7.
Table 89. JESD204B Lane Control Register 2, Address 0x083 (Default = 0x32)
Bit No. Access Bit Description
7 Unused.
[6:4] RW Physical Lane D assignment.
000: Logical Lane 0.
001: Logical Lane 1.
010: Logical Lane 2.
011: Logical Lane 3 (default).
100: Logical Lane 4.
101: Logical Lane 5.
110: Logical Lane 6.
111: Logical Lane 7.
3 Unused.
[2:0] RW Physical Lane C assignment.
000: Logical Lane 0.
001: Logical Lane 1.
010: Logical Lane 2 (default).
011: Logical Lane 3.
100: Logical Lane 4.
101: Logical Lane 5.
110: Logical Lane 6.
111: Logical Lane 7.
AD9625 Data Sheet
Rev. C | Page 66 of 72
Table 90. JESD204B Lane Control Register 3, Address 0x084 (Default = 0x54)
Bit No. Access Bit Description
7 Unused.
[6:4] RW Physical Lane F assignment.
000: Logical Lane 0.
001: Logical Lane 1.
010: Logical Lane 2.
011: Logical Lane 3.
100: Logical Lane 4.
101: Logical Lane 5 (default).
110: Logical Lane 6.
111: Logical Lane 7.
3 Unused.
[2:0] RW Physical Lane E assignment.
000: Logical Lane 0.
001: Logical Lane 1.
010: Logical Lane 2.
011: Logical Lane 3.
100: Logical Lane 4 (default).
101: Logical Lane 5.
110: Logical Lane 6.
111: Logical Lane 7.
Table 91. JESD204B Lane Control Register 4, Address 0x085 (Default = 0x76)
Bit No. Access Bit Description
7 Unused.
[6:4] RW Physical Lane H assignment.
000: Logical Lane 0.
001: Logical Lane 1.
010: Logical Lane 2.
011: Logical Lane 3.
100: Logical Lane 4.
101: Logical Lane 5.
110: Logical Lane 6.
111: Logical Lane 7 (default).
3 Unused.
[2:0] RW Physical Lane G assignment.
000: Logical Lane 0.
001: Logical Lane 1.
010: Logical Lane 2.
011: Logical Lane 3.
100: Logical Lane 4.
101: Logical Lane 5.
110: Logical Lane 6 (default).
111: Logical Lane 7.
Table 92. Unused, Address 0x088 (Default = 0x67)
Bit No. Access Bit Description
[7:0] RW Unused.
Table 93. Unused, Address 0x089 (Default = 0xF0)
Bit No. Access Bit Description
[7:0] RW Unused.
Data Sheet AD9625
Rev. C | Page 67 of 72
Table 94. Control Register, Address 0x08A (Default = 0x20)
Bit No. Access Bit Description
[7:6] Unused.
[5:4] RW Reserved; Bits[5:4] must be set to 10.
[3:2] Unused.
[1:0] RW Bits[1:0] must be set to 00 for LMFC JESD204B alignment with SYSREF±.
Bits[1:0] must be set to 10 for control bit timestamping with SYSREF±.
Table 95. JESD204B Local Multiframe Clock Offset Control Register, Address 0x08B (Default = 0x00)
Bit No. Access Bit Description
[7:5] Unused.
[4:0] RW Local multiframe clock (LMFC) phase offset value. These bits provide the reset value for LMFC phase counter when
SYSREF± pins are asserted; this is used for deterministic delay applications.
Table 96. JESD204B Local Frame Clock Offset Control Register, Address 0x08C (Default = 0x00)
Bit No. Access Bit Description
[7:0] RW Local frame clock phase offset value. Reset value for frame clock phase counter when SYSREF± pins are asserted. For
the AD9625, only values from 0 to 7 are valid. This is used for deterministic delay applications.
Table 97. DIVCLK± Register, Address 0x0F8 (Default = 0x00)
Bit No. Access Bit Description
[7:1] RW Spare customer register.
0 RW Register control to set the ratio between ADC sampling clock and DIVCLK±.
0: divide by 4.
1: not used.
Table 98. Reserved Register, Address 0x0F9
Bit No. Access Bit Description
[7:0] RW Reserved.
Table 99. Customer Spare Register, Address 0x0FF (Default = 0x00)
Bit No. Access Bit Description
[7:1] Unused.
0 RW Register map master/slave transfer bit. Self-clearing bit used to synchronize the transfer of data from the master to
the slave registers.
0: no effect.
1: transfers data from the master registers, written by the register maps, to the slave registers.
Table 100. Interrupt Request (IRQ) Status Register, Address 0x100 (Default = 0x00)
Bit No. Access Bit Description
7 RO Interrupt request PLL lock error.
1: the PLL is unlocked.
6 Unused.
5 RO Unused.
4 RO Unused.
3 RO Interrupt request SYSREF± hold error.
1: a hold error has occurred with the last SYSREF± signal received. To clear this error, set and clear Bit 6 in Register
0x03A.
2 RO Interrupt request SYSREF± setup error.
1: a setup error has occurred with the last SYSREF± signal received. To clear this error, set and clear Bit 6 in Register 0x03A.
1 Unused.
0 RO Interrupt request clock error.
AD9625 Data Sheet
Rev. C | Page 68 of 72
Table 101. Interrupt Request (IRQ) Mask Control Register, Address 0x101 (Default = 0xBC)
Bit No. Access Bit Description
7 RW Interrupt request PLL lock error masked.
1: PLL unlocked events are masked.
6 Unused.
5 RW Must be set to 1.
4 RW Must be set to 1.
3 RW Interrupt request SYSREhold error.
1: a hold error has occurred with the last SYSREsignal received. To clear this error, set and clear Bit 6 in Register 0x03A.
2 RW Interrupt request SYSREF± setup error.
1: a setup error has occurred with the last SYSREF± signal received. To clear this error, set and clear Bit 6 in Register 0x03A.
1 Unused.
0 RW Interrupt request clock error mask.
1: clock error has occurred and the validity of the output data cannot be guaranteed. The only way to recover from this
error is to reset the device.
Table 102. Digital Control Register, Address 0x105 (Default = 0x00)
Bit No. Access Bit Description
[7:5] Unused.
4 RW Must be set to 0.
3 RW Must be set to 0.
2 RW Must be set to 0.
1 RW Must be set to 0.
0 RW Must be set to 0.
Table 103. Digital Calibration Threshold Control Register, Address 0x10A (Default = 0x10)
Bit No. Access Bit Description
[7:5] Unused.
4 RW Enable data set threshold logic for background gain.
[0:3] Unused.
Table 104. Digital Calibration Data Set Threshold Register, Address 0x10D (Default = 0x3D)
Bit No. Access Bit Description
[7:0] RW Data set threshold for background gain calibration.
Table 105. Digital Calibration Data Set Threshold Register, Address 0x10E (Default = 0x14)
Bit No. Access Bit Description
[7:0] RW Data set threshold for background gain calibration.
Table 106. DIVCLK± Output Control Register, Address 0x120 (Default = 0x11)
Bit No. Access Bit Description
[7:5] Unused.
4 RW DIVCLK± output disable. DIVCLK± is 1/4th of the sample clock frequency.
0: DIVCLK± output is disabled.
1: DIVCLK± output is enabled.
3 RW DIVCLK± output termination selection.
0: DIVCLK± output uses an external 100 Ω resistive termination.
1: DIVCLK± output uses no external resistive termination.
2 Unused.
[1:0] RW Control the differential swing for the DIVCLK± output.
00: 100 mV p-p differential.
01: 200 mV p-p differential.
10: 300 mV p-p differential.
11: 400 mV p-p differential.
Data Sheet AD9625
Rev. C | Page 69 of 72
Table 107. Trim Setting Control Register, Address 0x121 (Default = 0x00 for AD9625-2.5 and AD9625-2.6; Default = 0x03 for
AD9625-2.0)
Bit No. Access Bit Description
[7:2] Reserved.
[1:0] RW Select trim setting, based on sample rate (AD9625-2.0 and AD9625-2.5):
00: Trim 0: for 2.5 GSPS encode rate (default for AD9625-2.5) (not available for AD9625-2.0).
01: Trim 1: for 2.4 GSPS to 2.5 GSPS encode rate (not available for AD9625-2.0).
10: Trim 2: for 2.2 GSPS to 2.4 GSPS encode rate (not available for AD9625-2.0).
11: Trim 3: for 330 MSPS to 2.2 GSPS encode rate (default for AD9625-2.0).
Select trim setting, based on sample rate (AD9625-2.6):
00: Trim 0: for 2.55 GSPS to 2.6 GSPS encode rate (default for AD9625-2.6).
01: Trim 1: for 2.4 GSPS to 2.55 GSPS encode rate.
10: Trim 2: for 2.2 GSPS to 2.4 GSPS encode rate.
11: Trim 3: for 330 MSPS to 2.2 GSPS encode rate.
Table 108. Unused Register, Address 0x12A (Default = 0x05)
Bit No. Access Bit Description
[7:0] RW Reserved; maintain default setting of 0x05.
Table 109. DDC 0 Gain Control Register, Address 0x130 (Default = 0x00)
Bit No. Access Bit Description
[7:6] Unused.
[5:4] RW DDC 0 polyphase (decimate by 2) gain in units of 6 dB.
00: 0 dB gain.
01: 6 dB gain.
10: 12 dB gain.
11: 18 dB gain.
[3:2] Unused.
[1:0] RW DDC 0 polyphase (decimate by 8) gain in units of 6 dB.
00: 0 dB gain.
01: 6 dB gain.
10: 12 dB gain.
11: 18 dB gain.
Table 110. DDC 0 Phase Increment Least Significant Bits Register, Address 0x131 (Default = 0x00)
Bit No. Access Bit Description
[7:0] RW DDC 0 NCO phase increment value. Phase increment for the NCO within DDC 0 (Bits[7:0]).
The output frequency = (decimal(Register 0x132[1:0]; Register 0x131[7:0]) × fS)/1024.
Table 111. DDC 0 Phase Increment Most Significant Bits Register, Address 0x132 (Default = 0x00)
Bit No. Access Bit Description
[7:2] Unused.
[1:0] RW DDC 0 NCO phase increment value. Phase increment for the NCO within DDC 0 (Bits[9:8]).
Table 112. DDC 1 Gain Control Register, Address 0x138 (Default = 0x00)
Bit No. Access Bit Description
[7:6] Unused.
[5:4] RW DDC 1 polyphase (decimate by 2) gain in units of 6 dB.
00: 0 dB gain.
01: 6 dB gain.
10: 12 dB gain.
11: 18 dB gain.
[3:2] Unused.
AD9625 Data Sheet
Rev. C | Page 70 of 72
Bit No. Access Bit Description
[1:0] RW DDC 1 polyphase (decimate by 8) gain in units of 6 dB.
00: 0 dB gain.
01: 6 dB gain
10: 12 dB gain.
11: 18 dB gain.
Table 113. DDC 1 Phase Increment Least Significant Bits Register, Address 0x139 (Default = 0x00)
Bit No. Access Bit Description
[7:0] RW DDC 1 NCO phase increment value. Phase increment for the NCO within DDC 1 (Bits[7:0]).
The output frequency = (decimal(Register 0x13A[1:0]; Register 0x139[7:0]) × fS)/1024.
Table 114. DDC 1 Phase Increment Most Significant Bits Register, Address 0x13A (Default = 0x00)
Bit No. Access Bit Description
[7:2] Unused.
[1:0] RW DDC1 NCO phase increment value (Bits[9:8]).
Table 115. SYSREF±Hold Time Guardband Register, Address 0x13B (Default = 0x00)
Bit No. Access Bit Description
[7:5] RW These bits increase the SYSREF± hold time guardband that is used to assert the SYSREF± hold IRQ flag in register
0x100[3]. This time is informational only and does not change the actual hold time for SYSREF±.
000: No additional guardband hold time.
001: 35 ps of additional hold time guardband for 0x100[3].
010: 70 ps of additional hold time guardband for 0x100[3].
011: 105 ps of additional hold time guardband for 0x100[3].
100: 140 ps of additional hold time guardband for 0x100[3].
101: 175 ps of additional hold time guardband for 0x100[3].
110: 210 ps of additional hold time guardband for 0x100[3].
111: 245 ps of additional hold time guardband for 0x100[3].
[4:0] RW Reserved.
Table 116. SYSREF± Setup Time Guardband Register, Address 0x13C (Default = 0x00)
Bit No. Access Bit Description
[7:5] RW These bits increase the SYSREF± setup time guardband that is used to assert the SYSREF± setup IRQ flag in register
0x100[2]. This time is informational only and does not change the actual setup time for SYSREF±.
000: No additional guardband setup time.
001: 35 ps of additional setup time guardband for 0x100[2].
010: 70 ps of additional setup time guardband for 0x100[2].
011: 105 ps of additional setup time guardband for 0x100[2].
100: 140 ps of additional setup time guardband for 0x100[2].
101: 175 ps of additional setup time guardband for 0x100[2].
110: 210 ps of additional setup time guardband for 0x100[2].
111: 245 ps of additional setup time guardband for 0x100[2].
[4:0] RW Reserved.
Data Sheet AD9625
Rev. C | Page 71 of 72
APPLICATIONS INFORMATION
DESIGN GUIDELINES
Before starting system level design and layout of the AD9625, it
is recommended that the designer become familiar with these
guidelines, which discuss the special circuit connections and
layout requirements needed for certain pins.
POWER AND GROUND RECOMMENDATIONS
When connecting power to the AD9625, it is recommended
that separate supplies are used: one supply for the analog output
(AVDD), and a separate supply for the digital outputs (DRVDD
and DVDD). The designer can use several different decoupling
capacitors to cover both high and low frequencies. Locate these
capacitors close to the point of entry at the PCB level and close
to the pins of the part with minimal trace length.
When using the AD9625, a single PCB ground plane is
sufficient. With proper decoupling and smart partitioning
of the PCB analog, digital, and clock sections, optimum
performance is easily achieved.
CLOCK STABILITY CONSIDERATIONS
When powered on, the AD9625 enters an initialization phase
during which an internal state machine sets up the biases and
the registers for proper operation. During the initialization
process, the AD9625 needs a stable clock. If the ADC clock
source is not present or not stable during ADC power-up, it
disrupts the state machine and causes the ADC to start up in
a less than optimum state. To correct this, an initialization
sequence must be invoked after the ADC clock is stable or any
change in the sampling clock frequency is made. By issuing a
digital reset via Register 0x00. The pseudo code sequence for a
digital reset is as follows:
#Stable Clock at the input to the AD9625
SPI_Write (0x00, 0x3C); # Reset
SPI_Write (0x080 0xFF) #SPI register transfer
SPI_Write (0x00, 0x00); # Clear Reset
SPI_Write (0x080 0xFF) #SPI register transfer
#Write further configurations
SPI PORT
When the full dynamic performance of the converter is
required, do not activate the SPI port. Because the SCLK, CSB,
and SDIO signals are typically asynchronous to the ADC clock,
noise from these signals can degrade converter performance.
If the on-board SPI bus is used for other devices, it may be
necessary to provide buffers between this bus and the AD9625
to keep these signals from transitioning at the converter input
pins during critical sampling periods.
AD9625 Data Sheet
Rev. C | Page 72 of 72
OUTLINE DIMENSIONS
COMPLIANT TO JEDEC STANDARDS MO-275-GGAB-1.
0.80
0.80 REF
0.51 REF
0.75
REF
A
B
C
D
E
F
G
91011121314 8 7 564231
BOTTOM VIEW
10.40 SQ
H
J
K
L
M
N
P
DETAIL A
TOP VIEW
COPLANARITY
0.12
0.50
0.45
0.40
BALL DIAMETER
SEATING
PLANE
12.10
12.00 SQ
11.90
A1 BALL
PAD CORNER
A1 BALL
PAD CORNER
1.70
1.59
1.50
11.20 SQ
1.33
1.26
1.19
0.38
0.33
0.28
7.50
REF SQ
PKG-004709
12-07-2015-B
SIDE VIEW
DETAIL A
Figure 107. 196-Ball Ball Grid Array, Thermally Enhanced [BGA_ED]
(BP-196-2)
Dimensions shown in millimeters
ORDERING GUIDE
Model1 Temperature Range Package Description Package Option
AD9625BBPZ-2.5 −40°C to +85°C 196-Ball Ball Grid Array, Thermally Enhanced [BGA_ED] BP-196-2
AD9625BBPZ-2.0 −40°C to +85°C 196-Ball Ball Grid Array, Thermally Enhanced [BGA_ED] BP-196-2
AD9625BBPZ-2.6 −40°C to +85°C 196-Ball Ball Grid Array, Thermally Enhanced [BGA_ED] BP-196-2
AD9625BBP-2.6 −40°C to +85°C 196-Ball Ball Grid Array, PbSn, Thermally Enhanced [BGA_ED] BP-196-2
AD9625BBP-2.5 −40°C to +85°C 196-Ball Ball Grid Array, PbSn, Thermally Enhanced [BGA_ED] BP-196-2
AD9625BBPZRL-2.5 −40°C to +85°C 196-Ball Ball Grid Array, Thermally Enhanced [BGA_ED], 13” Tape and Reel BP-196-2
AD9625BBPZRL-2.0 −40°C to +85°C 196-Ball Ball Grid Array, Thermally Enhanced [BGA_ED], 13” Tape and Reel BP-196-2
AD9625BBPRL-2.5 −40°C to +85°C 196-Ball BGA, PbSn, Thermally Enhanced [BGA_ED], 13” Tape and Reel BP-196-2
AD9625BBPRL-2.6 −40°C to +85°C 196-Ball BGA, PbSn, Thermally Enhanced [BGA_ED], 13” Tape and Reel BP-196-2
AD9625-2.6EB Evaluation Board with AD9625
AD9625-2.5EBZ Evaluation Board with AD9625
AD9625-2.0EBZ Evaluation Board with AD9625
1 Z = RoHS Compliant Part.
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