14-Bit, 1.25 GSPS/1 GSPS/820 MSPS/500 MSPS
JESD204B, Dual Analog-to-Digital Converter
Data Sheet
AD9680
Rev. E Document Feedback
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FEATURES
JESD204B (Subclass 1) coded serial digital outputs
1.65 W total power per channel at 1 GSPS (default settings)
SFDR at 1 GSPS = 85 dBFS at 340 MHz, 80 dBFS at 1 GHz
SNR at 1 GSPS = 65.3 dBFS at 340 MHz (AIN = −1.0 dBFS),
60.5 dBFS at 1 GHz (AIN = −1.0 dBFS)
ENOB = 10.8 bits at 10 MHz
DNL = ±0.5 LSB
INL = ±2.5 LSB
Noise density = −154 dBFS/Hz at 1 GSPS
1.25 V, 2.5 V, and 3.3 V dc supply operation
No missing codes
Internal ADC voltage reference
Flexible input range: 1.46 V p-p to 1.94 V p-p
AD9680-1250: 1.58 V p-p nominal
AD9680-1000 and AD9680-820: 1.70 V p-p nominal
AD9680-500: 1.46 V p-p to 2.06 V p-p (2.06 V p-p nominal)
Programmable termination impedance
400 Ω, 200 Ω, 100 Ω, and 50 Ω differential
2 GHz usable analog input full power bandwidth
95 dB channel isolation/crosstalk
Amplitude detect bits for efficient AGC implementation
2 integrated wideband digital processors per channel
12-bit NCO, up to 4 half-band filters
Differential clock input
Integer clock divide by 1, 2, 4, or 8
Flexible JESD204B lane configurations
Small signal dither
APPLICATIONS
Communications
Diversity multiband, multimode digital receivers
3G/4G, TD-SCDMA, W-CDMA, GSM, LTE
General-purpose software radios
Ultrawideband satellite receivers
Instrumentation
Radars
Signals intelligence (SIGINT)
DOCSIS 3.0 CMTS upstream receive paths
HFC digital reverse path receivers
FUNCTIONAL BLOCK DIAGRAM
VIN+A
VIN–A
VIN+B
VIN–B
CLK+
CLK–
AD9680
SERDOUT0±
SERDOUT1±
SERDOUT2±
SERDOUT3±
÷2
÷4
SYSREF±
CLOCK
GENERATION
14
14
PDWN/
STBY
SYNCINB±
FD_A
FD_B
BUFFER
BUFFER
JESD204B
HIGH SPEED SERIALIZER
Tx OUTPUTS
JESD204B
SUBCLAS S 1
CONTROL
V_1P0
÷8
AGND DRGND DGND
SDIO SCLK CSB
AVDD1
(1.25V) AVDD2
(2.5V) AVDD3
(3.3V) AVDD1_SR
(1.25V) DVDD
(1.25V) DRVDD
(1.25V) SPIVDD
(1. 8V TO 3.3V)
4
FAST
DETECT
FAST
DETECT
SIGNAL
MONITOR
SIGNAL
MONITOR
ADC
CORE
ADC
CORE
SPI CONTROL
DDC
DDC
11752-001
CONTROL
REGISTERS
Figure 1.
PRODUCT HIGHLIGHTS
1. Wide full power bandwidth supports IF sampling of signals
up to 2 GHz.
2. Buffered inputs with programmable input termination eases
filter design and implementation.
3. Four integrated wideband decimation filters and numerically
controlled oscillator (NCO) blocks supporting multiband
receivers.
4. Flexible serial port interface (SPI) controls various product
features and functions to meet specific system requirements.
5. Programmable fast overrange detection.
6. 9 mm × 9 mm, 64-lead LFCSP.
AD9680 Data Sheet
Rev. E | Page 2 of 105
TABLE OF CONTENTS
Features .............................................................................................. 1
Applications ....................................................................................... 1
Functional Block Diagram .............................................................. 1
Product Highlights ........................................................................... 1
Revision History ............................................................................... 3
General Description ......................................................................... 5
Specifications ..................................................................................... 6
DC Specifications ......................................................................... 6
AC Specifications .......................................................................... 7
Digital Specifications ................................................................... 9
Switching Specifications ............................................................ 10
Timing Specifications ................................................................ 11
Absolute Maximum Ratings .......................................................... 13
Thermal Characteristics ............................................................ 13
ESD Caution ................................................................................ 13
Pin Configuration and Function Descriptions ........................... 14
Typical Performance Characteristics ........................................... 16
AD9680-1250 .............................................................................. 16
AD9680-1000 .............................................................................. 20
AD9680-820 ................................................................................ 25
AD9680-500 ................................................................................ 30
Equivalent Circuits ......................................................................... 34
Theory of Operation ...................................................................... 36
ADC Architecture ....................................................................... 36
Analog Input Considerations.................................................... 36
Voltage Reference ....................................................................... 42
Clock Input Considerations ...................................................... 43
ADC Overrange and Fast Detect .................................................. 45
ADC Overrange .......................................................................... 45
Fast Threshold Detection (FD_A and FD_B) ......................... 45
Signal Monitor ................................................................................ 46
SPORT Over JESD204B ............................................................. 47
Digital Downconverter (DDC) ..................................................... 49
DDC I/Q Input Selection .......................................................... 49
DDC I/Q Output Selection ....................................................... 49
DDC General Description ........................................................ 49
Frequency Translation.................................................................... 55
Frequency Translation General Description .............................. 55
DDC NCO Plus Mixer Loss and SFDR ................................... 56
Numerically Controlled Oscillator........................................... 56
FIR Filters ........................................................................................ 58
FIR Filters General Description ............................................... 58
Half-Band Filters ........................................................................ 59
DDC Gain Stage ......................................................................... 61
DDC Complex to Real Conversion ......................................... 61
DDC Example Configurations ................................................. 62
Digital Outputs ............................................................................... 65
Introduction to the JESD204B Interface ................................. 65
JESD204B Overview .................................................................. 65
Functional Overview ................................................................. 66
JESD204B Link Establishment ................................................. 67
Physical Layer (Driver) Outputs .............................................. 68
JESD204B Tx Converter Mapping ........................................... 71
Configuring the JESD204B Link .............................................. 73
Deterministic Latency .................................................................... 76
Subclass 0 Operation .................................................................. 76
Subclass 1 Operation .................................................................. 76
Multichip Synchronization............................................................ 78
Normal Mode .............................................................................. 78
Timestamp Mode ....................................................................... 78
SYSRE Input ........................................................................... 80
SYSREF± Setup/Hold Window Monitor ................................. 82
Latency ............................................................................................. 84
End to End Total Latency .......................................................... 84
Example Latency Calculation ................................................... 84
Test Modes ....................................................................................... 85
ADC Test Modes ........................................................................ 85
JESD204B Block Test Modes..................................................... 86
Serial Port Interface ........................................................................ 88
Configuration Using the SPI ..................................................... 88
Hardware Interface ..................................................................... 88
SPI Accessible Features .............................................................. 88
Memory Map .................................................................................. 89
Reading the Memory Map Register Table ............................... 89
Memory Map Register Table ..................................................... 90
Applications Information ............................................................ 104
Power Supply Recommendations ........................................... 104
Exposed Pad Thermal Heat Slug Recommendations .......... 104
AVDD1_SR (Pin 57) and AGND (Pin 56 and Pin 60) ............ 104
Outline Dimensions ..................................................................... 105
Ordering Guide ........................................................................ 105
Data Sheet AD9680
Rev. E | Page 3 of 105
REVISION HISTORY
3/2019—Rev. D to Rev. E
Changes to Figure 146 .................................................................... 50
11/2017Rev. C to Rev. D
Changes to Table 2............................................................................. 7
Change to Junction Temperature Range, Table 6 ........................ 13
Changes to Figure 17 ...................................................................... 17
Changes to Figure 18 ...................................................................... 18
Changes to Figure 34 ...................................................................... 20
Changes to Figure 65 and Figure 66 ............................................. 26
Changes to Figure 67 and Figure 68 ............................................. 27
Changes to Figure 118 to Figure 120 ............................................ 38
Added Deterministic Latency Section, Subclass 0 Operation
Section, Subclass 1 Operation Section, Deterministic Latency
Requirements Section, Setting Deterministic Latency Registers
Section, and Figure 171; Renumbered Sequentially ................... 75
Added Figure 172 and Figure 173 ................................................. 76
Changes to Multichip Synchronization Section .......................... 77
Added Normal Mode Section, Timestamp Mode Section, and
Figure 174 ......................................................................................... 77
Added Figure 175 ............................................................................ 78
Added SYSREF± Input Section, SYSREF± Control Features
Section, and Figure 176 to Figure 179 .......................................... 79
Added Figure 180 and Figure 181 ................................................. 80
Added Latency Section, End to End Total Latency Section,
Example Latency Calculation Section, and Table 29 to
Table 31 ............................................................................................. 83
Updated Outline Dimensions ......................................................103
Changes to Ordering Guide .........................................................103
11/2015Rev. B to Rev. C
Added AD9680-1250 ......................................................... Universal
Changes to Features Section ............................................................ 1
Change to General Description Section ......................................... 4
Changes to Table 1............................................................................. 5
Changes to Table 2............................................................................. 6
Changes to Table 4............................................................................. 9
Changes to Table 5........................................................................... 10
Changes to Figure 4......................................................................... 11
Changes to Pin 14 Description, Table 8 ....................................... 14
Added AD9680-1250 Section and Figure 6 to Figure 29;
Renumbered Sequentially .............................................................. 15
Changes to Figure 113 .................................................................... 34
Changes to Analog Input Considerations Section ...................... 35
Changes to Table 9........................................................................... 36
Changes to Input Buffer Control Registers (0x018, 0x019,
0x01A, 0x935, 0x934, 0x11A) Section .......................................... 37
Added Figure 118 to Figure 120 .................................................... 37
Changes to Table 10 ........................................................................ 40
Changes to Table 17 ........................................................................ 57
Changes to ADC Test Modes Section ........................................... 78
Changes to Table 36 ........................................................................ 83
Changes to Ordering Guide ........................................................... 97
3/2015Rev. A to Rev. B
Added AD9680-820 ........................................................... Universal
Changes to Features Section ............................................................ 1
Changes to Table 1 ............................................................................ 5
Changes to Table 2 ............................................................................ 6
Changes to Table 3 ............................................................................ 8
Changes to Table 4 ............................................................................ 9
Added Figure 14; Renumbered Sequentially ............................... 15
Added AD9680-820 Section and Figure 31 Through Figure 36 .... 19
Added Figure 37 Through Figure 42 ............................................ 20
Added Figure 43 Through Figure 48 ............................................ 21
Added Figure 49 Through Figure 54 ............................................ 22
Added Figure 55 .............................................................................. 23
Changes to Figure 69 and Figure 70 ............................................. 26
Changes to Input Buffer Control Registers (0x018, 0x019, 0x01A,
0x935, 0x934, 0x11A) Section, Table 9, and Figure 93 .................... 31
Added Figure 99 Through Figure 100 .......................................... 33
Changes to Table 10 ........................................................................ 34
Changes to Clock Jitter Considerations Section ......................... 37
Added Figure 112 ............................................................................ 37
Changes to Digital Downconverter (DDC) Section ................... 42
Changes to Table 17 ........................................................................ 51
Changes to Table 36 ........................................................................ 77
Changes to Ordering Guide ........................................................... 91
12/2014Rev. 0 to Rev. A
Added AD9680-500 ........................................................... Universal
Changes to Features Section and Figure 1 ..................................... 1
Changes to General Description Section ....................................... 4
Changes to Specifications Section and Table 1 ............................. 5
Changes to AC Specifications Section and Table 2 ....................... 6
Changes to Digital Specifications Section ..................................... 8
Changes to Switching Specifications Section and Table 4 ........... 9
Changes to Table 6, Thermal Characteristics Section, and
Table 7 ............................................................................................... 11
Change to Digital Inputs Description, Table 8 ............................ 13
Added AD9680-1000 Section, Figure 10, and Figure 11;
Renumbered Sequentially .............................................................. 14
Changes to Figure 6 to Figure 9 .................................................... 14
Added Figure 12 to Figure 14 ........................................................ 15
Changes to Figure 15 to Figure 17 ................................................ 15
Changes to Figure 18 to Figure 21 ................................................ 16
Changes to Figure 25 and Figure 29 ............................................. 17
Changes to Figure 30 ...................................................................... 18
Deleted Figure 35, Figure 36, and Figure 38 ................................ 19
Added AD9680-500 Section and Figure 31 to Figure 54 ............. 19
AD9680 Data Sheet
Rev. E | Page 4 of 105
Changes to Analog Input Considerations Section and
Differential Input Configurations Section .................................. 25
Added Input Buffer Control Registers (0x018, 0x019, 0x01A,
0x935, 0x934, 0x11A) Section, Figure 66, Figure 68, and Table 9;
Renumbered Sequentially .............................................................. 26
Changes to Analog Input Buffer Controls and SFDR
Optimization Section and Figure 67 ............................................ 26
Added Figure 69 to Figure 72........................................................ 27
Added Figure 73 to Figure 75........................................................ 28
Changes to Table 10 ........................................................................ 28
Added Input Clock Divider ½ Period Delay Adjust Section and
Clock Fine Delay Adjust Section .................................................. 30
Changes to Figure 83 and Temperature Diode Section ............. 31
Added Signal Monitor Section and Figure 86 to Figure 89 ...... 33
Changes to Table 11 ........................................................................ 39
Changes to Table 12 to Table 14 .................................................... 40
Changes to Table 16 ........................................................................ 41
Deleted Figure 65 and Figure 66 ................................................... 45
Changes to Table 17 ........................................................................ 45
Changes to Table 19 to Table 20 ................................................... 46
Changes to Table 22 ........................................................................ 47
Changes to Table 23 ........................................................................ 49
Changes to JESD204B Link Establishment Section ................... 53
Added Figure 105 to Figure 110 ................................................... 56
Changes to Example 1: Full Bandwidth Mode Section ............. 60
Added Multichip Synchronization Section, Figure 115 to
Figure 117, and Table 28 ................................................................ 62
Added Test Modes Section and Table 29 to Table 33 ................. 66
Changes to Reading the Memory Map Register Table Section ...... 70
Changes to Table 36 ........................................................................ 71
Changes to Power Supply Recommendations Section,
Figure 118, and Exposed Pad Thermal Heat Slug
Recommendations Section ............................................................ 83
Changes to Ordering Guide .......................................................... 84
5/2014Revision 0: Initial Version
Data Sheet AD9680
Rev. E | Page 5 of 105
GENERAL DESCRIPTION
The AD9680 is a dual, 14-bit, 1.25 GSPS/1 GSPS/820 MSPS/
500 MSPS analog-to-digital converter (ADC). The device has
an on-chip buffer and sample-and-hold circuit designed for low
power, small size, and ease of use. This device is designed for
sampling wide bandwidth analog signals of up to 2 GHz. The
AD9680 is optimized for wide input bandwidth, high sampling
rate, excellent linearity, and low power in a small package.
The dual ADC cores feature a multistage, differential pipelined
architecture with integrated output error correction logic. Each
ADC features wide bandwidth inputs supporting a variety of
user-selectable input ranges. An integrated voltage reference
eases design considerations.
The analog input and clock signals are differential inputs. Each
ADC data output is internally connected to two digital down-
converters (DDCs). Each DDC consists of up to five cascaded
signal processing stages: a 12-bit frequency translator (NCO),
and four half-band decimation filters. The DDCs are bypassed
by default.
In addition to the DDC blocks, the AD9680 has several
functions that simplify the automatic gain control (AGC)
function in the communications receiver. The programmable
threshold detector allows monitoring of the incoming signal
power using the fast detect output bits of the ADC. If the input
signal level exceeds the programmable threshold, the fast detect
indicator goes high. Because this threshold indicator has low
latency, the user can quickly turn down the system gain to avoid
an overrange condition at the ADC input.
Users can configure the Subclass 1 JESD204B-based high speed
serialized output in a variety of one-, two-, or four-lane
configurations, depending on the DDC configuration and the
acceptable lane rate of the receiving logic device. Multiple device
synchronization is supported through the SYSREF± and
SYNCIN input pins.
The AD9680 has flexible power-down options that allow
significant power savings when desired. All of these features can
be programmed using a 1.8 V to 3.3 V capable, 3-wire SPI.
The AD9680 is available in a Pb-free, 64-lead LFCSP and is
specified over the −40°C to +85°C industrial temperature range.
This product is protected by a U.S. patent.
AD9680 Data Sheet
Rev. E | Page 6 of 105
SPECIFICATIONS
DC SPECIFICATIONS
AVDD1 = 1.25 V, AVDD2 = 2.5 V, AVDD3 = 3.3 V, AVDD1_SR = 1.25 V, DVDD = 1.25 V, DRVDD = 1.25 V, SPIVDD = 1.8 V, specified
maximum sampling rate for each speed grade, AIN = −1.0 dBFS, clock divider = 2, default SPI settings, TA = 25°C, unless otherwise noted.
Table 1.
AD9680-500 AD9680-820 AD9680-1000 AD9680-1250
Parameter Temp Min Typ Max Min Typ Max Min Typ Max Min Typ Max Unit
RESOLUTION Full 14 14 14 14 Bits
ACCURACY
No Missing Codes Full Guaranteed Guaranteed Guaranteed Guaranteed
Offset Error Full 0.3 0 +0.3 −0.3 0 +0.3 −0.31 0 +0.31 −0.31 0 +0.31 % FSR
Offset Matching Full 0 0.3 0 0.23 0 0.23 0 0.3 % FSR
Gain Error Full −6 0 +6 −6 0 +6 −6 0 +6 −6 0 +6 % FSR
Gain Matching
Full
5.1
1
5.5
1
4.5
1
4.5
% FSR
Differential Nonlinearity
(DNL)
Full 0.6 ±0.5 +0.7 −0.7 ±0.5 +0.8 0.7 ±0.5 +0.8 −0.8 ±0.5 +0.8 LSB
Integral Nonlinearity (INL) Full 4.5 ±2.5 +5.0 −3.3 ±2.5 +4.3 −5.7 ±2.5 +6.9 −6 ±3 +6 LSB
TEMPERATURE DRIFT
Offset Error Full −3 10 −12 −15 ppm/°C
Gain Error Full ±25 ±54 ±13.8 92 ppm/°C
INTERNAL VOLTAGE
REFERENCE
Voltage Full 1.0 1.0 1.0 1.0 V
INPUT-REFERRED NOISE
VREF = 1.0 V 25°C 2.06 2.46 2.63 3.45 LSB rms
ANALOG INPUTS
Differential Input Voltage
Range (Programmable)
Full 1.46 2.06 2.06 1.46 1.70 1.94 1.46 1.70 1.94 1.46 1.58 1.94 V p-p
Common-Mode Voltage
(VCM)
25°C 2.05 2.05 2.05 2.05 V
Differential Input
Capacitance1
25°C 1.5 1.5 1.5 1.5 pF
Analog Input Full Power
Bandwidth
25°C 2 2 2 2 GHz
POWER SUPPLY
AVDD1 Full 1.22 1.25 1.28 1.22 1.25 1.28 1.22 1.25 1.28 1.22 1.25 1.28 V
AVDD2 Full 2.44 2.50 2.56 2.44 2.50 2.56 2.44 2.50 2.56 2.44 2.50 2.56 V
AVDD3 Full 3.2 3.3 3.4 3.2 3.3 3.4 3.2 3.3 3.4 3.2 3.3 3.4 V
AVDD1_SR Full 1.22 1.25 1.28 1.22 1.25 1.28 1.22 1.25 1.28 1.22 1.25 1.28 V
DVDD Full 1.22 1.25 1.28 1.22 1.25 1.28 1.22 1.25 1.28 1.22 1.25 1.28 V
DRVDD Full 1.22 1.25 1.28 1.22 1.25 1.28 1.22 1.25 1.28 1.22 1.25 1.28 V
SPIVDD Full 1.7 1.8 3.4 1.7 1.8 3.4 1.7 1.8 3.4 1.7 1.8 3.4 V
IAVDD1 Full 435 467 605 660 685 720 785 880 mA
I
AVDD2
Full
463
490
545
595
680
675
780
mA
IAVDD3 Full 87 101 125 140 125 142 125 142 mA
IAVDD1_SR Full 15 22 15 18 16 18 17 20 mA
IDVDD2 Full 145 152 205 246 208 269 250 325 mA
IDRVDD1 Full 190 237 200 240 200 225 220 300 mA
IDRVDD (L = 2 Mode) 25°C 140 N/A3 N/A3 N/A3 mA
ISPIVDD Full 5 6 5 6 5 6 5 6 mA
Data Sheet AD9680
Rev. E | Page 7 of 105
AD9680-500
AD9680-820
AD9680-1000
AD9680-1250
Parameter Temp Min Typ Max Min Typ Max Min Typ Max Min Typ Max Unit
POWER CONSUMPTION
Total Power Dissipation
(Including Output
Drivers)2
Full 2.2 2.9 3.3 3.7 W
Total Power Dissipation
(L = 2 Mode)
25°C
N/A
3
N/A
3
N/A
3
W
Power-Down Dissipation Full 700 820 835 1030 mW
Standby4 Full 1.2 1.3 1.4 1.66 W
1 All lanes running. Power dissipation on DRVDD changes with lane rate and number of lanes used.
2 Default mode. No DDCs used. L = 4, M = 2, F = 1.
3 N/A means not applicable. At the maximum sample rate, it is not applicable to use L = 2 mode on the JESD204B output interface because this exceeds the maximum
lane rate of 12.5 Gbps. L = 2 mode is supported when the equation ((M × N΄ × (10/8) × fOUT)/L) results in a line rate that is ≤12.5 Gbps. fOUT is the output sample rate and
is denoted by fS/DCM, where DCM is the decimation ratio.
4 Can be controlled by the SPI.
AC SPECIFICATIONS
AVDD1 = 1.25 V, AVDD2 = 2.5 V, AVDD3 = 3.3 V, AVDD1_SR = 1.25 V, DVDD = 1.25 V, DRVDD = 1.25 V, SPIVDD = 1.8 V, specified
maximum sampling rate for each speed grade, AIN = −1.0 dBFS, clock divider = 2, default SPI settings, TA = 25°C, unless otherwise noted.
Table 2.
AD9680-500 AD9680-820 AD9680-1000 AD9680-1250
Parameter
1
Temp
Min
Typ
Max
Min
Typ
Max
Min
Typ
Max
Min
Typ
Max
Unit
ANALOG INPUT FULL SCALE Full 2.06 1.7 1.7 1.58 V p-p
NOISE DENSITY
2
Full
−153
−153
−154
−151.5
dBFS/Hz
SIGNAL-TO-NOISE RATIO
(SNR)3
fIN = 10 MHz 25°C 69.2 67.2 67.2 63.6 dBFS
fIN = 170 MHz Full 67.8 69.0 65.6 67.0 65.1 66.6 61.5 63.2 dBFS
fIN = 340 MHz 25°C 68.6 66.5 65.3 62.8 dBFS
fIN = 450 MHz 25°C 68.0 65.1 64.0 62.2 dBFS
fIN = 765 MHz 25°C 64.4 64.0 62.6 61.1 dBFS
f
IN
= 985 MHz
25°C
63.8
63.4
61.5
59.2
dBFS
fIN = 1950 MHz 25°C 60.5 59.7 57.0 55.5 dBFS
SNR AND DISTORTION RATIO
(SINAD)3
fIN = 10 MHz 25°C 69.0 67.1 67.1 63.5 dBFS
fIN = 170 MHz Full 67.6 68.8 65.2 66.8 65.0 66.4 61.4 62.8 dBFS
fIN = 340 MHz 25°C 68.4 66.3 65.2 62.6 dBFS
fIN = 450 MHz 25°C 67.9 64.7 63.8 61.8 dBFS
f
IN
= 765 MHz
25°C
64.2
63.5
62.5
60.8
dBFS
fIN = 985 MHz 25°C 63.6 62.7 61.4 58.2 dBFS
fIN = 1950 MHz 25°C 60.3 58.7 56.4 51.5 dBFS
EFFECTIVE NUMBER OF BITS
(ENOB)
fIN = 10 MHz 25°C 11.2 10.9 10.8 10.3 Bits
fIN = 170 MHz Full 10.9 11.1 10.5 10.8 10.5 10.7 9.9 10.1 Bits
fIN = 340 MHz 25°C 11.1 10.7 10.5 10.1 Bits
fIN = 450 MHz 25°C 11.0 10.5 10.3 10.0 Bits
fIN = 765 MHz 25°C 10.4 10.3 10.1 9.8 Bits
fIN = 985 MHz 25°C 10.3 10.1 9.9 9.4 Bits
fIN = 1950 MHz 25°C 9.7 9.5 9.1 8.3 Bits
AD9680 Data Sheet
Rev. E | Page 8 of 105
AD9680-500
AD9680-820
AD9680-1000
AD9680-1250
Parameter1 Temp Min Typ Max Min Typ Max Min Typ Max Min Typ Max Unit
SPURIOUS-FREE DYNAMIC
RANGE (SFDR)3
fIN = 10 MHz 25°C 83 91 88 84 dBFS
fIN = 170 MHz Full 80 88 75 83 75 85 74 77 dBFS
fIN = 340 MHz 25°C 83 81 85 78 dBFS
fIN = 450 MHz 25°C 81 78 82 76 dBFS
fIN = 765 MHz 25°C 80 78 82 77 dBFS
fIN = 985 MHz 25°C 75 74 80 71 dBFS
fIN = 1950 MHz 25°C 70 70 69 61 dBFS
WORST HARMONIC,
SECOND OR THIRD3
fIN = 10 MHz 25°C 83 −91 −88 −84 dBFS
fIN = 170 MHz Full 88 −80 83 −75 −85 −75 −77 74 dBFS
f
IN
= 340 MHz
25°C
−83
−81
−85
−78
dBFS
fIN = 450 MHz 25°C 81 −78 82 76 dBFS
fIN = 765 MHz 25°C 80 −78 82 77 dBFS
fIN = 985 MHz 25°C 75 −74 80 71 dBFS
fIN = 1950 MHz 25°C 70 −70 −69 −61 dBFS
WORST OTHER, EXCLUDING
SECOND OR THIRD
HARMONIC3
f
IN
= 10 MHz
25°C
95
−97
−95
−87
dBFS
fIN = 170 MHz Full 95 82 93 −80 −94 −81 −79 74 dBFS
fIN = 340 MHz 25°C 93 −91 88 81 dBFS
fIN = 450 MHz 25°C 93 −90 86 79 dBFS
fIN = 765 MHz 25°C 88 −83 −83 79 dBFS
f
IN
= 985 MHz
25°C
89
−84
−82
−77
dBFS
fIN = 1950 MHz 25°C 84 −74 −79 69 dBFS
TWO-TONE
INTERMODULATION
DISTORTION (IMD),
AIN1 AND AIN2 = −7 dBFS
fIN1 = 185 MHz,
fIN2 = 188 MHz
25°C −88 −90 −87 −82 dBFS
fIN1 = 338 MHz,
fIN2 = 341 MHz
25°C −88 −87 −88 −784 dBFS
CROSSTALK5 25°C 95 95 95 95 dB
FULL POWER BANDWIDTH6 25°C 2 2 2 2 GHz
1 See the AN-835 Application Note, Understanding High Speed ADC Testing and Evaluation, for definitions and for details on how these tests were completed.
2 Noise density is measured at a low analog input frequency (30 MHz).
3 See Table 10 for the recommended settings for full-scale voltage and buffer current settings.
4 Measurement taken with 449 MHz and 452 MHz inputs for two-tone.
5 Crosstalk is measured at 170 MHz with a −1.0 dBFS analog input on one channel and no input on the adjacent channel.
6 Measured with the circuit shown in Figure 115.
Data Sheet AD9680
Rev. E | Page 9 of 105
DIGITAL SPECIFICATIONS
AVDD1 = 1.25 V, AVDD2 = 2.5 V, AVDD3 = 3.3 V, AVDD1_SR = 1.25 V, DVDD = 1.25 V, DRVDD = 1.25 V, SPIVDD = 1.8 V, specified
maximum sampling rate for each speed grade, AIN = −1.0 dBFS, clock divider = 2, default SPI settings, TA = 25°C, unless otherwise noted.
Table 3.
Parameter Temperature Min Typ Max Unit
CLOCK INPUTS (CLK+, CLK−)
Logic Compliance Full LVDS/LVPECL
Differential Input Voltage Full 600 1200 1800 mV p-p
Input Common-Mode Voltage Full 0.85 V
Input Resistance (Differential) Full 35 kΩ
Input Capacitance Full 2.5 pF
SYSREF INPUTS (SYSREF+, SYSREF−)
Logic Compliance Full LVDS/LVPECL
Differential Input Voltage Full 400 1200 1800 mV p-p
Input Common-Mode Voltage Full 0.6 0.85 2.0 V
Input Resistance (Differential) Full 35 kΩ
Input Capacitance (Differential) Full 2.5 pF
LOGIC INPUTS (SDI, SCLK, CSB, PDWN/STBY)
Logic Compliance Full CMOS
Logic 1 Voltage Full 0.8 × SPIVDD V
Logic 0 Voltage Full 0 0.5 V
Input Resistance Full 30 kΩ
LOGIC OUTPUT (SDIO)
Logic Compliance Full CMOS
Logic 1 Voltage (I
OH
= 800 µA)
Full
0.8 × SPIVDD
V
Logic 0 Voltage (IOL = 50 µA) Full 0 0.5 V
SYNCIN INPUT (SYNCINB+/SYNCINB−)
Logic Compliance
Full
LVDS/LVPECL/CMOS
Differential Input Voltage Full 400 1200 1800 mV p-p
Input Common-Mode Voltage Full 0.6 0.85 2.0 V
Input Resistance (Differential) Full 35 kΩ
Input Capacitance Full 2.5 pF
LOGIC OUTPUTS (FD_A, FD_B)
Logic Compliance Full CMOS
Logic 1 Voltage Full 0.8 × SPIVDD V
Logic 0 Voltage Full 0 0.5 V
Input Resistance Full 30 kΩ
DIGITAL OUTPUTS (SERDOUTx±, x = 0 TO 3)
Logic Compliance
Full
CML
Differential Output Voltage Full 360 770 mV p-p
Output Common-Mode Voltage (VCM)
AC-Coupled 25°C 0 1.8 V
Short-Circuit Current (IDSHORT) 25°C 100 +100 mA
Differential Return Loss (RLDIFF)1 25°C 8 dB
Common-Mode Return Loss (RLCM)1 25°C 6 dB
Differential Termination Impedance Full 80 100 120
1 Differential and common-mode return loss are measured from 100 MHz to 0.75 × baud rate.
AD9680 Data Sheet
Rev. E | Page 10 of 105
SWITCHING SPECIFICATIONS
AVDD1 = 1.25 V, AVDD2 = 2.5 V, AVDD3 = 3.3 V, AVDD1_SR = 1.25 V, DVDD = 1.25 V, DRVDD = 1.25 V, SPIVDD = 1.8 V, specified
maximum sampling rate for each speed grade, AIN = −1.0 dBFS, default SPI settings, TA = 25°C, unless otherwise noted.
Table 4.
AD9680-500 AD9680-820 AD9680-1000 AD9680-1250
Parameter Temp Min Typ Max Min Typ Max Min Typ Max Min Typ Max Unit
CLOCK
Clock Rate (at
CLK+/CLK− Pins)
Full
0.3
4
0.3
4
0.3
4
0.3
4
GHz
Maximum Sample Rate1 Full 500 820 1000 1250 MSPS
Minimum Sample Rate2 Full 300 300 300 300 MSPS
Clock Pulse Width High Full 1000 609.7 500 400 ps
Clock Pulse Width Low Full 1000 609.7 500 400 ps
OUTPUT PARAMETERS
Unit Interval (UI)3 Full 80 200 80 121.95 80 100 80 80 ps
Rise Time (tR) (20% to
80% into 100 Ω Load)
25°C 24 32 24 32 24 32 24 32 ps
Fall Time (tF) (20% to 80%
into 100 Ω Load)
25°C 24 32 24 32 24 32 24 32 ps
PLL Lock Time 25°C 2 2 2 2 ms
Data Rate per Channel
(NRZ)4
25°C 3.125 5 12.5 3.125 8.2 12.5 3.125 10 12.5 3.1215 12.5 12.5 Gbps
LATENCY5
Pipeline Latency
Full
55
55
55
55
Clock
cycles
Fast Detect Latency Full 28 28 28 28 Clock
cycles
Wake-Up Time6
Standby 25°C 1 1 1 1 ms
Power-Down
25°C
4
4
4
4
ms
APERTURE
Aperture Delay (tA) Full 530 530 530 530 ps
Aperture Uncertainty
(Jitter, tJ)
Full
55
55
55
55
f
S
rms
Out-of-Range Recovery
Time
Full 1 1 1 1 Clock
cycles
1 The maximum sample rate is the clock rate after the divider.
2 The minimum sample rate operates at 300 MSPS with L = 2 or L = 1.
3 Baud rate = 1/UI. A subset of this range can be supported.
4 Default L = 4. This number can be changed based on the sample rate and decimation ratio.
5 No DDCs used. L = 4, M = 2, F = 1.
6 Wake-up time is defined as the time required to return to normal operation from power-down mode.
Data Sheet AD9680
Rev. E | Page 11 of 105
TIMING SPECIFICATIONS
Table 5.
Parameter Test Conditions/Comments Min Typ Max Unit
CLK+ to SYSREF+ TIMING REQUIREMENTS See Figure 3
tSU_SR Device clock to SYSREF+ setup time 117 ps
t
H_SR
Device clock to SYSREF+ hold time
−96
ps
SPI TIMING REQUIREMENTS See Figure 4
tDS Setup time between the data and the rising edge of SCLK 2 ns
t
DH
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 must be in a logic high state 10 ns
tLOW Minimum period that SCLK must be in a logic low state 10 ns
t
ACCESS
Maximum time delay between falling edge of SCLK and output
data valid for a read operation
6
10
ns
tDIS_SDIO Time required for the SDIO pin to switch from an output to an
input relative to the SCLK rising edge (not shown in Figure 4)
10 ns
Timing Diagrams
SERDOUT0–
N – 54
N – 53 N – 52 N – 51 N – 1
SAMPLE N
N + 1
APERTURE
DELAY
N – 55
CLK+
CLK–
CLK+
CLK–
SERDOUT0+
SERDOUT1–
SERDOUT1+
SERDOUT2–
SERDOUT2+
SERDOUT3–
SERDOUT3+
ABC D E F G H I JABCD E F G H I JABC D E F G H I J
A B C D E F G H I J A B C D E F G H I J A B C D E F G H I J
ABC D E F G H I JABC D E F G H IJABC D E F G H I J
A B C D E F G H I J A B C D E F G H I J A B C D E F G H I J
CONVE RTER0 M S B
CONVE RTER0 LSB
CONVE RTER1 M S B
CONVE RTER1 LSB
ANALOG
INPUT
SIGNAL
11752-002
SAMPLE N – 55
ENCODE D INT O 1
8-BIT/ 10- BIT S Y M BOL
SAMPLE N – 54
ENCODE D INT O 1
8-BIT/ 10- BIT S Y M BOL
SAMPLE N – 53
ENCODE D INT O 1
8-BIT/ 10- BIT S Y M BOL
Figure 2. Data Output Timing (Full Bandwidth Mode; L = 4; M = 2; F = 1)
AD9680 Data Sheet
Rev. E | Page 12 of 105
CLK+
CLK–
SYSREF+
SYSREF–
t
SU_SR
t
H_SR
11752-003
Figure 3. SYSREF± Setup and Hold Timing
DON’ T CARE
DON’ T CAREDON’ T CARE
DON’ T CARE
SDIO
SCLK
tStDH
tCLK
tDS tACCESS tH
R/W A14 A13 A12 A11 A10 A9 A8 A7 D7 D6 D3 D2 D1 D0
tLOW
tHIGH
CSB
11752-004
Figure 4. Serial Port Interface Timing Diagram
Data Sheet AD9680
Rev. E | Page 13 of 105
ABSOLUTE MAXIMUM RATINGS
Table 6.
Parameter Rating
Electrical
AVDD1 to AGND
1.32 V
AVDD1_SR to AGND 1.32 V
AVDD2 to AGND 2.75 V
AVDD3 to AGND 3.63 V
DVDD to DGND 1.32 V
DRVDD to DRGND
1.32 V
SPIVDD to AGND 3.63 V
AGND to DRGND −0.3 V to +0.3 V
VIN±x to AGND 3.2 V
SCLK, SDIO, CSB to AGND −0.3 V to SPIVDD + 0.3 V
PDWN/STBY to AGND −0.3 V to SPIVDD + 0.3 V
Operating Temperature Range
−40°C to +85°C
Junction Temperature Range −40°C to +125°C
Storage Temperature Range (Ambient) −65°C to +150°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
Typical θJA, θJB, and θJC are specified vs. the number of printed
circuit board (PCB) layers in different airflow velocities (in m/sec).
Airflow increases heat dissipation effectively reducing θJA and
θJB. In addition, metal in direct contact with the package leads
and exposed pad from metal traces, through holes, ground, and
power planes, reduces θJA. Thermal performance for actual
applications requires careful inspection of the conditions in
an application. The use of appropriate thermal management
techniques is recommended to ensure that the maximum junction
temperature does not exceed the limits shown in Table 6.
Table 7. Thermal Resistance Values
PCB Type
Airflow
Velocity
(m/sec) θJA ΨJB θJC_TOP θJC_BOT Unit
JEDEC
2s2p Board
0.0 17.81, 2 6.31, 3 4.71, 4 1.21, 4 °C/W
1.0
15.6
1, 2
5.9
1, 3
N/A
5
°C/W
2.5 15.01, 2 5.71, 3 N/A5 °C/W
1 Per JEDEC 51-7, plus JEDEC 51-5 2s2p test board.
2 Per JEDEC JESD51-2 (still air) or JEDEC JESD51-6 (moving air).
3 Per JEDEC JESD51-8 (still air).
4 Per MIL-STD 883, Method 1012.1.
5 N/A means not applicable.
ESD CAUTION
AD9680 Data Sheet
Rev. E | Page 14 of 105
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
AD9680
TOP VIEW
(No t t o Scal e)
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
FD_A
DRGND
DRVDD
SYNCINB–
SYNCINB+
SERDOUT0–
SERDOUT0+
SERDOUT1–
SERDOUT1+
SERDOUT2–
SERDOUT2+
SERDOUT3–
SERDOUT3+
DRVDD
DRGND
FD_B
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
AVDD1
AVDD2
AVDD2
AVDD1
AGND
SYSREF–
SYSREF+
AVDD1_SR
AGND
AVDD1
CLK–
CLK+
AVDD1
AVDD2
AVDD2
AVDD1
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
AVDD1
AVDD1
AVDD2
AVDD3
VIN–A
VIN+A
AVDD3
AVDD2
AVDD2
AVDD2
AVDD2
V_1P0
SPIVDD
PDWN/STBY
DVDD
DGND
AVDD1
AVDD1
AVDD2
AVDD3
VIN–B
VIN+B
AVDD3
AVDD2
AVDD2
AVDD2
SPIVDD
CSB
SCLK
SDIO
DVDD
DGND
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
NOTES
1. EXPOSED PAD. THE EXPOSED THERMAL PAD ON THE BOTTO M O F T HE
PACKAG E P ROVIDES THE GROUND RE FENCE FOR AV DDx. T HIS EX P OSED
PAD MUS T BE CO NNE CTED T O G ROUND FOR PROPER OPE RATION.
11752-005
Figure 5. Pin Configuration (Top View)
Table 8. Pin Function Descriptions
Pin No. Mnemonic Type Description
Power Supplies
0 EPAD Ground Exposed Pad. The exposed thermal pad on the bottom of the
package provides the ground reference for AVDDx. This
exposed pad must be connected to ground for proper
operation.
1, 2, 47, 48, 49, 52, 55, 61, 64 AVDD1 Supply Analog Power Supply (1.25 V Nominal).
3, 8, 9, 10, 11, 39, 40, 41,
46, 50, 51, 62, 63
AVDD2 Supply Analog Power Supply (2.5 V Nominal).
4, 7, 42, 45
AVDD3
Supply
Analog Power Supply (3.3 V Nominal).
13, 38 SPIVDD Supply Digital Power Supply for SPI (1.8 V to 3.3 V).
15, 34 DVDD Supply Digital Power Supply (1.25 V Nominal).
16, 33 DGND Ground Ground Reference for DVDD.
18, 31 DRGND Ground Ground Reference for DRVDD.
19, 30 DRVDD Supply Digital Driver Power Supply (1.25 V Nominal).
56, 60 AGND1 Ground Ground Reference for SYSREF±.
57 AVDD1_SR1 Supply Analog Power Supply for SYSREF± (1.25 V Nominal).
Analog
5, 6 VIN−A, VIN+A Input ADC A Analog Input Complement/True.
12 V_1P0 Input/DNC 1.0 V Reference Voltage Input/Do Not Connect. This pin is
configurable through the SPI as a no connect or an input. Do
not connect this pin if using the internal reference. Requires a
1.0 V reference voltage input if using an external voltage
reference source.
44, 43 VIN−B, VIN+B Input ADC B Analog Input Complement/True.
53, 54 CLK+, CLK− Input Clock Input True/Complement.
Data Sheet AD9680
Rev. E | Page 15 of 105
Pin No.
Mnemonic
Type
Description
CMOS Outputs
17, 32 FD_A, FD_B Output Fast Detect Outputs for Channel A and Channel B.
Digital Inputs
20, 21 SYNCINB−, SYNCINB+ Input Active Low JESD204B LVDS Sync Input True/Complement.
58, 59 SYSREF+, SYSREF− Input Active High JESD204B LVDS System Reference Input
True/Complement.
Data Outputs
22, 23 SERDOUT0−, SERDOUT0+ Output Lane 0 Output Data Complement/True.
24, 25 SERDOUT1−, SERDOUT1+ Output Lane 1 Output Data Complement/True.
26, 27
SERDOUT2−, SERDOUT2+
Output
Lane 2 Output Data Complement/True.
28, 29 SERDOUT3−, SERDOUT3+ Output Lane 3 Output Data Complement/True.
Device Under Test (DUT)
Controls
14 PDWN/STBY Input Power-Down Input (Active High). The operation of this pin
depends on the SPI mode and can be configured as power-
down or standby. Requires an external 10 kΩ pull-down resistor.
35 SDIO Input/Output SPI Serial Data Input/Output.
36
SCLK
Input
SPI Serial Clock.
37 CSB Input SPI Chip Select (Active Low).
1 To ensure proper ADC operation, connect AVDD1_SR and AGND separately from the AVDD1 and EPAD connection. For more information, see the Applications
Information section.
AD9680 Data Sheet
Rev. E | Page 16 of 105
TYPICAL PERFORMANCE CHARACTERISTICS
AD9680-1250
AVDD1 = 1.25 V, AVDD1_SR = 1.25 V, AVDD2 = 2.5 V, AVDD3 = 3.3 V, DVDD = 1.25 V, DRVDD = 1.25 V, SPIVDD = 1.8 V, 1.58 V p-p
full-scale differential input, AIN = −1.0 dBFS, default SPI settings, clock divider = 2, TA = 25°C, 128k FFT sample, unless otherwise noted.
See Table 10 for recommended settings.
–130
–110
–90
–70
–50
–30
–10
0625.000
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= –1dBFS
SNR = 64d BFS
ENOB = 10.3 BI TS
SFDR = 82dBF S
BUFF E R CURRE NT = 3.
78.125 156.250 234.375 312.500 390.625 468.750 546.875
11752-606
Figure 6. Single-Tone FFT with fIN = 10.3 MHz
–130
–110
–90
–70
–50
–30
–10
0625.000
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= –1dBFS
SNR = 63. 4dBF S
ENOB = 10.2 BI TS
SFDR = 79dBF S
BUFF E R CURRE NT = 3.
78.125 156.250 234.375 312.500 390.625 468.750 546.875
11752-607
Figure 7. Single-Tone FFT with fIN = 170.3 MHz
–130
–110
–90
–70
–50
–30
–10
0625.000
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= –1dBFS
SNR = 62. 8dBF S
ENOB = 10.1 BI TS
SFDR = 76dBF S
BUFF E R CURRE NT = 3.
78.125 156.250 234.375 312.500 390.625 468.750 546.875
11752-608
Figure 8. Single-Tone FFT with fIN = 340.3 MHz
–130
–110
–90
–70
–50
–30
–10
0625.000
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= –1dBFS
SNR = 62. 5dBF S
ENOB = 9.9 BI TS
SFDR = 70dBF S
BUFF E R CURRE NT = 3.
78.125 156.250 234.375 312.500 390.625 468.750 546.875
11752-609
Figure 9. Single-Tone FFT with fIN = 450.3 MHz
–130
–110
–90
–70
–50
–30
–10
0625.000
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= –1dBFS
SNR = 60. 9dBF S
ENOB = 9.8 BI TS
SFDR = 74dBF S
BUFF E R CURRE NT = 5.
78.125 156.250 234.375 312.500 390.625 468.750 546.875
11752-610
Figure 10. Single-Tone FFT with fIN = 765.3 MHz
–120
–100
–80
–60
–40
–20
0
0625.000
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= –1dBFS
SNR = 59. 7dBF S
ENOB = 9.6 BI TS
SFDR = 74dBF S
BUFF E R CURRE NT = 5.
78.125 156.250 234.375 312.500 390.625 468.750 546.875
11752-611
Figure 11. Single-Tone FFT with fIN = 985.3 MHz
Data Sheet AD9680
Rev. E | Page 17 of 105
–120
–100
–80
–60
–40
–20
0
0625.000
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= –1dBFS
SNR = 58. 5dBF S
ENOB = 9.3 BI TS
SFDR = 68dBF S
BUFF E R CURRE NT = 5.
78.125 156.250 234.375 312.500 390.625 468.750 546.875
11752-612
Figure 12. Single-Tone FFT with fIN = 1205.3 MHz
–120
–100
–80
–60
–40
–20
0
0625.000
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= –1dBFS
SNR = 56. 6dBF S
ENOB = 9.0 BI TS
SFDR = 67dBF S
BUFF E R CURRE NT = 7.
78.125 156.250 234.375 312.500 390.625 468.750 546.875
11752-613
Figure 13. Single-Tone FFT with fIN = 1602.3 MHz
–120
–100
–80
–60
–40
–20
0
0625.000
AMPLITUDE (dBFS)
FREQUENCY (MHz)
AIN = –1dBFS
SNR = 55. 4dBF S
ENOB = 8.8 BI TS
SFDR = 63dBF S
BUFF E R CURRE NT = 8.
78.125 156.250 234.375 312.500 390.625 468.750 546.875
11752-614
Figure 14. Single-Tone FFT with fIN = 1954.3 MHz
60
85
80
75
70
65
SNR/S FDR (dBFS )
SAMPLE RATE (MHz)
SNR
SFDR
1000 1020 1040 1060 1080 1100 1120 1140 1160 1180 1200 1220 1240 1260
11752-615
Figure 15. SNR/SFDR vs. fS, fIN = 170.3 MHz; Buffer Control 1 (0x018) = 3.5×
667.3589.3511.3433.3355.3290.3212.3147.310.3
SNR/S FDR (dBFS )
INPUT F RE QUENCY ( M Hz )
60
65
70
75
80
85 3.5× S NR ( dBF S )
3.5× S FDR (dBFS )
4.5× S NR ( dBF S )
4.5× S FDR (dBFS )
11752-616
Figure 16. SNR/SFDR vs. fIN; fIN < 700 MHz;
Buffer Control 1 (0x018) = 3.5× and 4.5×
SNR/S FDR (dBFS )
INPUT F RE QUENCY ( M Hz )
55
60
65
70
75
80
628.3 706.6 784.3 862.3 940.3 1018.3 1096.3 1174.3 1252.3
11752-617
SNR
SFDR
Figure 17. SNR/SFDR vs. fIN; 650 MHz < fIN < 1.3 GHz;
Buffer Control 1 (0x018) = 6.
AD9680 Data Sheet
Rev. E | Page 18 of 105
SNR/ SFDR (dBF S )
INPUT F RE QUENCY ( M Hz )
50
55
60
65
70
75
80
1252.3 1356.3 1460.3 1564.3 1668.3 177.23 1876.3 1980.3
11752-618
SFDR
SNR
Figure 18. SNR/SFDR vs. fIN; 1.3 GHz < fIN < 2GHz;
Buffer Control 1 (0x018) = 8.5×
–120
–100
–80
–60
–40
–20
0
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN1
AND A
IN2
= –7dBFS
SFDR = 82dBF S
IMD2 = 84dBF S
IMD3 = 82dBF S
BUFF E R CURRE NT = 3.
11752-095
078.125 156.250 234.375 312.500 390.625 468.750 546.875 625.000
Figure 19. Two-Tone FFT; fIN1 = 184 MHz, fIN2 = 187 MHz
–120
–100
–80
–60
–40
–20
0
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN1
AND A
IN2
= –7dBFS
SFDR = 78dBF S
IMD2 = 78dBF S
IMD3 = 78dBF S
BUFF E R CURRE NT = 5.
11752-096
078.125 156.250 234.375 312.500 390.625 468.750 546.875 625.000
Figure 20. Two-Tone FFT; fIN1 = 449 MHz, fIN2 = 452 MHz
–84–90 –78 –72 –66 –60 –54 –48 –42 –36 –30 –24 –18 –12 –6 0
SF DR/ IMD3 ( dBc AND dBFS)
INPUT AMPLITUDE (dBFS)
–120
0
–20
–40
–60
–80
–100
IM D3 ( dBc)
IM D3 ( dBFS )
SF DR ( dBFS )
SF DR ( dBc)
11752-622
Figure 21. Two-Tone SFDR/IMD3 vs. Input Amplitude (AIN) with
fIN1 = 184 MHz and fIN2 = 187 MHz
–84–90 –78 –72 –66 –60 –54 –48 –42 –36 –30 –24 –18 –12 –6 0
SF DR/ IMD3 ( dBc AND dBFS)
INPUT AMPLITUDE (dBFS)
–140
–120
0
–20
–40
–60
–80
–100
IMD3 ( dBc)
IMD3 ( dBF S )
SFDR ( dBF S )
SFDR ( dBc)
11752-623
Figure 22. Two-Tone IMD3/SFDR vs. Input Amplitude (AIN) with
fIN1 = 449 MHz and fIN2 = 452 MHz
–84–90 –78 –72 –66 –60 –54 –48 –42 –36 –30 –24 –18 –12 –6 0
SNR/S FDR (dB)
INPUT AMPLITUDE (dBFS)
–40
–20
0
20
40
60
80
100
120
SNR (d BFS)
SNR (d Bc)
SFDR ( dBc)
SFDR ( dBF S )
11752-624
Figure 23. SNR/SFDR vs. Analog Input Level, fIN = 170.3 MHz
Data Sheet AD9680
Rev. E | Page 19 of 105
55
85
80
75
70
65
60
SNR/S FDR (dBFS )
TEMPERATURE (°C)
–48 –38 –28 –18 –8 212 22 32 42 52 62 72 82 92 102 112
SNR
SFDR
11752-625
Figure 24. SNR/SFDR vs. Temperature, fIN = 170.3 MHz
–4
–3
–2
–1
0
1
2
3
4
016000
INL (LSB)
OUT P UT CO DE
2000 4000 6000 8000 10000 12000 14000
11752-626
Figure 25. INL, fIN = 10.3 MHz
–0.4
–0.3
–0.2
–0.1
0
0.1
0.2
0.3
0.4
016000
DNL ( LSB)
OUT P UT CO DE
2000 4000 6000 8000 10000 12000 14000
11752-627
Figure 26. DNL, fIN = 15 MHz
NUMBER OF HIT S
CODE
0
200000
400000
600000
800000
1000000
1200000
N – 10
N – 9
N – 8
N – 7
N – 6
N – 5
N – 4
N – 3
N – 2
N – 1
N
N + 1
N + 2
N + 3
N + 4
N + 5
N + 6
N + 7
N + 8
N + 9
N + 10
3.45 L S B rms
11752-628
Figure 27. Input-Referred Noise Histogram
POWER (W)
TEMPERATURE (°C)
–48 –38 –28 –18 –8 212 22 32 42 52 62 72 82
3.55
3.60
3.65
3.70
3.75
3.80
3.85
3.90
3.95
4.00
11752-629
Figure 28. Power Dissipation vs. Temperature
3.3
3.4
3.5
3.6
3.7
3.8
3.9
4.0
POWER DISSIPATIO N (W )
SAMPLE RATE (MHz)
1000 1020 1040 1060 1080 1100 1120 1140 1160 1180 1200 1220 1240 1260
11752-630
Figure 29. Power Dissipation vs. fS
AD9680 Data Sheet
Rev. E | Page 20 of 105
AD9680-1000
AVDD1 = 1.25 V, AVDD1_SR = 1.25 V, AVDD2 = 2.5 V, AVDD3 = 3.3 V, DVDD = 1.25 V, DRVDD = 1.25 V, SPIVDD = 1.8 V, 1.7 V p-p
full-scale differential input, AIN = −1.0 dBFS, default SPI settings, clock divider = 2, TA = 25°C, 128k FFT sample, unless otherwise noted.
See Table 10 for recommended settings.
–130
–110
–90
–70
–50
–30
–10
0500400300200100
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= –1dBFS
SNR = 67. 2dBF S
ENOB = 10.8 BI TS
SFDR = 88dBF S
BUFF E R CONT ROL 1 = 1.
11752-100
Figure 30. Single-Tone FFT with fIN = 10.3 MHz
–130
–110
–90
–70
–50
–30
–10
0500400300200100
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= –1dBFS
SNR = 66. 6dBF S
ENOB = 10.7 BI TS
SFDR = 85dBF S
BUFF E R CONT ROL 1 = 3.
11752-101
Figure 31. Single-Tone FFT with fIN = 170.3 MHz
–130
–110
–90
–70
–50
–30
–10
0500400300200100
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= –1dBFS
SNR = 65. 3dBF S
ENOB = 10.5 BI TS
SFDR = 85dBF S
BUFF E R CONT ROL 1 = 3.
11752-102
Figure 32. Single-Tone FFT with fIN = 340.3 MHz
–130
–110
–90
–70
–50
–30
–10
0500400
300200100
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= –1dBFS
SNR = 64. 0dBF S
ENOB = 10.3 BI TS
SFDR = 82dBF S
BUFF E R CONT ROL 1 = 3.
11752-103
Figure 33. Single-Tone FFT with fIN = 450.3 MHz
0500400300200100
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= –1dBFS
SNR = 62. 6dBF S
ENOB = 10.1 BI TS
SFDR = 82dBF S
BUFFER CO NTROL 1 = 6.
11752-104
Figure 34. Single-Tone FFT with fIN = 765.3 MHz
0500400300200100
AMPLITUDE (dBFS)
FREQUENCY (MHz)
AIN = –1dBFS
SNR = 60. 5dBF S
ENOB = 9.9 BI TS
SFDR = 80dBF S
BUFF E R CONT ROL 1 = 6.
11752-105
–120
–100
–80
–60
–40
–20
0
Figure 35. Single-Tone FFT with fIN = 985.3 MHz
Data Sheet AD9680
Rev. E | Page 21 of 105
0500
400300200100
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= –1dBFS
SNR = 59. 8BFS
ENOB = 9.6 BI TS
SFDR = 79dBF S
BUFF E R CONT ROL 1 = 8.
–120
–100
–80
–60
–40
–20
0
11752-107
Figure 36. Single-Tone FFT with fIN = 1293.3 MHz
0500400300200100
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= –1dBFS
SNR = 57. 7dBF S
ENOB = 9.2 BI TS
SFDR = 70dBF S
BUFF E R CONT ROL 1 = 8.
11752-108
–120
–100
–80
–60
–40
–20
0
Figure 37. Single-Tone FFT with fIN = 1725.3 MHz
11752-506
AMPLITUDE (dBFS)
FREQUENCY (MHz)
–120
–100
–80
–60
–40
–20
0
0100 200 300 400 500
A
IN
= –1dBFS
SNR = 57. 0dBF S
ENOB = 9.1 BI TS
SFDR = 69dBF S
BUFF E R CURRE NT = 6.
Figure 38. Single-Tone FFT with fIN = 1950.3 MHz
SNR/ SFDR (dBF S)
SAMPLE RATE (MHz)
60
65
70
75
80
85
90
11752-201
700 750 800 850 900 950 1000 1050 1100
SNR (dBFS )
SF DR ( dBFS )
Figure 39. SNR/SFDR vs. fS, fIN = 170.3 MHz; Buffer Control 1 (0x018) = 3.0×
SNR/ SFDR (dBF S)
90
85
80
75
70
65
60
55
50
10.3 63.3 100.3 170.3 225.3
ANALO G I NP UT FRE QUENCY (MHz)
302.3 341.3 403.3 453.3 502.3
1.5× S FDR (dBFS )
1.5× S NR ( dBF S )
3.0× S FDR (dBFS )
3.0× S NR ( dBF S )
11752-216
Figure 40. SNR/SFDR vs. fIN; fIN < 500 MHz;
Buffer Control 1 (0x018) = 1.5× and 3.0×
50
100
60
70
80
90
476.8 554.4 593.2 670.8 748.4 826.0 903.6 981.2
ANALO G I NP UT FREQ UE NC Y (MHz)
SNR/ SFDR (dBF S)
4.0× S FDR
4.0× S NRFS
6.0× S FDR
6.0× S NRFS
11752-218
Figure 41. SNR/SFDR vs. fIN; 500 MHz < fIN < 1 GHz;
Buffer Control 1 (0x018) = 4.0× and 6.0×
AD9680 Data Sheet
Rev. E | Page 22 of 105
50
60
70
80
100
90
ANALO G I NP UT FREQUENCY (MHz)
978.5 1065.0 1142.4 1220.0 1297.3 1374.8 1452.2
SFDR
SNR
SNR/S FDR (dBFS )
11752-219
Figure 42. SNR/SFDR vs. fIN; 1 GHz < fIN < 1.5 GHz;
Buffer Control 1 (0x018) = 6.0×
50
60
70
100
90
80
ANALO G I NP UT FREQUENCY (MHz)
1513.3 1607.4 1701.6 1795.6 1889.7
SNR/S FDR (dBFS )
11752-220
SFDR
SNR
Figure 43. SNR/SFDR vs. fIN; 1.5 GHz < fIN < 2 GHz;
Buffer Control 1 (0x018) = 7.5×
AMPLITUDE (dBFS)
FREQUENCY (MHz)
–120
–100
–80
–60
–40
–20
0
0500400300200100
11752-205
AIN1 AND AIN2 = –7dBF S
SFDR = 87dBF S
IMD2 = 93dBF S
IMD3 = 87dBF S
BUFF E R CONT ROL 1 = 3.
Figure 44. Two-Tone FFT; fIN1 = 184 MHz, fIN2 = 187 MHz
AMPLITUDE (dBFS)
FREQUENCY (MHz)
–120
–100
–80
–60
–40
–20
0
0500400300200100
11752-206
A
IN1
AND A
IN2
= –7dBFS
SFDR = 88dBF S
IMD2 = 93dBF S
IMD3 = 88dBF S
BUFF E R CONT ROL 1 = 4.
Figure 45. Two-Tone FFT; fIN1 = 338 MHz, fIN2 = 341 MHz
–84–90 –78 –72 –66 –60 –54 –48 –42 –36 –30 –24 –18 –12 –6
SFDR/I M D3 ( dBc AND dBFS)
INPUT AMPLITUDE (dBFS)
–140
–120
–100
–80
–60
–40
–20
20
0
11752-207
SF DR ( dBc)
SF DR ( dBFS )
IM D3 ( dBc)
IM D3 ( dBFS )
Figure 46. Two-Tone SFDR/IMD3 vs. Input Amplitude (AIN) with
fIN1 = 184 MHz and fIN2 = 187 MHz
–84–90 –78 –72 –66 –60 –54 –48 –42 –36 –30 –24 –18 –12 –6
SNR/S FDR (dBc AND dBFS)
INPUT AMPLITUDE (dBFS)
–140
–120
–100
–80
–60
–40
–20
20
0
11752-208
SF DR ( dBc)
SF DR ( dBFS )
IM D3 ( dBc)
IM D3 ( dBFS )
Figure 47. Two-Tone IMD3/SFDR vs. Input Amplitude (AIN) with
fIN1 = 338 MHz and fIN2 = 341 MHz
Data Sheet AD9680
Rev. E | Page 23 of 105
–84–90 –78 –72 –66 –60 –54 –48 –42 –36 –30 –24 –18 –12 –6 0
SNR/ SFDR (dB)
INPUT AMPLITUDE (dBFS)
–20
–10
0
10
110
100
90
80
70
60
50
40
30
20
11752-209
SF DR ( dBc)
SF DR ( dBFS )
SNR (dBFS )
SNR (dBc)
Figure 48. SNR/SFDR vs. Analog Input Level, fIN = 170.3 MHz
SNR/S FDR (dBFS )
TEMPERATURE (°C)
50
100
80
90
70
60
–50 –40 –30 –20 –10 010 20 30 40 50 60 70 80 90
SFDR
SNR
11752-210
Figure 49. SNR/SFDR vs. Temperature, fIN = 170.3 MHz
INL (LSB)
OUTPUT CODE
–3
3
2
1
0
–1
–2
016000
14000
1200010000
80006000
40002000
11752-211
Figure 50. INL, fIN = 10.3 MHz
DNL (LSB)
OUTPUT CODE
–0.6
0.6
0.4
0.2
0
–0.2
–0.4
0160001400012000
1000080006000
40002000
11752-212
Figure 51. DNL, fIN = 15 MHz
AD9680 Data Sheet
Rev. E | Page 24 of 105
NUMBER O F HI TS
CODE
0
25000
20000
15000
10000
5000
N + 6
N + 5N + 4
N + 3N + 2
N + 1
NN – 1
N – 2N – 3
N – 4
N – 5N – 6
11752-213
2.63 LSB rms
Figure 52. Input-Referred Noise Histogram
POWER DISSIPATI O N (W)
TEMPERATURE (°C)
3.15
3.40
3.35
3.30
3.25
3.20
–50 –40 –30 –20 –10 010 20 30 40 50 60 70 80 90
11752-214
L = 4
M = 2
F = 1
Figure 53. Power Dissipation vs. Temperature
POWER DISSIPATI O N (W)
SAMPLE RATE (MHz)
2.90
2.95
3.00
3.05
3.10
3.15
3.20
3.25
3.30
3.35
3.40
11752-215
700 750 800 850 900 950 1000 1050 1100
L = 4, M = 2, F = 1
Figure 54. Power Dissipation vs. fS
Data Sheet AD9680
Rev. E | Page 25 of 105
AD9680-820
AVDD1 = 1.25 V, AVDD1_SR = 1.25 V, AVDD2 = 2.5 V, AVDD3 = 3.3 V, DVDD = 1.25 V, DRVDD = 1.25 V, SPIVDD = 1.8 V, 1.7 V p-p
full-scale differential input, AIN = −1.0 dBFS, default SPI settings, clock divider = 2, TA = 25°C, 128k FFT sample, unless otherwise noted.
See Table 10 for recommended settings.
11752-507
AMPLITUDE (dBFS)
FREQUENCY (MHz)
–120
–100
–80
–60
–40
–20
0
082 164 246 328 410
AIN = –1dBFS
SNR = 67. 2dBF S
ENOB = 10.9BI TS
SF DR = 89dBF S
BUFFER CO NTROL 1 = 1.
Figure 55. Single-Tone FFT with fIN = 10.3 MHz
11752-508
AMPLITUDE (dBFS)
FREQUENCY (MHz)
–120
–100
–80
–60
–40
–20
0
082 164 246 328 410
A
IN
= –1d BFS
SNR = 67.0dBFS
ENO B = 10. 8 BIT S
SF DR = 83dBFS
BUFFER CO NTRO L 1 = 2.
Figure 56. Single-Tone FFT with fIN = 170.3 MHz
11752-509
AMPLITUDE (dBFS)
FREQUENCY (MHz)
–120
–100
–80
–60
–40
–20
0
082 164 246 328 410
A
IN
= –1d BFS
SNR = 66.5dBFS
ENO B = 10. 7 BIT S
SF DR = 86dBFS
BUFFER CO NTRO L 1 = 3.
Figure 57. Single-Tone FFT with fIN = 340.3 MHz
11752-510
AMPLITUDE (dBFS)
FREQUENCY (MHz)
–120
–100
–80
–60
–40
–20
0
082 164 246 328 410
A
IN
= –1dBFS
SNR = 65. 1dBF S
ENOB = 10.5 BI TS
SF DR = 79dBF S
BUFFER CO NTROL 1 = 6.
Figure 58. Single-Tone FFT with fIN = 450.3 MHz
11752-511
AMPLITUDE (dBFS)
FREQUENCY (MHz)
–120
–100
–80
–60
–40
–20
0
082 164 246 328 410
A
IN
= –1d BFS
SNR = 64.0dBFS
ENO B = 10. 3 BIT S
SF DR = 79dBFS
BUFFER CO NTRO L 1 = 6.
Figure 59. Single-Tone FFT with fIN = 765.3 MHz
11752-512
AMPLITUDE (dBFS)
FREQUENCY (MHz)
–120
–100
–80
–60
–40
–20
0
082 164 246 328 410
A
IN
= –1d BFS
SNR = 63.4dBFS
ENO B = 10. 1 BIT S
SF DR = 74dBFS
BUFFER CO NTRO L 1 = 8.
Figure 60. Single-Tone FFT with fIN = 985.3 MHz
AD9680 Data Sheet
Rev. E | Page 26 of 105
11752-513
AMPLITUDE (dBFS)
FREQUENCY (MHz)
–120
–100
–80
–60
–40
–20
0
082 164 246 328 410
AIN = –1dBFS
SNR = 62. 0dBF S
ENOB = 9.9 BI TS
SFDR = 76dBF S
BUFF E R CONT ROL 1 = 6.
Figure 61. Single-Tone FFT with fIN = 1205.3 MHz
11752-514
AMPLITUDE (dBFS)
FREQUENCY (MHz)
–120
–100
–80
–60
–40
–20
0
082 164 246 328 410
A
IN
= –1dBFS
SNR = 60. 5dBF S
ENOB = 9.5 BI TS
SFDR = 68dBF S
BUFF E R CONT ROL 1 = 7.
Figure 62. Single-Tone FFT with fIN = 1720.3 MHz
11752-515
AMPLITUDE (dBFS)
FREQUENCY (MHz)
–120
–100
–80
–60
–40
–20
0
082 164 246 328 410
A
IN
= –1d BFS
SNR = 59.7dBFS
ENO B = 9. 5 BIT S
SF DR = 69dBFS
BUFFER CO NTRO L 1 = 8.
Figure 63. Single-Tone FFT with fIN = 1950.3 MHz
11752-516
SNR/S FDR (dBFS )
SAMPLE RATE (MHz)
50
55
60
65
70
75
80
85
90
500 550 600 650 700 750 800 850 900
SNR
SFDR
Figure 64. SNR/SFDR vs. fS, fIN = 170.3 MHz;
Buffer Control 1 (0x018) = 3.0×
11752-517
SNR/S FDR (dBFS )
ANALOG INPUT FRE QUENCY ( M Hz )
50
55
60
65
70
75
80
85
90
95
10.3
65.5
95.3
125.4
150.3
170.3
180.3
210.5
240.3
270.3
301.3
330.3
340.7
360.3
390.3
420.3
450.3
SFDR
SNR
Figure 65. SNR/SFDR vs. fIN; fIN < 450 MHz;
Buffer Control 1 (0x018) = 3.0×
11752-518
SNR/ SFDR (dBF S)
ANALOG INPUT FRE QUENCY ( M Hz )
50
55
60
65
70
75
80
85
450.3 480.3 510.3 515.3 610.3 766.3 810.3 985.3
SFDR
SNR
Figure 66. SNR/SFDR vs. fIN; 450 MHz < fIN < 1 GHz;
Buffer Control 1 (0x018) = 6.5×
Data Sheet AD9680
Rev. E | Page 27 of 105
11752-519
SNR/S FDR (dBFS )
ANALOG INPUT FRE QUENCY ( M Hz )
50
55
60
65
70
75
80
985.3 1022.3 1110.3 1205.3 1315.3 1420.3 1510.3
SFDR
SNR
Figure 67. SNR/SFDR vs. fIN; 1 GHz < fIN < 1.5 GHz;
Buffer Control 1 (0x018) = 6.5×
11752-520
SNR/S FDR (dBFS )
ANALO G I NP UT FRE QUENCY ( M Hz )
50
55
60
65
70
75
1510.3 1600.3 1720.3 1810.3 1920.3 1950.3
SFDR
SNR
Figure 68. SNR/SFDR vs. fIN; 1.5 GHz < fIN < 2 GHz;
Buffer Control 1 (0x018) = 8.5×
11752-529
AMPLITUDE (dBFS)
FREQUENCY (MHz)
–120
–100
–80
–60
–40
–20
0
082 164 246 328 410
AIN1 AND AI N2 = –7dBF S
SFDR = 90dBF S
IMD2 = 90dBF S
IMD3 = 91dBF S
BUFF E R CURRE NT = 3.
Figure 69. Two-Tone FFT; fIN1 = 184 MHz, fIN2 = 187 MHz
11752-527
AMPLITUDE (dBFS)
FREQUENCY (MHz)
–120
–100
–80
–60
–40
–20
0
082 164 246 328 410
AIN1 AND AI N2 = –7dBF S
SFDR = 87dBF S
IMD2 = 92dBF S
IMD3 = 87dBF S
BUFF E R CURRE NT = 3.
Figure 70. Two-Tone FFT; fIN1 = 338 MHz, fIN2 = 341 MHz
11752-528
SFDR/I M D3 ( dBc AND dBFS)
INPUT AMPLITUDE (dBFS)
–120
–100
–80
–60
–40
–20
0
–87 –81 –75 –69 –63 –57 –51 –45 –39 –33 –27 –21 –15 –9
IMD3 (dBc)
IMD3 (dBFS)
SFDR (dBc)
SFDR (dBFS)
Figure 71. Two-Tone SFDR/IMD3 vs. Input Amplitude (AIN) with
fIN1 = 184 MHz and fIN2 = 187 MHz
11752-535
SF DR/ IMD3 ( dBc AND dBFS)
INPUT AMPLITUDE (dBFS)
–120
–100
–80
–60
–40
–20
0
–87 –81 –75 –69 –63 –57 –51 –45 –39 –33 –27 –21 –15 –9
IMD3 (dBc)
IMD3 (dBFS)
SFDR (dBc)
SFDR (dBFS)
Figure 72. Two-Tone IMD3/SFDR vs. Input Amplitude (AIN) with
fIN1 = 338 MHz and fIN2 = 341 MHz
AD9680 Data Sheet
Rev. E | Page 28 of 105
11752-521
SNR/S FDR (dBc AND dBFS)
INPUT AMPLITUDE (dBFS)
–30
–15
0
15
30
45
60
75
90
105
120
–95
–90
–85
–80
–75
–70
–65
–60
–55
–50
–45
–40
–35
–30
–25
–20
–15
–10
–5
0
SNR (dBc)
SNR (dBFS )
SF DR ( dBc)
SF DR ( dBFS )
Figure 73. SNR/SFDR vs. Analog Input Level, fIN = 170.3 MHz
11752-533
SNR/S FDR (dBFS )
TEMPERATURE (°C)
60
65
70
75
80
85
90
–45 –30 –15 –5 515 25 45 65 85
SNR (d BFS)
SFDR ( dBF S )
Figure 74. SNR/SFDR vs. Temperature, fIN = 170.3 MHz
11752-534
INL (LSB)
OUT P UT CO DE
–2.0
–1.5
–1.0
–0.5
0
0.5
1.0
1.5
2.0
2.5
02000 4000 6000 8000 10000 12000 14000 16000
Figure 75. INL, fIN = 10.3 MHz
11752-530
DNL ( LSB)
OUT P UT CO DE
–0.30
–0.25
–0.20
–0.15
–0.10
–0.05
0
0.05
0.10
0.15
0.20
0.25
02000 4000 6000 8000 10000 12000 14000 16000
Figure 76. DNL, fIN = 15 MHz
Data Sheet AD9680
Rev. E | Page 29 of 105
11752-531
NUMBER OF HIT S
CODE
0
200000
400000
600000
800000
1000000
1200000
1400000
1600000
N – 10
N – 9
N – 8
N – 7
N – 6
N – 5
N – 4
N – 3
N – 2
N – 1
N
N + 1
N + 2
N + 3
N + 4
N + 5
N + 6
N + 7
N + 8
N + 9
N + 10
2.46 L S B rms
Figure 77. Input-Referred Noise Histogram
11752-532
POWER (W)
TEMPERATURE (°C)
2.76
2.78
2.80
2.82
2.84
2.86
2.88
2.90
–45 –30 –15 –5 515 25 45 65 85
Figure 78. Power Dissipation vs. Temperature
11752-522
POWER (W)
SAMPLE RATE (MHz)
2.5
2.6
2.7
2.8
2.9
3.0
3.1
500
525
550
575
600
625
650
675
700
725
750
775
800
825
850
875
900
Figure 79. Power Dissipation vs. fS ; L = 4, M = 2, F = 1 for fS ≥ 625 MSPS and
L = 2, M = 2, F = 2 for fS < 625 MSPS (Default SPI)
AD9680 Data Sheet
Rev. E | Page 30 of 105
AD9680-500
AVDD1 = 1.25 V, AVDD1_SR = 1.25 V, AVDD2 = 2.5 V, AVDD3 = 3.3 V, DVDD = 1.25 V, DRVDD = 1.25 V, SPIVDD = 1.8 V, 2.06 V p-p
full-scale differential input, AIN = −1.0 dBFS, default SPI settings, clock divider = 2, TA = 25°C, 128k FFT sample, unless otherwise noted.
See Table 10 for recommended settings.
025 50 75 100 125 150 175 200 225 250
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= −1dBFS
SNR = 68. 9dBF S
ENOB = 10.9 BI TS
SFDR = 83dBF S
BUFFER CO NTROL 1 = 2.
–140
–120
–100
–80
–60
–40
–20
0
11752-132
Figure 80. Single-Tone FFT with fIN = 10.3 MHz
–140
–120
–100
–80
–60
–40
–20
0
025 50 75 100 125 150 175 200 225 250
AMPLITUDE (dBFS)
FREQUENCY (MHz)
AIN = −1dBFS
SNR = 68. 9dBF S
ENOB = 11 BITS
SFDR = 88dBF S
BUFF E R CONT ROL 1 = 2.0×
11752-133
Figure 81. Single-Tone FFT with fIN = 170.3 MHz
025 50 75 100 125 150 175 200 225 250
–140
–120
–100
–80
–60
–40
–20
0
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= −1dBFS
SNR = 68. 5dBF S
ENOB = 10.9 BI TS
SFDR = 83dBF S
BUFF E R CONT ROL 1 = 4.5×
11752-134
Figure 82. Single-Tone FFT with fIN = 340.3 MHz
025 50 75 100 125 150 175 200 225 250
–140
–120
–100
–80
–60
–40
–20
0
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= −1dBFS
SNR = 67. 8dBF S
ENOB = 10.8 BI TS
SFDR = 83dBF S
BUFF E R CONT ROL 1 = 4.5×
11752-135
Figure 83. Single-Tone FFT with fIN = 450.3 MHz
–140
–120
–100
–80
–60
–40
–20
0
025 50 75 100 125 150 175 200 225 250
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= −1dBFS
SNR = 64. 7dBF S
ENOB = 10.4 BI TS
SFDR = 80dBF S
BUFF E R CONT ROL 1 = 5.
11752-136
Figure 84. Single-Tone FFT with fIN = 765.3 MHz
–140
–120
–100
–80
–60
–40
–20
0
025 50 75 100 125 150 175 200 225 250
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= −1dBFS
SNR = 64. 0dBF S
ENOB = 10.3 BI TS
SFDR = 76dBF S
BUFF E R CONT ROL 1 = 5.
11752-137
Figure 85. Single-Tone FFT with fIN = 985.3 MHz
Data Sheet AD9680
Rev. E | Page 31 of 105
–140
–120
–100
–80
–60
–40
–20
0
025 50 75 100 125 150 175 200 225 250
AMPLITUDE (dBFS)
FREQUENCY (MHz)
AIN = −1dBFS
SNR = 63. 0dBF S
ENOB = 10.0 BI TS
SFDR = 69dBF S
BUFF E R CONT ROL 1 = 8.
11752-138
Figure 86. Single-Tone FFT with fIN = 1310.3 MHz
–140
–120
–100
–80
–60
–40
–20
0
025 50 75 100 125 150 175 200 225 250
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= −1dBFS
SNR = 61. 5dBF S
ENOB = 9.8 BI TS
SFDR = 69dBF S
BUFF E R CONT ROL 1 = 8.
11752-139
Figure 87. Single-Tone FFT with fIN = 1710.3 MHz
–140
–120
–100
–80
–60
–40
–20
0
025 50 75 100 125 150 175 200 225 250
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN
= −1dBFS
SNR = 60. 8dBF S
ENOB = 9.6 BI TS
SFDR = 68dBF S
BUFF E R CONT ROL 1 = 8.
11752-140
Figure 88. Single-Tone FFT with fIN = 1950.3 MHz
60
65
70
75
80
85
90
95
300 320 340 360 380 400
SAMPLE FREQUENCY (MHz)
SNR/ SFDR (dBF S )
420 440 460 480 500 530 550
SFDR
SNR
11752-141
Figure 89. SNR/SFDR vs. fS, fIN = 170.3 MHz; Buffer Control 1 = 2.0×
50
60
70
80
90
100
10.3 95.3 150.3 180.3 240.3 301.3 340.7 390.3 450.3
SNR/S FDR (dBFS )
ANALO G I NP UT FREQUENCY (MHz)
11752-142
2.0× S NR
2.0× S FDR
4.5× S NR
4.5× S FDR
Figure 90. SNR/SFDR vs. fIN; fIN < 500 MHz;
Buffer Control 1 (0x018) = 2.0× and 4.5×
50
60
70
80
90
100
SNR/ SFDR (dBF S )
450.3 480.3 510.3 515.3 610.3 765.3 810.3 985.3 1010.3
ANALO G I NP UT FREQUENCY (MHz)
4.0× S NR
4.0× S FDR
8.0× S NR
8.0× S FDR
11752-143
Figure 91. SNR/SFDR vs. fIN; 500 MHz < fIN < 1 GHz;
Buffer Control 1 (0x018) = 4.0× and 8.0×
AD9680 Data Sheet
Rev. E | Page 32 of 105
SNR/S FDR (dBFS )
50
60
65
55
70
75
80
1010.3 1205.3 1410.3 1600.3 1810.3 1950.3
ANALOG INPUT FREQUENCY (MHz)
7.0× S NR
7.0× S FDR
8.0× S NR
8.0× S FDR
11752-144
Figure 92. SNR/SFDR vs. fIN; 1 GHz < fIN < 2 GHz;
Buffer Control 1 (0x018) = 7.0× and 8.0×
–120
–100
–80
–60
–40
–20
0
050 100 150 200 250
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN1
AND A
IN2
= –7dBFS
SFDR = 88dBF S
IMD2 = 94dBF S
IMD3 = 88dBF S
BUFF E R CONT ROL 1 = 2.0×
11752-146
Figure 93. Two-Tone FFT; fIN1 = 184 MHz, fIN2 = 187 MHz
–120
–100
–80
–60
–40
–20
0
050 100 150 200 250
AMPLITUDE (dBFS)
FREQUENCY (MHz)
A
IN1
AND A
IN2
= –7dBFS
SFDR = 88dBF S
IMD2 = 88dBF S
IMD3 = 89dBF S
BUFF E R CONT ROL 1 = 4.5×
11752-147
Figure 94. Two-Tone FFT; fIN1 = 338 MHz, fIN2 = 341 MHz
–120
–100
–80
–60
–40
–20
0
90
84
78
72
66
60
54
48
42
36
30
24
18
12
SF DR/IM D3 ( dBc AND dBFS)
INPUT AMPLI T UDE (dBFS)
SFDR ( dBc)
SFDR ( dBF S )
IMD3 (dBc)
IMD3 (dBFS)
11752-148
Figure 95. Two-Tone SFDR/IMD3 vs. Input Amplitude (AIN) with
fIN1 = 184 MHz and fIN2 = 187 MHz
–120
–100
–80
–60
–40
–20
0
–90 –81 –72 –63 –54 –45 –36 –27 –18 –9
SF DR/IM D3 ( dBc AND dBF S )
AMPLITUDE (dBFS)
11752-149
SFDR ( dBc)
SFDR ( dBF S )
IMD3 (dBc)
IMD3 (dBFS)
Figure 96. Two-Tone IMD3/SFDR vs. Input Amplitude (AIN) with
fIN1 = 338 MHz and fIN2 = 341 MHz
–20
–10
0
10
20
30
40
50
60
70
80
90
100
110
–90 –80 –70 –60 –50 –40 –30 –20 –10
0
SNR/ SFDR (dBc AND d BFS)
INPUT AMPLI T UDE (dBFS)
11752-150
SFDR ( dBF S )
SNR (d BFS)
SFDR ( dBc)
SNR (d Bc)
Figure 97. SNR/SFDR vs. Analog Input Level, fIN = 170.3 MHz
Data Sheet AD9680
Rev. E | Page 33 of 105
11752-151
65
70
75
80
85
90
95
–40 –15 10 35 60 85
SNR/ SFDR (dBF S )
TEMPERATURE (°C)
SFDR
SNR
Figure 98. SNR/SFDR vs. Temperature, fIN = 170.3 MHz
–2.0
–1.5
–1.0
–0.5
0
0.5
1.0
1.5
2.0
2.5
3.0
02000 4000 6000 8000 10000 12000 14000 16000
INL (LSB)
OUT P UT CO DE
11752-152
Figure 99. INL, fIN = 10.3 MHz
–0.8
–0.6
–0.4
–0.2
0
0.2
0.4
0.6
0.8
02000 4000 6000 8000 10000 12000 14000 16000
DNL (LSB)
OUT P UT CO DE
11752-153
Figure 100. DNL, fIN = 15 MHz
0
100000
200000
300000
400000
500000
600000
700000
800000
900000
N – 10
N – 9
N – 8
N – 7
N – 6
N – 5
N – 4
N – 3
N – 2
N – 1
N
N + 1
N + 2
N + 3
N + 4
N + 5
N + 6
N + 7
N + 8
N + 9
N + 10
NUMBER O F HI TS
OUT P UT CO DE
2.06 L S B RM S
11752-154
Figure 101. Input-Referred Noise Histogram
2.20
2.22
2.24
2.26
2.28
2.30
2.32
–45 –35 –5 15 25 45 65 85
POWER (W)
TEMPERATURE (°C)
11752-155
L = 4
M = 2
F = 1
Figure 102. Power Dissipation vs. Temperature
1.87
1.92
1.97
2.02
2.07
2.12
2.17
2.22
2.27
2.32
2.37
300 320 340 360 380 400 420 440 460 480 500 520 540
POWER (W)
SAMPLE RAT E (MHz)
11752-156
L = 4, M = 2, F = 1
L = 2, M = 2, F = 2
Figure 103. Power Dissipation vs. fS
AD9680 Data Sheet
Rev. E | Page 34 of 105
EQUIVALENT CIRCUITS
A
IN
CONTROL
(SPI)
10pF
VIN+x
VIN–x
AVDD3
AVDD3
AVDD3
V
CM
BUFFER
400Ω
200Ω
200Ω
67Ω
28Ω
200Ω
200Ω
67Ω
28Ω
AVDD3
AVDD3
1.5pF3pF
1.5pF3pF
11752-011
Figure 104. Analog Inputs
CLK+
CLK–
AVDD1
25Ω
AVDD1
25Ω
20kΩ20kΩ
V
CM
= 0.85V
11752-012
Figure 105. Clock Inputs
SYSREF+
AVDD1_SR
1kΩ
SYSREF–
AVDD1_SR
1kΩ
20kΩ
20kΩ
LEVEL
TRANSLATOR VCM = 0. 85V
11752-013
Figure 106. SYSREF± Inputs
DRVDD
DRGND
DRVDD
DRGND
OUTPUT
DRIVER
EMPHASIS/SWING
CONTROL (SPI)
DATA+
DATA–
SERDOUTx+
x = 0, 1, 2, 3
SERDOUTx–
x = 0, 1, 2, 3
11752-014
Figure 107. Digital Outputs
20kΩ
20kΩ
LEVEL
TRANSLATOR VCM = 0. 85V
SYNCI NB± P IN
CONTROL (SPI)
SYNCINB+
DVDD
1kΩ
DGND
SYNCINB–
DVDD
1kΩ
DGND
VCM
11752-015
Figure 108. SYNCINB± Inputs
30kΩ
SPIVDD
ESD
PROTECTED
ESD
PROTECTED
1kΩ
SPIVDD
SCLK
11752-016
Figure 109. SCLK Input
Data Sheet AD9680
Rev. E | Page 35 of 105
30kΩ
ESD
PROTECTED
ESD
PROTECTED
1kΩ
SPIVDD
CSB
11752-017
Figure 110. CSB Input
30kΩ
ESD
PROTECTED
ESD
PROTECTED
1kΩ
SPIVDD
SPIVDD
SDI
SDIO
SDO
11752-018
Figure 111. SDIO Input
ESD
PROTECTED
ESD
PROTECTED
SPIVDD
FD_A/FD_B
FD
JESD LMFC
FD_x P I N CONT ROL ( S P I)
JESD SY NC~
TE M P E RATURE DI ODE
(F D_A ONLY )
11752-019
Figure 112. FD_A/FD_B Outputs
ESD
PROTECTED
ESD
PROTECTED
1kΩ
SPIVDD
PDWN/
STBY
PDWN
CONTROL (SPI)
11752-020
Figure 113. PDWN/STBY Input
ESD
PROTECTED
ESD
PROTECTED
V_1P0
V_1P0 P IN
CONTROL (SPI)
AVDD2
11752-021
Figure 114. V_1P0 Input/Output
AD9680 Data Sheet
Rev. E | Page 36 of 105
THEORY OF OPERATION
The AD9680 has two analog input channels and four JESD204B
output lane pairs. The ADC is designed to sample wide bandwidth
analog signals of up to 2 GHz. The AD9680 is optimized for wide
input bandwidth, high sampling rate, excellent linearity, and
low power in a small package.
The dual ADC cores feature a multistage, differential pipelined
architecture with integrated output error correction logic. Each
ADC features wide bandwidth inputs supporting a variety of
user-selectable input ranges. An integrated voltage reference
eases design considerations.
The AD9680 has several functions that simplify the AGC
function in a communications receiver. The programmable
threshold detector allows monitoring of the incoming signal
power using the fast detect output bits of the ADC. If the input
signal level exceeds the programmable threshold, the fast detect
indicator goes high. Because this threshold indicator has low
latency, the user can quickly turn down the system gain to avoid
an overrange condition at the ADC input.
The Subclass 1 JESD204B-based high speed serialized output data
lanes can be configured in one-lane (L = 1), two-lane (L = 2),
and four-lane (L = 4) configurations, depending on the sample
rate and the decimation ratio. Multiple device synchronization
is supported through the SYSREF± and SYNCINB± input pins.
ADC ARCHITECTURE
The architecture of the AD9680 consists of an input buffered
pipelined ADC. The input buffer is designed to provide a
termination impedance to the analog input signal. This
termination impedance can be changed using the SPI to meet
the termination needs of the driver/amplifier. The default
termination value is set to 400 Ω. The equivalent circuit diagram of
the analog input termination is shown in Figure 104. The input
buffer is optimized for high linearity, low noise, and low power.
The input buffer provides a linear high input impedance (for
ease of drive) and reduces kickback from the ADC. The buffer is
optimized for high linearity, low noise, and low power. The
quantized outputs from each stage are combined into a final
14-bit result in the digital correction logic. The pipelined
architecture permits the first stage to operate with a new input
sample; at the same time, the remaining stages operate with the
preceding samples. Sampling occurs on the rising edge of the clock.
ANALOG INPUT CONSIDERATIONS
The analog input to the AD9680 is a differential buffer. The
internal common-mode voltage of the buffer is 2.05 V. The
clock signal alternately switches the input circuit between
sample mode and hold mode. When the input circuit is switched
into sample mode, the signal source must be capable of charging
the sample capacitors and settling within one-half of a clock cycle.
A small resistor, in series with each input, can help reduce the peak
transient current injected from the output stage of the driving
source. In addition, low Q inductors or ferrite beads can be placed
on each leg of the input to reduce high differential capacitance at
the analog inputs and, thus, achieve the maximum bandwidth of
the ADC. Such use of low Q inductors or ferrite beads is required
when driving the converter front end at high IF frequencies.
Either a differential capacitor or two single-ended capacitors
can be placed on the inputs to provide a matching passive network.
This ultimately creates a low-pass filter at the input, which limits
unwanted broadband noise. For more information, refer to the
AN-742 Application Note, the AN-827 Application Note, and
the Analog Dialogue articleTransformer-Coupled Front-End
for Wideband A/D Converters” (Volume 39, April 2005). In
general, the precise values depend on the application.
For best dynamic performance, the source impedances driving
VIN+x and VIN−x must be matched such that common-mode
settling errors are symmetrical. These errors are reduced by the
common-mode rejection of the ADC. An internal reference
buffer creates a differential reference that defines the span of the
ADC core.
Maximum SNR performance is achieved by setting the ADC
to the largest span in a differential configuration. In the case
of the AD9680, the available span is programmable through
the SPI port from 1.46 V p-p to 2.06 V p-p differential, with
1.58 V p-p differential being the default for the AD9680-1250,
1.70 V p-p differential being the default for the AD9680-1000
and AD9680-820, and 2.06 V p-p differential being the default
for the AD9680-500.
Differential Input Configurations
There are several ways to drive the AD9680, either actively or
passively. However, optimum performance is achieved by
driving the analog input differentially.
For applications where SNR and SFDR are key parameters,
differential transformer coupling is the recommended input
configuration (see Figure 115 and Table 9) because the noise
performance of most amplifiers is not adequate to achieve the
true performance of the AD9680.
For low to midrange frequencies, a double balun or double
transformer network (see Figure 115 and Table 9) is recom-
mended for optimum performance of the AD9680. For higher
frequencies in the second or third Nyquist zones, it is better
to remove some of the front-end passive components to ensure
wideband operation (see Figure 115 and Table 9).
Data Sheet AD9680
Rev. E | Page 37 of 105
ADC
R1
R2
R1 0.1µF
0.1µF
0.1µF C2
R3
R3
BALUN
NOTES
1. SEE TABLE 9 F OR COM P ONENT VALUES.
R2
C1
C1
11752-168
Figure 115. Differential Transformer-Coupled Configuration for AD9680
Table 9. Differential Transformer-Coupled Input Configuration Component Values
Device Frequency Range Transformer R1 (Ω) R2 (Ω) R3 (Ω) C1 (pF) C2 (pF)
AD9680-500 DC to 250 MHz ETC1-1-13 10 50 10 4 2
250 MHz to 2 GHz BAL-0006/BAL-0006SMG 10 50 10 4 2
AD9680-820 DC to 410 MHz ETC1-1-13 10 50 10 4 2
410 MHz to 2 GHz BAL-0006/BAL-0006SMG 10 50 10 4 2
AD9680-1000 DC to 500 MHz ETC1-1-13/BAL-0006SMG 25 25 10 4 2
500 MHz to 2 GHz BAL-0006/BAL-0006SMG 25 25 0 Open Open
AD9680-1250 DC to 625 MHz BAL-0006SMG 10 50 15 4 2
625 MHz to 2 GHz BAL-0006SMG 10 50 0 Open Open
Input Common Mode
The analog inputs of the AD9680 are internally biased to the
common mode as shown in Figure 116. The common-mode
buffer has a limited range in that the performance suffers greatly
if the common-mode voltage drops by more than 100 m V.
Therefore, in dc-coupled applications, set the common-mode
voltage to 2.05 V, ±100 mV to ensure proper ADC operation.
The full-scale voltage setting must be at a 1.7 V p-p differential
if running in a dc-coupled application.
Analog Input Buffer Controls and SFDR Optimization
The AD9680 input buffer offers flexible controls for the analog
inputs, such as input termination, buffer current, and input full-
scale adjustment. All the available controls are shown in Figure 116.
10pF
VIN+x
VIN–x
AVDD3
AVDD3
AVDD3
V
CM
BUFFER
400Ω
200Ω
200Ω
67Ω
28Ω
200Ω
200Ω
67Ω
28Ω
AVDD3
AVDD3
1.5pF3pF
1.5pF3pF
AIN CO NTRO L
SPI REGISTERS
(0x008, 0x015,
0x016, 0x018,
0x019, 0x01A,
0x11A, 0x934,
0x935)
11752-169
Figure 116. Analog Input Controls
Using the 0x018, 0x019, 0x01A, 0x11A, 0x934, and 0x935 registers,
the buffer behavior on each channel can be adjusted to optimize the
SFDR over various input frequencies and bandwidths of interest.
Input Buffer Control Registers (0x018, 0x019, 0x01A,
0x935, 0x934, 0x11A)
The input buffer has many registers that set the bias currents and
other settings for operation at different frequencies. These bias
currents and settings can be changed to suit the input frequency
range of operation. Register 0x018 controls the buffer bias current
to help with the kickback from the ADC core. This setting can be
scaled from a low setting of 1.0× to a high setting of 8.5×. The
default setting is 3.0× for the AD9680-1000 and AD9680-820,
and 2.0× for the AD9680-500. These settings are sufficient for
operation in the first Nyquist zone for the products. When the
input buffer current in Register 0x018 is set, the amount of
current required by the AVDD3 supply changes. This relationship
is shown in Figure 117. For a complete list of buffer current
settings, see Table 39.
AD9680 Data Sheet
Rev. E | Page 38 of 105
I
AVDD3
(mA)
BUFFER CONTROL 1 SETTING
1.5× 2. 3.5× 4. 5.5× 6. 7. 8.5×
11752-341
50
100
150
200
250
300
AD9680-1250,
AD9680-1000,
AND
AD9680-820
AD9680-500
Figure 117. IAVDD3 vs. Buffer Control 1 Setting in Register 0x018
The 0x019, 0x01A, 0x11A, and 0x935 registers offer secondary
bias controls for the input buffer for frequencies >500 MHz.
Register 0x934 can be used to reduce input capacitance to achieve
wider signal bandwidth but may result in slightly lower linearity
and noise performance. These register settings do not impact the
AVDD3 power as much as Register 0x018 does. For frequencies
<500 MHz, it is recommended to use the default settings for
these registers. Table 10 shows the recommended values for the
buffer current control registers for various speed grades.
Register 0x11A is used when sampling in higher Nyquist zones
(>500 MHz for the AD9680-1000). This setting enables the ADC
sampling network to optimize the sampling and settling times
internal to the ADC for high frequency operation. For frequencies
greater than 500 MHz, it is recommended to operate the ADC core
at a 1.46 V full-scale setting irrespective of the speed grade. This
setting offers better SFDR without any significant penalty in SNR.
Figure 118, Figure 119, and Figure 120 show the SFDR vs.
analog input frequency for various buffer settings for the
AD9680-1250. The recommended settings shown in Table 10
were used to take the data while changing the contents of
Register 0x018 only.
60
65
70
75
80
85
SFDR (dBFS)
INPUT F RE QUENCY ( M Hz )
10.3 147.3 212.3 290.3 355.3 433.3 511.3 589.3 667.3
2.5×
3.5×
4.5×
5.5×
11752-631
Figure 118. Buffer Current Sweeps, AD9680-1250 (SFDR vs. IBUFF);
fIN < 500 MHz; Front-End Network Shown in Figure 115
55
60
65
70
75
80
SFDR ( dBF S )
INPUT F RE QUENCY ( M Hz )
602.3 680.3 758.3 836.3 914.3 992.3 1070.3 1148.3 1226.3
3.5×
4.5×
5.5×
6.5×
11752-632
Figure 119. Buffer Current Sweeps, AD9680-1250 (SFDR vs. IBUFF);
600 MHz < fIN < 1300 MHz; Front-End Network Shown in Figure 115
58
60
64
68
72
62
66
70
74
76
SFDR ( dBF S )
INPUT F RE QUENCY ( M Hz )
6.5×
7.5×
8.5×
1304.3 1408.3 1512.3 1616.3 1720.3 1824.3 1928.3
11752-633
Figure 120. Buffer Current Sweeps, AD9680-1250 (SFDR vs. IBUFF);
1300 MHz < fIN < 2000 MHz; Front-End Network Shown in Figure 115
Figure 121, Figure 122, and Figure 123 show the SFDR vs.
analog input frequency for various buffer settings for the
AD9680-1000. The recommended settings shown in Table 10
were used to take the data while changing the contents of
Register 0x018 only.
50
55
60
65
70
75
80
85
90
10 60 110 160 210 260 310 360 410 460
SFDR (dBFS)
ANALO G I NP UT FRE QUENCY (MHz)
1.5×
3.0×
4.5×
11752-170
Figure 121. Buffer Current Sweeps, AD9680-1000 (SFDR vs. IBUFF);
fIN < 500 MHz; Front-End Network Shown in Figure 115
Data Sheet AD9680
Rev. E | Page 39 of 105
40
45
50
55
60
65
70
75
80
85
SFDR (dBFS)
ANALO G I NP UT FRE QUENCY (MHz)
503.4 677.6 851.9 1026.2 1200.5 1374.8
4.0×
5.0×
6.0×
11752-172
Figure 122. Buffer Current Sweeps, AD9680-1000 (SFDR vs. IBUFF);
500 MHz < fIN < 1500 MHz; Front-End Network Shown in Figure 115
40
45
50
55
60
65
70
75
80
SFDR ( dBF S )
ANALO G I NP UT FRE QUENCY (MHz)
1513.4 1607.4 1701.5 1795.6 1889.8
4.5×
5.5×
6.5×
7.5×
8.5×
11752-173
Figure 123. Buffer Current Sweeps, AD9680-1000 (SFDR vs. IBUFF);
1500 MHz < fIN < 2000 MHz; Front-End Network Shown in Figure 115
In certain high frequency applications, the SFDR can be improved
by reducing the full-scale setting, as shown in Table 10. At high
frequencies, the performance of the ADC core is limited by jitter.
The SFDR can be improved by backing off of the full scale level.
Figure 124 shows the SFDR and SNR vs. full-scale input level at
different high frequencies for the AD9680-1000.
1.52GHz
1.65GHz
1.76GHz
1.9GHz
1.95GHz
55
60
65
70
75
80
55
60
65
70
75
80
–3 –2 –1
SFDR (dBFS)
SNR (dBc)
INPUT LEVEL (dBFS)
11752-174
1.52GHz
1.65GHz
1.76GHz
1.9GHz
1.95GHz
Figure 124. SNR/SFDR vs. Analog Input Level vs. Input Frequencies, AD9680-1000
Figure 125, Figure 126, and Figure 127 show the SFDR vs.
analog input frequency for various buffer settings for the
AD9680-820. The recommended settings shown in Table 10
were used to take the data while changing the contents of
Register 0x018 only.
11752-523
SF DR ( dBFS )
ANALOG INPUT FRE QUENCY ( M Hz )
50
55
60
65
70
75
80
85
90
95
10.3
65.5
95.3
125.4
150.3
170.3
180.3
210.5
240.3
270.3
301.3
330.3
340.7
360.3
390.3
420.3
450.3
1.5×
2.0×
3.0×
4.5×
Figure 125. Buffer Current Sweeps, AD9680-820 (SFDR vs. IBUFF);
fIN < 500 MHz; Front-End Network Shown in Figure 115
11752-524
SF DR ( dBFS )
ANALOG INPUT FREQUENCY ( M Hz )
50
55
60
65
70
75
80
85
420.3
450.3
480.3
510.3
515.3
610.3
766.3
810.3
985.3
1022.3
3.5×
4.5×
5.5×
6.5×
7.5×
Figure 126. Buffer Current Sweeps, AD9680-820 (SFDR vs. IBUFF);
500 MHz < fIN < 1000 MHz; Front-End Network Shown in Figure 115
AD9680 Data Sheet
Rev. E | Page 40 of 105
11752-525
SF DR ( dBFS )
ANALOG INPUT FREQUENCY ( M Hz )
50
55
60
65
70
75
80
1022.3
1110.3
1205.3
1315.3
1420.3
1510.3
1600.3
1720.3
1810.3
1920.3
1950.3
6.5×
7.5×
8.5×
Figure 127. Buffer Current Sweeps, AD9680-820 (SFDR vs. IBUFF);
1000 MHz < fIN < 2000 MHz; Front-End Network Shown in Figure 115
Figure 128, Figure 129, and Figure 130 show the SFDR vs.
analog input frequency for various buffer settings for the
AD9680-500. The recommended settings shown in Table 10
were used to take the data while changing the contents of
Register 0x018 only.
30
40
50
60
70
80
90
100
10.3 95.3 150.3 180.3 240.3 301.3 340.7 390.3 450.3
SFDR (dBFS)
ANALO G I NP UT FREQUENCY (MHz)
1.0×
1.5×
2.0×
3.0×
4.5×
11752-145
Figure 128. Buffer Current Sweeps, AD9680-500 (SFDR vs. IBUFF);
fIN < 500 MHz; Front-End Network Shown in Figure 115 Buffer Control 1
(0x018) = 1.0×, 1.5×, 2.0×, 3.0×, or 4.5×
65
70
75
80
85
90
95
450.3 480.3 510.3 515.3
ANALO G I NP UT FRE QUENCY (MHz)
610.3 765.3 810.3 985.3
SFDR (dBFS)
4.0×
5.0×
6.0×
7.0×
8.0×
11752-175
Figure 129. Buffer Current Sweeps, AD9680-500 (SFDR vs. IBUFF);
450 MHz < fIN < 1000 MHz; Front-End Network Shown in Figure 115
SF DR ( dBFS )
40
45
50
55
60
65
70
75
80
1010.3 1205.3 1410.3 1600.3 1810.3 1950.3
ANALO G I NP UT FRE QUENCY (MHz)
4.0×
5.0×
6.0×
7.0×
8.0×
11752-176
Figure 130. Buffer Current Sweeps, AD9680-500 (SFDR vs. IBUFF);
1 GHz < fIN < 2 GHz; Front-End Network Shown in Figure 115
Data Sheet AD9680
Rev. E | Page 41 of 105
Table 10. Recommended Register Settings for SFDR Optimization at Different Input Frequencies
Product Frequency
Buffer
Control 1
(0x018)
Buffer
Current
Control
Buffer
Control 2
(0x019)
Buffer
Bias
Setting
Buffer
Control 3
(0x01A)
Buffer
Bias
Setting
Buffer
Control 4
(0x11A)
High
Frequency
Setting
Buffer
Control 5
(0x935)
Low
Frequency
Setting
Input
Full-Scale
Range
(0x025)
Input
Full-
Scale
Control
(0x030)
Input
Termination
(0x016)1
Input
Capacitance
(0x934)
AD9680-
500
DC to
250 MHz
0x20
(2.0×)
0x60
(Setting 3)
0x0A
(Setting 3)
0x00 (off)
0x04 (on)
0x0C
(2.06 V p-p)
0x04
0x0C/0x1C/…
0x1F
250 MHz to
500 MHz
0x70
(4.5×)
0x60
(Setting 3)
0x0A
(Setting 3)
0x00 (off) 0x04 (on) 0x0C
(2.06 V p-p)
0x04 0x0C/0x1C/… 0x1F
500 MHz to
1 GHz
0x80
(5.0×)
0x40
(Setting 1)
0x08
(Setting 1)
0x00 (off) 0x00 (off) 0x08
(1.46 V p-p)
0x18 0x0C/0x1C/… 0x1F or
0x002
1 GHz to
2 GHz
0xF0
(8.5×)
0x40
(Setting 1)
0x08
(Setting 1)
0x00 (off) 0x00 (off) 0x08
(1.46 V p-p)
0x18 0x0C/0x1C/… 0x1F or 0x001
AD9680-
820
DC to
200 MHz
0x10
(1.5×)
0x40
(Setting 1)
0x09
(Setting 2)
0x00 (off) 0x04 (on) 0x0A
(1.70 V p-p)
0x14 0x0C/0x1C/… 0x1F
DC to
410 MHz
0x40
(3.0×)
0x40
(Setting 1)
0x09
(Setting 2)
0x00 (off) 0x04 (on) 0x0A
(1.70 V p-p)
0x14 0x0C/0x1C/… 0x1F
500 MHz to
1 GHz
0x80
(5.0×)
0x40
(Setting 1)
0x08
(Setting 1)
0x00 (off)
0x00 (off)
0x08
(1.46 V p-p)
0x18
0x0C/0x1C/…
0x1F or 0x00
2
1 GHz to
2 GHz
0xF0
(8.5×)
0x40
(Setting 1)
0x08
(Setting 1)
0x00 (off) 0x00 (off) 0x08
(1.46 V p-p)
0x18 0x0C/0x1C/… 0x1F or 0x001
AD9680-
1000
DC to
150 MHz
0x10
(1.5×)
0x50
(Setting 2)
0x09
(Setting 2)
0x00 (off)
0x04 (on)
0x0A
(1.70 V p-p)
0x18
0x0E/0x1E/…
0x1F
DC to
500 MHz
0x40
(3.0×)
0x50
(Setting 2)
0x09
(Setting 2)
0x00 (off) 0x04 (on) 0x0A
(1.70 V p-p)
0x18 0x0E/0x1E/… 0x1F
500 MHz to
1 GHz
0xA0
(6.0×)
0x60
(Setting 3)
0x09
(Setting 2)
0x20 (on) 0x00 (off) 0x08
(1.46 V p-p)
0x18 0x0E/0x1E/… 0x1F or 0x001
1 GHz to
2 GHz
0xD0
(7.5×)
0x70
(Setting 4)
0x09
(Setting 2)
0x20 (on) 0x00 (off) 0x08
(1.46 V p-p)
0x18 0x0E/0x1E/… 0x1F or 0x001
AD9680-
1250
DC to
625 MHz
0x50
(3.5×)
0x50
(Setting 2)
0x09
(Setting 2)
0x00 (off) 0x04 (on) 0x0A
(1.58 V p-p)
0x18 0x0E/0x1E/… 0x1F
>625 MHz
0xA0
(6.0×)
0x50
(Setting 2)
0x09
(Setting 2)
N/A
3
0x00 (off)
0x08
(1.46 V p-p)
0x18
0x0E/0x1E/…
0x1F or 0x00
1
1 The input termination can be changed to accommodate the application with little or no impact to ac performance.
2 The input capacitance can be set to 1.5 pF to achieve wider input bandwidth but results in slightly lower ac performance.
3 N/A means not applicable.
AD9680 Data Sheet
Rev. E | Page 42 of 105
Absolute Maximum Input Swing
The absolute maximum input swing allowed at the inputs of the
AD9680 is 4.3 V p-p differential. Signals operating near or at
this level can cause permanent damage to the ADC.
VOLTAGE REFERENCE
A stable and accurate 1.0 V voltage reference is built into the
AD9680. This internal 1.0 V reference is used to set the full-
scale input range of the ADC. The full-scale input range can
be adjusted via the ADC Function Register 0x025. For more
information on adjusting the input swing, see Table 39. Figure 131
shows the block diagram of the internal 1.0 V reference controls.
ADC
CORE
FULL-SCALE
VOLTAGE
ADJUST
V_1P0 PIN
CONTROL SPI
REGISTER
(0x025, 0x02,
AND 0x024)
V_1P0
VIN–A/
VIN–B
VIN+A/
VIN+B
INTERNAL
V_1P0
GENERATOR
INPUT FULL-SCALE
RANGE ADJUS T
SPI REGISTER
(0x025, 0x02,
AND 0x024)
11752-031
Figure 131. Internal Reference Configuration and Controls
The SPI Register 0x024 enables the user to either use this internal
1.0 V reference, or to provide an external 1.0 V reference. When
using an external voltage reference, provide a 1.0 V reference.
The full-scale adjustment is made using the SPI, irrespective of
the reference voltage. For more information on adjusting the
full-scale level of the AD9680, refer to the Memory Map Register
Table section.
The use of an external reference may be necessary, in some
applications, to enhance the gain accuracy of the ADC or to
improve thermal drift characteristics. Figure 132 shows the
typical drift characteristics of the internal 1.0 V reference.
–50 025 90
V_1P0 VOLT AGE (V)
TEMPERATURE (°C)
0.9998
0.9999
1.0000
1.0001
1.0002
1.0003
1.0004
1.0005
1.0006
1.0007
1.0008
1.0009
1.0010
11752-106
Figure 132. Typical V_1P0 Drift
The external reference must be a stable 1.0 V reference. The
ADR130 is a good option for providing the 1.0 V reference.
Figure 133 shows how the ADR130 can be used to provide the
external 1.0 V reference to the AD9680. The grayed out areas
show unused blocks within the AD9680 while using the
ADR130 to provide the external reference.
FULL-SCALE
VOLTAGE
ADJUST
V_1P0
0.1µF
V
OUT 4
SET
5
NC
6
V
IN
3
GND
2
NC
1
ADR130
0.1µF
INPUT
FULL-SCALE
CONTROL
INTERNAL
V_1P0
GENERATOR
11752-032
Figure 133. External Reference Using ADR130
Data Sheet AD9680
Rev. E | Page 43 of 105
CLOCK INPUT CONSIDERATIONS
For optimum performance, drive the AD9680 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 clock drivers. These pins are biased internally
and require no additional biasing.
Figure 134 shows a preferred method for clocking the AD9680.
The low jitter clock source is converted from a single-ended
signal to a differential signal using an RF transformer.
ADC
CLK+
CLK–
0.1µF
0.1µF
100Ω
50Ω
CLOCK
INPUT 1:1Z
11752-035
Figure 134. Transformer-Coupled Differential Clock
Another option is to ac couple a differential CML or LVDS
signal to the sample clock input pins, as shown in Figure 135
and Figure 136.
ADC
CLK+
CLK–
0.1µF
0.1µF
Z0 = 50Ω
Z0 = 50Ω
33Ω 33Ω
71Ω 10pF
3.3V
11752-036
Figure 135. Differential CML Sample Clock
ADC
CLK+
CLK–
0.1µF
0.1µF
0.1µF
0.1µF
50Ω1
50Ω1
100Ω
CLO CK INPUT
LVDS
DRIVER
CLK+
CLK–
150Ω RESISTORS ARE OPTIONAL.
CLO CK INPUT
11752-037
Figure 136. Differential LVDS Sample Clock
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. In applications where the clock duty cycle cannot
be guaranteed to be 50%, a higher multiple frequency clock can be
supplied to the device. The AD9680 can be clocked at 2 GHz with
the internal clock divider set to 2. The output of the divider offers
a 50% duty cycle, high slew rate (fast edge) clock signal to the
internal ADC. See the Memory Map section for more details on
using this feature.
Input Clock Divider
The AD9680 contains an input clock divider with the ability to
divide the Nyquist input clock by 1, 2, 4, and 8. The divider
ratios can be selected using Register 0x10B. This is shown in
Figure 137.
The maximum frequency at the CLK± inputs is 4 GHz. This is
the limit of the divider. In applications where the clock input is
a multiple of the sample clock, care must be taken to program
the appropriate divider ratio into the clock divider before applying
the clock signal. This ensures that the current transients during
device startup are controlled.
CLK+
CLK– ÷2
÷4
REG 0x10B
÷8
11752-038
Figure 137. Clock Divider Circuit
The AD9680 clock divider can be synchronized using the
external SYSREF± input. A valid SYSRE causes the clock
divider to reset to a programmable state. This synchronization
feature allows multiple devices to have their clock dividers
aligned to guarantee simultaneous input sampling. See the
Memory Map section for more information.
Input Clock Divider ½ Period Delay Adjust
The input clock divider inside the AD9680 provides phase delay
in increments of ½ the input clock cycle. Register 0x10C can be
programmed to enable this delay independently for each channel.
Changing this register does not affect the stability of the
JESD204B link.
Clock Fine Delay Adjust
The AD9680 sampling edge instant can be adjusted by writing to
Register 0x117 and Register 0x118. Setting Bit 0 of Register 0x117
enables the feature, and Bits[7:0] of Register 0x118 set the value
of the delay. This value can be programmed individually for
each channel. The clock delay can be adjusted from −151.7 ps
to +150 ps in ~1.7 ps increments. The clock delay adjust takes
effect immediately when it is enabled via SPI writes. Enabling
the clock fine delay adjust in Register 0x117 causes a datapath
reset. However, the contents of Register 0x118 can be changed
without affecting the stability of the JESD204B link.
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 (2 × π × fA × tJ)
AD9680 Data Sheet
Rev. E | Page 44 of 105
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 138).
11752-039
130
120
110
100
90
80
70
60
50
40
3010 100 1000 10000
SNR (dB)
ANALO G I NP UT FRE QUENCY ( M Hz )
12.5
f
S
25
f
S
50
f
S
100
f
S
200
f
S
400
f
S
800
f
S
Figure 138. Ideal SNR vs. Input Frequency and Jitter
Treat the clock input as an analog signal in cases where aperture
jitter may affect the dynamic range of the AD9680. Separate
power supplies for clock drivers from the ADC output driver
supplies to avoid modulating the clock signal with digital noise.
If the clock is generated from another type of source (by gating,
dividing, or other methods), retime the clock by the original clock
at the last step. Refer to the AN-501 Application Note and the
AN-756 Application Note for more in-depth information about
jitter performance as it relates to ADCs.
Figure 139 shows the estimated SNR of the AD9680-1000 across
input frequency for different clock induced jitter values. The
SNR can be estimated by using the following equation:
+=
10
10 101010log(dBFS)
JITTER
ADC
SNR
SNR
SNR
11752-526
SNR (d BFS)
INPUT F RE QUENCY ( M Hz )
45
50
55
60
65
70
10 100 1K 10K
25f
s
50f
s
75f
s
100f
s
125f
s
150f
s
175f
s
200f
s
Figure 139. Estimated SNR Degradation for the AD9680-1000 vs.
Input Frequency and RMS Jitter
Power-Down/Standby Mode
The AD9680 has a PDWN/STBY pin that can be used to
configure the device in power-down or standby mode. The
default operation is PDWN. The PDWN/STBY pin is a logic
high pin. When in power-down mode, the JESD204B link is
disrupted. The power-down option can also be set via
Register 0x03F and Register 0x040.
In standby mode, the JESD204B link is not disrupted and
transmits zeros for all converter samples. This can be changed
using Register 0x571, Bit 7 to select /K/ characters.
Temperature Diode
The AD9680 contains a diode-based temperature sensor for
measuring the temperature of the die. This diode can output a
voltage and serve as a coarse temperature sensor to monitor the
internal die temperature.
The temperature diode voltage can be output to the FD_A pin
using the SPI. Use Register 0x028, Bit 0 to enable or disable the
diode. Register 0x028 is a local register. Channel A must be
selected in the device index register (0x008) to enable the
temperature diode readout. Configure the FD_A pin to output
the diode voltage by programming Register 0x040[2:0]. See
Table 39 for more information.
The voltage response of the temperature diode (SPIVDD =
1.8 V) is shown in Figure 140.
DIODE VOLTAGE (V)
TEMPERATURE (°C)
0.60
0.65
0.70
0.75
0.80
0.85
0.90
11752-353
–55 –45 –35 –25 –15 –5 515 25 35 45 55 65 75 85 95 105 115 125
Figure 140. Temperature Diode Voltage vs. Temperature
Data Sheet AD9680
Rev. E | Page 45 of 105
ADC OVERRANGE AND FAST DETECT
In receiver applications, it is desirable to have a mechanism to
reliably determine when the converter is about to be clipped.
The standard overrange bit in the JESD204B outputs provides
information on the state of the analog input that is of limited
usefulness. Therefore, it is helpful to have a programmable
threshold below full scale that allows time to reduce the gain
before the clip actually occurs. In addition, because input
signals can have significant slew rates, the latency of this
function is of major concern. Highly pipelined converters can
have significant latency. The AD9680 contains fast detect
circuitry for individual channels to monitor the threshold and
assert the FD_A and FD_B pins.
ADC OVERRANGE
The ADC overrange indicator is asserted when an overrange is
detected on the input of the ADC. The overrange indicator can
be embedded within the JESD204B link as a control bit (when
CSB > 0). The latency of this overrange indicator matches the
sample latency.
The AD9680 also records any overrange condition in any of the
eight virtual converters. For more information on the virtual
converters, refer to Figure 146. The overrange status of each virtual
converter is registered as a sticky bit in Register 0x563. The
contents of Register 0x563 can be cleared using Register 0x562,
by toggling the bits corresponding to the virtual converter to set
and reset position.
FAST THRESHOLD DETECTION (FD_A AND FD_B)
The FD bit is immediately set whenever the absolute value of
the input signal exceeds the programmable upper threshold
level. The FD bit is only cleared when the absolute value of the
input signal drops below the lower threshold level for greater
than the programmable dwell time. This feature provides
hysteresis and prevents the FD bit from excessively toggling.
The operation of the upper threshold and lower threshold
registers, along with the dwell time registers, is shown in
Figure 141.
The FD indicator is asserted if the input magnitude exceeds the
value programmed in the fast detect upper threshold registers,
located at Register 0x247 and Register 0x248. The selected
threshold register is compared with the signal magnitude at the
output of the ADC. The fast upper threshold detection has a
latency of 28 clock cycles (maximum). The approximate upper
threshold magnitude is defined by
Upper Threshold Magnitude (dBFS)
= 20 log (Threshold Magnitude/213)
The FD indicators are not cleared until the signal drops below
the lower threshold for the programmed dwell time. The lower
threshold is programmed in the fast detect lower threshold
registers, located at Register 0x249 and Register 0x24A. The fast
detect lower threshold register is a 13-bit register that is compared
with the signal magnitude at the output of the ADC. This
comparison is subject to the ADC pipeline latency, but is
accurate in terms of converter resolution. The lower threshold
magnitude is defined by
Lower Threshold Magnitude (dBFS)
= 20 log (Threshold Magnitude/213)
For example, to set an upper threshold of −6 dBFS, write 0xFFF
to Register 0x247 and Register 0x248. To set a lower threshold
of −10 dBFS, write 0xA1D to Register 0x249 and Register 0x24A.
The dwell time can be programmed from 1 to 65,535 sample
clock cycles by placing the desired value in the fast detect dwell
time registers, located at Register 0x24B and Register 0x24C.
See the Memory Map section (Register 0x040, and Register 0x245
to Register 0x24C in Table 39) for more details.
UPPE R THRESHOLD
LOWER THRESHOLD
FD_A OR FD_B
MIDSCALE
DWELL TIME
TIMER RESET BY
RIS E ABO V E
LOWER
THRESHOLD
TIMER COMPLET ES BEFO RE
SI GNAL RISES ABOVE
LOWER THRESHOLD
DWELL TIME
11752-040
Figure 141. Threshold Settings for FD_A and FD_B Signals
AD9680 Data Sheet
Rev. E | Page 46 of 105
SIGNAL MONITOR
The signal monitor block provides additional information about
the signal being digitized by the ADC. The signal monitor
computes the peak magnitude of the digitized signal. This
information can be used to drive an AGC loop to optimize the
range of the ADC in the presence of real-world signals.
The results of the signal monitor block can be obtained either
by reading back the internal values from the SPI port or by
embedding the signal monitoring information into the
JESD204B interface as special control bits. A global, 24-bit
programmable period controls the duration of the
measurement. Figure 142 shows the simplified block diagram
of the signal monitor block.
FROM
MEMORY
MAP DOWN
COUNTER IS
COUNT = 1?
MAGNITUDE
STORAGE
REGISTER
FROM
INPUT SIGNAL
MONITOR
HOLDING
REGISTER
LOAD
CLEAR
COMPARE
A > B
LOAD
LOAD TO SPORT OVER
JESD204B AND
MEMORY MAP
SIGNAL MONITOR
PERIOD REGISTER
(SMPR)
0x271, 0x272, 0x273
11752-087
Figure 142. Signal Monitor Block
The peak detector captures the largest signal within the
observation period. The detector only observes the magnitude
of the signal. The resolution of the peak detector is a 13-bit
value, and the observation period is 24 bits and represents
converter output samples. The peak magnitude can be derived
by using the following equation:
Peak Magnitude (dBFS) = 20log(Peak Detector Value/213)
The magnitude of the input port signal is monitored over a
programmable time period, which is determined by the signal
monitor period register (SMPR). The peak detector function is
enabled by setting Bit 1 of Register 0x270 in the signal monitor
control register. The 24-bit SMPR must be programmed before
activating this mode.
After enabling peak detection mode, the value in the SMPR is
loaded into a monitor period timer, which decrements at the
decimated clock rate. The magnitude of the input signal is
compared with the value in the internal magnitude storage
register (not accessible to the user), and the greater of the two
is updated as the current peak level. The initial value of the
magnitude storage register is set to the current ADC input signal
magnitude. This comparison continues until the monitor period
timer reaches a count of 1.
When the monitor period timer reaches a count of 1, the 13-bit
peak level value is transferred to the signal monitor holding
register, which can be read through the memory map or output
through the SPORT over the JESD204B interface. The monitor
period timer is reloaded with the value in the SMPR, and the
countdown restarts. In addition, the magnitude of the first
input sample is updated in the magnitude storage register, and
the comparison and update procedure, as explained previously,
continues.
Data Sheet AD9680
Rev. E | Page 47 of 105
SPORT OVER JESD204B
The signal monitor data can also be serialized and sent over the
JESD204B interface as control bits. These control bits must be
deserialized from the samples to reconstruct the statistical data.
The signal control monitor function is enabled by setting Bits[1:0]
of Register 0x279 and Bit 1 of Register 0x27A. Figure 143 shows
two different example configurations for the signal monitor
control bit locations inside the JESD204B samples. A maximum
of three control bits can be inserted into the JESD204B samples;
however, only one control bit is required for the signal monitor.
Control bits are inserted from MSB to LSB. If only one control bit
is to be inserted (CS = 1), only the most significant control bit is
used (see Example Configuration 1 and Example Configuration 2
in Figure 143). To select the SPORT over JESD204B option,
program Register 0x559, Register 0x55A, and Register 0x58F.
See Table 39 for more information on setting these bits.
Figure 144 shows the 25-bit frame data that encapsulates the
peak detector value. The frame data is transmitted MSB first
with five 5-bit subframes. Each subframe contains a start bit
that can be used by a receiver to validate the deserialized data.
Figure 145 shows the SPORT over JESD204B signal monitor
data with a monitor period timer set to 80 samples.
15
14-BIT CO NV E RTER RES OL UTION (N = 14)
TAIL
X
1
CONTROL
BIT
(CS = 1)
1-BIT
CONTROL
BIT
(CS = 1)
14 13 12 11 10 9876543210
15 14 13 12 11 10 9876543210
1 TAI L
BIT
SERIALIZED SIGNAL MONITOR
FRAM E DATA
EXAMPLE
CONFIGURATION 1
(N' = 16, N = 15, CS = 1)
EXAMPLE
CONFIGURATION 2
(N' = 16, N = 14, CS = 1)
SERIALIZED SIGNAL MONITOR
FRAM E DATA
16-BIT JES D204B S AM P LE SIZ E ( N' = 16)
S[13]
XS[12]
XS[11]
XS[10]
XS[9]
XS[8]
XS[7]
XS[6]
XS[5]
XS[4]
XS[3]
XS[2]
XS[1]
XS[0]
X
CTRL
[BIT 2]
X
CTRL
[BIT 2]
X
S[14]
XS[13]
XS[12]
XS[11]
XS[10]
XS[9]
XS[8]
XS[7]
XS[6]
XS[5]
XS[4]
XS[3]
XS[2]
XS[1]
XS[0]
X
15-BIT CO NV E RTER RES OL UTION (N = 15)
16-BIT JES D204B S AM P LE SIZ E ( N' = 16)
11752-088
Figure 143. Signal Monitor Control Bit Locations
25-BIT
FRAME
5-BIT IDLE
SUB-FRAME
(OPTIONAL)
5-BIT IDENTIFIER
SUB-FRAME
5-BIT DAT A
MSB
SUB-FRAME
5-BIT DAT A
SUB-FRAME
5-BIT DAT A
SUB-FRAME
5-BIT DAT A
LSB
SUB-FRAME
5-BIT SUB- FRAMES
P[] = P E AK M AGNI TUDE VALUE
IDLE
1IDLE
1IDLE
1IDLE
1IDLE
1
START
0P[0] 0 0 0
START
0P[4] P[3] P[2] P1]
START
0P[8] P[7] P[6] P5]
START
0P[12] P[11] P[10] P[9]
START
0ID[3]
0ID[2]
0ID[1]
0ID[0]
1
11752-089
Figure 144. SPORT over JESD204B Signal Monitor Frame Data
AD9680 Data Sheet
Rev. E | Page 48 of 105
PAYLOAD #3
25-BI T FRAM E ( N)
PAYLOAD #3
25-BI T FRAM E ( N + 1)
PAYLOAD #3
25-BI T FRAM E ( N + 2)
IDLE IDLE IDLE IDLE IDLE IDLEIDLE IDLE IDLE IDLE IDLEIDENT. DATA
MSB DATA DATA DATA
LSB
IDLE IDLE IDLE IDLE IDLE IDLEIDLE IDLE IDLE IDLE IDLEIDENT. DATA
MSB DATA DATA DATA
LSB
IDLE IDLE IDLE IDLE IDLE IDLE
IDLE IDLE IDLE IDLE IDLEIDENT. DATA
MSB DATA DATA DATA
LSB
SMP R = 80 S AM P LES ( 0x271 = 0x50; 0x272 = 0x00; 0x273 = 0x00)
80 SAMPLE PERIOD
80 SAMPLE PERIOD
80 SAMPLE PERIOD
11752-090
Figure 145. SPORT over JESD204B Signal Monitor Example with Period = 80 Samples
Data Sheet AD9680
Rev. E | Page 49 of 105
DIGITAL DOWNCONVERTER (DDC)
The AD9680 includes four digital downconverters (DDC 0 to
DDC 3) that provide filtering and reduce the output data rate.
This digital processing section includes an NCO, a half-band
decimating filter, an FIR filter, a gain stage, and a complex-real
conversion stage. Each of these processing blocks has control lines
that allow it to be independently enabled and disabled to provide
the desired processing function. The digital downconverter can
be configured to output either real data or complex output data.
The DDCs output a 16-bit stream. To enable this operation, the
converter number of bits, N, is set to a default value of 16, even
though the analog core only outputs 14 bits. In full bandwidth
operation, the ADC outputs are the 14-bit word followed by
two zeros, unless the tail bits are enabled.
DDC I/Q INPUT SELECTION
The AD9680 has two ADC channels and four DDC channels.
Each DDC channel has two input ports that can be paired to
support both real or complex inputs through the I/Q crossbar
mux. For real signals, both DDC input ports must select the
same ADC channel (for example, DDC Input Port I = ADC
Channel A, and Input Port Q = ADC Channel A). For complex
signals, each DDC input port must select different ADC
channels (for example, DDC Input Port I = ADC Channel A,
and Input Port Q = ADC Channel B).
The inputs to each DDC are controlled by the DDC input
selection registers (Register 0x311, Register 0x331, Register 0x351,
and Register 0x371). See Table 39 for information on how to
configure the DDCs.
DDC I/Q OUTPUT SELECTION
Each DDC channel has two output ports that can be paired to
support both real or complex outputs. For real output signals,
only the DDC Output Port I is used (the DDC Output Port Q is
invalid). For complex I/Q output signals, both DDC Output
Port I and DDC Output Port Q are used.
The I/Q outputs to each DDC channel are controlled by the
DDC complex to real enable bit (Bit 3) in the DDC control
registers (Register 0x310, Register 0x330, Register 0x350, and
Register 0x370).
The Chip Q ignore bit (Bit 5) in the chip application mode
register (Register 0x200) controls the chip output muxing of all
the DDC channels. When all DDC channels use real outputs,
this bit must be set high to ignore all DDC Q output ports.
When any of the DDC channels are set to use complex I/Q
outputs, the user must clear this bit to use both DDC Output
Port I and DDC Output Port Q. For more information, see
Figure 154.
DDC GENERAL DESCRIPTION
The four DDC blocks are used to extract a portion of the full
digital spectrum captured by the ADC(s). They are intended for
IF sampling or oversampled baseband radios requiring wide
bandwidth input signals.
Each DDC block contains the following signal processing stages.
Frequency Translation Stage (Optional)
The frequency translation stage consists of a 12-bit complex NCO
and quadrature mixers that can be used for frequency translation
of both real or complex input signals. This stage shifts a portion
of the available digital spectrum down to baseband.
Filtering Stage
After shifting down to baseband, the filtering stage decimates
the frequency spectrum using a chain of up to four half-band
low-pass filters for rate conversion. The decimation process
lowers the output data rate, which in turn reduces the output
interface rate.
Gain Stage (Optional)
Due to losses associated with mixing a real input signal down to
baseband, the gain stage compensates by adding an additional
0 dB or 6 dB of gain.
Complex to Real Conversion Stage (Optional)
When real outputs are necessary, the complex to real conversion
stage converts the complex outputs back to real by performing
an fS/4 mixing operation plus a filter to remove the complex
component of the signal.
Figure 146 shows the detailed block diagram of the DDCs
implemented in the AD9680.
AD9680 Data Sheet
Rev. E | Page 50 of 105
NCO
+
MIXER
(OPTIONAL)
COMPLEX TO REAL
CONVERSION
(OPTIONAL)
HB4 FI R
DCM = BYP AS S OR 2
HB3 FI R
DCM = BYP AS S OR 2
HB2 FI R
DCM = BYP AS S OR 2
HB1 FI R
DCM = 2
GAI N = 0dB
OR 6d B
DDC 3
SYSREF±
REAL/I
REAL/Q
REAL/I
CONVE RTER 6
Q CO NV E RTER 7
I
Q
NCO
+
MIXER
(OPTIONAL)
COMPLEX TO REAL
CONVERSION
(OPTIONAL)
HB4 FI R
DCM = BYP AS S OR 2
HB3 FI R
DCM = BYP AS S OR 2
HB2 FI R
DCM = BYP AS S OR 2
HB1 FI R
DCM = 2
GAI N = 0dB
OR 6d B
DDC 0
SYSREF±
REAL/I
REAL/Q
REAL/I
CONVE RTER 0
Q CO NV E RTER 1
I
Q
NCO
+
MIXER
(OPTIONAL)
COMPLEX TO REAL
CONVERSION
(OPTIONAL)
HB4 FI R
DCM = BYP AS S OR 2
HB3 FI R
DCM = BYP AS S OR 2
HB2 FI R
DCM = BYP AS S OR 2
HB1 FI R
DCM = 2
GAI N = 0dB
OR 6d B
DDC 1
SYSREF±
REAL/I
REAL/Q
REAL/I
CONVE RTER 2
Q CO NV E RTER 3
I
Q
NCO
+
MIXER
(OPTIONAL)
COMPLEX TO REAL
CONVERSION
(OPTIONAL)
HB4 FI R
DCM = BYP AS S OR 2
HB3 FI R
DCM = BYP AS S OR 2
HB2 FI R
DCM = BYP AS S OR 2
HB1 FI R
DCM = 2
GAI N = 0dB
OR 6d B
DDC 2
SYSREF±
REAL/I
REAL/Q
REAL/I
CONVE RTER 4
Q CO NV E RTER 5
I
Q
OUTP UT INTERF ACE
I/Q CROS SBAR MUX
ADC
SAMPLING
AT
fS
REAL/I
ADC
SAMPLING
AT
fS
REAL/Q
SYNCHRONIZATION
CONT ROL CIRCUITS
SYSREF
11752-041
Figure 146. DDC Detailed Block Diagram
Figure 147 shows an example usage of one of the four DDC
blocks with a real input signal and four half-band filters (HB4,
HB3, HB2, and HB1). It shows both complex (decimate by 16)
and real (decimate by 8) output options.
When DDCs have different decimation ratios, the chip
decimation ratio (Register 0x201) must be set to the lowest
decimation ratio of all the DDC blocks. In this scenario,
samples of higher decimation ratio DDCs are repeated to match
the chip decimation ratio sample rate. Whenever the NCO
frequency is set or changed, the DDC soft reset must be issued.
If the DDC soft reset is not issued, the output may potentially
show amplitude variations.
Table 11, Table 12, Table 13, Table 14, and Table 15 show the
DDC samples when the chip decimation ratio is set to 1, 2, 4, 8,
or 16, respectively.
Data Sheet AD9680
Rev. E | Page 51 of 105
cos(ωt)
90°
I
Q
REAL
BANDWIDTH OF
INTEREST
BANDWIDTH OF
INTEREST IMAGE
DIGITAL FILTER
RESPONSE
DC
DC
ADC
SAMPLING
AT fS
REAL REAL
HALF-
BAND
FILTER
HB4 FI R
2
HALF-
BAND
FILTER
HB3 FI R
2
HALF-
BAND
FILTER
HB2 FI R
2
HALF-
BAND
FILTER
HB1 FI R
I I
HALF-
BAND
FILTER
HB4 FI R
2
HALF-
BAND
FILTER
HB3 FI R
2
HALF-
BAND
FILTER
HB2 FI R
2
HALF-
BAND
FILTER
HB1 FI R
Q Q
ADC
REAL I NP UT—S AM P LED AT f
S
FILTERING STAGE
4 DIGITAL HALF-BAND FILTERS
(HB4 + HB3 + HB2 + HB1)
FREQ UENCY TRANSLATION STAGE (O PTIO NAL )
DIGITAL MIXER + NCO FORf
S/3 TUNING, THE FREQ UE NCY
TUNING WORD = ROUND ((
f
S/3)/
f
S × 4096) = + 1365 ( 0x555) NCO TUNES CE NTER O F
BANDWIDTH OF INT E RE S T
TO BASEBAND
BANDWIDTH OF
INTEREST IMAGE
(–6d B LOS S DUE TO
NCO + M IXE R)
BANDWIDTH OF INT E RE S T
(–6d B LOS S DUE TO
NCO + M IXE R)
f
S/2
f
S/3
f
S/4
f
S/8
f
S/16
f
S/8
f
S/4
f
S/3
f
S/2
f
S/16
f
S/32
f
S/32
f
S/2
f
S/3
f
S/4
f
S/8
f
S/16
f
S/8
f
S/4
f
S/3
f
S/2
f
S/16
f
S/32
f
S/32
–sin(ωt)
12-BIT
NCO
DC
DIGITAL FILTER
RESPONSE
DC
DC
I
Q
I
Q
2
2
I
Q
REAL/I
COMPLEX
TO
REAL
I
Q
GAIN STAGE (OPTIONAL)
0dB OR 6dB GAIN
COMPLEX (I/Q) OUTPUTS
DECIMATE BY 16
GAIN STAGE (OPTIONAL)
0dB OR 6dB GAIN
REAL (I ) O UT PUTS
DECIMATE BY 8
COMPLEX TO REAL
CONVERSION S T AGE (OPTIONAL)
f
S/4 MIXING + COMPLEX FILTER TO REMOVE Q
f
S/8
f
S/16
f
S/8
f
S/16
f
S/32
f
S/32
f
S/8
f
S/16
f
S/8
f
S/16
f
S/32
f
S/32
f
S/16
f
S/16
f
S/32
f
S/32
6dB GAIN TO
COMPENSATE FOR
NCO + MIXER LOSS
6dB GAIN TO
COMPENSATE FOR
NCO + MIXER LOSS
DOWNSAMPLE BY 2
+6dB
+6dB
+6dB
+6dB
11752-042
Figure 147. DDC Theory of Operation Example (Real InputDecimate by 16)
AD9680 Data Sheet
Rev. E | Page 52 of 105
Table 11. DDC Samples, Chip Decimation Ratio = 1
Real (I) Output (Complex to Real Enabled) Complex (I/Q) Outputs (Complex to Real Disabled)
HB1 FIR
(DCM1 = 1)
HB2 FIR +
HB1 FIR
(DCM1 = 2)
HB3 FIR +
HB2 FIR +
HB1 FIR
(DCM1 = 4)
HB4 FIR +
HB3 FIR +
HB2 FIR +
HB1 FIR
(DCM1 = 8)
HB1 FIR
(DCM1 = 2)
HB2 FIR +
HB1 FIR
(DCM1 = 4)
HB3 FIR +
HB2 FIR +
HB1 FIR
(DCM1 = 8)
HB4 FIR +
HB3 FIR +
HB2 FIR +
HB1 FIR
(DCM1 = 16)
N N N N N N N N
N + 1 N + 1 N + 1 N + 1 N + 1 N + 1 N + 1 N + 1
N + 2 N N N N N N N
N + 3 N + 1 N + 1 N + 1 N + 1 N + 1 N + 1 N + 1
N + 4 N + 2 N N N + 2 N N N
N + 5 N + 3 N + 1 N + 1 N + 3 N + 1 N + 1 N + 1
N + 6 N + 2 N N N + 2 N N N
N + 7 N + 3 N + 1 N + 1 N + 3 N + 1 N + 1 N + 1
N + 8 N + 4 N + 2 N N + 4 N + 2 N N
N + 9 N + 5 N + 3 N + 1 N + 5 N + 3 N + 1 N + 1
N + 10 N + 4 N + 2 N N + 4 N + 2 N N
N + 11 N + 5 N + 3 N + 1 N + 5 N + 3 N + 1 N + 1
N + 12 N + 6 N + 2 N N + 6 N + 2 N N
N + 13 N + 7 N + 3 N + 1 N + 7 N + 3 N + 1 N + 1
N + 14 N + 6 N + 2 N N + 6 N + 2 N N
N + 15 N + 7 N + 3 N + 1 N + 7 N + 3 N + 1 N + 1
N + 16 N + 8 N + 4 N + 2 N + 8 N + 4 N + 2 N
N + 17 N + 9 N + 5 N + 3 N + 9 N + 5 N + 3 N + 1
N + 18 N + 8 N + 4 N + 2 N + 8 N + 4 N + 2 N
N + 19 N + 9 N + 5 N + 3 N + 9 N + 5 N + 3 N + 1
N + 20 N + 10 N + 4 N + 2 N + 10 N + 4 N + 2 N
N + 21 N + 11 N + 5 N + 3 N + 11 N + 5 N + 3 N + 1
N + 22 N + 10 N + 4 N + 2 N + 10 N + 4 N + 2 N
N + 23 N + 11 N + 5 N + 3 N + 11 N + 5 N + 3 N + 1
N + 24 N + 12 N + 6 N + 2 N + 12 N + 6 N + 2 N
N + 25 N + 13 N + 7 N + 3 N + 13 N + 7 N + 3 N + 1
N + 26 N + 12 N + 6 N + 2 N + 12 N + 6 N + 2 N
N + 27 N + 13 N + 7 N + 3 N + 13 N + 7 N + 3 N + 1
N + 28 N + 14 N + 6 N + 2 N + 14 N + 6 N + 2 N
N + 29 N + 15 N + 7 N + 3 N + 15 N + 7 N + 3 N + 1
N + 30 N + 14 N + 6 N + 2 N + 14 N + 6 N + 2 N
N + 31 N + 15 N + 7 N + 3 N + 15 N + 7 N + 3 N + 1
1 DCM means decimation.
Data Sheet AD9680
Rev. E | Page 53 of 105
Table 12. DDC Samples, Chip Decimation Ratio = 2
Real (I) Output (Complex to Real Enabled) Complex (I/Q) Outputs (Complex to Real Disabled)
HB2 FIR +
HB1 FIR
(DCM1 = 2)
HB3 FIR +
HB2 FIR +
HB1 FIR
(DCM1 = 4)
HB4 FIR +
HB3 FIR +
HB2 FIR +
HB1 FIR
(DCM1 = 8)
HB1 FIR
(DCM1 = 2)
HB2 FIR +
HB1 FIR
(DCM1 = 4)
HB3 FIR +
HB2 FIR +
HB1 FIR
(DCM1 = 8)
HB4 FIR +
HB3 FIR +
HB2 FIR +
HB1 FIR
(DCM1 = 16)
N N
N
N N
N
N
N + 1 N + 1 N + 1 N + 1 N + 1 N + 1 N + 1
N + 2 N N N + 2 N N N
N + 3 N + 1
N + 1
N + 3 N + 1
N + 1
N + 1
N + 4 N + 2
N
N + 4 N + 2
N
N
N + 5 N + 3
N + 1
N + 5 N + 3
N + 1
N + 1
N + 6 N + 2 N N + 6 N + 2 N N
N + 7 N + 3 N + 1 N + 7 N + 3 N + 1 N + 1
N + 8 N + 4 N + 2 N + 8 N + 4 N + 2 N
N + 9 N + 5
N + 3
N + 9 N + 5
N + 3
N + 1
N + 10 N + 4
N + 2
N + 10 N + 4
N + 2
N
N + 11 N + 5
N + 3
N + 11 N + 5
N + 3
N + 1
N + 12 N + 6 N + 2 N + 12 N + 6 N + 2 N
N + 13 N + 7 N + 3 N + 13 N + 7 N + 3 N + 1
N + 14 N + 6
N + 2
N + 14 N + 6
N + 2
N
N + 15 N + 7
N + 3
N + 15 N + 7
N + 3
N + 1
1 DCM means decimation.
Table 13. DDC Samples, Chip Decimation Ratio = 4
Real (I) Output (Complex to Real Enabled) Complex (I/Q) Outputs (Complex to Real Disabled)
HB3 FIR + HB2 FIR +
HB1 FIR (DCM1 = 4)
HB4 FIR + HB3 FIR +
HB2 FIR + HB1 FIR
(DCM1 = 8)
HB2 FIR + HB1 FIR
(DCM1 = 4)
HB3 FIR + HB2 FIR +
HB1 FIR (DCM1 = 8)
HB4 FIR + HB3 FIR +
HB2 FIR + HB1 FIR
(DCM1 = 16)
N N N N N
N + 1 N + 1 N + 1 N + 1 N + 1
N + 2 N N + 2 N N
N + 3 N + 1
N + 3 N + 1
N + 1
N + 4
N + 2
N + 4
N + 2
N
N + 5 N + 3 N + 5 N + 3 N + 1
N + 6 N + 2 N + 6 N + 2 N
N + 7 N + 3 N + 7 N + 3 N + 1
1 DCM means decimation.
Table 14. DDC Samples, Chip Decimation Ratio = 8
Real (I) Output (Complex to Real Enabled) Complex (I/Q) Outputs (Complex to Real Disabled)
HB4 FIR + HB3 FIR + HB2 FIR + HB1 FIR (DCM1 = 8)
HB3 FIR + HB2 FIR + HB1 FIR
(DCM1 = 8)
HB4 FIR + HB3 FIR + HB2 FIR +
HB1 FIR (DCM1 = 16)
N N N
N + 1 N + 1 N + 1
N + 2 N + 2 N
N + 3 N + 3 N + 1
N + 4 N + 4 N + 2
AD9680 Data Sheet
Rev. E | Page 54 of 105
Real (I) Output (Complex to Real Enabled)
Complex (I/Q) Outputs (Complex to Real Disabled)
HB4 FIR + HB3 FIR + HB2 FIR + HB1 FIR (DCM1 = 8)
HB3 FIR + HB2 FIR + HB1 FIR
(DCM1 = 8)
HB4 FIR + HB3 FIR + HB2 FIR +
HB1 FIR (DCM1 = 16)
N + 5 N + 5 N + 3
N + 6 N + 6 N + 2
N + 7 N + 7 N + 3
1 DCM means decimation.
Table 15. DDC Samples, Chip Decimation Ratio = 16
Real (I) Output (Complex to Real Enabled) Complex (I/Q) Outputs (Complex to Real Disabled)
HB4 FIR + HB3 FIR + HB2 FIR + HB1 FIR (DCM1 = 16) HB4 FIR + HB3 FIR + HB2 FIR + HB1 FIR (DCM1 = 16)
Not applicable N
Not applicable N + 1
Not applicable
N + 2
Not applicable N + 3
1 DCM means decimation.
If the chip decimation ratio is set to decimate by 4, DDC 0 is set to use HB2 + HB1 filters (complex outputs decimate by 4), and DDC 1 is
set to use HB4 + HB3 + HB2 + HB1 filters (real outputs decimate by 8), then DDC 1 repeats its output data two times for every one
DDC 0 output. The resulting output samples are shown in Table 16.
Table 16. DDC Output Samples when Chip DCM1 = 4, DDC 0 DCM1 = 4 (Complex), and DDC 1 DCM1 = 8 (Real)
DDC 0 DDC 1
DDC Input Samples
Output Port I Output Port Q Output Port I Output Port Q
N I0 [N] Q0 [N] I1 [N] Not applicable
N + 1
N + 2
N + 3
N + 4 I0 [N + 1] Q0 [N + 1] I1 [N + 1] Not applicable
N + 5
N + 6
N + 7
N + 8 I0 [N + 2] Q0 [N + 2] I1 [N] Not applicable
N + 9
N + 10
N + 11
N + 12 I0 [N + 3] Q0 [N + 3] I1 [N + 1] Not applicable
N + 13
N + 14
N + 15
1 DCM means decimation.
Data Sheet AD9680
Rev. E | Page 55 of 105
FREQUENCY TRANSLATION
FREQUENCY TRANSLATION GENERAL DESCRIPTION
Frequency translation is accomplished by using a 12-bit
complex NCO along with a digital quadrature mixer. The
frequency translation translates either a real or complex input
signal from an intermediate frequency (IF) to a baseband
complex digital output (carrier frequency = 0 Hz).
The frequency translation stage of each DDC can be controlled
individually and supports four different IF modes using Bits[5:4] of
the DDC control registers (Register 0x310, Register 0x330,
Register 0x350, and Register 0x370). These IF modes are
Variable IF mode
0 Hz IF (ZIF) mode
fS/4 Hz IF mode
Test mode
Variable IF Mode
NCO and mixers are enabled. NCO output frequency can be
used to digitally tune the IF frequency.
0 Hz IF (ZIF) Mode
Mixers are bypassed and the NCO is disabled.
fS/4 Hz IF Mode
Mixers and NCO are enabled in special down mixing by fS/4
mode to save power.
Test Mode
Input samples are forced to 0.999 to positive full scale. NCO is
enabled. This test mode allows the NCOs to directly drive the
decimation filters.
Figure 148 and Figure 149 show examples of the frequency
translation stage for both real and complex inputs.
BANDWIDTH OF
INTEREST
BANDWIDTH OF
INTEREST IMAGE
NCO FRE QUENCY T UNING WORD (FTW) S ELECT ION
12-BI T NCO FTW = M IXI NG F RE QUENCY/ADC SAMP LE RATE × 4096
ADC + DIGI T AL MIXE R + NCO
REAL INPUT—SAM P LED AT
f
S
DC
f
S
/2
f
S
/3
f
S
/4
f
S
/8
f
S
/16
f
S
/8
f
S
/4
f
S
/3
f
S
/2
f
S
/16
f
S
/32
f
S
/32
DC
f
S
/32
f
S
/32
DC
f
S
/32
f
S
/32
cos(ωt)
90°
I
Q
ADC
SAMPLING
AT
f
S
REAL REAL
–sin(ωt)
12-BIT
NCO
POSITIVE FTW VALUES
NEGATIVE FTW VALUES
COMPLEX
–6dB LOS S DUE TO
NCO + MIXER
12-BI T NCO FTW =
ROUND ( (
f
S
/3)/
f
S
× 4096) = + 1365 ( 0x555)
12-BI T NCO FTW =
ROUND ( (
f
S
/3)/
f
S
× 4096) = –1365 ( 0xAAB)
11752-043
Figure 148. DDC NCO Frequency Tuning Word SelectionReal Inputs
AD9680 Data Sheet
Rev. E | Page 56 of 105
NCO FRE QUENCY TUNING WO RD (FTW) S ELE CTION
12-BI T NCO FT W = MIXI NG F RE QUENCY/ADC SAM P LE RAT E × 4096
QUADRATURE ANAL O G MIX ER +
2 ADCs + QUADRATURE DIGI TAL
MIXER + NCO
COMPLEX INPUT—SAMPLED AT
f
S
f
S
/2
f
S
/3
f
S
/4
f
S
/8
f
S
/16
f
S
/8
f
S
/4
f
S
/3
f
S
/2
f
S
/16
f
S
/32
f
S
/32
f
S
/32
f
S
/32
DC
DC
12-BI T NCO FT W =
ROUND ( (
f
S
/3)/
f
S
× 4096) = + 1365 ( 0x555)
BANDWIDTH OF
INTEREST
POSITIVE FTW VALUES
IM AGE DUE TO
ANALOG I/Q
MISMATCH
REAL
I
Q
QUADRATURE MIXER
I
Q
I
+
Q
Q
I
Q+
+
Q
I
I
COMPLEX
I
Q
–sin(ωt)
ADC
SAMPLING
AT
f
S
ADC
SAMPLING
AT
f
S
90°
PHASE
12-BIT
NCO 90°
11752-044
Figure 149. DDC NCO Frequency Tuning Word SelectionComplex Inputs
DDC NCO PLUS MIXER LOSS AND SFDR
When mixing a real input signal down to baseband, 6 dB of loss
is introduced in the signal due to filtering of the negative image.
An additional 0.05 dB of loss is introduced by the NCO. The
total loss of a real input signal mixed down to baseband is 6.05 dB.
For this reason, it is recommended that the user compensate for
this loss by enabling the additional 6 dB of gain in the gain stage
of the DDC to recenter the dynamic range of the signal within
the full scale of the output bits.
When mixing a complex input signal down to baseband, the
maximum value each I/Q sample can reach is 1.414 × full scale
after it passes through the complex mixer. To avoid overrange
of the I/Q samples and to keep the data bit widths aligned with
real mixing, 3.06 dB of loss (0.707 × full scale) is introduced in
the mixer for complex signals. An additional 0.05 dB of loss is
introduced by the NCO. The total loss of a complex input signal
mixed down to baseband is −3.11 dB.
The worst case spurious signal from the NCO is greater than
102 dBc SFDR for all output frequencies.
NUMERICALLY CONTROLLED OSCILLATOR
The AD9680 has a 12-bit NCO for each DDC that enables the
frequency translation process. The NCO allows the input
spectrum to be tuned to dc, where it can be effectively filtered
by the subsequent filter blocks to prevent aliasing. The NCO
can be set up by providing a frequency tuning word (FTW) and
a phase offset word (POW).
Setting Up the NCO FTW and POW
The NCO frequency value is given by the 12-bit twos
complement number entered in the NCO FTW. Frequencies
between −fS/2 and fS/2 (fS/2 excluded) are represented using the
following frequency words:
0x800 represents a frequency of –fS/2.
0x000 represents dc (frequency is 0 Hz).
0x7FF represents a frequency of +fS/2 – fS/212.
The NCO frequency tuning word can be calculated using the
following equation:
=
S
SC
f
f
fMod
roundFTW
NCO ),
(
2_ 12
where:
NCO_FTW is a 12-bit twos complement number representing
t h e N C O F T W.
fS is the AD9680 sampling frequency (clock rate) in Hz.
fC is the desired carrier frequency in Hz.
Mod( ) is a remainder function. For example, Mod(110,100) =
10, and for negative numbers, Mod(–32, 10) = 2.
round( ) is a rounding function. For example, round(3.6) = 4,
and for negative numbers, round(–3.4)= 3.
Data Sheet AD9680
Rev. E | Page 57 of 105
Note that this equation applies to the aliasing of signals in the
digital domain (that is, aliasing introduced when digitizing
analog signals).
For example, if the ADC sampling frequency (fS) is 1250 MSPS
and the carrier frequency (fC) is 416.667 MHz,
MHz1365
1250
1250
,
667.
416
(
2
_
12
=
=Mod
round
FTW
NCO
This, in turn, converts to 0x555 in the 12-bit twos complement
representation for NCO_FTW. The actual carrier frequency can
be calculated based on the following equation:
MHz56
.
416
2
_
12 =
×
= S
C
f
FTWNCO
actual
f
A 12-bit POW is available for each NCO to create a known phase
relationship between multiple AD9680 chips or individual DDC
channels inside one AD9680.
The following procedure must be followed to update the FTW
and/or POW registers to ensure proper operation of the NCO:
Write to the FTW registers for all the DDCs.
Write to the POW registers for all the DDCs.
Synchronize the NCOs either through the DDC soft reset
bit accessible through the SPI, or through the assertion of
the SYSREF± pin.
Note that the NCOs must be synchronized either through SPI
or through the SYSREF± pin after all writes to the FTW or POW
registers have completed. This synchronization is necessary to
ensure the proper operation of the NCO.
NCO Synchronization
Each NCO contains a separate phase accumulator word (PAW)
that determines the instantaneous phase of the NCO. The initial
reset value of each PAW is determined by the POW described
in the Setting Up the NCO FTW and POW section. The phase
increment value of each PAW is determined by the FTW.
Two methods can be used to synchronize multiple PAWs within
the chip:
Using the SPI. The DDC NCO soft reset bit in the DDC
synchronization control register (Register 0x300, Bit 4)
can be used to reset all the PAWs in the chip. This is
accomplished by toggling the DDC NCO soft reset bit.
This method can only be used to synchronize DDC
channels within the same AD9680 chip.
Using the SYSREF± pin. When the SYSREF± pin is enabled
in the SYSREF± control registers (Register 0x120 and
Register 0x121), and the DDC synchronization is enabled
in Bits[1:0] in the DDC synchronization control register
(Register 0x300), any subsequent SYSREF± event resets all
the PAWs in the chip. This method can be used to synchronize
DDC channels within the same AD9680 chip, or DDC
channels within separate AD9680 chips.
Mixer
The NCO is accompanied by a mixer, whose operation is
similar to an analog quadrature mixer. The mixer performs the
downconversion of input signals (real or complex) by using the
NCO frequency as a local oscillator. For real input signals, this
mixer performs a real mixer operation (with two multipliers).
For complex input signals, the mixer performs a complex mixer
operation (with four multipliers and two adders). The mixer
adjusts its operation based on the input signal (real or complex)
provided to each individual channel. The selection of real or
complex inputs can be controlled individually for each DDC
block by using Bit 7 of the DDC control register (Register 0x310,
Register 0x330, Register 0x350, and Register 0x370).
AD9680 Data Sheet
Rev. E | Page 58 of 105
FIR FILTERS
FIR FILTERS GENERAL DESCRIPTION
There are four sets of decimate-by-2, low-pass, half-band, finite
impulse response (FIR) filters (HB1 FIR, HB2 FIR, HB3 FIR,
and HB4 FIR, shown in Figure 146). These filters follow the
frequency translation stage. After the carrier of interest is tuned
down to dc (carrier frequency = 0 Hz), these filters efficiently lower
the sample rate while providing sufficient alias rejection from
unwanted adjacent carriers around the bandwidth of interest.
HB1 FIR is always enabled and cannot be bypassed. The HB2,
HB3, and HB4 FIR filters are optional and can be bypassed for
higher output sample rates.
Table 17 shows the different bandwidth options by including
different half-band filters. In all cases, the DDC filtering stage of
the AD9680 provides less than −0.001 dB of pass-band ripple and
>100 dB of stop-band alias rejection.
Table 18 shows the amount of stop-band alias rejection for
multiple pass-band ripple/cutoff points. The decimation ratio
of the filtering stage of each DDC can be controlled individually
through Bits[1:0] of the DDC control registers (0x310, 0x330,
0x350, and 0x370).
Table 17. DDC Filter Characteristics
ADC
Sample
Rate
(MSPS)
Half Band
Filter
Selection
Real Output Complex (I/Q) Output
Alias
Protected
Bandwidth
(MHz)
Ideal SNR
Improvement
(dB)1
Pass-
Band
Ripple
(dB)
Alias
Rejection
(dB)
Decimation
Ratio
Output
Sample
Rate
(MSPS)
Decimation
Ratio
Output
Sample
Rate
(MSPS)
1250 HB1 1 1250 2 625 (I) +
625 (Q)
481.25 1 <−0.001 >100
HB1 + HB2 2 625 4 312.5 (I) +
312.5 (Q)
240.62 4
HB1 + HB2 +
HB3
4 312.5 8 156.25 (I) +
156.25 (Q)
120.31 7
HB1 + HB2 +
HB3 + HB4
8
156.25
16
78.125 (I) +
78.125 (Q)
60.15
10
1000 HB1 1 1000 2 500 (I) +
500 (Q)
385.0 1
HB1 + HB2 2 500 4 250 (I) +
250 (Q)
192.5 4
HB1 + HB2 +
HB3
4 250 8 125 (I) +
125 (Q)
96.3 7
HB1 + HB2 +
HB3 + HB4
8 125 16 62.5 (I) +
62.5 (Q)
48.1 10
820 HB1 1 820 2 410 (I) +
410 (Q)
315.7 1
HB1 + HB2 2 410 4 205 (I) +
205 (Q)
157.8 4
HB1 + HB2 +
HB3
4 205 8 102.5 (I) +
102.5 (Q)
78.9 7
HB1 + HB2 +
HB3 + HB4
8 102.5 16 51.25 (I) +
51.25 (Q)
39.4 10
500 HB1 1 500 2 250 (I) +
250 (Q)
192.5 1
HB1 + HB2 2 250 4 125 (I) +
125 (Q)
96.3 4
HB1 + HB2 +
HB3
4 125 8 62.5 (I) +
62.5 (Q)
48.1 7
HB1 + HB2 +
HB3 + HB4
8 62.5 16 31.25 (I) +
31.25 (Q)
24.1 10
1 Ideal SNR improvement due to oversampling and filtering = 10log(bandwidth/(fS/2)).
Data Sheet AD9680
Rev. E | Page 59 of 105
Table 18. DDC Filter Alias Rejection
Alias
Rejection (dB)
Pass-Band Ripple/
Cutoff Point (dB)
Alias Protected Bandwidth for
Real (I) Outputs1
Alias Protected Bandwidth for
Complex (I/Q) Outputs1
>100
<−0.001
<38.5% × f
OUT
<77% × f
OUT
90 <−0.001 <38.7% × fOUT <77.4% × fOUT
85 <0.001 <38.9% × fOUT <77.8% × fOUT
63.3 <−0.006 <40% × fOUT <80% × fOUT
25 −0.5 44.4% × fOUT 88.8% × fOUT
19.3 1.0 45.6% × fOUT 91.2% × fOUT
10.7 3.0 48% × fOUT 96% × fOUT
1 fOUT is the ADC input sample rate fS/DDC decimation ratio.
HALF-BAND FILTERS
The AD9680 offers four half-band filters to enable digital signal
processing of the ADC converted data. These half-band filters
can be bypassed and can be individually selected.
HB4 Filter
The first decimate-by-2, half-band, low-pass FIR filter (HB4) uses
an 11-tap, symmetrical, fixed-coefficient filter implementation,
optimized for low power consumption. The HB4 filter is only used
when complex outputs (decimate by 16) or real outputs (decimate
by 8) are enabled; otherwise, the filter is bypassed. Table 19 and
Figure 150 show the coefficients and response of the HB4 filter.
Table 19. HB4 Filter Coefficients
HB4 Coefficient
Number
Normalized
Coefficient
Decimal Coefficient
(15-Bit)
C1, C11 0.006042 99
C2, C10 0 0
C3, C9 −0.049316 808
C4, C8 0 0
C5, C7 0.293273 4805
C6 0.500000 8192
0
–120
–100
–80
–60
–40
–20
00.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
MAG NITUDE ( dB)
NORMALIZED FREQUENCYπ RAD/SAMPLE)
11752-045
Figure 150. HB4 Filter Response
HB3 Filter
The second decimate-by-2, half-band, low-pass, FIR filter (HB3)
uses an 11-tap, symmetrical, fixed coefficient filter implementation,
optimized for low power consumption. The HB3 filter is only used
when complex outputs (decimate by 8 or 16) or real outputs
(decimate by 4 or 8) are enabled; otherwise, the filter is bypassed.
Table 20 and Figure 151 show the coefficients and response of
the HB3 filter.
Table 20. HB3 Filter Coefficients
HB3 Coefficient
Number
Normalized
Coefficient
Decimal Coefficient
(18-Bit)
C1, C11 0.006554 859
C2, C10
0
0
C3, C9 −0.050819 6661
C4, C8 0 0
C5, C7 0.294266 38,570
C6 0.500000 65,536
0
–120
–100
–80
–60
–40
–20
00.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
MAG NITUDE ( dB)
NORMALIZED FREQUENCYπ RAD/SAMPLE)
11752-046
Figure 151. HB3 Filter Response
AD9680 Data Sheet
Rev. E | Page 60 of 105
HB2 Filter
The third decimate-by-2, half-band, low-pass FIR filter (HB2)
uses a 19-tap, symmetrical, fixed coefficient filter implementation
that is optimized for low power consumption. The HB2 filter is
only used when complex outputs (decimate by 4, 8, or 16) or
real outputs (decimate by 2, 4, or 8) are enabled; otherwise, the
filter is bypassed.
Table 21 and Figure 152 show the coefficients and response of
the HB2 filter.
Table 21. HB2 Filter Coefficients
HB2 Coefficient
Number
Normalized
Coefficient
Decimal Coefficient
(19-Bit)
C1, C19 0.000614 161
C2, C18 0 0
C3, C17 −0.005066 −1328
C4, C16 0 0
C5, C15 0.022179 5814
C6, C14 0 0
C7, C13 −0.073517 −19,272
C8, C12 0 0
C9, C11 0.305786 80,160
C10 0.500000 131,072
0
–120
–100
–80
–60
–40
–20
00.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
MAG NITUDE ( dB)
NORMALIZED FREQUENCYπ RAD/SAMPLE)
11752-047
Figure 152. HB2 Filter Response
HB1 Filter
The fourth and final decimate-by-2, half-band, low-pass FIR
filter (HB1) uses a 55-tap, symmetrical, fixed coefficient filter
implementation, optimized for low power consumption. The
HB1 filter is always enabled and cannot be bypassed. Table 22
and Figure 153 show the coefficients and response of the HB1
filter.
0
–120
–100
–80
–60
–40
–20
00.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
MAG NITUDE ( dB)
NORMALIZED FREQUENCYπ RAD/SAMPLE)
11752-048
Figure 153. HB1 Filter Response
Table 22. HB1 Filter Coefficients
HB1 Coefficient
Number
Normalized
Coefficient
Decimal Coefficient
(21-Bit)
C1, C55 −0.000023 −24
C2, C54 0 0
C3, C53
0.000097
102
C4, C52 0 0
C5, C51 −0.000288 −302
C6, C50 0 0
C7, C49 0.000696 730
C8, C48 0 0
C9, C47 −0.0014725 −1544
C10, C46 0 0
C11, C45 0.002827 2964
C12, C44 0 0
C13, C43 −0.005039 −5284
C14, C42
0
0
C15, C41 0.008491 8903
C16, C40 0 0
C17, C39 −0.013717 −14,383
C18, C38 0 0
C19, C37 0.021591 22,640
C20, C36 0 0
C21, C35 −0.033833 −35,476
C22, C34 0 0
C23, C33 0.054806 57,468
C24, C32 0 0
C25, C31
−0.100557
−105,442
C26, C30 0 0
C27, C29 0.316421 331,792
C28 0.500000 524,288
Data Sheet AD9680
Rev. E | Page 61 of 105
DDC GAIN STAGE
Each DDC contains an independently controlled gain stage.
The gain is selectable as either 0 dB or 6 dB. When mixing a real
input signal down to baseband, it is recommended that the user
enable the 6 dB of gain to recenter the dynamic range of the
signal within the full scale of the output bits.
When mixing a complex input signal down to baseband, the
mixer has already recentered the dynamic range of the signal
within the full scale of the output bits and no additional gain is
necessary. However, the optional 6 dB gain can be used to
compensate for low signal strengths. The downsample by 2
portion of the HB1 FIR filter is bypassed when using the
complex to real conversion stage (see Figure 154).
DDC COMPLEX TO REAL CONVERSION
Each DDC contains an independently controlled complex to
real conversion block. The complex to real conversion block
reuses the last filter (HB1 FIR) in the filtering stage, along with
an fS/4 complex mixer to upconvert the signal.
After up converting the signal, the Q portion of the complex
mixer is no longer needed and is dropped.
Figure 154 shows a simplified block diagram of the complex to
real conversion.
LOW-PASS
FILTER
2
I
Q
REAL
HB1 FI R
LOW-PASS
FILTER 2
HB1 FI R
0
1
COMPLEX TO
REAL E NABLE
Q
90°
+
COMPLEX TO REAL CONVERSION
I
Q
I
Q
GAIN STAGE
cos(ωt)
sin(ωt)
fS/4
I/REAL
0dB
OR
6dB
0dB
OR
6dB
0dB
OR
6dB
0dB
OR
6dB
11752-049
Figure 154. Complex to Real Conversion Block
AD9680 Data Sheet
Rev. E | Page 62 of 105
DDC EXAMPLE CONFIGURATIONS
Table 23 describes the register settings for multiple DDC example configurations.
Table 23. DDC Example Configurations
Chip
Application
Layer
Chip
Decimation
Ratio
DDC
Input
Type
DDC
Output
Type
Bandwidth
per DDC1
No. of Virtual
Converters
Required Register Settings2
One DDC 2 Complex Complex 38.5% × fS 2 Register 0x200 = 0x01 (one DDC; I/Q selected)
Register 0x201 = 0x01 (chip decimate by 2)
Register 0x310 = 0x83 (complex mixer; 0 dB gain; variable IF;
complex outputs; HB1 filter)
Register 0x311 = 0x04 (DDC I input = ADC Channel A;
DDC Q input = ADC Channel B)
Register 0x314, Register 0x315, Register 0x320, Register 0x321 =
FTW and POW set as required by application for DDC 0
Two DDCs 4 Complex Complex 19.25% × fS 4 Register 0x200 = 0x02 (two DDCs; I/Q selected)
Register 0x201 = 0x02 (chip decimate by 4)
Register 0x310, Register 0x330 = 0x80 (complex mixer; 0 dB
gain; variable IF; complex outputs; HB2 + HB1 filters)
Register 0x311, Register 0x331 = 0x04 (DDC I input =
ADC Channel A; DDC Q input = ADC Channel B)
Register 0x314, Register 0x315, Register 0x320, Register 0x321 =
FTW and POW set as required by application for DDC 0
Register 0x334, Register 0x335, Register 0x340, Register 0x341 =
FTW and POW set as required by application for DDC 1
Two DDCs 4 Complex Real 9.63% × fS 2 Register 0x200 = 0x22 (two DDCs; I only selected)
Register 0x201 = 0x02 (chip decimate by 4)
Register 0x310, Register 0x330 = 0x89 (complex mixer; 0 dB
gain; variable IF; real output; HB3 + HB2 + HB1 filters)
Register 0x311, Register 0x331 = 0x04 (DDC I Input = ADC
Channel A; DDC Q Input = ADC Channel B)
Register 0x314, Register 0x315, Register 0x320, Register 0x321 =
FTW and POW set as required by application for DDC 0
Register 0x334, Register 0x335, Register 0x340, Register 0x341 =
FTW and POW set as required by application for DDC 1
Two DDCs 4 Real Real 9.63% × fS 2 Register 0x200 = 0x22 (two DDCs; I only selected)
Register 0x201 = 0x02 (chip decimate by 4)
Register 0x310, Register 0x330 = 0x49 (real mixer; 6 dB gain;
variable IF; real output; HB3 + HB2 + HB1 filters)
Register 0x311 = 0x00 (DDC 0 I input = ADC Channel A;
DDC 0 Q input = ADC Channel A)
Register 0x331 = 0x05 (DDC 1 I input = ADC Channel B;
DDC 1 Q input = ADC Channel B)
Register 0x314, Register 0x315, Register 0x320, Register 0x321 =
FTW and POW set as required by application for DDC 0
Register 0x334, Register 0x335, Register 0x340, Register 0x341 =
FTW and POW set as required by application for DDC 1
Data Sheet AD9680
Rev. E | Page 63 of 105
Chip
Application
Layer
Chip
Decimation
Ratio
DDC
Input
Type
DDC
Output
Type
Bandwidth
per DDC1
No. of Virtual
Converters
Required Register Settings2
Two DDCs 4 Real Complex 19.25% × fS 4 Register 0x200 = 0x02 (two DDCs; I/Q selected)
Register 0x201 = 0x02 (chip decimate by 4)
Register 0x310, Register 0x330 = 0x40 (real mixer; 6 dB gain;
variable IF; complex output; HB2 + HB1 filters)
Register 0x311 = 0x00 (DDC 0 I input = ADC Channel A;
DDC 0 Q input = ADC Channel A)
Register 0x331 = 0x05 (DDC 1 I input = ADC Channel B;
DDC 1 Q input = ADC Channel B)
Register 0x314, Register 0x315, Register 0x320, Register 0x321 =
FTW and POW set as required by application for DDC 0
Register 0x334, Register 0x335, Register 0x340, Register 0x341 =
FTW and POW set as required by application for DDC 1
Two DDCs 8 Real Real 4.81% × fS 2 Register 0x200 = 0x22 (two DDCs; I only selected)
Register 0x201 = 0x03 (chip decimate by 8)
Register 0x310, Register 0x330 = 0x4A (real mixer; 6 dB gain;
variable IF; real output; HB4 + HB3 + HB2 + HB1 filters)
Register 0x311 = 0x00 (DDC 0 I input = ADC Channel A;
DDC 0 Q input = ADC Channel A)
Register 0x331 = 0x05 (DDC 1 I input = ADC Channel B;
DDC 1 Q input = ADC Channel B)
Register 0x314, Register 0x315, Register 0x320, Register 0x321 =
FTW and POW set as required by application for DDC 0
Register 0x334, Register 0x335, Register 0x340, Register 0x341 =
FTW and POW set as required by application for DDC 1
Four DDCs 8 Real Complex 9.63% × fS 8 Register 0x200 = 0x03 (four DDCs; I/Q selected)
Register 0x201 = 0x03 (chip decimate by 8)
Register 0x310, Register 0x330, Register 0x350, Register 0x370 =
0x41 (real mixer; 6 dB gain; variable IF; complex output;
HB3+HB2+HB1 filters)
Register 0x311 = 0x00 (DDC 0 I input = ADC Channel A;
DDC 0 Q input = ADC Channel A)
Register 0x331 = 0x00 (DDC 1 I input = ADC Channel A;
DDC 1 Q input = ADC Channel A)
Register 0x351 = 0x05 (DDC 2 I input = ADC Channel B;
DDC 2 Q input = ADC Channel B)
Register 0x371 = 0x05 (DDC 3 I input = ADC Channel B;
DDC 3 Q input = ADC Channel B)
Register 0x314, Register 0x315, Register 0x320, Register 0x321 =
FTW and POW set as required by application for DDC 0
Register 0x334, Register 0x335, Register 0x340, Register 0x341 =
FTW and POW set as required by application for DDC 1
Register 0x354, Register 0x355, Register 0x360, Register 0x361 =
FTW and POW set as required by application for DDC 2
Register 0x374, Register 0x375, Register 0x380, Register 0x381 =
FTW and POW set as required by application for DDC 3
AD9680 Data Sheet
Rev. E | Page 64 of 105
Chip
Application
Layer
Chip
Decimation
Ratio
DDC
Input
Type
DDC
Output
Type
Bandwidth
per DDC1
No. of Virtual
Converters
Required Register Settings2
Four DDCs 8 Real Real 4.81% × fS 4 Register 0x200 = 0x23 (four DDCs; I only selected)
Register 0x201 = 0x03 (chip decimate by 8)
Register 0x310, Register 0x330, Register 0x350, Register 0x370 =
0x4A (real mixer; 6 dB gain; variable IF; real output; HB4 +
HB3 + HB2 + HB1 filters)
Register 0x311 = 0x00 (DDC 0 I input = ADC Channel A;
DDC 0 Q input = ADC Channel A)
Register 0x331 = 0x00 (DDC 1 I input = ADC Channel A;
DDC 1 Q input = ADC Channel A)
Register 0x351 = 0x05 (DDC 2 I input = ADC Channel B;
DDC 2 Q input = ADC Channel B)
Register 0x371 = 0x05 (DDC 3 I input = ADC Channel B;
DDC 3 Q input = ADC Channel B)
Register 0x314, Register 0x315, Register 0x320, Register 0x321 =
FTW and POW set as required by application for DDC 0
Register 0x334, Register 0x335, Register 0x340, Register 0x341 =
FTW and POW set as required by application for DDC 1
Register 0x354, Register 0x355, Register 0x360, Register 0x361 =
FTW and POW set as required by application for DDC 2
Register 0x374, Register 0x375, Register 0x380, Register 0x381 =
FTW and POW set as required by application for DDC 3
Four DDCs 16 Real Complex 4.81% × fS 8 Register 0x200 = 0x03 (four DDCs; I/Q selected)
Register 0x201 = 0x04 (chip decimate by 16)
Register 0x310, Register 0x330, Register 0x350, Register 0x370 =
0x42 (real mixer; 6 dB gain; variable IF; complex output;
HB4 + HB3 + HB2 + HB1 filters)
Register 0x311 = 0x00 (DDC 0 I input = ADC Channel A;
DDC 0 Q input = ADC Channel A)
Register 0x331 = 0x00 (DDC 1 I input = ADC Channel A;
DDC 1 Q input = ADC Channel A)
Register 0x351 = 0x05 (DDC 2 I input = ADC Channel B;
DDC 2 Q input = ADC Channel B)
Register 0x371 = 0x05 (DDC 3 I input = ADC Channel B;
DDC 3 Q input = ADC Channel B)
Register 0x314, Register 0x315, Register 0x320, Register 0x321 =
FTW and POW set as required by application for DDC 0
Register 0x334, Register 0x335, Register 0x340, Register 0x341 =
FTW and POW set as required by application for DDC 1
Register 0x354, Register 0x355, Register 0x360, Register 0x361 =
FTW and POW set as required by application for DDC 2
Register 0x374, Register 0x375, Register 0x380, Register 0x381 =
FTW and POW set as required by application for DDC 3
1 fS is the ADC sample rate. Bandwidths listed are <−0.001 dB of pass-band ripple and >100 dB of stop-band alias rejection.
2 The NCOs must be synchronized either through the SPI or through the SYSREF± pin after all writes to the FTW or POW registers have completed, to ensure the proper
operation of the NCO. See the NCO Synchronization section for more information.
Data Sheet AD9680
Rev. E | Page 65 of 105
DIGITAL OUTPUTS
INTRODUCTION TO THE JESD204B INTERFACE
The AD9680 digital outputs are designed to the JEDEC standard
JESD204B, serial interface for data converters. JESD204B is a
protocol to link the AD9680 to a digital processing device over a
serial interface with lane rates of up to 12.5 Gbps. The benefits
of the JESD204B interface over LVDS include a reduction in
required board area for data interface routing, and an ability to
enable smaller packages for converter and logic devices.
JESD204B OVERVIEW
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 through the use of special control
characters during the initial establishment of the link. Additional
control characters are embedded in the data stream to maintain
synchronization thereafter. A JESD204B receiver is required to
complete the serial link. For additional details on the JESD204B
interface, refer to the JESD204B standard.
The AD9680 JESD204B data transmit block maps up to two
physical ADCs or up to eight virtual converters (when DDCs
are enabled) over a link. A link can be configured to use one,
two, or four JESD204B lanes. The JESD204B specification refers
to a number of parameters to define the link, and these parameters
must match between the JESD204B transmitter (the AD9680
output) and the JESD204B receiver (the logic device input).
The JESD204B link is described according to the following
parameters:
L is the number of lanes/converter device (lanes/link)
(AD9680 value = 1, 2, or 4)
M is the number of converters/converter device (virtual
converters/link) (AD9680 value = 1, 2, 4, or 8)
F is the octets/frame (AD9680 value = 1, 2, 4, 8, or 16)
N΄ is the number of bits per sample (JESD204B word size)
(AD9680 value = 8 or 16)
N is the converter resolution (AD9680 value = 7 to 16)
CS is the number of control bits/sample
(AD9680 value = 0, 1, 2, or 3)
K is the number of frames per multiframe
(AD9680 value = 4, 8, 12, 16, 20, 24, 28, or 32 )
S is the samples transmitted/single converter/frame cycle
(AD9680 value = set automatically based on L, M, F, and N΄)
HD is the high density mode (AD9680 = set automatically
based on L, M, F, and N΄)
CF is the number of control words/frame clock cycle/
converter device (AD9680 value = 0)
Figure 155 shows a simplified block diagram of the AD9680
JESD204B link. By default, the AD9680 is configured to use
two converters and four lanes. Converter A data is output to
SERDOUT0± and/or SERDOUT1±, and Converter B is output
to SERDOUT2± and/or SERDOUT3±. The AD9680 allows
other configurations such as combining the outputs of both
converters onto a single lane, or changing the mapping of the
A and B digital output paths. These modes are set up via a quick
configuration register in the SPI register map, along with
additional customizable options.
By default in the AD9680, the 14-bit converter word from each
converter is broken into two octets (eight bits of data). Bit 13
(MSB) through Bit 6 are in the first octet. The second octet
contains Bit 5 through Bit 0 (LSB) and two tail bits. The tail bits
can be configured as zeros or a pseudorandom number
sequence. The tail bits can also be replaced with control bits
indicating overrange, SYSREF±, or fast detect output.
The two resulting octets can be scrambled. Scrambling is
optional; however, it is recommended to avoid spectral peaks
when transmitting similar digital data patterns. The scrambler
uses a self-synchronizing, polynomial-based algorithm defined
by the equation 1 + x14 + x15. The descrambler in the receiver is
a self-synchronizing version of the scrambler polynomial.
The two octets are then encoded with an 8-bit/10-bit encoder.
The 8-bit/10-bit encoder works by taking eight bits of data (an
octet) and encoding them into a 10-bit symbol. Figure 156
shows how the 14-bit data is taken from the ADC, how the tail
bits are added, how the two octets are scrambled, and how the
octets are encoded into two 10-bit symbols. Figure 156 illustrates
the default data format.
AD9680 Data Sheet
Rev. E | Page 66 of 105
ADC
A
ADC
B
SYSREF±
SYNCINB±
CONVE RTER A
INPUT
CONVE RTER B
INPUT
CONVE RTER 0
CONVE RTER 1
SERDOUT0–,
SERDOUT0+
SERDOUT1–,
SERDOUT1+
SERDOUT2–,
SERDOUT2+
SERDOUT3–,
SERDOUT3+
LANE MUX
AND MAPPING
(SPI
REG 0x5B0,
REG 0x5B2,
REG 0x5B3,
REG 0x5B5,
REG 0x5B6)
JESD204B L INK
CONTROL
(L.M.F)
(SPI REG 0x570)
MUX/
FORMAT
(SPI
REG 0x561,
REG 0x564)
11752-050
Figure 155. Transmit Link Simplified Block Diagram Showing Full Bandwidth Mode (Register 0x200 = 0x00)
8-BIT/10-BIT
ENCODER
SERDOUT0±
SERDOUT1±
TAIL BITS
0x571[6]
SERIALIZER
ADC
SYMBOL0 SYMBOL1
A13
A12
A11
A10
A9
A8
A7
A6
A5
A4
A3
A2
A1
A0
C2
C1
C0
MSB
LSB
CONT ROL BITS
ADC TEST PATTERNS
(RE0x550,
REG 0x551 TO
REG 0x558)JESD204B SAMPLE
CONSTRUCTION
JESD204B
INTERFACE
TEST PATTERN
(REG 0x573,
REG 0x551 TO
REG 0x558)
FRAME
CONSTRUCTION
JESD20 4 B DATA
LI NK LAYE R TES T
PATTERNS
REG 0x574[2:0]
SCRAMBLER
1 + x14 + x15
(OPTIONAL)
A13
A12
A11
A10
A9
A8
A7
A6
A5
A4
A3
A2
A1
A0
C2
T
MSB
LSB
OCTET 0
OCTET 1
S7
S6
S5
S4
S3
S2
S1
S0
S7
S6
S5
S4
S3
S2
S1
S0
MSB
LSB
OCTET 0
OCTET 1
abcde f ghij
abc d efghi j
abijab i j
11752-051
JESD204B
LO NG TRANSPORT
TEST PATTERN
REG 0x571[5]
Figure 156. ADC Output Data Path Showing Data Framing
TRANSPORT
LAYER PHYSICAL
LAYER
DATA L INK
LAYER
Tx OUTPUT
SAMPLE
CONSTRUCTION FRAME
CONSTRUCTION SCRAMBLER ALIGNMENT
CHARACTER
GENERATION 8-BIT/10-BIT
ENCODER CROSSBAR
MUX SERIALIZER
PROCESSED
SAMPLES
FRO M ADC
SYSREF±
SYNCINB±
11752-052
Figure 157. Data Flow
FUNCTIONAL OVERVIEW
The block diagram in Figure 157 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 open source initiative (OSI) model widely
used to describe the abstraction layers of communications
systems. These layers are the transport layer, data link layer,
and physical layer (serializer and output driver).
Transport Layer
The transport layer handles packing the data (consisting of
samples and optional control bits) into JESD204B frames that
are mapped to 8-bit octets. These octets are sent to the data link
layer. The transport layer mapping is controlled by rules derived
from the link parameters. Tail bits are added to fill gaps where
required. The following equation can be used to determine the
number of tail bits within a sample (JESD204B word):
T = NCS
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, inserting control characters for multichip
synchronization/lane alignment/monitoring, and encoding
8-bit octets into 10-bit symbols. 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 to verify the settings in the transport layer.
Data Sheet AD9680
Rev. E | Page 67 of 105
Physical Layer
The physical layer consists of the high speed circuitry clocked at
the serial clock rate. In this layer, parallel data is converted into
one, two, or four lanes of high speed differential serial data.
JESD204B LINK ESTABLISHMENT
The AD9680 JESD204B transmitter (Tx) interface operates in
Subclass 1 as defined in the JEDEC Standard 204B (July 2011
specification). The link establishment process is divided into the
following steps: code group synchronization and SYNCINB±,
initial lane alignment sequence, and user data and error correction.
Code Group Synchronization (CGS) and SYNCINB±
The CGS is the process by which the JESD204B receiver finds
the boundaries between the 10-bit symbols in the stream of
data. During the CGS phase, the JESD204B transmit block
transmits /K28.5/ characters. The receiver must locate /K28.5/
characters in its input data stream using clock and data recovery
(CDR) techniques.
The receiver issues a synchronization request by asserting the
SYNCINB± pin of the AD9680 low. The JESD204B Tx then begins
sending /K/ characters. Once the receiver has synchronized, it waits
for the correct reception of at least four consecutive /K/ symbols. It
then deasserts SYNCINB±. The AD9680 then transmits an ILAS
on the following local multiframe clock (LMFC) boundary.
For more information on the code group synchronization
phase, refer to the JEDEC Standard JESD204B, July 2011,
Section 5.3.3.1.
The SYNCINB± pin operation can also be controlled by the
SPI. The SYNCINB± signal is a differential dc-coupled LVDS
mode signal by default, but it can also be driven single-ended.
For more information on configuring the SYNCINB± pin
operation, refer to Register 0x572.
The SYNCINB± pins can also be configured to run in CMOS
(single-ended) mode, by setting Bit[4] in Register 0x572. When
running SYNCINB± in CMOS mode, connect the CMOS
SYNCINB signal to Pin 21 (SYNCINB+) and leave Pin 20
(SYNCINB−) floating.
Initial Lane Alignment Sequence (ILAS)
The ILAS phase follows the CGS phase and begins on the next
LMFC boundary. The ILAS consists of four multiframes, 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 158. 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/ character (/K28.4/), followed by link configuration
parameters over 14 configuration octets (see Table 24) and
ends with an /A/ character. Many of the parameter values
are of the value 1 notation.
Multiframe 3. Begins with an /R/ character (/K28.0/) and
ends with an /A/ character (/K28.3/).
Multiframe 4. Begins with an /R/ character (/K28.0/) and
ends with an /A/ character (/K28.3/).
User Data and Error Detection
After the initial lane alignment sequence is complete, the user
data is sent. Normally, within a frame, all characters are considered
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 it can be disabled using the 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 receiver (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 asserting 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 can be modified using SPI.
The frame alignment character insertion (FACI) is enabled by
default. More information on the link controls is available in the
Memory Map section, Register 0x571.
8-Bit/10-Bit Encoder
The 8-bit/10-bit encoder converts 8-bit octets into 10-bit symbols
and inserts control characters into the stream when needed.
The control characters used in JESD204B are shown in Table 24.
The 8-bit/10-bit encoding ensures that the signal is dc balanced by
using the same number of ones and zeros across multiple symbols.
The 8-bit/10-bit interface has options that can be controlled via
the SPI. These operations include bypass and invert. These options
are troubleshooting tools for the verification of the digital front
end (DFE). See the Memory Map section, Register 0x572[2:1]
for information on configuring the 8-bit/10-bit encoder.
AD9680 Data Sheet
Rev. E | Page 68 of 105
KK R D D AR Q C C D D A R D D A R D D A D
START OF
ILAS START OF LINK
CONF IGURATI ON DATA
END OF
MULTIFRAME
START OF
USER DAT A
11752-053
Figure 158. Initial Lane Alignment Sequence
Table 24. AD9680 Control Characters used in JESD204B
Abbreviation Control Symbol 8-Bit Value
10-Bit Value,
RD1 = −1
10-Bit Value,
RD1 = +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 0100 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
1 RD means running disparity.
PHYSICAL LAYER (DRIVER) OUTPUTS
Digital Outputs, Timing, and Controls
The AD9680 physical layer consists of drivers that are defined in
the JEDEC Standard JESD204B, July 2011. The differential digital
outputs are powered up by default. The drivers use a dynamic
100 Ω 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 159). Alternatively, single-ended 50 Ω termination
can be used. When single-ended termination is used, the
termination voltage is DRVDD/2. Otherwise, 0.1 µF ac coupling
capacitors can be used to terminate to any single-ended voltage.
OR
SERDOUTx+
DRVDD
VRXCM
SERDOUTx–
OUTPUT S WI NG = 300mV p-p
0.1µF
100Ω
50Ω50Ω
0.1µF
RECEIVER
VCM = VRXCM
100Ω
DIFFERENTIAL
TRACE P AIR
11752-054
Figure 159. AC-Coupled Digital Output Termination Example
The AD9680 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 Ω termination
resistor placed as close to the receiver inputs as possible. The
common mode of the digital output automatically biases itself
to half the DRVDD supply of 1.2 V (VCM = 0.6 V). See Figure 160
for dc coupling the outputs to the receiver logic.
SERDOUTx+
DRVDD
SERDOUTx–
OUTPUT S WI NG = 300mV p-p
100Ω RECEIVER
VCM = DRV DD/2
100Ω
DIFFERENTIAL
TRACE P AIR
11752-055
Figure 160. DC-Coupled Digital Output Termination Example
If there is no far-end receiver termination, or if there is poor
differential trace routing, timing errors can 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.
Figure 161 to Figure 166 show an example of the digital output
data eye, time interval error (TIE) jitter histogram, and bathtub
curve for one AD9680 lane running at 10 Gbps and 6 Gbps,
respectively. The format of the output data is twos complement
by default. To change the output data format, see the Memory Map
section (Register 0x561 in Table 39).
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. Use the de-emphasis feature
only 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 can cause the receiver eye
Data Sheet AD9680
Rev. E | Page 69 of 105
diagram to fail. Use the de-emphasis setting with caution
because it can increase electromagnetic interference (EMI). See
the Memory Map section (Register 0x5C1 to Register 0x5C5 in
Table 39) for more details.
Phase-Locked Loop
The phase-locked loop (PLL) is used to generate the serializer
clock, which operates at the JESD204B lane rate. The status of
the PLL lock can be checked in the PLL locked status bit
(Register 0x56F, Bit 7). This read only bit lets the user know if
the PLL has achieved a lock for the specific setup. The JESD204B
lane rate control, Bit 4 of Register 0x56E, must be set to
correspond with the lane rate.
400
–400
–300
–200
–100
0
100
200
300
–100 –80 –60 –40 –20 020 40 60 80
VOLT AGE (mV)
TIME (p s)
Tx EYE
MASK
11752-500
Figure 161. Digital Outputs Data Eye, External 100 Ω Terminations
at 10 Gbps
12000
10000
8000
6000
4000
2000
0–4 –2 0 2 4 6
HITS
TIME (ps)
11752-501
Figure 162. Digital Outputs Histogram, External 100 Ω Terminations
at 10 Gbps
1
1
–2
1
–4
1
–6
1
–8
1
–10
1
–12
1
–16
1
–14
–0.5 –0.4 –0.3 –0.2 –0.1 00.1 0.2 0.3 0.4 0.5
BER
UI
11752-502
Figure 163. Digital Outputs Bathtub Curve, External 100 Ω Terminations
at 10 Gbps
400
–400
–300
–200
–100
0
100
200
300
–150 –100 –50 050 100 150
VOLT AGE (mV)
TIME (ps)
Tx EYE
MASK
11752-503
Figure 164. Digital Outputs Data Eye, External 100 Ω Terminations
at 6 Gbps
AD9680 Data Sheet
Rev. E | Page 70 of 105
8000
6000
4000
2000
7000
4000
3000
1000
0–4 –3 –2 –1 013
24
HITS
TIME (p s)
11752-504
Figure 165. Digital Outputs Histogram, External 100 Ω Terminations
at 6 Gbps
1
1–2
1–4
1–6
1–8
1–10
1–12
1–16
1–14
–0.5 –0.4 –0.3 –0.2 –0.1 00.1 0.2 0.3 0.4 0.5
BER
UI
11752-505
Figure 166. Digital Outputs Bathtub Curve, External 100 Ω Terminations
at 6 Gbps
Data Sheet AD9680
Rev. E | Page 71 of 105
JESD204B TX CONVERTER MAPPING
To support the different chip operating modes, the AD9680
design treats each sample stream (real or I/Q) as originating
from separate virtual converters. The I/Q samples are always
mapped in pairs with the I samples mapped to the first virtual
converter and the Q samples mapped to the second virtual
converter. With this transport layer mapping, the number of
virtual converters are the same whether
A single real converter is used along with a digital
downconverter block producing I/Q outputs, or
An analog downconversion is used with two real
converters producing I/Q outputs.
Figure 167 shows a block diagram of the two scenarios
described for I/Q transport layer mapping.
The JESD204B Tx block for AD9680 supports up to four DDC
blocks. Each DDC block outputs either two sample streams (I/Q)
for the complex data components (real + imaginary), or one
sample stream for real (I) data. The JESD204B interface can be
configured to use up to eight virtual converters depending on the
DDC configuration. Figure 168 shows the virtual converters and
their relationship to the DDC outputs when complex outputs
are used. Table 25 shows the virtual converter mapping for each
chip operating mode when channel swapping is disabled.
REAL
I
Q
I
CONVE RTER 0
Q
CONVE RTER 1
ADC
ADC
90°
PHASE
Σ
JESD204B
Tx L LANES
I/Q ANALOG MIXING
M = 2
ADC
REAL REAL
I
CONVE RTER 0
Q
CONVE RTER 1
JESD204B
Tx L LANES
DIGITAL DOWNCO NVERSION
M = 2
DIGITAL
DOWN
CONVERSION
11752-058
Figure 167. I/Q Transport Layer Mapping
DDC 0
I
Q
I
Q
REAL/I
CONV E RT E R 0
Q
CONV E RT E R 1
REAL/I
REAL/Q
DDC 1
I
Q
I
Q
REAL/I
CONV E RT E R 2
Q
CONV E RT E R 3
REAL/I
REAL/Q
DDC 2
I
Q
I
Q
REAL/I
CONV E RT E R 4
Q
CONV E RT E R 5
REAL/I
REAL/Q
DDC 3
I
Q
I
Q
REAL/I
CONV E RT E R 6
Q
CONV E RT E R 7
REAL/I
REAL/Q
OUTPUT
INTERFACE
I/Q
CROSSBAR
MUX
ADC A
SAMPLING
AT
fS
REAL/I
ADC B
SAMPLING
AT
fS
REAL/Q
11752-059
Figure 168. DDCs and Virtual Converter Mapping
AD9680 Data Sheet
Rev. E | Page 72 of 105
Table 25. Virtual Converter Mapping
Number of
Virtual
Converters
Supported
Chip
Operating
Mode (0x200,
Bits[1:0])
Chip Q
Ignore
(0x200, Bit 5)
Virtual Converter Mapping
0 1 2 3 4 5 6 7
1 to 2 Full bandwidth
mode (0x0)
Real or
complex
(0x0)
ADC A
samples
ADC B
samples
Unused Unused Unused Unused Unused Unused
1 One DDC
mode
(0x1)
Real (I only)
(0x1)
DDC 0 I
samples
Unused Unused Unused Unused Unused Unused Unused
2 One DDC
mode
(0x1)
Complex (I/Q)
(0x0)
DDC 0 I
samples
DDC 0 Q
samples
Unused Unused Unused Unused Unused Unused
2 Two DDC
mode
(0x2)
Real (I only)
(0x1)
DDC 0 I
samples
DDC 1 I
samples
Unused Unused Unused Unused Unused Unused
4
Two DDC
mode
(0x2)
Complex (I/Q)
(0x0)
DDC 0 I
samples
DDC 0 Q
samples
DDC 1 I
samples
DDC 1 Q
samples
Unused
Unused
Unused
Unused
4
Four DDC
mode
(0x3)
Real (I only)
(0x1)
DDC 0 I
samples
DDC 1 I
samples
DDC 2 I
samples
DDC 3 I
samples
Unused
Unused
Unused
Unused
8
Four DDC
mode
(0x3)
Complex (I/Q)
(0x0)
DDC 0 I
samples
DDC 0 Q
samples
DDC 1 I
samples
DDC 1 Q
samples
DDC 2 I
samples
DDC 2 Q
samples
DDC 3 I
samples
DDC 3 Q
samples
Data Sheet AD9680
Rev. E | Page 73 of 105
CONFIGURING THE JESD204B LINK
The AD9680 has one JESD204B link. The device offers an easy
way to set up the JESD204B link through the JESD04B quick
configuration register (Register 0x570). The serial outputs
(SERDOUT0± to SERDOUT3±) are considered to be part of
one JESD204B link. The basic parameters that determine the
link setup are
Number of lanes per link (L)
Number of converters per link (M)
Number of octets per frame (F)
If the internal DDCs are used for on-chip digital processing, M
represents the number of virtual converters. The virtual converter
mapping setup is shown in Figure 168.
The maximum lane rate allowed by the JESD204B specification
is 12.5 Gbps. The lane line rate is related to the JESD204B
parameters using the following equation:
L
fNM
RateLineLane
OUT
×
××
=8
10
'
where
RatioDecimation
f
f
CLOCKADC
OUT
_
=
The decimation ratio (DCM) is the parameter programmed in
Register 0x201.
The following steps can be used to configure the output:
1. Power down the link.
2. Select quick configuration options.
3. Configure detailed options.
4. Set output lane mapping (optional).
5. Set additional driver configuration options (optional).
6. Power up the link.
If the lane line rate calculated is less than 6.25 Gbps, select
the low line rate option by programming a value of 0x10 to
Register 0x56E.
Table 26 and Table 27 show the JESD204B output configurations
supported for both N΄ = 16 and N΄ = 8 for a given number of
virtual converters. Take care to ensure that the serial line rate
for a given configuration is within the supported range of
3.125 Gbps to 12.5 Gbps.
Table 26. JESD204B Output Configurations for = 16
Number of Virtual
Converters
Supported
(Same Value as M)
JESD204B Quick
Configuration
(0x570)
JESD204B Serial
Line Rate1
JESD204B Transport Layer Settings2
L M F S HD N CS K3
1 0x01 20 × fOUT 1 1 2 1 0 8 to 16 16 0 to 3 Only valid K
values that
are divisible
by 4 are
supported
0x40
10 × f
OUT
2
1
1
1
1
8 to 16
16
0 to 3
0x41 10 × fOUT 2 1 2 2 0 8 to 16 16 0 to 3
0x80 5 × fOUT 4 1 1 2 1 8 to 16 16 0 to 3
0x81 5 × fOUT 4 1 2 4 0 8 to 16 16 0 to 3
2 0x0A 40 × fOUT 1 2 4 1 0 8 to 16 16 0 to 3
0x49 20 × fOUT 2 2 2 1 0 8 to 16 16 0 to 3
0x88 10 × fOUT 4 2 1 1 1 8 to 16 16 0 to 3
0x89 10 × fOUT 4 2 2 2 0 8 to 16 16 0 to 3
4 0x13 80 × fOUT 1 4 8 1 0 8 to 16 16 0 to 3
0x52 40 × fOUT 2 4 4 1 0 8 to 16 16 0 to 3
0x91 20 × fOUT 4 4 2 1 0 8 to 16 16 0 to 3
8 0x1C 160 × fOUT 1 8 16 1 0 8 to 16 16 0 to 3
0x5B 80 × fOUT 2 8 8 1 0 8 to 16 16 0 to 3
0x9A 40 × fOUT 4 8 4 1 0 8 to 16 16 0 to 3
1 fOUT = output sample rate = ADC sample rate/chip decimation ratio. The JESD204B serial line rate must be ≥3125 Mbps and ≤12,500 Mbps; when the serial line rate is
≤12.5 Gbps and ≥ 6.25 Gbps, the low line rate mode must be disabled (set Bit 4 to 0x0 in 0x56E). When the serial line rate is <6.25 Gbps and ≥3.125 Gbps, the low line
rate mode must be enabled (set Bit 4 to 0x1 in 0x56E).
2 JESD204B transport layer descriptions are as described in the JESD204B Overview section.
3 For F = 1, K = 20, 24, 28, and 32. For F = 2, K = 12, 16, 20, 24, 28, and 32. For F = 4, K = 8, 12, 16, 20, 24, 28, and 32. For F = 8 and F = 16, K = 4, 8, 12, 16, 20, 24, 28, and 32.
AD9680 Data Sheet
Rev. E | Page 74 of 105
Table 27. JESD204B Output Configurations for = 8
Number of Virtual
Converters Supported
(Same Value as M)
JESD204B Quick
Configuration
(0x570) Serial Line Rate1
JESD204B Transport Layer Settings2
L M F S HD N CS K3
1 0x00 10 × fOUT 1 1 1 1 0 7 to 8 8 0 to 1 Only valid K
values which
are divisible
by 4 are
supported
0x01 10 × fOUT 1 1 2 2 0 7 to 8 8 0 to 1
0x40 5 × fOUT 2 1 1 2 0 7 to 8 8 0 to 1
0x41 5 × fOUT 2 1 2 4 0 7 to 8 8 0 to 1
0x42 5 × fOUT 2 1 4 8 0 7 to 8 8 0 to 1
0x80 2.5 × fOUT 4 1 1 4 0 7 to 8 8 0 to 1
0x81 2.5 × fOUT 4 1 2 8 0 7 to 8 8 0 to 1
2 0x09 20 × fOUT 1 2 2 1 0 7 to 8 8 0 to 1
0x48 10 × fOUT 2 2 1 1 0 7 to 8 8 0 to 1
0x49 10 × fOUT 2 2 2 2 0 7 to 8 8 0 to 1
0x88 5 × fOUT 4 2 1 2 0 7 to 8 8 0 to 1
0x89 5 × fOUT 4 2 2 4 0 7 to 8 8 0 to 1
0x8A 5 × fOUT 4 2 4 8 0 7 to 8 8 0 to 1
1 fOUT = output sample rate = ADC sample rate/chip decimation ratio. The JESD204B serial line rate must be ≥3125 Mbps and ≤12,500 Mbps; when the serial line rate is
12.5 Gbps and ≥6.25 Gbps, the low line rate mode must be disabled (set Bit 4 to 0x0 in Register 0x56E). When the serial line rate is <6.25 Gbps and3.125 Gbps, the
low line rate mode must be enabled (set Bit 4 to 0x1 in Register 0x56E).
2 JESD204B transport layer descriptions are as described in the JESD204B Overview section.
3 For F = 1, K = 20, 24, 28, and 32. For F = 2, K = 12, 16, 20, 24, 28, and 32. For F = 4, K = 8, 12, 16, 20, 24, 28, and 32. For F = 8 and F = 16, K = 4, 8, 12, 16, 20, 24, 28, and 32.
See the Example 1: Full Bandwidth Mode section and the
Example 2: ADC with DDC Option (Two ADCs Plus Four
DDCs) section for two examples describing which JESD204B
transport layer settings are valid for a given chip mode.
Example 1: Full Bandwidth Mode
Chip application mode = full bandwidth mode (see Figure 169).
Two 14-bit converters at 1000 MSPS
Full bandwidth application layer mode
No decimation
JESD204B output configuration is as follows:
Two virtual converters required (see Table 26)
Output sample rate (fOUT) = 1000/1 = 1000 MSPS
JESD204B supported output configurations (see Table 26)
include:
N΄ = 16 bits
N = 14 bits
L = 4, M = 2, and F = 1, or L = 4, M = 2, and F = 2 (quick
configuration = 0x88 or 0x89)
CS = 0 to 2
K = 32
Output serial line rate = 10 Gbps per lane, low line rate
mode disabled
JESD204B
TRANSMIT
INTERFACE
FAST
DETECTION
FAST
DETECTION
CMOS
CMOS
CONVE RTER 0
CONVE RTER 1
14-BIT
AT
1Gbps
REAL/I
14-BIT
AT
1Gbps
REAL/Q
L
JESD204B
LANES
AT UP TO
12.5Gbps
11752-060
Figure 169. Full Bandwidth Mode
Example 2: ADC with DDC Option (Two ADCs Plus Four
DDCs)
Chip application mode = four-DDC mode. (see Figure 170).
Two 14-bit converters at 1 GSPS
Four DDC application layer mode with complex outputs
(I/Q)
Chip decimation ratio = 16
DDC decimation ratio = 16 (see Table 15).
JESD204B output configuration is as follows:
Virtual converters required = 8 (see Table 26)
Output sample rate (fOUT) = 1000/16 = 62.5 MSPS
Data Sheet AD9680
Rev. E | Page 75 of 105
JESD204B supported output configurations (see Table 26):
N΄ = 16 bits
N = 14 bits
L = 1, M = 8, and F = 16, or L = 2, M = 8, and F = 8 (quick
configuration = 0x1C or 0x5B)
CS = 0 to 1
K = 32
Output serial line rate = 10 Gbps per lane (L = 1) or 5 Gbps
per lane (L = 2)
For L = 1, low line rate mode is disabled. For L = 2, low line
rate mode is enabled.
Example 2 shows the flexibility in the digital and lane
configurations for the AD9680. The sample rate is 1 GSPS;
however, the outputs are all combined in either one or two
lanes, depending on the I/O speed capability of the receiving
device.
DDC 0
I
CONVE RTER 0
Q
CONVE RTER 1
REAL/I
DDC 1
I
CONVE RTER 2
Q
CONVE RTER 3
REAL/Q
DDC 2
I
CONVE RTER 4
Q
CONVE RTER 5
REAL/I
DDC 3
I
CONVE RTER 6
Q
CONVE RTER 7
REAL/Q
I/Q
CROSSBAR
MUX
ADC A
SAMPLING
AT
fS
REAL
ADC B
SAMPLING
AT
fS
REAL
SYNCHRONIZATION
CONT ROL CIRCUI TS
SYSREF
11752-061
L JES D204B
LANES UP TO
12.5Gbps
L
JESD204B
LANES
AT UP TO
12.5Gbps
Figure 170. Two ADC Plus Four DDC Mode
AD9680 Data Sheet
Rev. E | Page 76 of 105
DETERMINISTIC LATENCY
Both ends of the JESD204B link contain various clock domains
distributed throughout each system. Data traversing from one
clock domain to a different clock domain can lead to
ambiguous delays in the JESD204B link. These ambiguities lead
to nonrepeatable latencies across the link from one power cycle
or link reset to the next. Section 6 of the JESD204B specification
addresses the issue of deterministic latency with mechanisms
defined as Subclass 1 and Subclass 2.
The AD9680 supports JESD204B Subclass 0 and Subclass 1
operation. Register 0x590, Bit 5 sets the subclass mode for the
AD9680; the default mode is the Subclass 1 operating mode
(Register 0x590, Bit 5 = 1). If deterministic latency is not a
system requirement, Subclass 0 operation is recommended and
the SYSREF± signal may not be required. Even in Subclass 0
mode, the SYSREF± signal may be required in an application
where multiple AD9680 devices must be synchronized with each
other. This topic is addressed in the Timestamp Mode section.
SUBCLASS 0 OPERATION
If there is no requirement for multichip synchronization while
operating in Subclass 0 mode (Register 0x590, Bit 5 = 0), the
SYSREF± input can be left disconnected. In this mode, the
relationship of the JESD204B clocks between the JESD204B trans-
mitter and receiver are arbitrary but does not affect the ability of the
receiver to capture and align the lanes within the link.
SUBCLASS 1 OPERATION
The JESD204B protocol organizes data samples into octets, frames,
and multiframes as described in the Transport Layer section.
The local multiframe clock (LMFC) is synchronous with the
beginnings of these multiframes. In Subclass 1 operation, the
SYSREF± signal synchronizes the LMFCs for each device in a
link or across multiple links (within the AD9680, SYSREF± also
synchronizes the internal sample dividers), as shown in Figure 171.
The JESD204B receiver uses the multiframe boundaries and
buffering to achieve consistent latency across lanes (or even
multiple devices), and also to achieve a fixed latency between
power cycles and link reset conditions.
Deterministic Latency Requirements
Several key factors are required for achieving deterministic
latency in a JESD204B Subclass 1 system:
SYSREF± signal distribution skew within the system must
be less than the desired uncertainty for the system.
SYSREF± setup and hold time requirements must be met
for each device in the system.
The total latency variation across all lanes, links, and
devices must be ≤1 LMFC period (see Figure 171). This
includes both variable delays and the variation in fixed
delays from lane to lane, link to link, and device to device
in the system.
Setting Deterministic Latency Registers
The JESD204B receive buffer in the logic device buffers data
starting on the LMFC boundary. If the total link latency in the
system is near an integer multiple of the LMFC period, it is possible
that from one power cycle to the next, the data arrival time at
the receive buffer may straddle an LMFC boundary. To ensure
deterministic latency in this case, a phase adjustment of the
LMFC at either the transmitter or receiver must be performed.
Typically, adjustments to accommodate the receive buffer are
made to the LMFC of the receiver. In the AD9680, this adjustment
can be made using the LMFC offset bits (Register 0x578, Bits[4:0]).
These bits delay the LMFC in frame clock increments, depending
on the F parameter, which is the number of octets per lane per
frame). For F = 1, every 4th setting (0, 4, 8, …, and so on) results
in a 1-frame clock shift. For F = 2, every other setting (0, 2, 4, …,
and so on) results in a 1-frame clock shift. For all other values
of F, each setting results in a 1-frame clock shift.
ILASDATA
SYSREF
All LMFCs
DATA
DEVI CE CLO CK
SYSREF-ALIGNED
GLOBAL LMFC
POWER CY CLE VARIAT ION
(MUST BE <
tLMFC
)
SYSREF TO L MF C DELAY
11752-064
Figure 171. SYSREF± and LMFC
Data Sheet AD9680
Rev. E | Page 77 of 105
Figure 172 shows that, in the case where the link latency is near
an LMFC boundary, the local LMFC of the AD9680 can be
delayed to in turn delay the data arrival time at the receiver.
Figure 173 shows how the LMFC of the receiver is delayed to
accommodate the receive buffer timing. Refer to the applicable
JESD204B receiver user guide for details on making this
adjustment. If the total latency in the system is not near an
integer multiple of the LMFC period, or if the appropriate
adjustments have been made to the LMFC phase at the clock
source, it is still possible to have variable latency from one
power cycle to the next. In this case, check for the possibility
that the setup and hold time requirements for the SYSREF±
signal are not being met. Perform this check by reading the
SYSREF± setup and hold monitor register (Register 0x128).
This function is described in the SYSRE Setup/Hold Window
Monitor section.
If reading Register 0x128 indicates a timing problem, there are
adjustments that can made in the AD9680. Changing the
SYSREF± level used for alignment is possible using the SYSREF±
transition select bit (Register 0x120, Bit 4). Also, changing
which edge of the clock is used to capture SYSREF± can be
performed using the clock edge select bit (Register 0x120,
Bit 3). Both of these options are described in the SYSREF±
Control Features section. If neither of these measures help
achieve an acceptable setup and hold time, adjusting the phase
of SYSREF± and/or the device clock (CLK±) may be required.
SYREF-ALIGNED
GLOBAL LMFC
POWER CY CLE VARIATIO N
ILAS DATA
ILAS DATA
DATA
(AT Tx I NP UT)
DATA
(AT Rx INPUT)
Tx LOCAL LMFC
Tx L M FC MOVED ( DE LAYI NG T HE ARRIVAL OF DATA RELATIVE
TO THE GLOBAL LMFC) SO THE RECEIVE BUFFER RELEASE
TIME IS ALW AYS REFERENCED TO THE SAME LMFC EDGE
LMFCTX DELAY TIME
11752-702
Figure 172. Adjusting the JESD204B Tx LMFC in the AD9680
SYREF-ALIGNED
GLOBAL LMFC
DATA
(AT Tx I NP UT)
DATA
(AT Rx INPUT)
Rx LOCAL LMFC
POWER CY CLE VARIAT ION
ILAS ILAS DATA
ILAS DATA
Rx LMFC MOVED SO THE RECEIVE BUFFER RELEASE TIME
IS ALWAYS REFERENCED TO THE SAME LMFC EDGE
LMFC
RX
DELAY TIME
11752-703
Figure 173. Adjusting the JESD204B Rx LMFC in the Logic Device
AD9680 Data Sheet
Rev. E | Page 78 of 105
MULTICHIP SYNCHRONIZATION
The flowchart shown in Figure 175 describes the internal
mechanism for multichip synchronization in the AD9680.
There are two methods by which multichip synchronization can
take place, as determined by the chip synchronization mode bit
(Register 0x1FF , Bit 0). Each method involves different
applications of the SYSREF± signal.
NORMAL MODE
The default sate of the chip synchronization mode bit is 0,
which configures the AD9680 for normal chip synchronization.
The JESD204B standard specifies the use of SYSREF± to provide
deterministic latency within a single link. This same concept, when
applied to a system with multiple converters and logic devices, can
also provide multichip synchronization. In Figure 175, this is
referred to as normal mode. Following the process outlined in the
flowchart ensures that the AD9680 is configured appropriately.
Consult the logic devices user intellectual property (IP) guide to
ensure that the JESD204B receivers are configured appropriately.
TIMESTAMP MODE
For all AD9680 full bandwidth operating modes, the SYSREF
input can also be used to timestamp samples. This is another
method by which multiple channels and multiple devices can
achieve synchronization. This is especially effective when
synchronizing multiple devices to one or more logic devices.
The logic devices simply buffer the data streams, identify the
time stamped samples and align them. When the chip
synchronization mode bit (0x1FF [0]) is set to 1, the timestamp
method is used for synchronization of multiple channels and/or
devices. In timestamp mode, the clocks are not reset but
instead, the coinciding sample is time stamped using the
JESD204B control bits of that sample. To operate in timestamp
mode, these additional settings are necessary:
Continuous or N-shot SYSREF enabled (0x120[2:1] = 1 or 2)
At least one control bit must be enabled (CS > 0,
Register 0x58F, Bits[7:6] = 1, 2, or 3)
Set the function for one of the control bits to SYSREF
Register 0x559, Bits[2:0] = 5 if using Control Bit 0
Register 0x559, Bits[6:4] = 5 if using Control Bit 1
Register 0x55A, Bits[2:0] = 5 if using Control Bit 2
Control bits must be enabled MSB first. In other words, if only
using one control bit (CS = 1), Control Bit 2 must be enabled. If
two control bits are sued, then Control Bits[2:1] must be enabled.
Figure 174 provides an illustration of how the input sample
coincident with SYSREF is time stamped and ultimately output
of the ADC. In this example, there are two control bits and
Control Bit 1 is the bit indicating which sample was coincident
with the SYSREF rising edge. Note that the pipeline latencies for
each channel are identical. If so desired, the SYSREF timestamp
delay register (0x123) can be used to adjust the timing of which
sample is time stamped.
Note that time stamping is not supported by any AD9680
operating modes that use decimation.
SYSREF
A
IN
B
A
IN
A
ENCO DE CLK
N
N – 1
N + 3
N + 2
N + 1
N
N – 1
N + 3
N + 2
N + 1 CHANNEL B
CHANNEL A N – 1 NN + 1
N + 1
N + 2 N + 3 0000 0100 00
N – 1 NN + 2 N + 3 0000 0100 00
14-BIT SAMPLES O UT
2 CONTROL BITS
CONTROL BI T 0 USED TO
TIME ST AMP AMPLE N
11752-704
Figure 174. AD9680 TimestampingCS = 2 (Register 0x58F, Bits[7:6] = 2), Control Bit 1 is SYSREF± (Register 0x559, Bits[6:4] = 5)
Data Sheet AD9680
Rev. E | Page 79 of 105
YES
CLEAR SYSREF
IG NORE COUNTE R
AND DISABLE S Y S RE F
(CL E AR BI T 2 I N 0x0120)
INCREMENT
SYSREF IGNORE
COUNTER
UPDATE
SETUP/HOLD
DETE CTO R S TATUS
(0x128)
YES
NO
SYSREF
ENABLED?
(0x120)
SYSREF
MODE
(0x120)
NO
CLOCK
DIVIDER
> 1?
(0x10B)
YES
NO
INPUT
CLOCK
DIVIDER
ALIGNMENT
REQUIRED?
YES
NO
NO
YES
ALIGN CLOCK
DIVIDER
PHASE TO
SYSREF
SYNCHRONIZATION
MODE?
(0x1FF)
TIMESTAMP
MODE
NORMAL
MODE
YES SYSREF±
INSERTED
IN JES D204B
CONTROL BITS
BACK TO S TART
NO
DDC NCO
ALIGNMENT
ENABLED?
(0x300)
YES
NO NO
YES SEND K28. 5
CHARACTERS
NORMAL
JESD204B
INITIALIZATION
SYSREF±
ENABLE D IN
CONTROL BITS?
(0x559, 0x55A,
0x58F)
RESET
SYSREF± IGNORE
COUNTER
START
SYSREF±
ASSERTED? YES N-SHOT
MODE
CONTINUOUS
MODE
NO
YES
ALIGN SIGNAL
MONITOR
COUNTERS
YES
NO NO
YES
NO
INCREMENT
SYSREF
COUNTER
(0x12A)
SYSREF±
TIMESTAMP
DELAY
(0x123)
BACK TO S TART
SYSREF±
IGNORE
COUNTER
EXPIRED?
(0x121)
CLOCK
DIVIDER
AUTO ADJUS T
ENABLED?
(0x10D)
RAMP
TEST
MODE
ENABLED?
(0x550)
SYSREF± RESETS
RAMP TEST
MODE
GENERATOR
JESD204B
LMFC
ALIGNMENT
REQUIRED?
ALI GN PHAS E
OF ALL
INT E RNAL CL OCKS
(I NCLUDING LM FC)
TO SYSREF
SEND I NV ALI D
8-BIT/10-BIT
CHARACTERS
(AL L 0's)
SYNC~
ASSERTED
SIGNAL
MONITOR
ALIGNMENT
ENABLED?
(0x26F)
ALI GN DDC
NCO PHAS E
ACCUMULATOR
11752-112
Figure 175. SYSREF± Capture Scenarios and Multichip Synchronization
AD9680 Data Sheet
Rev. E | Page 80 of 105
SYSREF± INPUT
The SYSREF± input signal is used as a high accuracy system
reference for deterministic latency and multichip synchronization.
The AD9680 accepts a single-shot or periodic input signal. The
SYSREF± mode select bits (Register 0x120, Bits[2:1]) select the
input signal type and also arm the SYSREF± state machine
when set. If in single- (or N) shot mode (Register 0x120,
Bits[2:1] = 2), the SYSREF± mode select bit self clears after the
appropriate SYSREF± transition is detected. The pulse width
must have a minimum width of two CLK± periods. If the clock
divider (Register 0x10B, Bits[2:0]) is set to a value other than
divide by 1, then multiply this minimum pulse width
requirement by the divide ratio (for example, if set to divide by
8, the minimum pulse width is 16 CLK± cycles). When using a
continuous SYSREF± signal (Register 0x120, Bits[2:1] = 1), the
period of the SYSREF± signal must be an integer multiple of the
LMFC. Derive the LMFC using the following formula:
LMFC = ADC Clock/S × K
where:
S is the JESD204B parameter for number of samples per
converter.
K is JESD204B parameter for number of frames per multiframe.
The input clock divider, DDCs, signal monitor block, and
JESD204B link are all synchronized using the SYSREF± input
when in normal synchronization mode (Register 0x1FF, Bits[1:0] =
0). The SYSREF± input can also be used to time stamp an ADC
sample to provide a mechanism for synchronizing multiple
AD9680 devices in a system. For the highest level of timing
accuracy, SYSREF± must meet the setup and hold requirements
relative to the CLK± input. There are several features in the
AD9680 to ensure these requirements are met (see the
SYSRE Control Features section).
SYSREF± Control Features
SYSREF± is used, along with the input clock (CLK±), as part of
a source synchronous timing interface and requires setup and
hold timing requirements of 117 ps and −96 ps, relative to the
input clock (see Figure 176). The AD9680 has several features to
meet these requirements. First, the SYSREF± sample event can
be defined as either a synchronous low to high transition
or synchronous high to low transition. Second, the AD9680
allows the SYSREF± signal to be sampled using either the rising
edge or falling edge of the input clock. Figure 176, Figure 177,
Figure 178, and Figure 179 show all four possible combinations.
The third SYSREF± related feature available is the ability to
ignore a programmable number (up to 16) of SYSREF± events.
The SYSREF± ignore feature is enabled by setting the SYSREF±
mode register (Register 0x0120, Bits[2:1]) to 2’b10, which is
labeled as N-shot mode. The AD9680 is able to ignore N
SYSREF± events, which is useful to handle periodic SYSREF±
signals that require time to settle after startup. Ignoring SYSREF±
until the clocks in the system have settled avoids an inaccurate
SYSRE trigger. Figure 180 shows an example of the SYSREF±
ignore feature when ignoring three SYSREF± events.
CLK
SYSREF
HOLD
REQUIREMENT
SETUP
REQUIREMENT
117ps
–96ps
SYSREF
SAMPLE POINT
KEEP OUT WINDOW
11752-706
Figure 176. SYSREF± Setup and Hold Time Requirements; SYSREF± Low to
High Transition Using the Rising Edge Clock (Default)
117ps
–96ps
CLK
SYSREF
HOLD
REQUIREMENT
SETUP
REQUIREMENT
SYSREF
SAMPLE POINT
11752-707
Figure 177. SYSREF± Low to High Transition Using Falling Edge Clock
Capture (Register 0x0120, Bit 4 = 1’b0 and Register 0x0120, Bit 3 = 1’b1)
CLK
SYSREF
117ps
–96ps
HOLD
REQUIREMENT
SETUP
REQUIREMENT
SYSREF
SAMPLE POINT
11752-708
Figure 178. SYSREF± High to Low Transition Using Rising Edge Clock Capture
(Register 0x0120, Bit 4 = 1’b1 and Register 0x0120, Bit 3 = 1’b0)
CLK
SYSREF
117ps
–96ps
HOLD
REQUIREMENT
SETUP
REQUIREMENT
SYSREF
SAMPLE POINT
11752-709
Figure 179. SYSREF± High to Low Transition Using Falling Edge Clock
Capture (Register 0x0120, Bit 4= 1’b1 and Register 0x0120, Bit 3 = 1’b1)
Data Sheet AD9680
Rev. E | Page 81 of 105
CLK
SYSREF
SYSREF SAMPLE PART 1 SYSREF SAMPLE PART 2 SYSREF SAMPLE PART 3 SYSREF SAMPLE PART 4 SYSREF SAMPLE PART 5
IGNORE FIRST T HREE SYSREFs SAMPLE THE FOURTH SYSREF
11752-079
Figure 180. SYSREF± Ignore Example; SYSREF± Ignore Count Bits (Register 0x0121, Bits[3:0]) = 3
CLK
SYSREF
SYSREF SKEW WINDOW = ±3
SYSREF SKEW WINDOW = ±2
SYSREF SKEW WINDOW = ±1
SYSREF SKEW WINDOW = 0
11752-080
Figure 181. SYSREF± Skew Window
When in continuous SYSREF± mode (Register 0x120, Bits[2:1] =
1), the AD9680 monitors the placement of the SYSREF± leading
edge compared to the internal LMFC. If the SYSREF± edge is
captured with a clock edge other than the one that is aligned
with LMFC, the AD9680 initiates a resynchronization of the
link. Because the input clock rates for the AD9680 can be up to
4 GHz, the AD9680 provides another SYSREF± related feature
that makes it possible to accommodate periodic SYSREF±
signals where cycle accurate capture is not feasible or not
required. For these scenarios, the AD9680 has a programmable
SYSREF± skew window that allows the internal dividers to
remain undisturbed, unless SYSREF± occurs outside the skew
window. The resolution of the SYSREF± skew window is set in
sample clock cycles. If the SYSREF± negative skew window is 1
and the positive skew window is 1, then the total skew window
is ±1 sample clock cycles, meaning that, as long as SYSREF± is
captured within ±1 sample clock cycle of the clock that is aligned
with LMFC, the link continues to operate normally. If the SYSRE
has jitter, which can cause a misalignment between SYSRE and
the LMFC, the system continues to run without a resynchro-
nization, while still allowing the device to monitor for larger
errors not caused by jitter. For the AD9680, the positive and
negative skew window is controlled by the SYSREF± window
negative bits (Register 0x0122, Bits[3:2]) and the SYSREF±
window positive bits (Register 0x0122, Bits[1:0]). Figure 181
shows information on the location of the skew window settings
relative to Phase 0 of the internal dividers. Negative skew is defined
as occurring before the internal dividers reach Phase 0 and positive
skew is defined after the internal dividers reach Phase 0.
AD9680 Data Sheet
Rev. E | Page 82 of 105
SYSREF± SETUP/HOLD WINDOW MONITOR
To ensure a valid SYSREF± signal capture, the AD9680 has a
SYSREF± setup/hold window monitor. This feature allows the
system designer to determine the location of the SYSREF±
signals relative to the CLK± signals by reading back the amount
of setup/hold margin on the interface through the memory
map. Figure 182 and Figure 183 show the setup and hold status
values for different phases of SYSREF±. The setup detector
returns the status of the SYSREF± signal before the CLK± edge,
and the hold detector returns the status of the SYSREF signal
after the CLK± edge. Register 0x128 stores the status of
SYSRE and lets the user know if the SYSREF± signal is
captured by the ADC.
Table 28 describes the contents of Register 0x128 and how to
interpret them.
VALID
REG 0x128[ 3: 0]
CLK±
INPUT
SYSREF±
INPUT
FLIP-FLOP
HOLD (MIN)
FLIP-FLOP
HOLD (MIN)
FLIP-FLOP
SETUP (MIN)
11752-113
0xF
0xE
0xD
0xC
0xB
0xA
0x9
0x8
0x7
0x6
0x5
0x4
0x3
0x2
0x1
0x0
Figure 182. SYSREF± Setup Detector
Data Sheet AD9680
Rev. E | Page 83 of 105
CLK±
INPUT
SYSREF±
INPUT VALID
REG 0x128[7:4]
FLIP-FLOP
HOLD (MIN) FLIP-FLOP
HOLD (MIN)
FLIP-FLOP
SETUP (MIN)
11752-114
0xF
0xE
0xD
0xC
0xB
0xA
0x9
0x8
0x7
0x6
0x5
0x4
0x3
0x2
0x1
0x0
Figure 183. SYSREF± Hold Detector
Table 28. SYSREF± Setup/Hold Monitor, Register 0x128
Register 0x128[7:4]
Hold Status
Register 0x128[3:0]
Setup Status Description
0x0 0x0 to 0x7 Possible setup error. The smaller this number, the smaller the setup margin.
0x0 to 0x8
0x8
No setup or hold error (best hold margin).
0x8 0x9 to 0xF No setup or hold error (best setup and hold margin).
0x8 0x0 No setup or hold error (best setup margin).
0x9 to 0xF 0x0 Possible hold error. The larger this number, the smaller the hold margin.
0x0 0x0 Possible setup or hold error.
AD9680 Data Sheet
Rev. E | Page 84 of 105
LATENCY
END TO END TOTAL LATENCY
Total latency in the AD9680 is dependent on the various digital
signal processing (DSP) and JESD204B configuration modes.
Latency is fixed at 26 encode clocks through the ADC itself;
however, the latency through the DSP and JESD204B blocks can
vary greatly, depending on the configuration. Therefore, total
latency must be calculated based on the DSP options selected
and the JESD204B configuration.
Table 29 shows the combined latency through the ADC and
DSP blocks (including data formatting) for the different
application modes supported by the AD9680. Table 30 shows
the latency through the JESD204B block for each JESD204B
configuration and the various decimation modes supported for
those modes. For both tables, latency is in units of the encode
clock. Latency through the JESD204B clock can also be affected
by the decimation ratio in some JESD204B configurations.
Table 31 shows the latency for these modes for each of the
possible decimation ratios.
Table 29. Latency Through the ADC and DSP Blocks
ADC Application Mode
Latency (No. of
Encode Clocks),
ADC+DSP Total
Full Bandwidth 29
DDC (HB1)
(no mixer, complex outputs)
78
DDC (HB2 + HB1)
(no mixer, complex outputs)
132
DDC (HB3 +HB2 + HB1)
(no mixer, complex outputs)
232
DDC (HB4 + HB3 + HB2 + HB1)
(no mixer, complex outputs)
432
DEC2 + NSR 57
NSR 35
VDR 33
EXAMPLE LATENCY CALCULATION
For a configuration where the ADC application mode is full
bandwidth, the decimation ratio = 2, L = 4, M = 2, F = 1, and
S = 1 (JESD204B mode),
Latency = 29 + 30 = 59 encode clocks
Table 30. Latency Through JESD204B BlockFull Bandwidth Modes
JESD204B Quick Configuration
(Register 0x570)
Decimation
Ratio
JESD204B Transport Layer Settings
Latency (Encode CLK)
L
M
F
S
HD
N
0x01 1 1 1 2 1 0 8 to 16 16 13
0x40 1 2 1 1 1 1 8 to 16 16 28
0x41 1 2 1 2 2 0 8 to 16 16 28
0x80 1 4 1 1 2 1 8 to 16 16 53
0x81 1 4 1 2 4 0 8 to 16 16 53
0x0A 1 1 2 4 1 0 8 to 16 16 7
0x49 1 2 2 2 1 0 8 to 16 16 13
0x88 1 4 2 1 1 1 8 to 16 16 28
0x89 1 4 2 2 2 0 8 to 16 16 28
Table 31. Latency Through JESD204B Blockwith Decimation
JESD204B Quick Configuration
(Register 0x570)
Decimation
Ratio
JESD204B Transport Layer Settings
Latency (Encode CLK) L M F S HD N
0x88
2
4
2
1
1
1
8 to 16
16
30
0x89 2 4 2 2 2 0 8 to 16 16 30
0x13 2,4,8,161 1 4 8 1 0 8 to 16 16 4
0x52 2,4,8,161 2 4 4 1 0 8 to 16 16 7
0x91 2,4,8,161 4 4 2 1 0 8 to 16 16 13
0x1C
4,8,16
1
1
8
16
1
0
8 to 16
16
2
0x5B 4,8,161 2 8 8 1 0 8 to 16 16 4
0x9A 4,8,161 4 8 4 1 0 8 to 16 16 7
1 For these modes, changing decimation does not affect latency.
Data Sheet AD9680
Rev. E | Page 85 of 105
TEST MODES
ADC TEST MODES
The AD9680 has various test options that aid in the system level
implementation. The AD9680 has ADC test modes that are
available in Register 0x0550. These test modes are described in
Table 36. When an output test mode is enabled, the analog section
of the ADC is disconnected from the digital back end blocks,
and the test pattern is run through the output formatting block.
Some of the test patterns are subject to output formatting, and
some are not. The pseudorandom number (PN) generators
from the PN sequence tests can be reset by setting Bit 4 or Bit 5
of Register 0x0550. These tests can be performed with or
without an analog signal (if present, the analog signal is
ignored); however, they do require an encode clock.
If the application mode is set to select a DDC mode of
operation, the test modes must be enabled for each DDC
enabled. The test patterns can be enabled via Bit 2 and Bit 0 of
Register 0x0327, Register 0x0347, and Register 0x0367,
depending on which DDC(s) are selected. The (I) data uses the
test patterns selected for Channel A, and the (Q) data uses the
test patterns selected for Channel B. For DDC3 only, the (I) data
uses the test patterns from Channel A, and the (Q) data does
not output test patterns. Bit 0 of Register 0x0387 selects the
Channel A test patterns to be used for the (I) data. For more
information, see the AN-877 Application Note, Interfacing to
High Speed ADCs via SPI.
8-BIT/10-BIT
ENCODER
SERDOUT0±
SERDOUT1±
TAIL BITS
0x571[6]
SERIALIZER
ADC
SYMBOL0 SYMBOL1
A13
A12
A11
A10
A9
A8
A7
A6
A5
A4
A3
A2
A1
A0
C2
C1
C0
MSB
LSB
CONT ROL BI T S
ADC TEST PATTERNS
(RE0x550,
REG 0x551 TO
REG 0x558)JESD204B SAMPLE
CONSTRUCTION
JESD204B
INTERFACE
TEST PATTERN
(REG 0x573,
REG 0x551 TO
REG 0x558)
FRAME
CONSTRUCTION
JESD20 4 B DATA
LI NK LAYE R TES T
PATTERNS
REG 0x574[2:0]
SCRAMBLER
1 + x14 + x15
(OPTIONAL)
A13
A12
A11
A10
A9
A8
A7
A6
A5
A4
A3
A2
A1
A0
C2
T
MSB
LSB
OCTET 0
OCTET 1
S7
S6
S5
S4
S3
S2
S1
S0
S7
S6
S5
S4
S3
S2
S1
S0
MSB
LSB
OCTET 0
OCTET 1
a b c d e f g h i j
a b c d e f g h i j
a b i j a b i j
11752-051
JESD204B
LO NG TRANSPORT
TESTPATTERN
REG 0x571[5]
Figure 184. ADC Output Data Path Showing Data Framing
Table 36. ADC Test Modes1
Output Test Mode
Bit Sequence Pattern Name Expression
Default/
Seed Value Sample (N, N + 1, N + 2, …)
0000 Off (default) N/A N/A N/A
0001 Midscale short 0000 0000 0000 N/A N/A
0010 Positive full-scale short 01 1111 1111 1111 N/A N/A
0011 Negative full-scale short 10 0000 0000 0000 N/A N/A
0100 Checkerboard 10 1010 1010 1010 N/A 0x1555, 0x2AAA, 0x1555, 0x2AAA, 0x1555
0101
PN sequence long
x
23
+ x
18
+ 1
0x3AFF
0x3FD7, 0x0002, 0x26E0, 0x0A3D, 0x1CA6
0110 PN sequence short x9 + x5 + 1 0x0092 0x125B, 0x3C9A, 0x2660, 0x0c65, 0x0697
0111 One-/zero-word toggle 11 1111 1111 1111 N/A 0x0000, 0x3FFF, 0x0000, 0x3FFF, 0x0000
1000 User input Register 0x551 to
Register 0x558
N/A User Pattern 1[15:2], User Pattern 2[15:2],
User Pattern 3[15:2], User Pattern 4[15:2],
User Pattern 1[15:2] … for repeat mode.
User Pattern 1[15:2], User Pattern 2[15:2],
User Pattern 3[15:2], User Pattern 4[15:2],
0x0000 … for single mode.
1111 Ramp Output (x) % 214 N/A (x) % 214, (x +1) % 214, (x +2) % 214, (x +3) % 214
1 N/A means not applicable.
AD9680 Data Sheet
Rev. E | Page 86 of 105
JESD204B BLOCK TEST MODES
In addition to the ADC pipeline test modes, the AD9680 also has
flexible test modes in the JESD204B block. These test modes are
listed in Register 0x0573 and Register 0x0574. These test patterns
can be injected at various points along the output datapath. These
test injection points are shown in Figure 184. Table 37 describes
the various test modes available in the JESD204B block. For the
AD9680, a transition from test modes (Register 0x0573 ≠ 0x00)
to normal mode (Register 0x0573 = 0x00) requires an SPI soft
reset. This is done by writing 0x81 to Register 0x0000 (self cleared).
Transport Layer Sample Test Mode
The transport layer samples are implemented in the AD9680 as
defined by Section 5.1.6.3 in the JEDEC JESD204B specification.
These tests are shown in Register 0x0571, Bit 5. The test pattern
is equivalent to the raw samples from the ADC.
Interface Test Modes
The interface test modes are described in Register 0x0573, Bits[3:0].
These test modes are also explained in Table 37. The interface tests
can be injected at various points along the data. See Figure 87
for more information on the test injection points. Register 0x0573,
Bits[5:4] show where these tests are injected.
Table 38, Table 39, and Table 40 show examples of some of the
test modes when injected at the JESD sample input, PHY 10-bit
input, and scrambler 8-bit input. UPx in the tables represent the
user pattern control bits from the customer register map.
Table 37. JESD204B Interface Test Modes
Output Test Mode
Bit Sequence Pattern Name Expression Default
0000 Off (default) Not applicable Not applicable
0001
Alternating checker board
0x5555, 0xAAAA, 0x5555, …
Not applicable
0010 1/0 word toggle 0x0000, 0xFFFF, 0x0000, … Not applicable
0011 31-bit PN sequence x31 + x28 + 1 0x0003AFFF
0100 23-bit PN sequence x23 + x18 + 1 0x003AFF
0101 15-bit PN sequence x15 + x14 + 1 0x03AF
0110 9-bit PN sequence x9 + x5 + 1 0x092
0111
7-bit PN sequence
x
7
+ x
6
+ 1
0x07
1000 Ramp output (x) % 216 Ramp size depends on test injection point
1110 Continuous/repeat user test Register 0x551 to Register 0x558 User Pattern 1 to User Pattern 4, then repeat
1111 Single user test Register 0x551 to Register 0x558 User Pattern 1 to User Pattern 4, then zeros
Table 38. JESD204B Sample Input for M = 2, S = 2, N' = 16 (Register 0x0573[5:4] = 'b00)
Frame
Number
Converter
Number
Sample
Number
Alternating
Checkerboard
1/0 Word
Toggle Ramp PN9 PN23 User Repeat User Single
0 0 0 0x5555 0x0000 (x) % 216 0x496F 0xFF5C UP1[15:0] UP1[15:0]
0 0 1 0x5555 0x0000 (x) % 216 0x496F 0xFF5C UP1[15:0] UP1[15:0]
0 1 0 0x5555 0x0000 (x) % 216 0x496F 0xFF5C UP1[15:0] UP1[15:0]
0 1 1 0x5555 0x0000 (x) % 216 0x496F 0xFF5C UP1[15:0] UP1[15:0]
1 0 0 0xAAAA 0xFFFF (x +1) % 216 0xC9A9 0x0029 UP2[15:0] UP2[15:0]
1 0 1 0xAAAA 0xFFFF (x +1) % 216 0xC9A9 0x0029 UP2[15:0] UP2[15:0]
1 1 0 0xAAAA 0xFFFF (x +1) % 216 0xC9A9 0x0029 UP2[15:0] UP2[15:0]
1 1 1 0xAAAA 0xFFFF (x +1) % 216 0xC9A9 0x0029 UP2[15:0] UP2[15:0]
2 0 0 0x5555 0x0000 (x +2) % 216 0x980C 0xB80A UP3[15:0] UP3[15:0]
2 0 1 0x5555 0x0000 (x +2) % 216 0x980C 0xB80A UP3[15:0] UP3[15:0]
2 1 0 0x5555 0x0000 (x +2) % 216 0x980C 0xB80A UP3[15:0] UP3[15:0]
2 1 1 0x5555 0x0000 (x +2) % 216 0x980C 0xB80A UP3[15:0] UP3[15:0]
3 0 0 0xAAAA 0xFFFF (x +3) % 216 0x651A 0x3D72 UP4[15:0] UP4[15:0]
3 0 1 0xAAAA 0xFFFF (x +3) % 216 0x651A 0x3D72 UP4[15:0] UP4[15:0]
3 1 0 0xAAAA 0xFFFF (x +3) % 216 0x651A 0x3D72 UP4[15:0] UP4[15:0]
3 1 1 0xAAAA 0xFFFF (x +3) % 216 0x651A 0x3D72 UP4[15:0] UP4[15:0]
4 0 0 0x5555 0x0000 (x +4) % 216 0x5FD1 0x9B26 UP1[15:0] 0x0000
4 0 1 0x5555 0x0000 (x +4) % 216 0x5FD1 0x9B26 UP1[15:0] 0x0000
Data Sheet AD9680
Rev. E | Page 87 of 105
Frame
Number
Converter
Number
Sample
Number
Alternating
Checkerboard
1/0 Word
Toggle Ramp PN9 PN23 User Repeat User Single
4 1 0 0x5555 0x0000 (x +4) % 216 0x5FD1 0x9B26 UP1[15:0] 0x0000
4 1 1 0x5555 0x0000 (x +4) % 216 0x5FD1 0x9B26 UP1[15:0] 0x0000
Table 39. Physical Layer 10-Bit Input (Register 0x0573, Bits[5:4] = 'b01)
10-Bit Symbol
Number
Alternating
Checkerboard
1/0 Word
Toggle Ramp PN9 PN23 User Repeat User Single
0 0x155 0x000 (x) % 210 0x125 0x3FD UP1[15:6] UP1[15:6]
1 0x2AA 0x3FF (x + 1) % 210 0x2FC 0x1C0 UP2[15:6] UP2[15:6]
2
0x155
0x000
(x + 2) % 2
10
0x26A
0x00A
UP3[15:6]
UP3[15:6]
3 0x2AA 0x3FF (x + 3) % 210 0x198 0x1B8 UP4[15:6] UP4[15:6]
4 0x155 0x000 (x + 4) % 210 0x031 0x028 UP1[15:6] 0x000
5 0x2AA 0x3FF (x + 5) % 210 0x251 0x3D7 UP2[15:6] 0x000
6 0x155 0x000 (x + 6) % 210 0x297 0x0A6 UP3[15:6] 0x000
7 0x2AA 0x3FF (x + 7) % 210 0x3D1 0x326 UP4[15:6] 0x000
8 0x155 0x000 (x + 8) % 210 0x18E 0x10F UP1[15:6] 0x000
9 0x2AA 0x3FF (x + 9) % 210 0x2CB 0x3FD UP2[15:6] 0x000
10 0x155 0x000 (x + 10) % 210 0x0F1 0x31E UP3[15:6] 0x000
11 0x2AA 0x3FF (x + 11) % 210 0x3DD 0x008 UP4[15:6] 0x000
Table 40. Scrambler 8-Bit Input (Register 0x0573, Bits[5:4] = 'b10)
8-Bit Octet
Number
Alternating
Checkerboard
1/0 Word
Toggle Ramp PN9 PN23 User Repeat User Single
0 0x55 0x00 (x) % 28 0x49 0xFF UP1[15:9] UP1[15:9]
1 0xAA 0xFF (x + 1) % 28 0x6F 0x5C UP2[15:9] UP2[15:9]
2 0x55 0x00 (x + 2) % 28 0xC9 0x00 UP3[15:9] UP3[15:9]
3 0xAA 0xFF (x + 3) % 28 0xA9 0x29 UP4[15:9] UP4[15:9]
4 0x55 0x00 (x + 4) % 28 0x98 0xB8 UP1[15:9] 0x00
5 0xAA 0xFF (x + 5) % 28 0x0C 0x0A UP2[15:9] 0x00
6 0x55 0x00 (x + 6) % 28 0x65 0x3D UP3[15:9] 0x00
7 0xAA 0xFF (x + 7) % 28 0x1A 0x72 UP4[15:9] 0x00
8 0x55 0x00 (x + 8) % 28 0x5F 0x9B UP1[15:9] 0x00
9 0xAA 0xFF (x + 9) % 28 0xD1 0x26 UP2[15:9] 0x00
10 0x55 0x00 (x + 10) % 28 0x63 0x43 UP3[15:9] 0x00
11 0xAA 0xFF (x + 11) % 28 0xAC 0xFF UP4[15:9] 0x00
Data Link Layer Test Modes
The data link layer test modes are implemented in the AD9680
as defined by Section 5.3.3.8.2 in the JEDEC JESD204B
specification. These tests are shown in Register 0x574 Bits[2:0].
Test patterns inserted at this point are useful for verifying the
functionality of the data link layer. When the data link layer
test modes are enabled, disable SYNCINB± by writing 0xC0
to Register 0x0572.
AD9680 Data Sheet
Rev. E | Page 88 of 105
SERIAL PORT INTERFACE
The AD9680 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. For detailed operational information,
see the Serial Control Interface Standard (Rev. 1.0).
CONFIGURATION USING THE SPI
Three pins define the SPI of the AD9680 ADC: the SCLK pin,
the SDIO pin, and the CSB pin (see Table 37). 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 37. Serial Port Interface Pins
Pin
Function
SCLK Serial clock. The serial shift clock input that 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. An example of the
serial timing and its definitions can be found in Figure 4 and
Table 5.
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 can stall high between
bytes to allow 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, which 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
readback operation, performing a readback 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. For more information about this
and other features, see the Serial Control Interface Standard
(Rev. 1.0).
HARDWARE INTERFACE
The pins described in Table 37 comprise the physical interface
between the user programming device and the serial port of the
AD9680. 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 readback.
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 AD9680 to prevent these signals from
transitioning at the converter inputs during critical sampling
periods.
SPI ACCESSIBLE FEATURES
Table 38 provides a brief description of the general features that
are accessible via the SPI. These features are described in detail
in the Serial Control Interface Standard (Rev. 1.0). The AD9680
device-specific features are described in the Memory Map section.
Table 38. Features Accessible Using the SPI
Feature Name Description
Mode Allows the user to set either power-down mode or standby mode.
Clock Allows the user to access the clock divider via the SPI.
DDC Allows the user to set up decimation filters for different applications.
Test Input/Output Allows the user to set test modes to have known data on output bits.
Output Mode Allows the user to set up outputs.
SERDES Output Setup Allows the user to vary SERDES settings such as swing and emphasis.
Data Sheet AD9680
Rev. E | Page 89 of 105
MEMORY MAP
READING THE MEMORY MAP REGISTER TABLE
Each row in the memory map register table has eight bit
locations. The memory map is divided into four sections: the
Analog Devices SPI registers (Register 0x000 to Register 0x00D),
the analog input buffer control registers, the ADC function
registers, the DDC function registers, and the digital outputs
and test modes registers.
Table 39 (see the Memory Map Register Table section) documents
the default hexadecimal value for each hexadecimal address shown.
The column with the heading Bit 7 (MSB) is the start of the
default hexadecimal value given. For example, Address 0x561,
the output mode register, has a hexadecimal default value of
0x01, which 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 Table 39.
Open and Reserved Locations
All address and bit locations that are not included in Table 39
are not currently supported for this device. Write unused bits of
a valid address location with 0s unless the default value is set
otherwise. Writing to these locations is required only when part
of an address location is unassigned (for example, Address 0x561).
If the entire address location is open (for example, Address 0x13),
do not write to this address location.
Default Values
After the AD9680 is reset, critical registers are loaded with
default values. The default values for the registers are given in
the memory map register table, Table 39.
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.
X denotes a dont care bit.
Channel-Specific Registers
Some channel setup functions, such as the input termination
(Register 0x016), can be programmed to a different value for
each channel. In these cases, channel address locations are
internally duplicated for each channel. These registers and bits
are designated in Table 39 as local. These local registers and bits
can be accessed by setting the appropriate Channel A or Channel B
bits in Register 0x008. If both bits are set, the subsequent write
affects the registers of both channels. In a read cycle, set only
Channel A or Channel B to read one of the two registers. If both
bits are set during an SPI read cycle, the device returns the value
for Channel A. Registers and bits designated as global in Table 39
affect the entire device and the channel features for which
independent settings are not allowed between channels. The
settings in Register 0x005 do not affect the global registers and bits.
SPI Soft Reset
After issuing a soft reset by programming 0x81 to Register 0x000,
the AD9680 requires 5 ms to recover. When programming the
AD9680 for application setup, ensure that an adequate delay is
programmed into the firmware after asserting the soft reset and
before starting the device setup.
AD9680 Data Sheet
Rev. E | Page 90 of 105
MEMORY MAP REGISTER TABLE
All address locations that are not included in Table 39 are not currently supported for this device and must not be written.
Table 39. Memory Map Registers
Reg
Addr
(Hex)
Register
Name
Bit 7
(MSB) Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 (LSB) Default Notes
Analog Devices SPI Registers
0x000 INTERFACE_
CONFIG_A
Soft reset
(self
clearing)
LSB first
0 = MSB
1 = LSB
Address
ascension
0 0 Address
ascension
LSB first
0 = MSB
1 = LSB
Soft reset
(self
clearing)
0x00
0x001 INTERFACE_
CONFIG_B
Single
instruction
0 0 0 0 0 Datapath
soft reset
(self
clearing)
0 0x00
0x002 DEVICE_
CONFIG
(local)
0 0 0 0 0 0 00 = normal operation
10 = standby
11 = power-down
0x00
0x003 CHIP_TYPE 011 = high speed ADC 0x03 Read
only
0x004 CHIP_ID
(low byte)
1 1 0 0 0 1 0 1 0xC5 Read
only
0x005
CHIP_ID
(high byte)
0
0
0
0
0
0
0
0
0x00
Read
only
0x006 CHIP_
GRADE
1100 = 1250 MSPS
1010 = 1000 MSPS
1000 = 820 MSPS
0101 = 500 MSPS
X X X X Read
only
0x008 Device index 0 0 0 0 0 0 Channel B Channel A 0x0
0x00A Scratch pad 0 0 0 0 0 0 0 0 0x00
0x00B
SPI revision
0
0
0
0
0
0
0
1
0x01
0x00C Vendor ID
(low byte)
0 1 0 1 0 1 1 0 0x56 Read
only
0x00D Vendor ID
(high byte)
0 0 0 0 0 1 0 0 0x04 Read
only
Analog Input Buffer Control Registers
0x015 Analog input
(local)
0 0 0 0 0 0 0 Input
disable
0 =
normal
operation
1 = input
disabled
0x00
0x016 Input
termination
(local)
Analog input differential termination
0000 = 400 Ω (default)
0001 = 200 Ω
0010 = 100 Ω
0110 = 50 Ω
1110 = AD9680-1250 and AD9680-1000
1100 = AD9680-820 and AD9680-500
0x0E for
AD9680-
1250 and
AD9680-
1000;
0x0C for
AD9680-
820 and
AD9680-
500
0x934 Input
capacitance
(local)
0 0 0 0x1F = 3 pF to GND (default)
0x00 = 1.5 pF to GND
0x1F
Data Sheet AD9680
Rev. E | Page 91 of 105
Reg
Addr
(Hex)
Register
Name
Bit 7
(MSB) Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 (LSB) Default Notes
0x018 Buffer
Control 1
(local)
0000 = 1.0× buffer current
0001 = 1.5× buffer current
0010 = 2.0× buffer current (default for AD9680-500)
0011 = 2.5× buffer current
0100 = 3.0× buffer current (default for AD9680-1000
and AD9680-820)
0101 = 3.5× buffer current (default for AD9680-1250)
1111 = 8.5× buffer current
0 0 0 0 0x50 for
AD9680-
1250;
0x40 for
AD9680-
1000
and
AD9680-
820;
0x20 for
AD9680-
500
0x019 Buffer
Control 2
(local)
0100 = Setting 1 (default for AD9680-820)
0101 = Setting 2 (default for AD9680-1250 and
AD9680-1000)
0110 = Setting 3 (default for AD9680-500)
0111 = Setting 4
0 0 0 0 0x50 for
AD9680-
1250 and
AD9680-
1000;
0x40 for
AD9680-
820;
0x60 for
AD9680-
500
0x01A Buffer
Control 3
(local)
0 0 0 0 1000 = Setting 1
1001 = Setting 2 (default for AD9680-1250,
AD9680-1000 and AD9680-820)
1010 = Setting 3 (default for AD9680-500)
0x09 for
AD9680-
1250,
AD9680-
1000
and
AD9680-
820;
0x0A for
AD9680-
500
0x11A Buffer
Control 4
(local)
0 0 High
frequency
setting
0 = off
(default)
1 = on
0 0 0 0 0
0x935 Buffer
Control 5
(local)
0 0 0 0 0 Low
frequency
operation
0 = off
1 = on
(default)
0 0
0x025
Input full-
scale range
(local)
0
0
0
0
Full-scale adjust
0000 = 1.94 V
1000 = 1.46 V
1001 = 1.58 V (default for AD9680-1250)
1010 = 1.70 V (default for AD9680-1000 and
AD9680-820)
1011 = 1.82 V
1100 = 2.06 V (default for AD9680-500)
0x09 for
AD9680-
1250;
0x0A for
AD9680-
1000
and
AD9680-
820;
0x0C for
AD9680-
500
V p-p
differ-
ential;
use in
conjunc-
tion with
Reg.
0x030
AD9680 Data Sheet
Rev. E | Page 92 of 105
Reg
Addr
(Hex)
Register
Name
Bit 7
(MSB) Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 (LSB) Default Notes
0x030 Input full-
scale control
(local)
0 0 0 Full-scale control
See Table 10 for recommended settings
for different frequency bands;
default values:
AD9680-1250, AD9680-1000 = 110
AD9680-820 = 101
AD9680-500 = 001
AD9680-500 = 110 (for <1.82 V)
0 0 Used in
conjunc-
tion with
Reg.
0x025
ADC Function Registers
0x024 V_1P0
control
0 0 0 0 0 0 0 1.0 V
reference
select
0 =
internal
1 =
external
0x00
0x028 Temperature
diode
0 0 0 0 0 0 0 Diode
selection
0 =
no diode
selected
1 =
temper-
ature
diode
selected
0x00 Used in
conjunc-
tion with
Reg.
0x040
0x03F PDWN/
STBY pin
control (local)
0 = PDWN/
STBY
enabled
1 =
disabled
0 0 0 0 0 0 0 0x00 Used in
conjunc-
tion with
Reg.
0x040
0x040 Chip pin
control
PDWN/STBY function
00 = power down
01 = standby
10 = disabled
Fast Detect B (FD_B)
000 = Fast Detect B output
001 = JESD204B LMFC output
010 = JESD204B internal SYNC~ output
111 = disabled
Fast Detect A (FD_A)
000 = Fast Detect A output
001 = JESD204B LMFC output
010 = JESD204B internal SYNC~ output
011 = temperature diode
111 = disabled
0x3F
0x10B
Clock divider
0
0
0
0
0
000 = divide by 1
001 = divide by 2
011 = divide by 4
111 = divide by 8
0x00
0x10C
Clock divider
phase (local)
0
0
0
0
Independently controls Channel A and Channel B clock
divider phase offset
0000 = 0 input clock cycles delayed
0001 = ½ input clock cycles delayed
0010 = 1 input clock cycles delayed
0011 = 1½ input clock cycles delayed
0100 = 2 input clock cycles delayed
0101 = 2½ input clock cycles delayed
1111 = 7½ input clock cycles delayed
0x00
0x10D Clock divider
and SYSREF
control
Clock
divider
auto phase
adjust
0 =
disabled
1 =
enabled
0 0 0 Clock divider negative
skew window
00 = no negative skew
01 = 1 device clock of
negative skew
10 = 2 device clocks of
negative skew
11 = 3 device clocks of
negative skew
Clock divider positive
skew window
00 = no positive skew
01 = 1 device clock of
positive skew
10 = 2 device clocks of
positive skew
11 = 3 device clocks of
positive skew
0x00 Clock
divider
must be
>1
Data Sheet AD9680
Rev. E | Page 93 of 105
Reg
Addr
(Hex)
Register
Name
Bit 7
(MSB) Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 (LSB) Default Notes
0x117 Clock delay
control
0 0 0 0 0 0 0 Clock fine
delay
adjust
enable
0 =
disabled
1 =
enabled
0x00 Enabling
the clock
fine delay
adjust
causes a
datapath
reset
0x118 Clock fine
delay (local)
Clock Fine Delay Adjust[7:0],
twos complement coded control to adjust the fine sample clock skew in ~1.7 ps steps
≤ −88 = −151.7 ps skew
−87 = −150 ps skew
0 = 0 ps skew
≥ +87 = +150 ps skew
0x00 Used in
con-
junction
with Reg.
0x0117
0x11C
Clock status
0
0
0
0
0
0
0
0 = no
input
clock
detected
1 = input
clock
detected
Read
only
0x120 SYSREF±
Control 1
0 SYSREF±
flag reset
0 =
normal
opera-
tion
1 = flags
held in
reset
0 SYSREF±
transition
select
0 = low to
high
1 = high to
low
CLK±
edge
select
0 = rising
1 = falling
SYSREF± mode select
00 = disabled
01 = continuous
10 = N shot
0 0x00
0x121 SYSREF±
Control 2
0 0 0 0 SYSREF N-shot ignore counter select
0000 = next SYSREF± only
0001 = ignore the first SYSREF± transition
0010 = ignore the first two SYSREF± transitions
1111 = ignore the first 16 SYSREF± transitions
0x00 Mode
select
(Reg
0x120,
Bits [2:1])
must be
N-shot
0x123 SYSREF±
timestamp
delay control
SYSREF± timestamp delay, Bits[6:0]
0x00 = no delay
0x01 = 1 clock delay
0x7F = 127 clocks delay
0x00 Ignored
when
Reg.
0x01FF
= 0x00
0x128 SYSREF±
Status 1
SYSREF± hold status, Register 0x128[7:4] (see the
SYSREF± Setup/Hold Window Monitor section)
SYSREF± setup status, Register 0x128[3:0] (see the
SYSREF± Setup/Hold Window Monitor section)
Read
only
0x129
SYSREF± and
clock divider
status
0
0
0
0
Clock divider phase when SYSREF± was captured
0000 = in-phase
0001 = SYSREF± is ½ cycle delayed from clock
0010 = SYSREF± is 1 cycle delayed from clock
0011 = 1½ input clock cycles delayed
0100 = 2 input clock cycles delayed
0101 = 2½ input clock cycles delayed
1111 = 7½ input clock cycles delayed
Read
only
0x12A
SYSREF±
counter
SYSREF counter, Bits[7:0] increments when a SYSREF± is captured
Read
only
0x1FF Chip sync
mode
Synchronization mode
00 = normal
01 = timestamp
0x00
AD9680 Data Sheet
Rev. E | Page 94 of 105
Reg
Addr
(Hex)
Register
Name
Bit 7
(MSB) Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 (LSB) Default Notes
0x200 Chip
application
mode
0 0 Chip Q
ignore
0 = normal
(I/Q)
1 = ignore
(I only)
0 0 0 Chip operating mode
00 = full bandwidth mode
01 = DDC 0 on
10 = DDC 0 and DDC 1 on
11 = DDC 0, DDC 1,
DDC 2, and DDC 3 on
0x00
0x201 Chip
decimation
ratio
0 0 0 0 0 Chip decimation ratio select
000 = full sample rate (decimate = 1)
001 = decimate by 2
010 = decimate by 4
011 = decimate by 8
100 = decimate by 16
0x00
0x228 Customer
offset
Offset adjust in LSBs from +127 to −128 (twos complement format) 0x00
0x245 Fast detect
(FD) control
(local)
0 0 0 0 Force
FD_A/
FD_B pins;
0 = normal
function;
1 = force
to value
Force value of
FD_A/FD_B
pins if force
pins is true,
this value is
output on FD
pins
0 Enable
fast detect
output
0x00
0x247 FD upper
threshold
LSB (local)
Fast detect upper threshold, Bits[7:0] 0x00
0x248 FD upper
threshold
MSB (local)
0 0 0 Fast detect upper threshold, Bits[12:8] 0x00
0x249 FD lower
threshold
LSB (local)
Fast detect lower threshold, Bits[7:0] 0x00
0x24A FD lower
threshold
MSB (local)
0 0 0 Fast detect lower threshold, Bits[12:8] 0x00
0x24B FD dwell
time LSB
(local)
Fast detect dwell time, Bits[7:0] 0x00
0x24C FD dwell
time MSB
(local)
Fast detect dwell time, Bits[15:8] 0x00
0x26F Signal
monitor
synchroniza-
tion control
0 0 0 0 0 0 Synchronization mode
00 = disabled
01 = continuous
11 = one shot
0x00 Refer to
the
Signal
Monitor
section
0x270 Signal
monitor
control (local)
0 0 0 0 0 0 Peak
detector
0 =
disabled
1 =
enabled
0 0x00
0x271
Signal
Monitor
Period
Register 0
(local)
Signal monitor period, Bits[7:0]
0x80
In deci-
mated
output
clock
cycles
0x272 Signal
Monitor
Period
Register 1
(local)
Signal monitor period, Bits[15:8] 0x00 In deci-
mated
output
clock
cycles
Data Sheet AD9680
Rev. E | Page 95 of 105
Reg
Addr
(Hex)
Register
Name
Bit 7
(MSB) Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 (LSB) Default Notes
0x273 Signal
Monitor
Period
Register 2
(local)
Signal monitor period, Bits[23:16] 0x00 In deci-
mated
output
clock
cycles
0x274 Signal
monitor
result control
(local)
0 0 0 Result
update
1 =
update
results
(self clear)
0 0 0 Result
selection
0 =
reserved
1 = peak
detector
0x01
0x275
Signal
Monitor
Result
Register 0
(local)
Signal monitor result, Bits[7:0]
When Register 0x0274[0] = 1, Result Bits[19:7] = Peak Detector Absolute Value[12:0]; Result Bits[6:0] = 0
Read
only
Updated
based on
Reg.
0x274[4]
0x276 Signal
Monitor
Result
Register 1
(local)
Signal monitor result, Bits[15:8] Read
only
Updated
based on
Reg.
0x274[4]
0x277 Signal
Monitor
Result
Register 1
(local)
0 0 0 0 Signal monitor result, Bits[19:16] Read
only
Updated
based on
Reg.
0x274[4]
0x278 Signal
monitor
period
counter
result (local)
Period count result, Bits[7:0]
Read
only
Updated
based on
Reg.
0x274[4]
0x279 Signal
monitor
SPORT over
JESD204B
control (local)
0 0 0 0 0 0 00 = disabled
11 = enable
0x00
0x27A SPORT over
JESD204B
input
selection
(local)
0 0 0 0 0 0 Peak
detector
0 =
disabled
1 =
enabled
0 0x00
DDC Function Registers (See the Digital Downconverter (DDC) Section)
0x300 DDC
synchro-
nization
control
0 0 0 DDC NCO
soft reset
0 = normal
operation
1 = reset
0 0 Synchronization mode
(triggered by SYSREF±)
00 = disabled
01 = continuous
11 = one shot
0x310 DDC 0
control
Mixer
select
0 = real
mixer
1 =
complex
mixer
Gain
select
0 = 0 dB
gain
1 = 6 dB
gain
IF (intermediate
frequency) mode
00 = variable IF mode
(mixers and NCO
enabled)
01 = 0 Hz IF mode (mixer
bypassed, NCO disabled)
10 = fS/4 Hz IF mode (fs/4
downmixing mode)
11 = test mode (mixer
inputs forced to +fS,
NCO enabled)
Complex
to real
enable
0 =
disabled
1 =
enabled
0 Decimation rate select
(complex to real
disabled)
11 = decimate by 2
00 = decimate by 4
01 = decimate by 8
10 = decimate by 16
(complex to real
enabled)
11 = decimate by 1
00 = decimate by 2
01 = decimate by 4
10 = decimate by 8
0x00
AD9680 Data Sheet
Rev. E | Page 96 of 105
Reg
Addr
(Hex)
Register
Name
Bit 7
(MSB) Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 (LSB) Default Notes
0x311 DDC 0 input
selection
0 0 0 0 0 Q input
select
0 = Ch A
1 = Ch B
0 I input
select
0 = Ch A
1 = Ch B
0x00 Refer to
the DDC
section
0x314 DDC 0
frequency
LSB
DDC 0 NCO frequency value, Bits[7:0]
twos complement
0x00
0x315 DDC 0
frequency
MSB
X X X X DDC 0 NCO frequency value, Bits[11:8]
twos complement
0x00
0x320 DDC 0 phase
LSB
DDC 0 NCO phase value, Bits[7:0]
twos complement
0x00
0x321 DDC 0 phase
MSB
X X X X DDC 0 NCO phase value, Bits[11:8]
twos complement
0x00
0x327 DDC 0
output test
mode
selection
0 0 0 0 0 Q output
test mode
enable
0 = disabled
1 = enabled
from
Channel B
0 I output
test mode
enable
0 =
disabled
1 =
enabled
from
Channel A
0x00 Refer to
the DDC
section
0x330 DDC 1
control
Mixer
select
0 = real
mixer
1 =
complex
mixer
Gain
select
0 = 0 dB
gain
1 = 6 dB
gain
IF (intermediate
frequency) mode
00 = variable IF mode
(mixers and NCO
enabled)
01 = 0 Hz IF mode (mixer
bypassed, NCO disabled)
10 = fADC/4 Hz IF mode
(fADC/4 downmixing
mode)
11 = test mode (mixer
inputs forced to +fS,
NCO enabled)
Complex
to real
enable
0 =
disabled
1 =
enabled
0 Decimation rate select
(complex to real
disabled)
11 = decimate by 2
00 = decimate by 4
01 = decimate by 8
10 = decimate by 16
(complex to real
enabled)
11 = decimate by 1
00 = decimate by 2
01 = decimate by 4
10 = decimate by 8
0x00
0x331 DDC 1 input
selection
0 0 0 0 0 Q input
select
0 = Ch A
1 = Ch B
0 I input
select
0 = Ch A
1 = Ch B
0x05 Refer to
the DDC
section
0x334 DDC 1
frequency
LSB
DDC 1 NCO frequency value, Bits[7:0]
twos complement
0x00
0x335 DDC 1
frequency
MSB
X X X X DDC 1 NCO frequency value, Bits[11:8]
twos complement
0x00
0x340 DDC 1 phase
LSB
DDC 1 NCO phase value, Bits[7:0]
twos complement
0x00
0x341 DDC 1 phase
MSB
X X X X DDC 1 NCO phase value, Bits[11:8]
twos complement
0x00
0x347
DDC 1
output test
mode
selection
0
0
0
0
0
Q output
test mode
enable
0 = disabled
1 = enabled
from Ch B
0
I output
test mode
enable
0 =
disabled
1 =
enabled
from Ch A
0x00
Refer to
the DDC
section
Data Sheet AD9680
Rev. E | Page 97 of 105
Reg
Addr
(Hex)
Register
Name
Bit 7
(MSB) Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 (LSB) Default Notes
0x350 DDC 2
control
Mixer
select
0 = real
mixer
1 =
complex
mixer
Gain
select
0 = 0 dB
gain
1 = 6 dB
gain
IF mode
00 = variable IF mode
(mixers and NCO
enabled)
01 = 0 Hz IF mode (mixer
bypassed, NCO disabled)
10 = fADC/4 Hz IF mode
(fADC/4 downmixing
mode)
11 = test mode (mixer
inputs forced to +fS,
NCO enabled)
Complex
to real
enable
0 =
disabled
1 =
enabled
0 Decimation rate select
(complex to real
disabled)
11 = decimate by 2
00 = decimate by 4
01 = decimate by 8
10 = decimate by 16
(complex to real
enabled)
11 = decimate by 1
00 = decimate by 2
01 = decimate by 4
10 = decimate by 8
0x00
0x351 DDC 2 input
selection
0 0 0 0 0 Q input
select
0 = Ch A
1 = Ch B
0 I input
select
0 = Ch A
1 = Ch B
0x00 Refer to
the DDC
section
0x354 DDC 2
frequency
LSB
DDC 2 NCO frequency value, Bits[7:0]
twos complement
0x00
0x355
DDC2
frequency
MSB
X
X
X
X
DDC 2 NCO frequency value, Bits[11:8]
twos complement
0x00
0x360 DDC 2 phase
LSB
DDC 2 NCO phase value, Bits[7:0]
twos complement
0x00
0x361 DDC 2 phase
MSB
X X X X DDC 2 NCO phase value, Bits[11:8]
twos complement
0x00
0x367 DDC 2
output test
mode
selection
0 0 0 0 0 Q output
test mode
enable
0 = disabled
1 = enabled
from Ch B
0 I output
test mode
enable
0 =
disabled
1 =
enabled
from Ch A
0x00 Refer to
the DDC
section
0x370 DDC 3
control
Mixer
select
0 = real
mixer
1 =
complex
mixer
Gain
select
0 = 0 db
gain
1 = 6 db
gain
IF mode
00 = variable IF mode
(mixers and NCO
enabled)
01 = 0 Hz IF mode(mixer
bypassed, NCO disabled)
10 = fADC/4 Hz IF mode
(fADC/4 downmixing
mode)
11 = test mode (mixer
inputs forced to +fS,
NCO enabled)
Complex
to real
enable
0 =
disabled
1 =
enabled
0 Decimation rate select
(complex to real
disabled)
11 = decimate by 2
00 = decimate by 4
01 = decimate by 8
10 = decimate by 16
(complex to real
enabled)
11 = decimate by 1
00 = decimate by 2
01 = decimate by 4
10 = decimate by 8
0x00
0x371 DDC 3 input
selection
0 0 0 0 0 Q input
select
0 = Ch A
1 = Ch B
0 I input
select
0 = Ch A
1 = Ch B
0x05 Refer to
the DDC
section
0x374 DDC 3
frequency
LSB
DDC 3 NCO frequency value, Bits[7:0]
twos complement
0x00
0x375
DDC 3
frequency
MSB
X
X
X
X
DDC 3 NCO frequency value, Bits[11:8]
twos complement
0x00
0x380 DDC3 phase
LSB
DDC 3 NCO phase value, Bits[7:0]
twos complement
0x00
0x381 DDC 3 phase
MSB
X X X X DDC 3 NCO phase value, Bits[11:8]
twos complement
0x00
AD9680 Data Sheet
Rev. E | Page 98 of 105
Reg
Addr
(Hex)
Register
Name
Bit 7
(MSB) Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 (LSB) Default Notes
0x387 DDC 3
output test
mode
selection
0 0 0 0 0 0 0 I output
test mode
enable
0 =
disabled
1 =
enabled
from Ch A
0x00 Refer to
the DDC
section
Digital Outputs and Test Modes
0x550 ADC test
modes
(local)
User
pattern
selection
0 = conti-
nuous
repeat
1 = single
pattern
0 Reset PN
long gen
0 = long
PN enable
1 = long
PN reset
Reset PN
short gen
0 = short
PN enable
1 = short
PN reset
Test mode selection
0000 = off, normal operation
0001 = midscale short
0010 = positive full scale
0011 = negative full scale
0100 = alternating checker board
0101 = PN sequence, long
0110 = PN sequence, short
0111 = 1/0 word toggle
1000 = the user pattern test mode (used with
Register 0x0550, Bit 7 and User Pattern 1 to
User Pattern 4 registers)
1111 = ramp output
0x00
0x551 User Pattern
1 LSB
0 0 0 0 0 0 0 0 0x00 Used
with Reg.
0x550
and Reg.
0x573
0x552 User Pattern
1 MSB
0 0 0 0 0 0 0 0 0x00 Used
with Reg.
0x550
and Reg.
0x573
0x553 User Pattern
2 LSB
0 0 0 0 0 0 0 0 0x00 Used
with Reg.
0x550
and Reg.
0x573
0x554
User Pattern
2 MSB
0
0
0
0
0
0
0
0
0x00
Used
with Reg.
0x550
and Reg.
0x573
0x555 User Pattern
3 LSB
0 0 0 0 0 0 0 0 0x00 Used
with Reg.
0x550
and Reg.
0x573
0x556 User Pattern
3 MSB
0 0 0 0 0 0 0 0 0x00 Used
with Reg.
0x550
and Reg.
0x573
0x557 User Pattern
4 LSB
0 0 0 0 0 0 0 0 0x00 Used
with Reg.
0x550
and Reg.
0x573
0x558 User Pattern
4 MSB
0 0 0 0 0 0 0 0 0x00 Used
with Reg.
0x550
and Reg.
0x573
Data Sheet AD9680
Rev. E | Page 99 of 105
Reg
Addr
(Hex)
Register
Name
Bit 7
(MSB) Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 (LSB) Default Notes
0x559 Output Mode
Control 1
0 Converter Control Bit 1 selection
000 = tie low (1’b0)
001 = overrange bit
011 = fast detect (FD) bit
101 = SYSRE
Only used when CS (Register 0x58F)
= 2 or 3
0 Converter Control Bit 0 selection
000 = tie low (1’b0)
001 = overrange bit
011 = fast detect (FD) bit
101 = SYSRE
Only used when CS (Register 0x58F) = 3
0x00
0x55A
Output Mode
Control 2
0
0
0
0
0
Converter Control Bit 2 selection
000 = tie low (1’b0)
001 = overrange bit
011 = fast detect (FD) bit
101 = SYSREF
Used when CS (Register 0x58F) = 1, 2, or 3
0x01
0x561 Output
mode
0 0 0 0 0 Sample
invert
0 = normal
1 = sample
invert
Data format select
00 = offset binary
01 = twos complement
0x01
0x562 Output
overrange
(OR) clear
Virtual
Converter 7
OR
0 = OR bit
enabled
1 = OR bit
cleared
Virtual
Converter
6 OR
0 = OR bit
enabled
1 = OR bit
cleared
Virtual
Converter 5
OR
0 = OR bit
enabled
1 = OR bit
cleared
Virtual
Converter 4
OR
0 = OR bit
enabled
1 = OR bit
cleared
Virtual
Converter
3 OR
0 = OR bit
enabled
1 = OR bit
cleared
Virtual
Converter 2
OR
0 = OR bit
enabled
1 = OR bit
cleared
Virtual
Converter 1
OR
0 = OR bit
enabled
1 = OR bit
cleared
Virtual
Converter
0 OR
0 = OR bit
enabled
1 = OR bit
cleared
0x00
0x563 Output OR
status
Virtual
Converter 7
OR
0 = no OR
1 = OR
occurred
Virtual
Converter
6 OR
0 = no
OR
1 = OR
occurred
Virtual
Converter 5
OR
0 = no OR
1 = OR
occurred
Virtual
Converter 4
OR
0 = no OR
1 = OR
occurred
Virtual
Converter
3 OR
0 = no OR
1 = OR
occurred
Virtual
Converter 2
OR
0 = no OR
1 = OR
occurred
Virtual
Converter 1
OR
0 = no OR
1 = OR
occurred
Virtual
Converter
0 OR
0 = no OR
1 = OR
occurred
0x00 Read
only
0x564 Output
channel
select
0 0 0 0 0 0 0 Converter
channel
swap
0 =
normal
channel
ordering
1 =
channel
swap
enabled
0x00
0x56E JESD204B
lane rate
control
0 0 0 0 = serial
lane rate
≥6.25 Gbps
and
≤12.5 Gbps
1 = serial
lane rate
must be ≥
3.125 Gbps
and
≤6.25 Gbps
0 0 0 0 0x00 for
AD9680-
1250,
AD9680-
1000 and
AD9680-
820;
0x10 for
AD9680-
500
0x56F JESD204B
PLL lock
status
PLL lock
0 = not
locked
1 = locked
0 0 0 0 0 0 0 0x00 Read
only
AD9680 Data Sheet
Rev. E | Page 100 of 105
Reg
Addr
(Hex)
Register
Name
Bit 7
(MSB) Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 (LSB) Default Notes
0x570 JESD204B
quick config-
uration
JESD204B quick configuration
L = number of lanes = 2Register 0x570, Bits[7:6]
M = number of converters = 2Register 0x570, Bits[5:3]
F = number of octets/frame = 2 Register 0x570, Bits[2:0]
0x88 for
AD9680-
1250,
AD9680-
1000 and
AD9680-
820;
0x49 for
AD9680-
500
Refer to
Table 26
and
Table 27
0x571 JESD204B
Link Mode
Control 1
Standby
mode
0 = all
converter
outputs 0
1 = CGS
(/K28.5/)
Tail bit
(t) PN
0 =
disable
1 =
enable
T = N΄
N − CS
Long
transport
layer test
0 =
disable
1 =
enable
Lane synch-
ronization
0 = disable
FACI uses
/K28.7/
1 = enable
FACI uses
/K28.3/ and
/K28.7/
ILAS sequence mode
00 = ILAS disabled
01 = ILAS enabled
11 = ILAS always on test
mode
FACI
0 =
enabled
1 =
disabled
Link
control
0 = active
1 = power
down
0x14
0x572 JESD204B
Link Mode
Control 2
SYNCINB± pin control
00 = normal
10 = ignore SYNCINB±
(force CGS)
11 = ignore SYNCINB±
(force ILAS/user data)
SYNCINB±
pin invert
0 = active
low
1 = active
high
SYNCINB±
pin type
0 =
differential
1 = CMOS
0 8-bit/10-bit
bypass
0 = normal
1 = bypass
8-/10-bit
bit invert
0 =
normal
1 = invert
the abcd
efghij
symbols
0 0x00
0x573 JESD204B
Link Mode
Control 3
CHKSUM mode
00 = sum of all 8-bit link
config registers
01 = sum of individual
link config fields
10 = checksum set to
zero
Test injection point
00 = N΄ sample input
01 = 10-bit data at
8-bit/10-bit output
(for PHY testing)
10 = 8-bit data at
scrambler input
JESD204B test mode patterns
0000 = normal operation (test mode disabled)
0001 = alternating checker board
0010 = 1/0 word toggle
0011 = 31-bit PN sequence—X31 + X28 + 1
0100 = 23-bit PN sequence—X23 + X18 + 1
0101 = 15-bit PN sequence—X15 + X14 + 1
0110 = 9-bit PN sequenceX9 + X5 + 1
0111 = 7-bit PN sequenceX7 + X6 + 1
1000 = ramp output
1110 = continuous/repeat user test
1111 = single user test
0x00
0x574 JESD204B
Link Mode
Control 4
ILAS delay
0000 = transmit ILAS on first LMFC after SYNCINB±
deasserted
0001 = transmit ILAS on second LMFC after
SYNCINB± deasserted
1111 = transmit ILAS on 16th LMFC after SYNCINB±
deasserted
0 Link layer test mode
000 = normal operation (link layer test
mode disabled)
001 = continuous sequence of /D21.5/
characters
100 = modified RPAT test sequence
101 = JSPAT test sequence
110 = JTSPAT test sequence
0x00
0x578 JESD204B
LMFC offset
0 0 0 LMFC phase offset value[4:0] 0x00
0x580 JESD204B
DID config
JESD204B Tx DID value[7:0] 0x00
0x581 JESD204B
BID config
0 0 0 0 JESD204B Tx BID value, Bits[3:0] 0x00
0x583 JESD204B LID
Config 1
0 0 0 Lane 0 LID value, Bits[4:0] 0x00
0x584 JESD204B LID
Config 2
0 0 0 Lane 1 LID value, Bits[4:0] 0x01
0x585 JESD204B LID
Config 3
0 0 0 Lane 2 LID value, Bits[4:0] 0x01
0x586
JESD204B LID
Config 4
0
0
0
Lane 3 LID value, Bits[4:0]
0x03
Data Sheet AD9680
Rev. E | Page 101 of 105
Reg
Addr
(Hex)
Register
Name
Bit 7
(MSB) Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 (LSB) Default Notes
0x58B JESD204B
parameters
SCR/L
JESD204B
scrambling
(SCR)
0 =
disabled
1 =
enabled
0 0 0 0 0 JESD204B lanes (L)
00 = 1 lane
01 = 2 lanes
11 = 4 lanes
Read only, see
Register 0x570
0x8X
0x58C
JESD204B F
config
Number of octets per frame, F = Register 0x58C[7:0] + 1
0x88
Read
only,
see Reg.
0x570
0x58D
JESD204B K
config
0
0
0
Number of frames per multiframe, K = Register 0x58D[4:0] + 1
Only values where (F × K) mod 4 = 0 are supported
0x1F
See Reg.
0x570
0x58E JESD204B M
config
Number of Converters per Link[7:0]
0x00 = link connected to one virtual converter (M = 1)
0x01 = link connected to two virtual converters (M = 2)
0x03 = link connected to four virtual converters (M = 4)
0x07 = link connected to eight virtual converters (M = 8)
Read
only
0x58F JESD204B
CS/N config
Number of control bits
(CS) per sample
00 = no control bits
(CS = 0)
01 = 1 control bit (CS =
1); Control Bit 2 only
10 = 2 control bits
(CS = 2); Control Bit 2
and 1 only
11 = 3 control bits
(CS = 3); all control bits
(2, 1, 0)
0 ADC converter resolution (N)
0x06 = 7-bit resolution
0x07 = 8-bit resolution
0x08 = 9-bit resolution
0x09 = 10-bit resolution
0x0A = 11-bit resolution
0x0B = 12-bit resolution
0x0C = 13-bit resolution
0x0D = 14-bit resolution
0x0E = 15-bit resolution
0x0F = 16-bit resolution
0x0F
0x590 JESD204B N’
config
0 0 Subclass
support
(Subclass V)
0 =
Subclass 0
(no deter-
ministic
latency)
1 =
Subclass 1
ADC number of bits per sample (N’)
0x7 = 8 bits
0xF = 16 bits
0x2F
0x591 JESD204B S
config
0 0 1 Samples per converter frame cycle (S)
S value = Register 0x591[4:0] + 1
0x20 Read
only
0x592 JESD204B HD
and CF
config
HD value
0 =
disabled
1 =
enabled
0 0 Control words per frame clock cycle per link (CF)
CF value = Register 0x592, Bits[4:0]
0x80 Read
only
0x5A0 JESD204B
CHKSUM 0
CHKSUM value for SERDOUT0±, Bits[7:0] 0x81 Read
only
0x5A1 JESD204B
CHKSUM 1
CHKSUM value for SERDOUT1±, Bits[7:0] 0x82 Read
only
0x5A2 JESD204B
CHKSUM 2
CHKSUM value for SERDOUT2±, Bits[7:0] 0x82 Read
only
0x5A3 JESD204B
CHKSUM 3
CHKSUM value for SERDOUT3±, Bits[7:0] 0x84 Read
only
0x5B0 JESD204B
lane power-
down
1 SERD-
OUT3±
0 = on
1 = off
1 SERD-
OUT2±
0 = on
1 = off
1 SERD-
OUT1±
0 = on
1 = off
1 SERD-
OUT0±
0 = on
1 = off
0xAA
AD9680 Data Sheet
Rev. E | Page 102 of 105
Reg
Addr
(Hex)
Register
Name
Bit 7
(MSB) Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 (LSB) Default Notes
0x5B2 JESD204B
lane
SERDOUT
assign
X X X X 0 SERDOUT0± lane assignment
000 = Logical Lane 0
001 = Logical Lane 1
010 = Logical Lane 2
011 = Logical Lane 3
0x00
0x5B3 JESD204B
lane
SERDOUT
assign
X X X X 0 SERDOUT1± lane assignment
000 = Logical Lane 0
001 = Logical Lane 1
010 = Logical Lane 2
011 = Logical Lane 3
0x11
0x5B5 JESD204B
lane
SERDOUT
assign
X X X X 0 SERDOUT2± lane assignment
000 = Logical Lane 0
001 = Logical Lane 1
010 = Logical Lane 2
011 = Logical Lane 3
0x22
0x5B6 JESD204B
lane
SERDOUT
assign
X X X X 0 SERDOUT3± lane assignment
000 = Logical Lane 0
001 = Logical Lane 1
010 = Logical Lane 2
011 = Logical Lane 3
0x33
0x5BF JESD
serializer
drive adjust
0 0 0 0 Swing voltage
0000 = 237.5 mV
0001 = 250 mV
0010 = 262.5 mV
0011 = 275 mV
0100 = 287.5 mV
0101 = 300 mV (default)
0110 = 312.5 mV
0111 = 325 mV
1000 = 337.5 mV
1001 = 350 mV
1010 = 362.5 mV
1011 = 375 mV
1100 = 387.5 mV
1101 = 400 mV
1110 = 412.5 mV
1111 = 425 mV
0x05
0x5C1 De-emphasis
select
0 SERD-
OUT3±
0 =
disable
1 =
enable
0 SERD-
OUT2±
0 =
disable
1 =
enable
0 SERDOUT1±
0 = disable
1 = enable
0 SERD-
OUT0±
0 = disable
1 = enable
0x00
0x5C2 De-emphasis
setting for
SERDOUT
0 0 0 0 SERDOUT0± de-emphasis settings
0000 = 0 dB
0001 = 0.3 dB
0010 = 0.8 dB
0011 = 1.4 dB
0100 = 2.2 dB
0101 = 3.0 dB
0110 = 4.0 dB
0111 = 5.0 dB
0x00
0x5C3 De-emphasis
setting for
SERDOUT
0 0 0 0 SERDOUT1± de-emphasis settings
0000 = 0 dB
0001 = 0.3 dB
0010 = 0.8 dB
0011 = 1.4 dB
0100 = 2.2 dB
0101 = 3.0 dB
0110 = 4.0 dB
0111 = 5.0 dB
0x00
Data Sheet AD9680
Rev. E | Page 103 of 105
Reg
Addr
(Hex)
Register
Name
Bit 7
(MSB) Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 (LSB) Default Notes
0x5C4 De-emphasis
setting for
SERDOUT
0 0 0 0 SERDOUT2± de-emphasis settings
0000 = 0 dB
0001 = 0.3 dB
0010 = 0.8 dB
0011 = 1.4 dB
0100 = 2.2 dB
0101 = 3.0 dB
0110 = 4.0 dB
0111 = 5.0 dB
0x00
0x5C5 De-emphasis
setting for
SERDOUT
0 0 0 0 SERDOUT3± de-emphasis settings
0000 = 0 dB
0001 = 0.3 dB
0010 = 0.8 dB
0011 = 1.4 dB
0100 = 2.2 dB
0101 = 3.0 dB
0110 = 4.0 dB
0111 = 5.0 dB
0x00
AD9680 Data Sheet
Rev. E | Page 104 of 105
APPLICATIONS INFORMATION
POWER SUPPLY RECOMMENDATIONS
The AD9680 must be powered by the following seven supplies:
AVDD1 = 1.25 V, AVDD2 = 2.5 V, AVDD3 = 3.3 V, AVDD1_SR =
1.25 V, DVDD = 1.25 V, DRVDD = 1.25 V, and SPIVDD = 1.80 V.
For applications requiring an optimal high power efficiency and
low noise performance, it is recommended that the ADP2164
and ADP2370 switching regulators be used to convert the 3.3 V,
5.0 V, or 12 V input rails to an intermediate rail (1.8 V and 3.8 V).
These intermediate rails are then postregulated by very low
noise, low dropout (LDO) regulators (ADP1741, ADM7172,
and ADP125). Figure 185 shows the recommended power
supply scheme for the AD9680.
AVDD1
1.25V
AVDD1_SR
1.25V
DVDD
1.25V
SPIVDD
(1.8V OR 3. 3V )
3.6V
3.3V
DRVDD
1.25V
1.8V
11752-063
ADP1741
ADP125 AVDD3
3.3V
ADM7172
OR
ADP1741 AVDD2
2.5V
ADP1741
Figure 185. High Efficiency, Low Noise Power Solution for the AD9680
It is not necessary to split all of these power domains in all cases.
The recommended solution shown in Figure 185 provides the
lowest noise, highest efficiency power delivery system for the
AD9680. If only one 1.25 V supply is available, route to AVDD1
first and then tap it off and isolate it with a ferrite bead or a filter
choke, preceded by decoupling capacitors for AVDD1_SR, DVDD,
and DRVDD, in that order. This is shown as the optional path
in Figure 185. The user can employ several different decoupling
capacitors to cover both high and low frequencies. These capacitors
must be located close to the point of entry at the PCB level and
close to the devices, with minimal trace lengths.
EXPOSED PAD THERMAL HEAT SLUG
RECOMMENDATIONS
The exposed pad on the underside of the ADC must be connected
to AGND to achieve the best electrical and thermal performance
of the AD9680. Connect an exposed continuous copper plane
on the PCB to the AD9680 exposed pad, Pin 0. The copper
plane must have several vias to achieve the lowest possible
resistive thermal path for heat dissipation to flow through the
bottom of the PCB. These vias must be solder filled or plugged.
The number of vias and the fill determine the resulting θJA
measured on the board.
To maximize the coverage and adhesion between the ADC and
PCB, partition the continuous copper plane by overlaying a
silkscreen on the PCB into several uniform sections. This
provides several tie points between the ADC and PCB during
the reflow process, whereas using one continuous plane with no
partitions only guarantees one tie point. See Figure 186 for a
PCB layout example. For detailed information on packaging
and the PCB layout of chip scale packages, see the AN-772
Application Note, A Design and Manufacturing Guide for the
Lead Frame Chip Scale Package (LFCSP).
11752-064
Figure 186. Recommended PCB Layout of Exposed Pad for the AD9680
AVDD1_SR (PIN 57) AND AGND (PIN 56 AND PIN 60)
AVDD1_SR (Pin 57) and AGND (Pin 56 and Pin 60) can be
used to provide a separate power supply node to the SYSREF±
circuits of AD9680. If running in Subclass 1, the AD9680 can
support periodic one-shot or gapped signals. To minimize the
coupling of this supply into the AVDD1 supply node, adequate
supply bypassing is needed.
Data Sheet AD9680
Rev. E | Page 105 of 105
OUTLINE DIMENSIONS
0.50
BSC
BOTTOM VIEW
TOP VIEW
7.70
7.60 SQ
7.50
0.45
0.40
0.35
0.80
0.75
0.70 0. 05 MAX
0.02 NO M
0.203 REF
COPLANARITY
0.08
0.30
0.25
0.18
09-25-2018-A
9.10
9.00 SQ
8.90
FOR PRO P E R CONNECT IO N OF
THE EXPOSED PAD, REFER TO
THE PIN CO NFIGURAT ION AND
FUNCTION DESCRIPTIONS
SECTION OF THIS DATA SHEET.
0.20 M IN
7.50 REF
COM P LIANT TO JEDE C S TANDARDS MO-220- WMMD
1
64
16
17
49
48
32
33
PKG-004396
SIDE VIEW
EXPOSED
PAD
SEATING
PLANE
PIN 1
INDICATOR
AREA
DETAIL A
(JEDEC 95)
PIN 1
IN DICATOR AR E A OP TIO NS
(SEE DETAIL A)
Figure 187. 64-Lead Lead Frame Chip Scale Package [LFCSP]
9 mm × 9 mm Body and 0.75 mm Package Height
(CP-64-15)
Dimensions shown in millimeters
ORDERING GUIDE
Model1 Temperature Range Package Description2 Package Option
AD9680BCPZ-1250
−40°C to +85°C
64-Lead Lead Frame Chip Scale Package [LFCSP]
CP-64-15
AD9680BCPZ-1000 −40°C to +85°C 64-Lead Lead Frame Chip Scale Package [LFCSP] CP-64-15
AD9680BCPZ-820 40°C to +85°C 64-Lead Lead Frame Chip Scale Package [LFCSP] CP-64-15
AD9680BCPZ-500 40°C to +85°C 64-Lead Lead Frame Chip Scale Package [LFCSP] CP-64-15
AD9680BCPZRL7-1250 40°C to +85°C 64-Lead Lead Frame Chip Scale Package [LFCSP] CP-64-15
AD9680BCPZRL7-1000 40°C to +85°C 64-Lead Lead Frame Chip Scale Package [LFCSP] CP-64-15
AD9680BCPZRL7-820 −40°C to +85°C 64-Lead Lead Frame Chip Scale Package [LFCSP] CP-64-15
AD9680BCPZRL7-500 −40°C to +85°C 64-Lead Lead Frame Chip Scale Package [LFCSP] CP-64-15
AD9680-1250EBZ
Evaluation Board for AD9680-1250
AD9680-1000EBZ Evaluation Board for AD9680-1000
AD9680-LF1000EBZ Evaluation Board for AD9680-1000 with 1 GHz Bandwidth
AD9680-820EBZ Evaluation Board for AD9680-820
AD9680-LF820EBZ Evaluation Board for AD9680-820 with 1 GHz Bandwidth
AD9680-500EBZ Evaluation Board for AD9680-500
AD9680-LF500EBZ
Evaluation Board for AD9680-500 with 1 GHz Bandwidth
1 Z = RoHS Compliant Part.
2 The AD9680-1250EBZ, AD9680-1000EBZ, AD9680-820EBZ, and AD9680-500EBZ evaluation boards are optimized for the full analog input frequency range of 2 GHz.
©20142019 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D11752-0-3/19(E)