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ADC08DJ3200

ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

ADC08DJ3200 6.4GSPS 单通道或 3.2GSPS 双通道

8 位射频采样模数转换器 (ADC)

1 特性

2 应用

1

•

ADC 内核：

•

卫星通信 (SATCOM)

合成孔径雷达 (SAR)

飞行时间和激光雷达测距

示波器和宽带数字转换器

微波回程连线

–

8 位分辨率

单通道模式下采样率高达 6.4GSPS

双通道模式下采样率高达 3.2GSPS

•

性能规格 (f_IN= 997MHz)：

射频采样软件定义无线电 (SDR)

光谱测量

–

ENOB：7.8 位

SFDR：

–

双通道模式：67dBFS

单通道模式：62dBFS

3 说明

ADC08DJ3200 器件是一款射频采样千兆采样模数转换

器 (ADC)，可对从直流到 10GHz 以上的输入频率进行

直接采样。在双通道下，ADC08DJ3200 的最大采样率

为 3200MSPS，单通道模式下的最大采样率为

•

V

–

_CMI为 0V 时的缓冲模拟输入：

模拟输入带宽 (-3dB)：8.0GHz

可用输入频率范围：>10GHz

满量程输入电压（V_FS，默认值）：0.8V_PP

模拟输入共模电压 (V_ICM)：0V

6400MSPS。通道数（双通道模式）和奎斯特带宽

（单通道模式）的可编程交换功能可用于开发灵活的硬

件，以满足高通道数或宽瞬时信号带宽应用的需求。

8.0GHz 的全功率输入带宽 (-3dB)，可用频率在双通道

和单通道模式下均超过 -3dB，可对频率捷变系统的

L、S、C 和 X 频带进行直接射频采样。

无噪声孔径延迟 (T_AD) 调节：

–

采样精度控制：19fs 步长

简化同步和交错

温度和电压不变延迟

•

简便易用的同步特性：

ADC08DJ3200 采用具有多达 16 个串行通道和子类 1

兼容性的高速 JESD204B 输出接口，可实现确定性延

迟和多器件同步。串行输出通道支持高达 12.8Gbps 的

速率，并可配置交换位速率和通道数。速率为 5GSPS

时，总共只需运行 4 个速率为 12.5Gbps 的通道，也

可使用 16 个通道将通道速率降低至 3.125Gbps。创

新同步具有无噪声孔径延迟 (T_AD) 调节和 SYSREF 窗

口等创新的同步特性，简化了相控阵雷达和 MIMO 通

信的系统设计。

–

自动 SYSREF 计时校准

样片标记时间戳

JESD204B 串行数据接口：

–

支持子类 0 和 1

最大通道速率：12.8Gbps

多达 16 个通道可降低通道速率

•

功耗：2.8W

电源电压：1.1V、1.9V

ADC08DJ3200 测量的输入带宽

3

器件信息⁽¹⁾

器件型号

封装

封装尺寸（标称值）

0

ADC08DJ3200

FCBGA (144) 10.00mm × 10.00mm

-3

(1) 如需了解所有可用封装，请参见数据表末尾的封装选项附录。

-6

-9

Single Channel Mode

Dual Channel Mode

-12

-15

0

2

4

6

8

Input Frequency (GHz)

10

12

D_BW

1

本文档旨在为方便起见，提供有关 TI 产品中文版本的信息，以确认产品的概要。有关适用的官方英文版本的最新信息，请访问 www.ti.com，其内容始终优先。 TI 不保证翻译的准确

性和有效性。在实际设计之前，请务必参考最新版本的英文版本。

English Data Sheet: SLVSDR1

ADC08DJ3200

ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

www.ti.com.cn

7.3 Feature Description................................................. 34

7.4 Device Functional Modes........................................ 48

7.5 Programming........................................................... 62

7.6 Register Maps......................................................... 63

Application and Implementation ...................... 107

8.1 Application Information.......................................... 107

8.2 Typical Applications ............................................. 107

8.3 Initialization Set Up .............................................. 114

Power Supply Recommendations.................... 114

9.1 Power Sequencing................................................ 116

1

2

3

4

5

6

特性.......................................................................... 1

应用.......................................................................... 1

说明.......................................................................... 1

修订历史记录 ........................................................... 2

Pin Configuration and Functions......................... 3

Specifications......................................................... 8

6.1 Absolute Maximum Ratings ...................................... 8

6.2 ESD Ratings.............................................................. 8

6.3 Recommended Operating Conditions....................... 9

6.4 Thermal Information.................................................. 9

6.5 Electrical Characteristics: DC Specifications .......... 10

6.6 Electrical Characteristics: Power Consumption ...... 12

8

9

10 Layout................................................................. 116

10.1 Layout Guidelines ............................................... 116

10.2 Layout Example .................................................. 117

11 器件和文档支持 ................................................... 120

11.1 器件支持 ............................................................. 120

11.2 文档支持.............................................................. 120

11.3 接收文档更新通知 ............................................... 120

11.4 支持资源.............................................................. 121

11.5 商标..................................................................... 121

11.6 静电放电警告....................................................... 121

11.7 Glossary.............................................................. 121

12 机械、封装和可订购信息..................................... 121

6.7 Electrical Characteristics: AC Specifications (Dual-

Channel Mode) ........................................................ 13

6.8 Electrical Characteristics: AC Specifications (Single-

Channel Mode) ........................................................ 16

6.9 Timing Requirements.............................................. 19

6.10 Switching Characteristics...................................... 20

6.11 Typical Characteristics.......................................... 23

Detailed Description ............................................ 33

7.1 Overview ................................................................. 33

7.2 Functional Block Diagram ....................................... 34

7

4 修订历史记录

注：之前版本的页码可能与当前版本有所不同。

Changes from Original (February 2018) to Revision A

Page

•

Changed Pin Functions table listed in alphanumeric order by pin name. .............................................................................. 4

Changed FFT plots in Typical Characteristics section to show improved look ................................................................... 23

已更改 product description in Overview section .................................................................................................................. 33

已更改 Device Comparison section to include all devices in the family. .............................................................................. 34

已更改 location of Analog Reference Voltage section. ........................................................................................................ 36

已更改 location of Temperature Monitoring Diode section. ................................................................................................. 38

已添加 requirement for at least 3 rising edges of SYSREF before SYSREF_POS output is valid...................................... 40

已更改 note in Power-Down Modes section to caution note explaining reliable serializer operation instead of the

information being presented under the Pin Functions table................................................................................................. 54

•

已更改 the Low-Power Background Calibration (LPBG) Mode section to provide additional detail of how to operate

the device in low-power background calibration mode......................................................................................................... 58

•

已添加 clarity about offset calibration when both CAL_OS and CAL_BG are enabled. ...................................................... 59

已更改 Trimming section to limit trimming to foreground (FG) calibration mode only to better reflect customer use

cases and simplify the explanation....................................................................................................................................... 60

•

已更改 additional clarity to Offset Filtering section to explain the frequency domain impact of the feature. ....................... 61

2

ADC08DJ3200

www.ti.com.cn

ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

5 Pin Configuration and Functions

AAV Package

144-Ball Flip Chip BGA

Top View

1

2

3

4

5

6

7

8

9

10

11

12

A

B

C

D

E

F

AGND

INA+

INAœ

AGND

DA3+

DA3œ

DA2+

DA2œ

DGND

TMSTP+

TMSTPœ

AGND

SYNCSE

VA11

AGND

VA19

AGND

INB+

AGND

VA11

AGND

INBœ

AGND

PD

AGND

NCOA0

NCOA1

CALTRIG

CALSTAT

VD11

DA7+

ORA0

ORA1

SCS

DA7œ

VD11

DGND

VD11

DGND

VD11

DGND

VD11

DB7œ

DB3œ

DA6+

VD11

DGND

VD11

DGND

VD11

DGND

VD11

DB6+

DB2+

DA6œ

DA5+

DA5œ

DA4+

DA4œ

DB4œ

DB4+

DB5œ

DB5+

DB6œ

DB2œ

DGND

DA1+

DA1œ

DA0+

DA0œ

DB0œ

DB0+

DB1œ

DB1+

DGND

BG

VA11

AGND

VA19

CLK+

AGND

VA19

AGND

VA19

SCLK

G

H

J

CLKœ

SDI

AGND

VD11

SDO

AGND

VA11

NCOB1

NCOB0

AGND

ORB1

ORB0

DB7+

DB3+

K

SYSREF+

SYSREFœ

AGND

TDIODE+

AGND

TDIODEœ

AGND

L

AGND

M

AGND

DGND

Not to scale

3

ADC08DJ3200

ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

www.ti.com.cn

Pin Functions

I/O

DESCRIPTION

NAME

NO.

A1, A2, A3,

A6, A7, B2,

B3, B4, B5,

B6, B7, C6,

D1, D6, E1,

E6, F2, F3,

F6, G2, G3,

G6, H1, H6,

J1, J6, L2, L3,

L4, L5, L6, L7,

M1, M2, M3,

M6, M7

Analog supply ground. Tie AGND and DGND to a common ground plane (GND) on the circuit

board.

AGND

—

Band-gap voltage output. This pin is capable of sourcing only small currents and driving limited

capacitive loads, as specified in the Recommended Operating Conditions table. This pin can be

left disconnected if not used.

BG

C3

F7

E7

O

I

Foreground calibration status output or device alarm output. Functionality is programmed through

CAL_STATUS_SEL. This pin can be left disconnected if not used.

CALSTAT

CALTRIG

Foreground calibration trigger input. This pin is only used if hardware calibration triggering is

selected in CAL_TRIG_EN, otherwise software triggering is performed using CAL_SOFT_TRIG.

Tie this pin to GND if not used.

Device (sampling) clock positive input. The clock signal is strongly recommended to be AC-

coupled to this input for best performance. In single-channel mode, the analog input signal is

sampled on both the rising and falling edges. In dual-channel mode, the analog signal is sampled

on the rising edge. This differential input has an internal untrimmed 100-Ω differential termination

and is self-biased to the optimal input common-mode voltage as long as DEVCLK_LVPECL_EN

is set to 0.

CLK+

F1

I

Device (sampling) clock negative input. TI strongly recommends using AC-coupling for best

performance.

CLK–

DA0+

DA0–

DA1+

DA1–

DA2+

DA2–

DA3+

DA3–

DA4+

DA4–

DA5+

DA5–

G1

E12

F12

C12

D12

A10

A11

A8

I

High-speed serialized data output for channel A, lane 0, positive connection. This differential

output must be AC-coupled and must always be terminated with a 100-Ω differential termination

at the receiver. This pin can be left disconnected if not used.

O

High-speed serialized data output for channel A, lane 0, negative connection. This pin can be left

disconnected if not used.

High-speed serialized data output for channel A, lane 1, positive connection. This differential

output must be AC-coupled and must always be terminated with a 100-Ω differential termination

at the receiver. This pin can be left disconnected if not used.

High-speed serialized data output for channel A, lane 1, negative connection. This pin can be left

disconnected if not used.

High-speed serialized-data output for channel A, lane 2, positive connection. This differential

output must be AC-coupled and must always be terminated with a 100-Ω differential termination

at the receiver. This pin can be left disconnected if not used.

High-speed serialized-data output for channel A, lane 2, negative connection. This pin can be left

disconnected if not used.

High-speed serialized-data output for channel A, lane 3, positive connection. This differential

output must be AC-coupled and must always be terminated with a 100-Ω differential termination

at the receiver. This pin can be left disconnected if not used.

High-speed serialized-data output for channel A, lane 3, negative connection. This pin can be left

disconnected if not used.

A9

High-speed serialized data output for channel A, lane 4, positive connection. This differential

output must be AC-coupled and must always be terminated with a 100-Ω differential termination

at the receiver. This pin can be left disconnected if not used.

E11

F11

C11

D11

High-speed serialized data output for channel A, lane 4, negative connection. This pin can be left

disconnected if not used.

High-speed serialized data output for channel A, lane 5, positive connection. This differential

output must be AC-coupled and must always be terminated with a 100-Ω differential termination

at the receiver. This pin can be left disconnected if not used.

High-speed serialized data output for channel A, lane 5, negative connection. This pin can be left

disconnected if not used.

4

ADC08DJ3200

www.ti.com.cn

ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

Pin Functions (continued)

I/O

DESCRIPTION

NAME

NO.

High-speed serialized data output for channel A, lane 6, positive connection. This differential

output must be AC-coupled and must always be terminated with a 100-Ω differential termination

at the receiver. This pin can be left disconnected if not used.

DA6+

B10

O

High-speed serialized data output for channel A, lane 6, negative connection. This pin can be left

disconnected if not used.

DA6–

DA7+

DA7–

DB0+

DB0–

DB1+

DB1–

DB2+

DB2–

DB3+

DB3–

DB4+

DB4–

DB5+

DB5–

DB6+

DB6–

DB7+

DB7–

B11

B8

High-speed serialized data output for channel A, lane 7, positive connection. This differential

output must be AC-coupled and must always be terminated with a 100-Ω differential termination

at the receiver. This pin can be left disconnected if not used.

High-speed serialized data output for channel A, lane 7, negative connection. This pin can be left

disconnected if not used.

B9

High-speed serialized data output for channel B, lane 0, positive connection. This differential

output must be AC-coupled and must always be terminated with a 100-Ω differential termination

at the receiver. This pin can be left disconnected if not used.

H12

G12

K12

J12

M10

M11

M8

High-speed serialized data output for channel B, lane 0, negative connection. This pin can be left

disconnected if not used.

High-speed serialized data output for channel B, lane 1, positive connection. This differential

output must be AC-coupled and must always be terminated with a 100-Ω differential termination

at the receiver. This pin can be left disconnected if not used.

High-speed serialized data output for channel B, lane 1, negative connection. This pin can be left

disconnected if not used.

High-speed serialized data output for channel B, lane 2, positive connection. This differential

output must be AC-coupled and must always be terminated with a 100-Ω differential termination

at the receiver. This pin can be left disconnected if not used.

High-speed serialized data output for channel B, lane 2, negative connection. This pin can be left

disconnected if not used.

High-speed serialized data output for channel B, lane 3, positive connection. This differential

output must be AC-coupled and must always be terminated with a 100-Ω differential termination

at the receiver. This pin can be left disconnected if not used.

High-speed serialized data output for channel B, lane 3, negative connection. This pin can be left

disconnected if not used.

M9

High-speed serialized data output for channel B, lane 4, positive connection. This differential

output must be AC-coupled and must always be terminated with a 100-Ω differential termination

at the receiver. This pin can be left disconnected if not used.

H11

G11

K11

J11

L10

L11

L8

High-speed serialized data output for channel B, lane 4, negative connection. This pin can be left

disconnected if not used.

High-speed serialized data output for channel B, lane 5, positive connection. This differential

output must be AC-coupled and must always be terminated with a 100-Ω differential termination

at the receiver. This pin can be left disconnected if not used.

High-speed serialized data output for channel B, lane 5, negative connection. This pin can be left

disconnected if not used.

High-speed serialized data output for channel B, lane 6, positive connection. This differential

output must be AC-coupled and must always be terminated with a 100-Ω differential termination

at the receiver. This pin can be left disconnected if not used.

High-speed serialized data output for channel B, lane 6, negative connection. This pin can be left

disconnected if not used.

High-speed serialized data output for channel B, lane 7, positive connection. This differential

output must be AC-coupled and must always be terminated with a 100-Ω differential termination

at the receiver. This pin can be left disconnected if not used.

High-speed serialized data output for channel B, lane 7, negative connection. This pin can be left

disconnected if not used.

L9

A12, B12, D9,

D10, F9, F10,

G9, G10, J9,

J10, L12, M12

Digital supply ground. Tie AGND and DGND to a common ground plane (GND) on the circuit

board.

DGND

—

5

ADC08DJ3200

ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

www.ti.com.cn

Pin Functions (continued)

I/O

DESCRIPTION

NAME

NO.

Channel A analog input positive connection. INA± is recommended for use in single channel

mode for optimal performance. The differential full-scale input voltage is determined by the

FS_RANGE_A register (see the Full-Scale Voltage (VFS) Adjustment section). This input is

terminated to ground through a 50-Ω termination resistor. The input common-mode voltage is

typically be set to 0 V (GND) and must follow the recommendations in the Recommended

Operating Conditions table. This pin can be left disconnected if not used.

INA+

A4

I

Channel A analog input negative connection. INA± is recommended for use in single channel

mode for optimal performance. See INA+ (pin A4) for detailed description. This input is terminated

to ground through a 50-Ω termination resistor. This pin can be left disconnected if not used.

INA–

INB+

INB–

A5

M4

M5

Channel B analog input positive connection. INA± is recommended for use in single channel

mode for optimal performance. The differential full-scale input voltage is determined by the

FS_RANGE_B register (see the Full-Scale Voltage (VFS) Adjustment section). This input is

terminated to ground through a 50-Ω termination resistor. The input common-mode voltage is

typically be set to 0 V (GND) and must follow the recommendations in the Recommended

Operating Conditions table. This pin can be left disconnected if not used.

Channel B analog input negative connection. INA± is recommended for use in single channel

mode for optimal performance. See INA+ (pin A4) for detailed description. This input is terminated

to ground through a 50-Ω termination resistor. This pin can be left disconnected if not used.

NCOA0

NCOA1

NCOB0

NCOB1

C7

D7

K7

J7

I

Tie this pin to GND.

Fast overrange detection status for channel A for the OVR_T0 threshold. When the analog input

exceeds the threshold programmed into OVR_T0, this status indicator goes high. The minimum

pulse duration is set by OVR_N. See the ADC Overrange Detection section for more information.

This pin can be left disconnected if not used.

ORA0

ORA1

ORB0

ORB1

C8

D8

K8

J8

O

Fast overrange detection status for channel A for the OVR_T1 threshold. When the analog input

exceeds the threshold programmed into OVR_T1, this status indicator goes high. The minimum

pulse duration is set by OVR_N. See the ADC Overrange Detection section for more information.

This pin can be left disconnected if not used.

Fast overrange detection status for channel B for the OVR_T0 threshold. When the analog input

exceeds the threshold programmed into OVR_T0, this status indicator goes high. The minimum

pulse duration is set by OVR_N. See the ADC Overrange Detection section for more information.

This pin can be left disconnected if not used.

Fast overrange detection status for channel B for the OVR_T1 threshold. When the analog input

exceeds the threshold programmed into OVR_T1, this status indicator goes high. The minimum

pulse duration is set by OVR_N. See the ADC Overrange Detection section for more information.

This pin can be left disconnected if not used.

This pin disables all analog circuits and serializer outputs when set high for temperature diode

calibration only. Do not use this pin to power down the device for power savings. Tie this pin to

GND during normal operation. For information regarding reliable serializer operation, see the

Power-Down Modes section.

PD

K6

F8

I

Serial interface clock. This pin functions as the serial-interface clock input that clocks the serial

programming data in and out. The Using the Serial Interface section describes the serial interface

in more detail. Supports 1.1-V to 1.9-V CMOS levels.

SCLK

Serial interface chip select active low input. The Using the Serial Interface section describes the

serial interface in more detail. Supports 1.1-V to 1.9-V CMOS levels. This pin has a 82-kΩ pullup

resistor to VD11.

SCS

SDI

E8

G8

H8

I

Serial interface data input. The Using the Serial Interface section describes the serial interface in

more detail. Supports 1.1-V to 1.9-V CMOS levels.

Serial interface data output. The Using the Serial Interface section describes the serial interface

in more detail. This pin is high impedance during normal device operation. This pin outputs 1.9-V

CMOS levels during serial interface read operations. This pin can be left disconnected if not used.

SDO

O

Single-ended JESD204B SYNC signal. This input is an active low input that is used to initialize

the JESD204C serial link in 8B/10B modes when SYNC_SEL is set to 0. When toggled low this

input initiates code group synchronization (see the Code Group Synchronization (CGS) section).

After code group synchronization, this input must be toggled high to start the initial lane alignment

sequence (see the Initial Lane Alignment Sequence (ILAS) section). A differential SYNC signal

can be used instead by setting SYNC_SEL to 1 and using TMSTP± as a differential SYNC input.

Tie this pin to GND if differential SYNC (TMSTP±) is used as the JESD204B SYNC signal.

SYNCSE

C2

I

6

ADC08DJ3200

www.ti.com.cn

ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

Pin Functions (continued)

I/O

DESCRIPTION

NAME

NO.

The SYSREF positive input is used to achieve synchronization and deterministic latency across

the JESD204B interface. This differential input (SYSREF+ to SYSREF–) has an internal

untrimmed 100-Ω differential termination and can be AC-coupled when SYSREF_LVPECL_EN is

set to 0. This input is self-biased when SYSREF_LVPECL_EN is set to 0. The termination

changes to 50 Ω to ground on each input pin (SYSREF+ and SYSREF–) and can be DC-coupled

when SYSREF_LVPECL_EN is set to 1. This input is not self-biased when

SYSREF+

K1

I

SYSREF_LVPECL_EN is set to 1 and must be biased externally to the input common-mode

voltage range provided in the Recommended Operating Conditions table.

SYSREF–

TDIODE+

TDIODE–

L1

K2

K3

I

SYSREF negative input

Temperature diode positive (anode) connection. An external temperature sensor can be

connected to TDIODE+ and TDIODE– to monitor the junction temperature of the device. This pin

can be left disconnected if not used.

Temperature diode negative (cathode) connection. This pin can be left disconnected if not used.

Timestamp input positive connection or differential JESD204B SYNC positive connection. This

input is a timestamp input, used to mark a specific sample, when TIMESTAMP_EN is set to 1.

This differential input is used as the JESD204B SYNC signal input when SYNC_SEL is set 1.

This input can be used as both a timestamp and differential SYNC input at the same time,

allowing feedback of the SYNC signal using the timestamp mechanism. TMSTP± uses active low

signaling when used as a JESD204B SYNC. For additional usage information, see the

Timestamp section.

TMSTP_RECV_EN must be set to 1 to use this input. This differential input (TMSTP+ to

TMSTP–) has an internal untrimmed 100-Ω differential termination and can be AC-coupled when

TMSTP_LVPECL_EN is set to 0. The termination changes to 50 Ω to ground on each input pin

(TMSTP+ and TMSTP–) and can be DC coupled when TMSTP_LVPECL_EN is set to 1. This pin

is not self-biased and therefore must be externally biased for both AC- and DC-coupled

configurations. The common-mode voltage must be within the range provided in the

Recommended Operating Conditions table when both AC and DC coupled. This pin can be left

disconnected and disabled (TMSTP_RECV_EN = 0) if SYNCSE is used for JESD204B SYNC

and timestamp is not required.

TMSTP+

B1

I

Timestamp input positive connection or differential JESD204B SYNC negative connection. This

pin can be left disconnected and disabled (TMSTP_RECV_EN = 0) if SYNCSE is used for

JESD204B SYNC and timestamp is not required.

TMSTP–

VA11

C1

I

C5, D2, D3,

D5, E5, F5,

G5, H5, J2,

J3, J5, K5

1.1-V analog supply

1.9-V analog supply

1.1-V digital supply

C4, D4, E2,

E3, E4, F4,

G4, H2, H3,

H4, J4, K4

VA19

VD11

I

C9, C10, E9,

E10, G7, H7,

H9, H10, K9,

K10

7

ADC08DJ3200

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6 Specifications

6.1 Absolute Maximum Ratings

over operating free-air temperature range (unless otherwise noted)⁽¹⁾

MIN

–0.3

–1.32

–0.1

MAX

2.35

1.32

0.1

UNIT

V

VA19⁽²⁾

VA11⁽²⁾

Supply voltage range

VD11⁽³⁾

Voltage between VD11 and VA11

Voltage between AGND and DGND

V

DA[7:0]+, DA[7:0]–, DB[7:0]+, DB[7:0]–,

TMSTP+, TMSTP–⁽³⁾

min(1.32,

VD11+0.5)

–0.5

min(1.32,

VA11+0.5)

CLK+, CLK–, SYSREF+, SYSREF–⁽²⁾

min(2.35,

VA19+0.5)

BG, TDIODE+, TDIODE–⁽²⁾

Pin voltage range

–0.5

–1

V

INA+, INA–, INB+, INB–⁽²⁾

1

CALSTAT, CALTRIG, NCOA0, NCOA1,

NCOB0, NCOB1, ORA0, ORA1, ORB0,

ORB1, PD, SCLK, SCS, SDI, SDO,

SYNCSE⁽²⁾

–0.5

VA19+0.5

Peak input current (any input except INA+, INA–, INB+, INB–)

Peak input current (INA+, INA–, INB+, INB–)

–25

–50

25

50

mA

Single-ended with Z_S-SE= 50 Ω or differential

Peak RF input power (INA+, INA–, INB+, INB–)

16.4

100

dBm

mA

with Z_S-DIFF= 100 Ω

Peak total input current (sum of absolute value of all currents forced in or out, not including

power-supply current)

Operating free-air temperature, T_A

Operating junction temperature, T_J

Storage temperature, T_stg

–40

–65

85

°C

150

(1) Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings

only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended

Operating Conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.

(2) Measured to AGND.

(3) Measured to DGND.

6.2 ESD Ratings

VALUE

±2500

±1000

UNIT

Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001⁽¹⁾

Charged-device model (CDM), per JEDEC specification JESD22-C101⁽²⁾

V_(ESD)

Electrostatic discharge

V

(1) JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.

(2) JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.

8

ADC08DJ3200

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ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

6.3 Recommended Operating Conditions

over operating free-air temperature range (unless otherwise noted)

MIN

1.8

NOM

1.9

1.1

0

MAX

2.0

UNIT

VA19, analog 1.9-V supply⁽¹⁾

V_DD

Supply voltage range

VA11, analog 1.1-V supply⁽¹⁾

VD11, digital 1.1-V supply⁽²⁾

INA+, INA–, INB+, INB–⁽¹⁾

1.05

–50

1.15

100

V

mV

V

CLK+, CLK–, SYSREF+,

SYSREF–⁽¹⁾⁽³⁾

TMSTP+, TMSTP–⁽¹⁾⁽⁴⁾

V_CMI

Input common-mode voltage

0

0.3

1.0

0.55

2.0

CLK+ to CLK–, SYSREF+ to

SYSREF–, TMSTP+ to TMSTP–

INA+ to INA–, INB+ to INB–⁽⁵⁾

0.4

Input voltage, peak-to-peak

differential

V_ID

V_PP-DIFF

1.0

CALTRIG, NCOA0, NCOA1,

NCOB0, NCOB1, PD, SCLK, SCS,

SDI, SYNCSE⁽¹⁾

V_IH

V_IL

High-level input voltage

Low-level input voltage

0.7

V

CALTRIG, NCOA0, NCOA1,

NCOB0, NCOB1, PD, SCLK, SCS,

SDI, SYNCSE⁽¹⁾

0.45

I_{C_TD}

C_L

Temperature diode input current

BG max load capacitance

BG max output current

TDIODE+ to TDIODE–

100

µA

pF

µA

50

100

70%

85

I_O

DC

T_A

Input clock duty cycle

30%

–40

50%

Operating free-air temperature

Operating junction temperature⁽⁶⁾⁽⁷⁾

°C

T_J

105

(1) Measured to AGND.

(2) Measured to DGND.

(3) TI strongly recommends that CLK± be AC-coupled with DEVCLK_LVPECL_EN set to 0 to allow CLK± to self-bias to the optimal input

common-mode voltage for best performance. TI recommends AC-coupling for SYSREF± unless DC-coupling is required, in which case

the LVPECL input mode must be used (SYSREF_LVPECL_EN = 1).

(4) TMSTP± does not have internal biasing that requires TMSTP± to be biased externally whether AC-coupled with TMSTP_LVPECL_EN =

0 or DC-coupled with TMSTP_LVPECL_EN = 1.

(5) The ADC output code saturates when V_IDfor INA± or INB± exceeds the programmed full-scale voltage (V_FS) set by FS_RANGE_A for

INA± or FS_RANGE_B for INB±.

(6) Prolonged use above this junction temperature may increase the device failure-in-time (FIT) rate.

(7) Tested up to 1000 hours continuous operation at T_J= 125°C. See the Absolute Maximum Ratings table for the absolute maximum

operational temperature.

6.4 Thermal Information

ADC08DJ3200

THERMAL METRIC⁽¹⁾

AAV (FCBGA)

UNIT

144 PINS

25.3

1.1

R_θJA

Junction-to-ambient thermal resistance

°C/W

R_θJC(top)

R_θJB

Junction-to-case (top) thermal resistance

Junction-to-board thermal resistance

8.2

ψ_JT

Junction-to-top characterization parameter

Junction-to-board characterization parameter

Junction-to-case (bottom) thermal resistance

0.1

ψ_JB

8.2

R_θJC(bot)

n/a

(1) For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application

report.

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6.5 Electrical Characteristics: DC Specifications

typical values are at T_A= 25°C, VA19 = 1.9 V , VA11 = 1.1 V, VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A =

FS_RANGE_B = 0xA000), input signal applied to INA± in single-channel modes, f_IN= 248 MHz, A_IN= –1 dBFS, f_CLK

=

maximum-rated clock frequency, filtered 1-V_PPsine-wave clock, JMODE = 17, and background calibration (unless otherwise

noted); minimum and maximum values are at nominal supply voltages and over the operating free-air temperature range

provided in the Recommended Operating Conditions table

PARAMETER

TEST CONDITIONS

MIN

TYP

MAX

UNIT

DC ACCURACY

Resolution

Resolution with no missing codes

8

±0.15

±0.3

Bits

LSB

DNL

INL

Differential nonlinearity

Integral nonlinearity

ANALOG INPUTS (INA+, INA–, INB+, INB–)

V_OFF

Offset error

Default full-scale voltage, OS_CAL disabled

±0.6

±55

mV

Input offset voltage

adjustment range

Available offset correction range (see

OS_CAL or OADJ_x_INx)

V_{OFF_ADJ}

Foreground calibration at nominal

temperature only

23

0

V_{OFF_DRIFT}

Offset drift

µV/°C

Foreground calibration at each temperature

Default full-scale voltage (FS_RANGE_A =

FS_RANGE_B = 0xA000)

750

800

850

500

Analog differential input full-

scale range

Maximum full-scale voltage (FS_RANGE_A

= FS_RANGE_B = 0xFFFF)

V_{IN_FSR}

1000

1040

480

mV_PP

Minimum full-scale voltage (FS_RANGE_A

= FS_RANGE_B = 0x2000)

Default FS_RANGE_A and FS_RANGE_B

setting, foreground calibration at nominal

temperature only, inputs driven by 50-Ω

source, includes effect of R_INdrift

–0.01

0.03

Analog differential input full-

scale range drift

V_{IN_FSR_DRIFT}

%/°C

Default FS_RANGE_A and FS_RANGE_B

setting, foreground calibration at each

temperature, inputs driven by 50-Ω source,

includes effect of R_INdrift

Analog differential input full-

scale range matching

Matching between INA+, INA– and INB+,

INB–, default setting, dual-channel mode

V_{IN_FSR_MATCH}

0.625%

50

Single-ended input resistance Each input pin is terminated to AGND,

to AGND measured at T_A= 25°C

R_IN

48

52

Ω

R_{IN_TEMPCO}

Input termination linear temperature coefficient

17.6

0.4

mΩ/°C

Single-channel mode at DC

Dual-channel mode at DC

Single-ended input

capacitance

C_IN

pF

0.4

TEMPERATURE DIODE CHARACTERISTICS (TDIODE+, TDIODE–)

Forced forward current of 100 µA. Offset

voltage (approximately 0.792 V at 0°C)

varies with process and must be measured

for each part. Offset measurement must be

done with the device unpowered or with the

PD pin asserted to minimize device self-

heating. Assert the PD pin only long enough

to take the offset measurement.

Temperature diode voltage

slope

ΔV_BE

–1.6

mV/°C

BAND-GAP VOLTAGE OUTPUT (BG)

V_BG

Reference output voltage

I

_L≤ 100 µA

1.1

V

Reference output temperature

drift

V_{BG_DRIFT}

I

–64

µV/°C

10

ADC08DJ3200

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ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

Electrical Characteristics: DC Specifications (continued)

typical values are at T_A= 25°C, VA19 = 1.9 V , VA11 = 1.1 V, VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A =

FS_RANGE_B = 0xA000), input signal applied to INA± in single-channel modes, f_IN= 248 MHz, A_IN= –1 dBFS, f_CLK

=

maximum-rated clock frequency, filtered 1-V_PPsine-wave clock, JMODE = 17, and background calibration (unless otherwise

noted); minimum and maximum values are at nominal supply voltages and over the operating free-air temperature range

provided in the Recommended Operating Conditions table

PARAMETER

TEST CONDITIONS

MIN

TYP

MAX

UNIT

CLOCK INPUTS (CLK+, CLK–, SYSREF+, SYSREF–, TMSTP+, TMSTP–)

Differential termination with

DEVCLK_LVPECL_EN = 0,

SYSREF_LVPECL_EN = 0, and

TMSTP_LVPECL_EN = 0

110

Z_T

Internal termination

Ω

Single-ended termination to GND (per pin)

with DEVCLK_LVPECL_EN = 0,

SYSREF_LVPECL_EN = 0, and

TMSTP_LVPECL_EN = 0

55

Self-biasing common-mode voltage for

CLK± when AC-coupled

0.26

(DEVCLK_LVPECL_EN must be set to 0)

Self-biasing common-mode voltage for

SYSREF± when AC-coupled

(SYSREF_LVPECL_EN must be set to 0)

and with receiver enabled

(SYSREF_RECV_EN = 1)

0.29

Input common-mode voltage,

self-biased

V_CM

V

Self-biasing common mode voltage for

SYSREF± when AC-coupled

(SYSREF_LVPECL_EN must be set to 0)

and with receiver disabled

VA11

(SYSREF_RECV_EN = 0)

Between positive and negative differential

input pins

C_{L_DIFF}

C_{L_SE}

Differential input capacitance

0.1

0.5

pF

Single-ended input

capacitance

Each input to ground

SERDES OUTPUTS (DA[7:0]+, DA[7:0]–, DB[7:0]+, DB[7:0]–)

Differential output voltage,

peak-to-peak

mV_PP-

DIFF

V

V_OD

100-Ω load

550

600

650

V_CM

Output common mode voltage AC coupled

Differential output impedance

VD11 / 2

100

Z_DIFF

Ω

CMOS INTERFACE (SCLK, SDI, SDO, SCS, PD, NCOA0, NCOA1, NCOB0, NCOB1, CALSTAT, CALTRIG, ORA0, ORA1, ORB0, ORB1,

SYNCSE)

I_IH

High-level input current

Low-level input current

Input capacitance

–40

40

µA

pF

V

I_IL

C_I

2

V_OH

V_OL

High-level output voltage

Low-level output voltage

I_LOAD= –400 µA

I_LOAD= 400 µA

1.65

150

mV

11

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ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

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6.6 Electrical Characteristics: Power Consumption

typical values are at T_A= 25°C, VA19 = 1.9 V, VA11 = 1.1 V, VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A =

FS_RANGE_B = 0xA000), input signal applied to INA± in single-channel modes, f_IN= 248 MHz, A_IN= –1 dBFS, f_CLK

=

maximum-rated clock frequency, filtered 1-V_PPsine-wave clock, JMODE = 17, and background calibration (unless otherwise

noted); minimum and maximum values are at nominal supply voltages and over the operating free-air temperature range

provided in the Recommended Operating Conditions table

PARAMETER

TEST CONDITIONS

MIN

TYP

899

501

451

2.8

MAX

950

620

650

3.2

UNIT

mA

W

I_VA19

I_VA11

I_VD11

P_DIS

I_VA19

I_VA11

I_VD11

P_DIS

I_VA19

I_VA11

I_VD11

P_DIS

I_VA19

I_VA11

I_VD11

P_DIS

I_VA19

I_VA11

I_VD11

P_DIS

1.9-V analog supply current

1.1-V analog supply current

1.1-V digital supply current

Power dissipation

Power mode 1: single-channel

mode, JMODE 5 (8 lanes),

foreground calibration

1.9-V analog supply current

1.1-V analog supply current

1.1-V digital supply current

Power dissipation

981

501

463

2.9

mA

W

Power mode 2: dual-channel mode,

JMODE 7 (8 lanes), foreground

calibration

1.9-V analog supply current

1.1-V analog supply current

1.1-V digital supply current

Power dissipation

1179

602

467

3.4

mA

W

Power mode 3: single-channel

mode, JMODE 5 (8 lanes),

background calibration

1.9-V analog supply current

1.1-V analog supply current

1.1-V digital supply current

Power dissipation

981

501

447

2.9

mA

W

Power mode 4: dual-channel mode,

JMODE 18 (16 lanes), foreground

calibration

1.9-V analog supply current

1.1-V analog supply current

1.1-V digital supply current

Power dissipation

899

519

363

2.6

mA

W

Power mode 5: single-channel

mode, JMODE 4 (4 lanes),

foreground calibration, f_CLK

2.5 GHz

=

12

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ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

6.7 Electrical Characteristics: AC Specifications (Dual-Channel Mode)

typical values are at T_A= 25°C, VA19 = 1.9 V, VA11 = 1.1 V, VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A =

FS_RANGE_B = 0xA000), f_IN= 248 MHz, A_IN= –1 dBFS, f_CLK= maximum-rated clock frequency, filtered 1-V_PPsine-wave

clock, JMODE = 18, and background calibration (unless otherwise noted); minimum and maximum values are at nominal

supply voltages and over the operating free-air temperature range provided in the Recommended Operating Conditions table

PARAMETER

TEST CONDITIONS

Foreground calibration

MIN

TYP

8.1

MAX

UNIT

Full-power input bandwidth

(–3 dB)⁽¹⁾

FPBW

XTALK

GHz

Background calibration

8.1

Dual-channel mode, aggressor =

400 MHz, –1 dBFS

–92

–67

Dual-channel mode, aggressor =

3 GHz, –1 dBFS

Channel-to-channel crosstalk

dB

Dual-channel mode, aggressor =

6 GHz, –1 dBFS

–61

Maximum CER, does not include

SerDes bit-error rate (BER)

Errors/

sample

CER

Code error rate

10^–18

No input, foreground calibration,

excludes DC offset, includes fixed

interleaving spur (f_s/ 2 spur)

NOISE_DC

DC input noise standard deviation

0.45

49.1

LSB

f_IN= 347 MHz, A_IN= –1 dBFS

f_IN= 347 MHz, A_IN= –1 dBFS,

maximum FS_RANGE_A and

FS_RANGE_B setting, foreground

calibration

49.3

f_IN= 997 MHz, A_IN= –1 dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS

49.0

48.8

Signal-to-noise ratio, large signal,

excluding DC, HD2 to HD9 and

interleaving spurs

47.0

SNR

dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS,

maximum FS_RANGE_A and

FS_RANGE_B setting, foreground

calibration

49.0

f_IN= 4997 MHz, A_IN= –1 dBFS

f_IN= 6397 MHz, A_IN= –1 dBFS

f_IN= 8197 MHz, A_IN= –1 dBFS

f_IN= 347 MHz, A_IN= –16 dBFS

f_IN= 997 MHz, A_IN= –16 dBFS

f_IN= 2397 MHz, A_IN= –16 dBFS

f_IN= 4997 MHz, A_IN= –16 dBFS

f_IN= 6397 MHz, A_IN= –16 dBFS

f_IN= 8197 MHz, A_IN= –16 dBFS

f_IN= 347 MHz, A_IN= –1 dBFS

f_IN= 997 MHz, A_IN= –1 dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS

f_IN= 4997 MHz, A_IN= –1 dBFS

f_IN= 6397 MHz, A_IN= –1 dBFS

f_IN= 8197 MHz, A_IN= –1 dBFS

f_IN= 347 MHz, A_IN= –1 dBFS

f_IN= 997 MHz, A_IN= –1 dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS

f_IN= 4997 MHz, A_IN= –1 dBFS

f_IN= 6397 MHz, A_IN= –1 dBFS

f_IN= 8197 MHz, A_IN= –1 dBFS

48.3

47.8

47.2

49.1

49.4

49.2

49.4

48.8

48.7

48.5

47.0

46.2

44.8

7.8

Signal-to-noise ratio, small signal,

excluding DC, HD2 to HD9 and

interleaving spurs

SNR

dBFS

Bits

Signal-to-noise and distortion ratio,

large signal, excluding DC and f_S/ 2

fixed spurs

46.3

SINAD

7.8

Effective number of bits, large

signal, excluding DC and f_S/ 2 fixed

spurs

7.4

7.8

ENOB

7.5

7.4

7.1

(1) Full-power input bandwidth (FPBW) is defined as the input frequency where the reconstructed output of the ADC drops 3 dB below the

power of a full-scale input signal at a low input frequency. Useable bandwidth may exceed the –3-dB full-power input bandwidth.

13

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ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

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Electrical Characteristics: AC Specifications (Dual-Channel Mode) (continued)

typical values are at T_A= 25°C, VA19 = 1.9 V, VA11 = 1.1 V, VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A =

FS_RANGE_B = 0xA000), f_IN= 248 MHz, A_IN= –1 dBFS, f_CLK= maximum-rated clock frequency, filtered 1-V_PPsine-wave

clock, JMODE = 18, and background calibration (unless otherwise noted); minimum and maximum values are at nominal

supply voltages and over the operating free-air temperature range provided in the Recommended Operating Conditions table

PARAMETER

TEST CONDITIONS

MIN

TYP

MAX

UNIT

f_IN= 347 MHz, A_IN= –1 dBFS

69

f_IN= 347 MHz, A_IN= –1 dBFS,

maximum FS_RANGE_A and

FS_RANGE_B setting, foreground

calibration

68

f_IN= 997 MHz, A_IN= –1 dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS

67

66

Spurious-free dynamic range, large

signal, excluding DC and f_S/ 2 fixed

spurs

55

SFDR

dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS,

maximum FS_RANGE_A and

FS_RANGE_B setting, foreground

calibration

62

f_IN= 4997 MHz, A_IN= –1 dBFS

f_IN= 6397 MHz, A_IN= –1 dBFS

f_IN= 8197 MHz, A_IN= –1 dBFS

f_IN= 347 MHz, A_IN= –16 dBFS

f_IN= 997 MHz, A_IN= –16 dBFS

f_IN= 2397 MHz, A_IN= –16 dBFS

f_IN= 4997 MHz, A_IN= –16 dBFS

f_IN= 6397 MHz, A_IN= –16 dBFS

f_IN= 8197 MHz, A_IN= –16 dBFS

57

55

52

67

Spurious-free dynamic range, small

signal, excluding DC and f_S/ 2 fixed

spurs

SFDR

f_S/ 2

dBFS

f_S/ 2 fixed interleaving spur,

independent of input signal

No input

–70

–75

–55

f_IN= 347 MHz, A_IN= –1 dBFS

f_IN= 347 MHz, A_IN= –1 dBFS,

maximum FS_RANGE_A and

FS_RANGE_B setting, foreground

calibration

–73

f_IN= 997 MHz, A_IN= –1 dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS

–75

–73

–60

HD2

Second-order harmonic distortion

dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS,

maximum FS_RANGE_A and

FS_RANGE_B setting, foreground

calibration

–72

f_IN= 4997 MHz, A_IN= –1 dBFS

f_IN= 6397 MHz, A_IN= –1 dBFS

f_IN= 8197 MHz, A_IN= –1 dBFS

f_IN= 347 MHz, A_IN= –1 dBFS

–68

–67

–61

–71

f_IN= 347 MHz, A_IN= –1 dBFS,

maximum FS_RANGE_A and

FS_RANGE_B setting, foreground

calibration

–69

f_IN= 997 MHz, A_IN= –1 dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS

–69

–67

–60

HD3

Third-order harmonic distortion

dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS,

maximum FS_RANGE_A and

FS_RANGE_B setting, foreground

calibration

–62

f_IN= 4997 MHz, A_IN= –1 dBFS

f_IN= 6397 MHz, A_IN= –1 dBFS

f_IN= 8197 MHz, A_IN= –1 dBFS

–57

–55

–52

14

ADC08DJ3200

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ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

Electrical Characteristics: AC Specifications (Dual-Channel Mode) (continued)

typical values are at T_A= 25°C, VA19 = 1.9 V, VA11 = 1.1 V, VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A =

FS_RANGE_B = 0xA000), f_IN= 248 MHz, A_IN= –1 dBFS, f_CLK= maximum-rated clock frequency, filtered 1-V_PPsine-wave

clock, JMODE = 18, and background calibration (unless otherwise noted); minimum and maximum values are at nominal

supply voltages and over the operating free-air temperature range provided in the Recommended Operating Conditions table

PARAMETER

TEST CONDITIONS

f_IN= 347 MHz, A_IN= –1 dBFS

f_IN= 997 MHz, A_IN= –1 dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS

f_IN= 4997 MHz, A_IN= –1 dBFS

f_IN= 6397 MHz, A_IN= –1 dBFS

f_IN= 8197 MHz, A_IN= –1 dBFS

f_IN= 347 MHz, A_IN= –1 dBFS

f_IN= 997 MHz, A_IN= –1 dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS

f_IN= 4997 MHz, A_IN= –1 dBFS

f_IN= 6397 MHz, A_IN= –1 dBFS

f_IN= 8197 MHz, A_IN= –1 dBFS

MIN

TYP

–72

–70

–69

–66

–64

–63

–74

–71

–73

–78

MAX

UNIT

–55

f_S/ 2 – f_INinterleaving spur, signal

dependent

f_S/ 2 – f_IN

dBFS

–60

Worst harmonic, fourth-order

distortion or higher

SPUR

dBFS

f_IN= 347 MHz ± 2.5 MHz,

A_IN= –7 dBFS per tone

–92

–80

–71

–63

–60

–49

f_IN= 997 MHz ± 2.5 MHz,

A_IN= –7 dBFS per tone

f_IN= 2485 MHz ± 2.5 MHz,

A_IN= –7 dBFS per tone

Third-order intermodulation

distortion

IMD3

dBFS

f_IN= 4997 MHz ± 2.5 MHz,

A_IN= –7 dBFS per tone

f_IN= 5997 MHz ± 2.5 MHz,

A_IN= –7 dBFS per tone

f_IN= 7997 MHz ± 2.5 MHz,

A_IN= –7 dBFS per tone

15

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6.8 Electrical Characteristics: AC Specifications (Single-Channel Mode)

typical values are at T_A= 25°C, VA19 = 1.9 V, VA11 = 1.1 V, VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A =

0xA000), input signal applied to INA±, f_IN= 248 MHz, A_IN= –1 dBFS, f_CLK= maximum-rated clock frequency, filtered 1-V_PP

sine-wave clock, JMODE = 17, and background calibration (unless otherwise noted); minimum and maximum values are at

nominal supply voltages and over the operating free-air temperature range provided in the Recommended Operating

Conditions table

PARAMETER

TEST CONDITIONS

Foreground calibration

MIN

TYP

7.9

MAX

UNIT

Full-power input bandwidth

(–3 dB)⁽¹⁾

FPBW

CER

GHz

Background calibration

7.9

Maximum CER, does not include

SerDes bit-error rate (BER)

Errors/

sample

Code error rate

10^–18

0.35

No input, foreground calibration,

excludes DC offset, includes fixed

interleaving spurs (f_S/ 2 and f_S/ 4

spurs)

NOISE_DCDC input noise standard deviation

LSB

f_IN= 347 MHz, A_IN= –1 dBFS

49.0

49.2

f_IN= 347 MHz, A_IN= –1 dBFS,

maximum FS_RANGE_A setting,

foreground calibration

f_IN= 997 MHz, A_IN= –1 dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS

49.0

48.8

Signal-to-noise ratio, large signal,

excluding DC, HD2 to HD9 and

interleaving spurs

47.0

SNR

dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS,

maximum FS_RANGE_A setting,

foreground calibration

49.0

f_IN= 4997 MHz, A_IN= –1 dBFS

f_IN= 6397 MHz, A_IN= –1 dBFS

f_IN= 8197 MHz, A_IN= –1 dBFS

f_IN= 347 MHz, A_IN= –16 dBFS

f_IN= 997 MHz, A_IN= –16 dBFS

f_IN= 2397 MHz, A_IN= –16 dBFS

f_IN= 4997 MHz, A_IN= –16 dBFS

f_IN= 6397 MHz, A_IN= –16 dBFS

f_IN= 8197 MHz, A_IN= –16 dBFS

f_IN= 347 MHz, A_IN= –1 dBFS

f_IN= 997 MHz, A_IN= –1 dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS

f_IN= 4997 MHz, A_IN= –1 dBFS

f_IN= 6397 MHz, A_IN= –1 dBFS

f_IN= 8197 MHz, A_IN= –1 dBFS

f_IN= 347 MHz, A_IN= –1 dBFS

f_IN= 997 MHz, A_IN= –1 dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS

f_IN= 4997 MHz, A_IN= –1 dBFS

f_IN= 6397 MHz, A_IN= –1 dBFS

f_IN= 8197 MHz, A_IN= –1 dBFS

48.2

47.9

47.1

49.2

48.7

48.4

48.0

47.2

46.6

44.8

7.8

Signal-to-noise ratio, small signal,

excluding DC, HD2 to HD9 and

interleaving spurs

SNR

dBFS

Signal-to-noise and distortion ratio,

large signal, excluding DC and f_S/ 2

fixed spurs

45.1

SINAD

7.8

Effective number of bits, large

signal, excluding DC and f_S/ 2 fixed

spurs

!~

dBFS!~Bit

s

7.2

7.7

ENOB

7.6

7.5

7.1

(1) Full-power input bandwidth (FPBW) is defined as the input frequency where the reconstructed output of the ADC drops 3 dB below the

power of a full-scale input signal at a low input frequency. Useable bandwidth may exceed the –3-dB full-power input bandwidth.

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Electrical Characteristics: AC Specifications (Single-Channel Mode) (continued)

typical values are at T_A= 25°C, VA19 = 1.9 V, VA11 = 1.1 V, VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A =

0xA000), input signal applied to INA±, f_IN= 248 MHz, A_IN= –1 dBFS, f_CLK= maximum-rated clock frequency, filtered 1-V_PP

sine-wave clock, JMODE = 17, and background calibration (unless otherwise noted); minimum and maximum values are at

nominal supply voltages and over the operating free-air temperature range provided in the Recommended Operating

Conditions table

PARAMETER

TEST CONDITIONS

MIN

TYP

MAX

UNIT

f_IN= 347 MHz, A_IN= –1 dBFS

66

f_IN= 347 MHz, A_IN= –1 dBFS,

maximum FS_RANGE_A setting,

foreground calibration

64

f_IN= 997 MHz, A_IN= –1 dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS

62

58

Spurious free dynamic range, large

signal, excluding DC, f_S/ 4 and

f_S/ 2 fixed spurs

45

SFDR

dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS,

maximum FS_RANGE_A setting,

foreground calibration

54

f_IN= 4997 MHz, A_IN= –1 dBFS

f_IN= 6397 MHz, A_IN= –1 dBFS

f_IN= 8197 MHz, A_IN= –1 dBFS

f_IN= 347 MHz, A_IN= –16 dBFS

f_IN= 997 MHz, A_IN= –16 dBFS

f_IN= 2397 MHz, A_IN= –16 dBFS

f_IN= 4997 MHz, A_IN= –16 dBFS

f_IN= 6397 MHz, A_IN= –16 dBFS

f_IN= 8197 MHz, A_IN= –16 dBFS

59

57

52

68

67

Spurious free dynamic range, small

signal, excluding DC, f_S/ 4 and

f_S/ 2 fixed spurs

SFDR

dBFS

No input, foreground calibration,

OS_CAL disabled, spur can be

improved by running OS_CAL

f_S/ 2 fixed interleaving spur,

independent of input signal

f_S/ 2

f_S/ 4

–65

dBFS

f_S/ 4 fixed interleaving spur,

independent of input signal

No input

–64

–74

–55

–60

f_IN= 347 MHz, A_IN= –1 dBFS

f_IN= 347 MHz, A_IN= –1 dBFS,

maximum FS_RANGE_A setting,

foreground calibration

–71

f_IN= 997 MHz, A_IN= –1 dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS

–72

–75

HD2

Second-order harmonic distortion

dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS,

maximum FS_RANGE_A setting,

foreground calibration

–72

f_IN= 4997 MHz, A_IN= –1 dBFS

f_IN= 6397 MHz, A_IN= –1 dBFS

f_IN= 8197 MHz, A_IN= –1 dBFS

f_IN= 347 MHz, A_IN= –1 dBFS

–72

–68

–71

f_IN= 347 MHz, A_IN= –1 dBFS,

maximum FS_RANGE_A setting,

foreground calibration

–69

f_IN= 997 MHz, A_IN= –1 dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS

–68

–60

HD3

Third-order harmonic distortion

dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS,

maximum FS_RANGE_A setting,

foreground calibration

–63

f_IN= 4997 MHz, A_IN= –1 dBFS

f_IN= 6397 MHz, A_IN= –1 dBFS

f_IN= 8197 MHz, A_IN= –1 dBFS

–59

–58

–55

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Electrical Characteristics: AC Specifications (Single-Channel Mode) (continued)

typical values are at T_A= 25°C, VA19 = 1.9 V, VA11 = 1.1 V, VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A =

0xA000), input signal applied to INA±, f_IN= 248 MHz, A_IN= –1 dBFS, f_CLK= maximum-rated clock frequency, filtered 1-V_PP

sine-wave clock, JMODE = 17, and background calibration (unless otherwise noted); minimum and maximum values are at

nominal supply voltages and over the operating free-air temperature range provided in the Recommended Operating

Conditions table

PARAMETER

TEST CONDITIONS

f_IN= 347 MHz, A_IN= –1 dBFS

f_IN= 997 MHz, A_IN= –1 dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS

f_IN= 4997 MHz, A_IN= –1 dBFS

f_IN= 6397 MHz, A_IN= –1 dBFS

f_IN= 8197 MHz, A_IN= –1 dBFS

f_IN= 347 MHz, A_IN= –1 dBFS

f_IN= 997 MHz, A_IN= –1 dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS

f_IN= 4997 MHz, A_IN= –1 dBFS

f_IN= 6397 MHz, A_IN= –1 dBFS

f_IN= 8197 MHz, A_IN= –1 dBFS

f_IN= 347 MHz, A_IN= –1 dBFS

f_IN= 997 MHz, A_IN= –1 dBFS

f_IN= 2397 MHz, A_IN= –1 dBFS

f_IN= 4997 MHz, A_IN= –1 dBFS

f_IN= 6397 MHz, A_IN= –1 dBFS

f_IN= 8197 MHz, A_IN= –1 dBFS

MIN

TYP

–68

–62

–58

–62

–63

–53

–72

–68

–65

–63

–73

–72

–73

–80

–82

–79

MAX

UNIT

–45

f_S/ 2 – f_INinterleaving spur, signal

dependent

f_S/ 2 – f_IN

f_S/ 4 ± f_IN

SPUR

dBFS

–60

f_S/ 4 ± f_INinterleaving spurs, signal

dependent

dBFS

Worst harmonic, fourth-order

distortion or higher

f_IN= 347 MHz ± 2.5 MHz,

A_IN= –7 dBFS per tone

–83

–79

–70

–64

–62

–52

f_IN= 997 MHz ± 2.5 MHz,

A_IN= –7 dBFS per tone

f_IN= 2485 MHz ± 2.5 MHz,

A_IN= –7 dBFS per tone

Third-order intermodulation

distortion

IMD3

dBFS

f_IN= 4997 MHz ± 2.5 MHz,

A_IN= –7 dBFS per tone

f_IN= 5997 MHz ± 2.5 MHz,

A_IN= –7 dBFS per tone

f_IN= 7997 MHz ± 2.5 MHz,

A_IN= –7 dBFS per tone

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6.9 Timing Requirements

MIN

NOM

MAX UNIT

DEVICE (Sampling) CLOCK (CLK+, CLK–)

Input clock frequency (CLK+, CLK–), both single-channel and dual-channel

modes⁽¹⁾

f_CLK

800

3200

MHz

SYSREF (SYSREF+, SYSREF–)

Width of invalid SYSREF capture region of CLK± period, indicating setup or

t_INV(SYSREF)

t_INV(TEMP)

t_INV(VA11)

48

0

ps

hold time violation, as measured by the SYSREF_POS status register⁽²⁾

Drift of invalid SYSREF capture region over temperature, positive number

indicates a shift toward the MSB of the SYSREF_POS register

ps/°C

ps/mV

Drift of invalid SYSREF capture region over the VA11 supply voltage, positive

number indicates a shift toward the MSB of the SYSREF_POS register

0.36

SYSREF_ZOOM = 0

Delay of the SYSREF_POS LSB

77

24

4

t_STEP(SP)

ps

SYSREF_ZOOM = 1

t_{(PH_SYS)}

t_{(PL_SYS)}

Minimum SYSREF± assertion duration after a SYSREF± rising edge event

Minimum SYSREF± de-assertion duration after a SYSREF± falling edge event

ns

1

JESD204B SYNC TIMING (SYNCSE or TMSTP±)

Minimum hold time from a multiframe boundary

JMODE = 4 or 6

JMODE = 5 or 7

21

17

(SYSREF rising edge captured high) to de-

assertion of the JESD204B SYNC signal

(SYNCSE if SYNC_SEL = 0 or TMSTP± if

SYNC_SEL = 1) for NCO synchronization

(NCO_SYNC_ILA = 1)

t_CLK

cycles

t_H(SYNCSE)

JMODE = 17 or 18

9

Minimum setup time from de-assertion of the

JESD204B SYNC signal (SYNCSE if SYNC_SEL

= 0 or TMSTP± if SYNC_SEL = 1) to multiframe

boundary (SYSREF rising edge captured high)

for NCO synchronization (NCO_SYNC_ILA = 1)

JMODE = 4 or 6

JMODE = 5 or 7

–2

2

t_CLK

cycles

t_SU(SYNCSE)

JMODE = 17 or 18

10

4

t_(SYNCSE)

SYNCSE minimum assertion time to trigger link resynchronization

Frames

SERIAL PROGRAMMING INTERFACE (SCLK, SDI, SCS)

f_CLK(SCLK)

t_(PH)

Maximum serial clock frequency

15.625

32

MHz

ns

Minimum serial clock high value pulse duration

Minimum serial clock low value pulse duration

Minimum setup time from SCS to rising edge of SCLK

Minimum hold time from rising edge of SCLK to SCS

Minimum setup time from SDI to rising edge of SCLK

Minimum hold time from rising edge of SCLK to SDI

t_(PL)

32

ns

t_SU(SCS)

t_H(SCS)

t_SU(SDI)

t_H(SDI)

30

ns

3

ns

30

ns

3

ns

(1) Unless functionally limited to a smaller range in 表 10 based on the programmed JMODE.

(2) Use SYSREF_POS to select an optimal SYSREF_SEL value for SYSREF capture, see the SYSREF Position Detector and Sampling

Position Selection (SYSREF Windowing) section for more information on SYSREF windowing. The invalid region, specified by

t_INV(SYSREF), indicates the portion of the CLK± period (t_CLK), as measured by SYSREF_SEL, that may result in a setup and hold violation.

Verify that the timing skew between SYSREF± and CLK± over system operating conditions from the nominal conditions (that used to

find optimal SYSREF_SEL) does not result in the invalid region occurring at the selected SYSREF_SEL position in SYSREF_POS,

otherwise a temperature-dependent SYSREF_SEL selection may be needed to track the skew between CLK± and SYSREF±.

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6.10 Switching Characteristics

typical values are at T_A= 25°C, VA19 = 1.9 V, VA11 = 1.1 V, VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A =

FS_RANGE_B = 0xA000), input signal applied to INA± in single-channel modes, f_IN= 248 MHz, A_IN= –1 dBFS, f_CLK

=

maximum-rated clock frequency, filtered 1-V_PPsine-wave clock, JMODE = 17, and background calibration (unless otherwise

noted); minimum and maximum values are at nominal supply voltages and over the operating free-air temperature range

provided in the Recommended Operating Conditions table

PARAMETER

TEST CONDITIONS

MIN

TYP

MAX

UNIT

DEVICE (Sampling) CLOCK (CLK+, CLK–)

Sampling (aperture) delay from

CLK± rising edge (dual-channel

mode) or rising and falling edge

(single-channel mode) to sampling

instant

TAD_COARSE = 0x00, TAD_FINE =

0x00, and TAD_INV = 0

t_AD

360

289

ps

Coarse adjustment (TAD_COARSE

= 0xFF)

Maximum t_ADadjust programmable

delay, not including clock inversion

(TAD_INV = 0)

t_TAD(MAX)

Fine adjustment (TAD_FINE = 0xFF)

Coarse adjustment (TAD_COARSE)

Fine adjustment (TAD_FINE)

4.9

1.13

19

ps

fs

t_ADadjust programmable delay step

size

t_TAD(STEP)

Minimum t_ADadjust coarse setting

(TAD_COARSE = 0x00, TAD_INV =

0)

50

t_AJ

Aperture jitter, rms

fs

Maximum t_ADadjust coarse setting

(TAD_COARSE = 0xFF) excluding

TAD_INV (TAD_INV = 0)

70⁽¹⁾

SERIAL DATA OUTPUTS (DA[7:0]+, DA[7:0]–, DB[7:0]+, DB[7:0]–)

f_SERDES

UI

Serialized output bit rate

1

12.8

Gbps

ps

Serialized output unit interval

78.125

1000

Low-to-high transition time

(differential)

20% to 80%, PRBS-7 test pattern,

12.8 Gbps, SER_PE = 0x04

t_TLH

t_THL

DDJ

RJ

37

ps

High-to-low transition time

(differential)

20% to 80%, PRBS-7 test pattern,

12.8 Gbps, SER_PE = 0x04

PRBS-7 test pattern, 12.8 Gbps,

SER_PE = 0x04, JMODE = 2

Data dependent jitter, peak-to-peak

Random jitter, RMS

7.8

1.1

PRBS-7 test pattern, 12.8 Gbps,

SER_PE = 0x04, JMODE = 2

Total jitter, peak-to-peak, with

Gaussian portion defined with

respect to a BER = 1e-15 (Q = 7.94)

PRBS-7 test pattern, 8 Gbps,

SER_PE = 0x04, JMODE = 4, 5, 6,

7

TJ

28

ps

(1) t_AJincreases because of additional attenuation on the internal clock path.

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Switching Characteristics (continued)

typical values are at T_A= 25°C, VA19 = 1.9 V, VA11 = 1.1 V, VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A =

FS_RANGE_B = 0xA000), input signal applied to INA± in single-channel modes, f_IN= 248 MHz, A_IN= –1 dBFS, f_CLK

=

maximum-rated clock frequency, filtered 1-V_PPsine-wave clock, JMODE = 17, and background calibration (unless otherwise

noted); minimum and maximum values are at nominal supply voltages and over the operating free-air temperature range

provided in the Recommended Operating Conditions table

PARAMETER

ADC CORE LATENCY

TEST CONDITIONS

MIN

TYP

MAX

UNIT

JMODE = 4

–4.5

–24.5

–5

JMODE = 5

JMODE = 6

JMODE = 7

JMODE = 17

JMODE = 18

Deterministic delay from the CLK±

edge that samples the reference

sample to the CLK± edge that

samples SYSREF going high⁽²⁾

t_ADC

t_CLKcycles

–25

–48.5

–49

JESD204B AND SERIALIZER LATENCY

JMODE = 4

JMODE = 5

JMODE = 6

JMODE = 7

JMODE = 17

JMODE = 18

67

106

67

80

119

80

Delay from the CLK± rising edge

that samples SYSREF high to the

first bit of the multiframe on the

t_TX

t_CLKcycles

JESD204B serial output lane

106

195

119

208

corresponding to the reference

(3)

sample of t_ADC

SERIAL PROGRAMMING INTERFACE (SDO)

Maximum delay from the falling

edge of the 16th SCLK cycle during

read operation for SDO transition

t_(OZD)

7

ns

from tri-state to valid data

Maximum delay from the SCS rising

t_(ODZ)

edge for SDO transition from valid

data to tri-state

7

ns

Maximum delay from the falling

edge of the 16th SCLK cycle during

read operation to SDO valid

t_(OD)

12

(2) t_ADCis an exact, unrounded, deterministic delay. The delay can be negative if the reference sample is sampled after the SYSREF high

capture point, in which case the total latency is smaller than the delay given by t_TX

.

(3) The values given for t_TXinclude deterministic and non-deterministic delays. The delay varies over process, temperature, and voltage.

JESD204B accounts for these variations when operating in subclass-1 mode in order to achieve deterministic latency. Proper receiver

RBD values must be chosen such that the elastic buffer release point does not occur within the invalid region of the local multiframe

clock (LMFC) cycle.

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S₁

S₂

S₀

t_AD

t_ADC

t_CLK

CLK+

CLKœ

SYSREF+

SYSREFœ

t_SU(SYSREF)

t_H(SYSREF)

t_TX

Start of Multi-Frame

DA0+/œ⁽¹⁾

S₁

S₂

S₀

(1) Only the SerDes lane DA0± is shown, but DA0± is representative of all lanes. The number of output lanes used and

bit-packing format is dependent on the programmed JMODE value.

图 1. ADC Timing Diagram

CLK+

CLKœ

SYSREF+

SYSREFœ

LMFC⁽¹⁾

(Internal)

One multi-frame

t_SU(SYNCSE)

t_H(SYNCSE)

SYNCSE

(SYNC_SEL = 0)

TMSTP+/œ

(SYNC_SEL = 1)

t_TX

Start of ILAS

/R

DA0+/œ⁽²⁾

(2) The internal LMFC is assumed to be aligned with the CLK± rising edge that captures the SYSREF± high value.

(3) Only SerDes lane DA0± is shown, but DA0± is representative of all lanes. All lanes output /R at approximately the

same point in time. The number of lanes is dependent on the programmed JMODE value.

图 2. SYNCSE and TMSTP± Timing Diagram for NCO Synchronization

1^stclock

16^thclock

24^thclock

SCLK

SCS

t_H(SCS)

t_SU(SCS)

t_(PH)

t_(PL)

t_H(SCS)

t_SU(SCS)

t_(PH)+ t_(PL)= t_(P)= 1 / ƒ_CLK(SCLK)

t_SU(SDI)t_H(SDI)

SDI

D7

D1

D0

Write Command

COMMAND FIELD

Hi-Z

t_(OD)

Hi-Z

t_(ODZ)

SDO

D1

D0

t_(OZD)

Read Command

图 3. Serial Interface Timing

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6.11 Typical Characteristics

typical values at T_A= 25°C, VA19 = 1.9 V, VA11 = VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A = FS_RANGE_B

= 0xA000), input signal applied to INA± in single-channel modes, f_IN= 347 MHz, A_IN= –1 dBFS, f_CLK= maximum-rated clock

frequency, filtered, 1-V_PPsine-wave clock, JMODE = 17, and background calibration (unless otherwise noted); SNR results

exclude DC, HD2 to HD9 and interleaving spurs; SINAD, ENOB, and SFDR results exclude DC and fixed-frequency

interleaving spurs

8

7.5

7

8

7.5

7

BG Calibration

FG Calibration

BG Calibration

FG Calibration

6.5

0

2000

4000

6000

8000

10000

0

2000

4000

6000

8000

10000

f_IN(MHz)

D002

D010

JMODE5, f_S= 6400 MSPS, FG and BG calibration

JMODE7, f_S= 3200 MSPS, foreground (FG) and background (BG)

calibration

Figure 4. ENOB vs Input Frequency

Figure 5. ENOB vs Input Frequency

75

SNR

SINAD

SFDR

SNR

SINAD

SFDR

70

65

70

65

60

55

50

45

40

60

55

50

45

40

0

2000

4000

6000

8000

10000

0

2000

4000

6000

8000

10000

f_IN(MHz)

D131

D129

JMODE7, f_S= 3200 MSPS, FG calibration

JMODE5, f_S= 6400 MSPS, FG calibration

Figure 6. SNR, SINAD, SFDR vs Input Frequency

Figure 7. SNR, SINAD, SFDR vs Input Frequency

-45

-50

-55

-60

-65

-70

-75

-80

-85

-45

-50

-55

-60

-65

-70

-75

-80

-85

-90

HD2

HD3

THD

HD2

HD3

THD

0

2000

4000

6000

8000

10000

0

2000

4000

6000

8000

10000

f_IN(MHz)

D132

D130

JMODE7, f_S= 3200 MSPS, FG calibration

Figure 8. HD2, HD3, THD vs Input Frequency

JMODE5, f_S= 6400 MSPS, FG calibration

Figure 9. HD2, HD3, THD vs Input Frequency

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Typical Characteristics (continued)

typical values at T_A= 25°C, VA19 = 1.9 V, VA11 = VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A = FS_RANGE_B

= 0xA000), input signal applied to INA± in single-channel modes, f_IN= 347 MHz, A_IN= –1 dBFS, f_CLK= maximum-rated clock

frequency, filtered, 1-V_PPsine-wave clock, JMODE = 17, and background calibration (unless otherwise noted); SNR results

exclude DC, HD2 to HD9 and interleaving spurs; SINAD, ENOB, and SFDR results exclude DC and fixed-frequency

interleaving spurs

75

70

65

60

55

50

45

40

75

70

65

60

55

50

45

40

SNR

SINAD

SFDR

SNR

SINAD

SFDR

0

2000

4000

6000

8000

10000

0

2000

4000

6000

8000

10000

f_IN(MHz)

D009

D001

JMODE7, f_S= 3200 MSPS, BG calibration

JMODE5, f_S= 6400 MSPS, BG calibration

Figure 10. SNR, SINAD, SFDR vs Input Frequency

Figure 11. SNR, SINAD, SFDR vs Input Frequency

-45

-50

-55

-60

-65

-70

-75

-80

-45

-50

-55

-60

-65

-70

-75

-80

HD2

HD3

THD

HD2

HD3

THD

0

2000

4000

6000

8000

10000

0

2000

4000

6000

8000

10000

f_IN(MHz)

D011

D003

JMODE7, f_S= 3200 MSPS, BG calibration

Figure 12. HD2, HD3, THD vs Input Frequency

JMODE5, f_S= 6400 MSPS, BG calibration

Figure 13. HD2, HD3, THD vs Input Frequency

8.25

8

8.25

8

7.75

7.5

7.75

7.5

7.25

800

1200

1600

2000

f_S(MSPS)

2400

2800

3200

1600

2400

3200

4000

f_S(MSPS)

4800

5600

6400

D013

D005

JMODE7, f_IN= 347 MHz, BG calibration

JMODE5, f_IN= 347 MHz, BG calibration

Figure 14. ENOB vs Sampling Rate

Figure 15. ENOB vs Sampling Rate

24

ADC08DJ3200

www.ti.com.cn

ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

Typical Characteristics (continued)

typical values at T_A= 25°C, VA19 = 1.9 V, VA11 = VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A = FS_RANGE_B

= 0xA000), input signal applied to INA± in single-channel modes, f_IN= 347 MHz, A_IN= –1 dBFS, f_CLK= maximum-rated clock

frequency, filtered, 1-V_PPsine-wave clock, JMODE = 17, and background calibration (unless otherwise noted); SNR results

exclude DC, HD2 to HD9 and interleaving spurs; SINAD, ENOB, and SFDR results exclude DC and fixed-frequency

interleaving spurs

75

70

65

60

55

50

45

40

35

75

70

65

60

55

50

45

40

35

SNR

SINAD

SFDR

SNR

SINAD

SFDR

800

1200

1600

2000

f_S(MSPS)

2400

2800

3200

1600

2400

3200

4000

f_S(MSPS)

4800

5600

6400

D012

D004

JMODE7, f_IN= 347 MHz, BG calibration

JMODE5, f_IN= 347 MHz, BG calibration

Figure 16. SNR, SINAD, SFDR vs Sampling Rate

Figure 17. SNR, SINAD, SFDR vs Sampling Rate

-55

-60

-65

-70

-75

-80

-85

-90

-55

-60

-65

-70

-75

-80

-85

-90

HD2

HD3

THD

HD2

HD3

THD

800

1200

1600

2000

f_S(MSPS)

2400

2800

3200

1600

2400

3200

4000

f_S(MSPS)

4800

5600

6400

D014

D006

JMODE7, f_IN= 347 MHz, BG calibration

JMODE5, f_IN= 347 MHz, BG calibration

Figure 18. HD2, HD3, THD vs Sampling Rate

Figure 19. HD2, HD3, THD vs Sampling Rate

0

-20

0

-20

-40

-60

-80

-100

-120

-100

-120

0

400

800

Frequency (MHz)

1200

1600

0

800

1600

Frequency (MHz)

2400

3200

D139

D134

JMODE7, f_IN= 350 MHz, FG calibration, SNR = 49.1 dBFS,

SFDR = 70.1 dBFS, ENOB = 7.80 bits

JMODE5, f_IN= 350 MHz, FG calibration, SNR = 49.0 dBFS,

SFDR = 64.0 dBFS, ENOB = 7.80 bits

Figure 20. Single-Tone FFT at A_IN= –1 dBFS

Figure 21. Single-Tone FFT at A_IN= –1 dBFS

25

ADC08DJ3200

ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

www.ti.com.cn

Typical Characteristics (continued)

typical values at T_A= 25°C, VA19 = 1.9 V, VA11 = VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A = FS_RANGE_B

= 0xA000), input signal applied to INA± in single-channel modes, f_IN= 347 MHz, A_IN= –1 dBFS, f_CLK= maximum-rated clock

frequency, filtered, 1-V_PPsine-wave clock, JMODE = 17, and background calibration (unless otherwise noted); SNR results

exclude DC, HD2 to HD9 and interleaving spurs; SINAD, ENOB, and SFDR results exclude DC and fixed-frequency

interleaving spurs

0

-20

-40

-60

-80

-100

-120

-100

-120

0

320

640 960

Frequency (MHz)

1280

1600

0

640

1280 1920

Frequency (MHz)

2560

3200

D140

D135

JMODE7, f_IN= 2400 MHz, FG calibration, SNR = 48.8 dBFS,

SFDR = 63.7 dBFS, ENOB = 7.74 bits

JMODE5, f_IN= 2400 MHz, FG calibration, SNR = 48.8 dBFS,

SFDR = 52.4 dBFS, ENOB = 7.53 bits

Figure 22. Single-Tone FFT at A_IN= –1 dBFS

Figure 23. Single-Tone FFT at A_IN= –1 dBFS

0

-20

-40

-20

-40

-60

-80

-100

-120

-100

-120

0

400

800

Frequency (MHz)

1200

1600

0

800

1600

Frequency (MHz)

2400

3200

D141

D136

JMODE7, f_IN= 5000 MHz, FG calibration, SNR = 48.4 dBFS,

SFDR = 57.1 dBFS, ENOB = 7.52 bits

JMODE5, f_IN= 5000 MHz, FG calibration, SNR = 48.3 dBFS,

SFDR = 57.2 dBFS, ENOB = 7.48 bits

Figure 24. Single-Tone FFT at A_IN= –1 dBFS

Figure 25. Single-Tone FFT at A_IN= –1 dBFS

0

-20

-40

-20

-40

-60

-80

-100

-120

-100

-120

0

400

800

Frequency (MHz)

1200

1600

0

800

1600

Frequency (MHz)

2400

3200

D145

D144

JMODE7, f_IN= 8200 MHz, FG calibration, SNR = 47.4 dBFS,

SFDR = 52.4 dBFS, ENOB = 7.19 bits

JMODE5, f_IN= 8200 MHz, FG calibration, SNR = 47.4 dBFS,

SFDR = 51.4 dBFS, ENOB = 7.10 bits

Figure 26. Single-Tone FFT at A_IN= –1 dBFS

Figure 27. Single-Tone FFT at A_IN= –1 dBFS

26

ADC08DJ3200

www.ti.com.cn

ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

Typical Characteristics (continued)

typical values at T_A= 25°C, VA19 = 1.9 V, VA11 = VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A = FS_RANGE_B

= 0xA000), input signal applied to INA± in single-channel modes, f_IN= 347 MHz, A_IN= –1 dBFS, f_CLK= maximum-rated clock

frequency, filtered, 1-V_PPsine-wave clock, JMODE = 17, and background calibration (unless otherwise noted); SNR results

exclude DC, HD2 to HD9 and interleaving spurs; SINAD, ENOB, and SFDR results exclude DC and fixed-frequency

interleaving spurs

0

-20

-40

-60

-80

-100

-120

-100

-120

0

400

800

Frequency (MHz)

1200

1600

0

800

1600

Frequency (MHz)

2400

3200

D142

D137

JMODE7, f_IN= 8200 MHz, FG calibration, SNR = 49.2 dBFS,

SFDR = 65.9 dBFS, ENOB = 7.80 bits

JMODE5, f_IN= 8200 MHz, FG calibration, SNR = 49.0 dBFS,

SFDR = 67.5 dBFS, ENOB = 7.79 bits

Figure 28. Single-Tone FFT at A_IN= –16 dBFS

Figure 29. Single-Tone FFT at A_IN= –16 dBFS

0.5

0.3

0.2

0.1

0

0.25

0

-0.1

-0.2

-0.3

-0.25

-0.5

0

255

0

255

Code

D048

D049

JMODE5, f_S= 6400 MSPS, FG calibration

Figure 30. DNL vs Code

Figure 31. INL vs Code

75

70

65

60

55

50

45

-55

-60

-65

-70

-75

-80

-85

-90

SNR

SINAD

SFDR

HD2

HD3

THD

-75

-50

-25

0

Ambient Temperature (°C)

25

50

75

100

125

-75

-50

-25

0

Ambient Temperature (°C)

25

50

75

100

125

D039

D041

JMODE5, f_S= 6400 MSPS, f_IN= 2400 MHz, BG calibration

Figure 32. SNR, SINAD, SFDR vs Temperature

Figure 33. HD2, HD3, THD vs Temperature

27

ADC08DJ3200

ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

www.ti.com.cn

Typical Characteristics (continued)

typical values at T_A= 25°C, VA19 = 1.9 V, VA11 = VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A = FS_RANGE_B

= 0xA000), input signal applied to INA± in single-channel modes, f_IN= 347 MHz, A_IN= –1 dBFS, f_CLK= maximum-rated clock

frequency, filtered, 1-V_PPsine-wave clock, JMODE = 17, and background calibration (unless otherwise noted); SNR results

exclude DC, HD2 to HD9 and interleaving spurs; SINAD, ENOB, and SFDR results exclude DC and fixed-frequency

interleaving spurs

8.5

8

7.75

7.5

FG Calibration at Each Temperature

FG Calibration at 25°C

BG Calibration

FG Calibration at Each Temperature

8

7.5

7

7.25

7

6.5

-75

-50

-25

0

25

50

Ambient Temperature (°C)

75

100

125

-75

-50

-25

0

25

50

Ambient Temperature (°C)

75

100

125

D040

D121

JMODE5, f_IN= 2400 MHz, f_S= 6400 MSPS

JMODE5, f_IN= 600 MHz, f_S= 6400 MSPS

Figure 34. ENOB vs Temperature and Calibration Type

Figure 35. ENOB vs Temperature and Calibration Type

70

52

FG Calibration at Each Temperature

FG Calibration at 25°C

FG Calibration at Each Temperature

FG Calibration at 25°C

51

50

49

48

47

46

65

60

55

50

-75

-50

-25

0

Ambient Temperature (°C)

25

50

75

100

125

-75

-50

-25

0

Ambient Temperature (°C)

25

50

75

100

125

D063

D064

JMODE5, f_IN= 600 MHz, f_S= 6400 MSPS

Figure 36. SNR vs Temperature and Calibration Type

Figure 37. SFDR vs Temperature and Calibration Type

-55

-45

FG Calibration at Each Temperature

FG Calibration at 25°C

FG Calibration at Each Temperature

FG Calibration at 25°C

-60

-65

-70

-75

-80

-85

-90

-50

-55

-60

-65

-70

-75

-80

-75

-50

-25

0

Ambient Temperature (°C)

25

50

75

100

125

-75

-50

-25

0

Ambient Temperature (°C)

25

50

75

100

125

D119

D120

JMODE5, f_IN= 600 MHz, f_S= 6400 MSPS

Figure 38. HD2 vs Temperature and Calibration Type

JMODE5, f_IN= 600 MHz, f_S= 6400 MSPS

Figure 39. HD3 vs Temperature and Calibration Type

28

ADC08DJ3200

www.ti.com.cn

ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

Typical Characteristics (continued)

typical values at T_A= 25°C, VA19 = 1.9 V, VA11 = VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A = FS_RANGE_B

= 0xA000), input signal applied to INA± in single-channel modes, f_IN= 347 MHz, A_IN= –1 dBFS, f_CLK= maximum-rated clock

frequency, filtered, 1-V_PPsine-wave clock, JMODE = 17, and background calibration (unless otherwise noted); SNR results

exclude DC, HD2 to HD9 and interleaving spurs; SINAD, ENOB, and SFDR results exclude DC and fixed-frequency

interleaving spurs

56

54

52

50

48

46

44

42

40

8

7.75

7.5

7.25

SNR

SINAD

SFDR

7

-5

-2.5

0

Supply Voltage (%)

2.5

5

-5

-2.5

0

Supply Voltage (%)

2.5

5

D036

D037

JMODE5, f_S= 6400 MSPS, f_IN= 2400 MHz, FG calibration

Figure 40. SNR, SINAD, SFDR vs Supply Voltage

Figure 41. ENOB vs Supply Voltage

1.2

-50

HD2

HD3

THD

-55

-60

-65

-70

-75

-80

-85

-90

1

0.8

0.6

0.4

IA19

IA11

ID11

0.2

0

-5

-2.5

0

Supply Voltage (%)

2.5

5

1600

2400

3200

4000

f_S(MSPS)

4800

5600

6400

D038

D007

JMODE5, f_S= 6400 MSPS, f_IN= 2400 MHz, FG calibration

JMODE5, f_IN= 347 MHz, FG calibration

Figure 42. HD2, HD3, THD vs Supply Voltage

Figure 43. Supply Current vs Sampling Rate

3.2

1.2

1

3

2.8

2.6

2.4

2.2

2

0.8

0.6

0.4

0.2

0

IA19

IA11

ID11

1600

2400

3200

4000

f_S(MSPS)

4800

5600

6400

800

1200

1600

2000

f_S(MSPS)

2400

2800

3200

D008

D015

JMODE5, f_IN= 347 MHz, FG calibration

JMODE7, f_IN= 347 MHz, FG calibration

Figure 44. Power Consumption vs Sampling Rate

Figure 45. Supply Current vs Sampling Rate

29

ADC08DJ3200

ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

www.ti.com.cn

Typical Characteristics (continued)

typical values at T_A= 25°C, VA19 = 1.9 V, VA11 = VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A = FS_RANGE_B

= 0xA000), input signal applied to INA± in single-channel modes, f_IN= 347 MHz, A_IN= –1 dBFS, f_CLK= maximum-rated clock

frequency, filtered, 1-V_PPsine-wave clock, JMODE = 17, and background calibration (unless otherwise noted); SNR results

exclude DC, HD2 to HD9 and interleaving spurs; SINAD, ENOB, and SFDR results exclude DC and fixed-frequency

interleaving spurs

3.2

1.4

1.2

1

3

2.8

2.6

2.4

2.2

2

0.8

0.6

0.4

0.2

0

IA19

IA11

ID11

800

1200

1600

2000

f_S(MSPS)

2400

2800

3200

-75

-50

-25

0

Ambient Temperature (°C)

25

50

75

100

125

D016

D047

JMODE7, f_IN= 347 MHz, FG calibration

JMODE5, f_S= 6400 MSPS, f_IN= 2400 MHz, BG calibration

Figure 46. Power Consumption vs Sampling Rate

Figure 47. Supply Current vs Temperature

1

4

0.9

0.8

0.7

0.6

0.5

3.75

3.5

3.25

3

2.75

2.5

2.25

2

0.4

IA19

IA11

ID11

0.3

0.2

BG Calibration

FG Calibration

-75

-50

-25

0

Ambient Temperature (°C)

25

50

75

100

125

-5

-2.5

0

Supply Voltage (%)

2.5

5

D046

D045

JMODE5, f_S= 6400 MSPS, f_IN= 2400 MHz, BG calibration

JMODE5, f_S= 6400 MSPS, FG calibration

Figure 48. Power Consumption vs Temperature

Figure 49. Supply Current vs Supply Voltage

3.2

1.2

1.1

1

3

2.8

2.6

2.4

0.9

0.8

0.7

FG Calibration

BG Calibration

LPBG Calibration

-5

-2.5

0

Supply Voltage (%)

2.5

5

800

1200

1600

2000

f_CLK(MHz)

2400

2800

3200

D044

D123

JMODE5, f_S= 6400 MSPS, FG calibration

Figure 50. Power Consumption vs Supply Voltage

JMODE5, f_IN= 607 MHz

Figure 51. IA19 Supply Current vs Clock Frequency

30

ADC08DJ3200

www.ti.com.cn

ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

Typical Characteristics (continued)

typical values at T_A= 25°C, VA19 = 1.9 V, VA11 = VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A = FS_RANGE_B

= 0xA000), input signal applied to INA± in single-channel modes, f_IN= 347 MHz, A_IN= –1 dBFS, f_CLK= maximum-rated clock

frequency, filtered, 1-V_PPsine-wave clock, JMODE = 17, and background calibration (unless otherwise noted); SNR results

exclude DC, HD2 to HD9 and interleaving spurs; SINAD, ENOB, and SFDR results exclude DC and fixed-frequency

interleaving spurs

0.8

0.6

0.4

0.2

0

0.8

0.6

0.4

0.2

0

FG Calibration

BG Calibration

LPBG Calibration

FG Calibration

BG Calibration

LPBG Calibration

800

1200

1600

2000

f_CLK(MHz)

2400

2800

3200

800

1200

1600

2000

f_CLK(MHz)

2400

2800

3200

D124

D117

JMODE5, f_IN= 607 MHz

Figure 52. IA11 Supply Current vs Clock Frequency

Figure 53. ID11 Supply Current vs Clock Frequency

4

1.5

FG Calibration

BG Calibration

LPBG Calibration

IA19

IA11

ID11

1.25

1

3.5

3

0.75

0.5

0.25

0

2.5

2

800

1200

1600

2000

f_CLK(MHz)

2400

2800

3200

4

6

8

10

JMODE

12

14

16

18

D118

D034

JMODE5, f_IN= 607 MHz

f_IN= 2400 MHz, f_CLK= 3200 MHz, FG calibration

Figure 54. Power Consumption vs Clock Frequency

Figure 55. Supply Current vs JMODE

1.5

4

FG Calibration

BG Calibration

LPBG Calibration

1.25

1

3.75

3.5

0.75

0.5

0.25

0

3.25

3

IA19

IA11

ID11

2.75

2.5

4

6

8

10

12

14

16

18

4

6

8

10

12

14

16

18

JMODE

D122

D033

f_IN= 2400 MHz, f_CLK= 3200 MHz, BG calibration

f_IN= 2400 MHz, f_CLK= 3200 MHz

Figure 57. Power Consumption vs JMODE

Figure 56. Supply Current vs JMODE

31

ADC08DJ3200

ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

www.ti.com.cn

Typical Characteristics (continued)

typical values at T_A= 25°C, VA19 = 1.9 V, VA11 = VD11 = 1.1 V, default full-scale voltage (FS_RANGE_A = FS_RANGE_B

= 0xA000), input signal applied to INA± in single-channel modes, f_IN= 347 MHz, A_IN= –1 dBFS, f_CLK= maximum-rated clock

frequency, filtered, 1-V_PPsine-wave clock, JMODE = 17, and background calibration (unless otherwise noted); SNR results

exclude DC, HD2 to HD9 and interleaving spurs; SINAD, ENOB, and SFDR results exclude DC and fixed-frequency

interleaving spurs

256

192

128

64

140

130

120

110

100

90

Zoomed Area

in Following Plot

0

5000 10000 15000 20000 25000 30000 35000

Sample Number

14800

15200

15600

Sample Number

16000

16400

D126

D125

JMODE4, f_CLK= 3200 MHz, f_IN= 3199.9 MHz

Figure 58. Background Calibration Core Transition

(AC Signal)

Figure 59. Background Calibration Core Transition

(AC Signal Zoomed)

260

240

220

32

-0.35 V Differential

200

180

160

140

120

100

80

+0.35 V Differential

-0.35 V Differential

0 V Differential

24

16

8

Zoomed Area

in Following Plot

60

40

20

0

1600 1700 1800 1900 2000 2100 2200 2300 2400

Sample Number

0

1000 2000 3000 4000 5000 6000 7000 8000

Sample Number

D127

D128

JMODE4, f_CLK= 3200 MHz, DC input

Figure 60. Background Calibration Core Transition

(DC Signal)

Figure 61. Background Calibration Core Transition

(DC Signal Zoomed)

32

ADC08DJ3200

www.ti.com.cn

ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

7 Detailed Description

7.1 Overview

ADC08DJ3200 device is an RF-sampling, giga-sample, analog-to-digital converter (ADC) that can directly sample

input frequencies from DC to above 10 GHz. In dual-channel mode, the ADC08DJ3200 can sample up to 3200

GSPS and up to 6400 GSPS in single-channel mode. Programmable tradeoffs in channel count (dual-channel

mode) and Nyquist bandwidth (single-channel mode) allow development of flexible hardware that meets the

needs of both high channel count or wide instantaneous signal bandwidth applications. Full-power input

bandwidth (–3 dB) of 8.0 GHz, with usable frequencies exceeding the –3-dB point in both dual- and single-

channel modes, allows direct RF sampling of L-band, S-band, C-band, and X-band for frequency agile systems.

ADC08DJ3200 uses a high-speed JESD204B output interface with up to 16 serialized lanes and subclass-1

compliance for deterministic latency and multi-device synchronization. The serial output lanes support up to 12.8

Gbps and can be configured to trade-off bit rate and number of lanes. At 5 Gsps, only four total lanes are

required running at 12.5 Gbps or 16 lanes can be used to reduce the lane rate to 3.125 Gbps.

A number of synchronization features, including noiseless aperture delay (t_AD) adjustment and SYSREF

windowing, simplify system design for multi-channel systems. Aperture delay adjustment can be used to simplify

SYSREF capture, to align the sampling instance between multiple ADCs or to sample an ideal location of a front-

end track and hold (T&H) amplifier output. SYSREF windowing offers a simplistic way to measure invalid timing

regions of SYSREF relative to the device clock and then choose an optimal sampling location. Dual-edge

sampling (DES) is implemented in single-channel mode to reduce the maximum clock rate applied to the ADC to

support a wide range of clock sources and relax setup and hold timing for SYSREF capture.

ADC08DJ3200 provides foreground and background calibration options for gain, offset and static linearity errors.

Foreground calibration is run at system startup or at specified times during which the ADC is offline and not

sending data to the logic device. Background calibration allows the ADC to run continually while the cores are

calibrated in the background so that the system does not experience downtime. The calibration routine is also

used to match the gain and offset between sub-ADC cores to minimize spurious artifacts from time interleaving.

33

ADC08DJ3200

ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

www.ti.com.cn

7.2 Functional Block Diagram

CALTRG

PD

SCLK

SDI

SDO

SCS\

SPI Registers and

Device Control

TMSTP+

TMSTP-

DA0+

DA0-

Input

MUX

JESD204B

Link A

ADC A

INA+

INA-

DA7+

DA7-

Over-

range

SYNCSE\

DB0+

DB0-

INB+

INB-

Input

MUX

JESD204B

Link B

ADC B

DB7+

DB7-

Aperture

Delay Adjust

CLK+

CLK-

Clock Distribution

and Synchronization

ORA0

ORA1

ORB0

ORB1

CALSTAT

Status

Indicators

SYSREF+

SYSREF-

SYSREF

Windowing

TDIODE+

TDIODE-

7.3 Feature Description

7.3.1 Device Comparison

The devices listed in 表 1 are part of a pin-to-pin compatible, high-speed, wide-bandwidth ADC family. The family

is offered to provide a scalable family of devices for varying resolution, sampling rate and signal bandwidth.

表 1. Device Family Comparison

MAXIMUM

SAMPLING RATE

DUAL CHANNEL

DECIMATION

SINGLE CHANNEL

DECIMATION

INTERFACE

(MAX LINERATE)

PART NUMBER

RESOLUTION

JESD204B /

JESD204C

(17.16 Gbps)

Single 10.4 GSPS

Dual 5.2 GSPS

ADC12DJ5200RF

12-bit

Complex: 4x, 8x

Single 6.4 GSPS

Dual 3.2 GSPS

Real: 2x

Complex: 4x, 8x, 16x

JESD204B

(12.8 Gbps)

ADC12DJ3200

ADC08DJ3200

ADC12DJ2700

12-bit

8-bit

None

Single 6.4 GSPS

Dual 3.2 GSPS

JESD204B

(12.8 Gbps)

None

Single 5.4 GSPS

Dual 2.7 GSPS

Real: 2x

Complex: 4x, 8x, 16x

JESD204B

(12.8 Gbps)

12-bit

34

ADC08DJ3200

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ZHCSHO8A –FEBRUARY 2018–REVISED APRIL 2020

7.3.2 Analog Inputs

The analog inputs of the ADC08DJ3200 have internal buffers to enable high input bandwidth and to isolate

sampling capacitor glitch noise from the input circuit. Analog inputs must be driven differentially because

operation with a single-ended signal results in degraded performance. Both AC-coupling and DC-coupling of the

analog inputs is supported. The analog inputs are designed for an input common-mode voltage (V_CMI) of 0 V,

which is terminated internally through single-ended, 50-Ω resistors to ground (GND) on each input pin. DC-

coupled input signals must have a common-mode voltage that meets the device input common-mode

requirements specified as V_CMIin the Recommended Operating Conditions table. The 0-V input common-mode

voltage simplifies the interface to split-supply, fully-differential amplifiers and to a variety of transformers and

baluns. The ADC08DJ3200 includes internal analog input protection to protect the ADC inputs during overranged

input conditions; see the Analog Input Protection section. 图 62 provides a simplified analog input model.

AGND

Analog Input

Protection

Diodes

50 ꢀ

INA+, INB+

ADC

INAœ, INBœ

Input Buffer

50 ꢀ

图 62. ADC08DJ3200 Analog Input Internal Termination and Protection Diagram

There is minimal degradation in analog input bandwidth when using single-channel mode versus dual-channel

mode. In single-channel mode, INA± is strongly recommended to be used as the input to the ADC because ADC

performance is optimized for INA±. However, either analog input (INA+ and INA– or INB+ and INB–) can be

used. Using INB± results in degraded performance unless custom trim routines are used to optimize performance

for INB± in each device. The desired input can be chosen using SINGLE_INPUT in the input mux control

register.

注

INA± is strongly recommended to be used as the input to the ADC in single-channel mode

for optimized performance.

7.3.2.1 Analog Input Protection

The analog inputs are protected against overdrive conditions by internal clamping diodes that are capable of

sourcing or sinking input currents during overrange conditions, see the voltage and current limits in the Absolute

Maximum Ratings table. The overrange protection is also defined for a peak RF input power in the Absolute

Maximum Ratings table, which is frequency independent. Operation above the maximum conditions listed in the

Recommended Operating Conditions table results in an increase in failure-in-time (FIT) rate, so the system must

correct the overdrive condition as quickly as possible. 图 62 shows the analog input protection diodes.

7.3.2.2 Full-Scale Voltage (V_FS) Adjustment

Input full-scale voltage (V_FS) adjustment is available, in fine increments, for each analog input through the

FS_RANGE_A register setting (see the INA full-scale range adjust register) and FS_RANGE_B register setting

(see the INB full-scale range adjust register) for INA± and INB±, respectively. The available adjustment range is

specified in the Electrical Characteristics: DC Specifications table. Larger full-scale voltages improve SNR and

noise floor (in dBFS/Hz) performance, but may degrade harmonic distortion. The full-scale voltage adjustment is

useful for matching the full-scale range of multiple ADCs when developing a multi-converter system or for

external interleaving of multiple ADC08DJ3200s to achieve higher sampling rates.

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7.3.2.3 Analog Input Offset Adjust

The input offset voltage for each input can be adjusted through the SPI register. The OADJ_A_INx registers

(registers 0x08A and 0x08D) are used to adjust ADC core A's offset voltage when sampling analog input x

(where x is A for INA± or B for INB±). OADJ_B_INx is used to adjust ADC core B's offset voltage when sampling

input x. These registers apply to both dual channel mode and single channel mode. To adjust the offset voltage

in dual channel mode simply adjust the offset to the ADC core sampling the desired input. In single channel

mode, both ADC core A's and ADC core B's offset must be adjusted together. The difference in the two core's

offsets in single channel mode results in a spur at f_S/2 that is independent of the input. These registers can be

used to compensate the f_S/2 spur in single channel mode. See the Calibration Modes and Trimming section for

more information.

7.3.3 ADC Core

The ADC08DJ3200 consists of a total of six ADC cores. The cores are interleaved for higher sampling rates and

swapped on-the-fly for calibration as required by the operating mode. This section highlights the theory and key

features of the ADC cores.

7.3.3.1 ADC Theory of Operation

The differential voltages at the analog inputs are captured by the rising edge of CLK± in dual-channel mode or by

the rising and falling edges of CLK± in single-channel mode. After capturing the input signal, the ADC converts

the analog voltage to a digital value by comparing the voltage to the internal reference voltage. If the voltage on

INA– or INB– is higher than the voltage on INA+ or INB+, respectively, then the digital output is a negative 2's

complement value. If the voltage on INA+ or INB+ is higher than the voltage on INA– or INB–, respectively, then

the digital output is a positive 2's complement value. 公式 1 can calculate the differential voltage at the input pins

from the digital output.

Code

2

^N

V_IN

=

V_FS

where

•

Code is the signed decimation output code (for example, –2048 to +2047)

N is the ADC resolution

and V_FSis the full-scale input voltage of the ADC as specified in the Recommended Operating Conditions

table, including any adjustment performed by programming FS_RANGE_A or FS_RANGE_B

(1)

7.3.3.2 ADC Core Calibration

ADC core calibration is required to optimize the analog performance of the ADC cores. Calibration must be

repeated when operating conditions change significantly, namely temperature, in order to maintain optimal

performance. The ADC08DJ3200 has a built-in calibration routine that can be run as a foreground operation or a

background operation. Foreground operation requires ADC downtime, where the ADC is no longer sampling the

input signal, to complete the process. Background calibration can be used to overcome this limitation and allow

constant operation of the ADC. See the Calibration Modes and Trimming section for detailed information on each

mode.

7.3.3.3 Analog Reference Voltage

The reference voltage for the ADC08DJ3200 is derived from an internal band-gap reference. A buffered version

of the reference voltage is available at the BG pin for user convenience. This output has an output-current

capability of ±100 µA. The BG output must be buffered if more current is required. No provision exists for the use

of an external reference voltage, but the full-scale input voltage can be adjusted through the full-scale-range

register settings. In unique cases, the VA11 supply voltage can act as the reference voltage by setting

BG_BYPASS (see the internal reference bypass register).

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7.3.3.4 ADC Overrange Detection

To ensure that system gain management has the quickest possible response time, a low-latency configurable

overrange function is included. The overrange function works by monitoring the converted 8-bit samples at the

ADC to quickly detect if the ADC is near saturation or already in an overrange condition. The absolute value of

the 8 bits of the ADC data are checked against two programmable thresholds, OVR_T0 and OVR_T1. These

thresholds apply to both channel A and channel B in dual-channel mode. 表 2 lists how an ADC sample is

converted to an absolute value for a comparison of the thresholds.

表 2. Conversion of ADC Sample for Overrange Comparison

ADC SAMPLE

(Offset Binary)

ADC SAMPLE

(2's Complement)

ABSOLUTE VALUE

8 BITS USED FOR COMPARISON

1111 1111 (255)

0111 1111 (+127)

111 1111 (127)

000 0000 (0)

1111 1111 (255)

0000 0000 (0)

1000 0000 (128)

0000 0001 (1)

0000 0000 (0)

1000 0001 (–127)

1000 0000 (–128)

111 1111 (127)

1111 1110 (254)

1111 1111 (255)

If the 8 bits of the absolute value equal or exceed the OVR_T0 or OVR_T1 thresholds during the monitoring

period, then the overrange bit associated with the threshold is set to 1, otherwise the overrange bit is 0. In dual-

channel mode, the overrange status can be monitored on the ORA0 and ORA1 pins for channel A and the ORB0

and ORB1 pins for channel B, where ORx0 corresponds to the OVR_T0 threshold and ORx1 corresponds to the

OVR_T1 threshold. In single-channel mode, the overrange status for the OVR_T0 threshold is determined by

monitoring both the ORA0 and ORB0 outputs and the OVR_T1 threshold is determined by monitoring both ORA1

and ORB1 outputs. In single-channel mode, the two outputs for each threshold must be OR'd together to

determine whether an overrange condition occurred. OVR_N can be used to set the output pulse duration from

the last overrange event. 表 3 lists the overrange pulse lengths for the various OVR_N settings (see the

overrange configuration register).

表 3. Overrange Monitoring Period for the ORA0, ORA1, ORB0, and ORB1 Outputs

OVERRANGE PULSE LENGTH SINCE LAST OVERRANGE

OVR_N

EVENT (DEVCLK Cycles)

0

1

2

3

4

5

6

7

8

16

32

64

128

256

512

1024

Typically, the OVR_T0 threshold can be set near the full-scale value (228 for example). When the threshold is

triggered, a typical system can turn down the system gain to avoid clipping. The OVR_T1 threshold can be set

much lower. For example, the OVR_T1 threshold can be set to 64 (peak input voltage of −12 dBFS). If the input

signal is strong, the OVR_T1 threshold is tripped occasionally. If the input is quite weak, the threshold is never

tripped. The downstream logic device monitors the OVR_T1 bit. If OVR_T1 stays low for an extended period of

time, then the system gain can be increased until the threshold is occasionally tripped (meaning the peak level of

the signal is above −12 dBFS).

7.3.3.5 Code Error Rate (CER)

ADC cores can generate bit errors within a sample, often called code errors (CER) or referred to as sparkle

codes, resulting from metastability caused by non-ideal comparator limitations. The ADC08DJ3200 uses a

unique ADC architecture that inherently allows significant code error rate improvements from traditional pipelined

flash or successive approximation register (SAR) ADCs. The code error rate of the ADC08DJ3200 is multiple

orders of magnitude better than what can be achieved in alternative architectures at equivalent sampling rates

providing significant signal reliability improvements.

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7.3.4 Temperature Monitoring Diode

A built-in thermal monitoring diode is made available on the TDIODE+ and TDIODE– pins. This diode facilitates

temperature monitoring and characterization of the device in higher ambient temperature environments. Although

the on-chip diode is not highly characterized, the diode can be used effectively by performing a baseline

measurement (offset) at a known ambient or board temperature and creating a linear equation with the diode

voltage slope provided in the Electrical Characteristics: DC Specifications table. Perform offset measurement

with the device unpowered or with the PD pin asserted to minimize device self-heating. Only assert the PD pin

long enough to take the offset measurement. Recommended monitoring devices include the LM95233 device

and similar remote-diode temperature monitoring products from Texas Instruments.

7.3.5 Timestamp

The TMSTP+ and TMSTP– differential input can be used as a time-stamp input to mark a specific sample based

on the timing of an external trigger event relative to the sampled signal. TIMESTAMP_EN (see the LSB control

bit output register) must be set in order to use the timestamp feature and output the timestamp data. When

enabled, the LSB of the 8-bit ADC digital output reports the status of the TMSTP± input. In effect, the 8-bit output

sample consists of the upper 7-bits of the 8-bit converter and the LSB of the 8-bit output sample is the output of a

parallel 1-bit converter (TMSTP±) with the same latency as the ADC core. The trigger must be applied to the

differential TMSTP+ and TMSTP– inputs. The trigger can be asynchronous to the ADC sampling clock and is

sampled at approximately the same time as the analog input. Timestamp cannot be used when a JMODE with

decimation is selected and instead SYSREF must be used to achieve synchronization through the JESD204B

subclass-1 method for achieving deterministic latency.

7.3.6 Clocking

The clocking subsystem of the ADC08DJ3200 has two input signals, device clock (CLK+, CLK–) and SYSREF

(SYSREF+, SYSREF–). Within the clocking subsystem there is a noiseless aperture delay adjustment (t_AD

adjust), a clock duty cycle corrector, and a SYSREF capture block. 图 63 describes the clocking subsystem.

Duty Cycle

Correction

t_ADAdjust

Clock Distribution

and Synchronization

CLK+

(ADC cores, digital,

JESD204B, etc.)

CLK-

SYSREF Capture

Automatic

SYSREF

Calibration

SYSREF+

SYSREF-

SYSREF Windowing

SYSREF_POS

SYSREF_SEL SRC_EN

图 63. ADC08DJ3200 Clocking Subsystem

The device clock is used as the sampling clock for the ADC core as well as the clocking for the digital processing

and serializer outputs. Use a low-noise (low jitter) device clock to maintain high signal-to-noise ratio (SNR) within

the ADC. In dual-channel mode, the analog input signal for each input is sampled on the rising edge of the

device clock. In single-channel mode, both the rising and falling edges of the device clock are used to capture

the analog signal to reduce the maximum clock rate required by the ADC. A noiseless aperture delay adjustment

(t_ADadjust) allows the user to shift the sampling instance of the ADC in fine steps in order to synchronize multiple

ADC08DJ3200s or to fine-tune system latency. Duty cycle correction is implemented in the ADC08DJ3200 to

ease the requirements on the external device clock while maintaining high performance. 表 4 summarizes the

device clock interface in dual-channel mode and single-channel mode.

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表 4. Device Clock vs Mode of Operation

MODE OF OPERATION

SAMPLING RATE VS f_CLK

1 × f_CLK

SAMPLING INSTANT

Rising edge

Dual-channel mode

Single-channel mode

2 × f_CLK

Rising and falling edge

SYSREF is a system timing reference used for JESD204B subclass-1 implementations of deterministic latency.

SYSREF is used to achieve deterministic latency and for multi-device synchronization. SYSREF must be

captured by the correct device clock edge in order to achieve repeatable latency and synchronization. The

ADC08DJ3200 includes SYSREF windowing and automatic SYSREF calibration to ease the requirements on the

external clocking circuits and to simplify the synchronization process. SYSREF can be implemented as a single

pulse or as a periodic clock. In periodic implementations, SYSREF must be equal to, or an integer division of, the

local multiframe clock frequency. 公式 2 is used to calculate valid SYSREF frequencies.

R ì f_CLK

f_SYSREF

=

10

ì

F

ì

K

ì

n

where

•

R and F are set by the JMODE setting (see 表 10)

f_CLKis the device clock frequency (CLK±)

K is the programmed multiframe length (see 表 10 for valid K settings)

and n is any positive integer

(2)

7.3.6.1 Noiseless Aperture Delay Adjustment (t_ADAdjust)

The ADC08DJ3200 contains a delay adjustment on the device clock (sampling clock) input path, called t_AD

adjust, that can be used to shift the sampling instance within the device in order to align sampling instances

among multiple devices or for external interleaving of multiple ADC08DJ3200s. Further, t_ADadjust can be used

for automatic SYSREF calibration to simplify synchronization; see the Automatic SYSREF Calibration section.

Aperture delay adjustment is implemented in a way that adds no additional noise to the clock path, however a

slight degradation in aperture jitter (t_AJ) is possible at large values of TAD_COARSE because of internal clock

path attenuation. The degradation in aperture jitter can result in minor SNR degradations at high input

frequencies (see t_AJin the Switching Characteristics table). This feature is programmed using TAD_INV,

TAD_COARSE, and TAD_FINE in the DEVCLK timing adjust ramp control register. Setting TAD_INV inverts the

input clock resulting in a delay equal to half the clock period. 表 5 summarizes the step sizes and ranges of the

TAD_COARSE and TAD_FINE variable analog delays. All three delay options are independent and can be used

in conjunction. All clocks within the device are shifted by the programmed t_ADadjust amount, which results in a

shift of the timing of the JESD204B serialized outputs and affects the capture of SYSREF.

表 5. t_ADAdjust Adjustment Ranges

ADJUSTMENT PARAMETER

ADJUSTMENT STEP

DELAY SETTINGS

MAXIMUM DELAY

TAD_INV

1 / (f_CLK× 2)

1

1 / (f_CLK× 2)

See t_TAD(STEP)in the Switching

Characteristics table

See t_TAD(MAX)in the Switching

Characteristics table

TAD_COARSE

TAD_FINE

256

See t_TAD(STEP)in the Switching

Characteristics table

See t_TAD(MAX)in the Switching

Characteristics table

In order to maintain timing alignment between converters, stable and matched power-supply voltages and device

temperatures must be provided.

Aperture delay adjustment can be changed on-the-fly during normal operation but may result in brief upsets to

the JESD204B data link. Use TAD_RAMP to reduce the probability of the JESD204B link losing synchronization;

see the Aperture Delay Ramp Control (TAD_RAMP) section.

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7.3.6.2 Aperture Delay Ramp Control (TAD_RAMP)

The ADC08DJ3200 contains a function to gradually adjust the t_ADadjust setting towards the newly written

TAD_COARSE value. This functionality allows the t_ADadjust setting to be adjusted with minimal internal clock

circuitry glitches. The TAD_RAMP_RATE parameter allows either a slower (one TAD_COARSE LSB per 256

t_CLKcycles) or faster ramp (four TAD_COARSE LSBs per 256 t_CLKcycles) to be selected. The TAD_RAMP_EN

parameter enables the ramp feature and any subsequent writes to TAD_COARSE initiate a new cramp.

7.3.6.3 SYSREF Capture for Multi-Device Synchronization and Deterministic Latency

The clocking subsystem is largely responsible for achieving multi-device synchronization and deterministic

latency. The ADC08DJ3200 uses the JESD204B subclass-1 method to achieve deterministic latency and

synchronization. Subclass 1 requires that the SYSREF signal be captured by a deterministic device clock (CLK±)

edge at each system power-on and at each device in the system. This requirement imposes setup and hold

constraints on SYSREF relative to CLK±, which can be difficult to meet at giga-sample clock rates over all

system operating conditions. The ADC08DJ3200 includes a number of features to simplify this synchronization

process and to relax system timing constraints:

•

The ADC08DJ3200 uses dual-edge sampling (DES) in single-channel mode to reduce the CLK± input

frequency by half and double the timing window for SYSREF (see 表 4)

•

A SYSREF position detector (relative to CLK±) and selectable SYSREF sampling position aid the user in

meeting setup and hold times over all conditions; see the SYSREF Position Detector and Sampling Position

Selection (SYSREF Windowing) section

•

Easy-to-use automatic SYSREF calibration uses the aperture timing adjust block (t_ADadjust) to shift the ADC

sampling instance based on the phase of SYSREF (rather than adjusting SYSREF based on the phase of the

ADC sampling instance); see the Automatic SYSREF Calibration section

7.3.6.3.1 SYSREF Position Detector and Sampling Position Selection (SYSREF Windowing)

The SYSREF windowing block is used to first detect the position of SYSREF relative to the CLK± rising edge and

then to select a desired SYSREF sampling instance, which is a delay version of CLK±, to maximize setup and

hold timing margins. In many cases a single SYSREF sampling position (SYSREF_SEL) is sufficient to meet

timing for all systems (device-to-device variation) and conditions (temperature and voltage variations). However,

this feature can also be used by the system to expand the timing window by tracking the movement of SYSREF

as operating conditions change or to remove system-to-system variation at production test by finding a unique

optimal value at nominal conditions for each system.

This section describes proper usage of the SYSREF windowing block. First, apply the device clock and SYSREF

to the device. The location of SYSREF relative to the device clock cycle is determined and stored in the

SYSREF_POS bits of the SYSREF capture position register. ADC08DJ3200 must see at least 3 rising edges of

SYSREF before the SYSREF_POS output is valid. Each bit of SYSREF_POS represents a potential SYSREF

sampling position. If a bit in SYSREF_POS is set to 1, then the corresponding SYSREF sampling position has a

potential setup or hold violation. Upon determining the valid SYSREF sampling positions (the positions of

SYSREF_POS that are set to 0) the desired sampling position can be chosen by setting SYSREF_SEL in the

clock control register 0 to the value corresponding to that SYSREF_POS position. In general, the middle

sampling position between two setup and hold instances is chosen. Ideally, SYSREF_POS and SYSREF_SEL

are performed at the nominal operating conditions of the system (temperature and supply voltage) to provide

maximum margin for operating condition variations. This process can be performed at final test and the optimal

SYSREF_SEL setting can be stored for use at every system power up. Further, SYSREF_POS can be used to

characterize the skew between CLK± and SYSREF± over operating conditions for a system by sweeping the

system temperature and supply voltages. For systems that have large variations in CLK± to SYSREF± skew, this

characterization can be used to track the optimal SYSREF sampling position as system operating conditions

change. In general, a single value can be found that meets timing over all conditions for well-matched systems,

such as those where CLK± and SYSREF± come from a single clocking device.

注

SYSREF_SEL must be set to 0 when using automatic SYSREF calibration; see the

Automatic SYSREF Calibration section.

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The step size between each SYSREF_POS sampling position can be adjusted using SYSREF_ZOOM. When

SYSREF_ZOOM is set to 0, the delay steps are coarser. When SYSREF_ZOOM is set to 1, the delay steps are

finer. See the Switching Characteristics table for delay step sizes when SYSREF_ZOOM is enabled and

disabled. In general, SYSREF_ZOOM is recommended to always be used (SYSREF_ZOOM = 1) unless a

transition region (defined by 1's in SYSREF_POS) is not observed, which can be the case for low clock rates.

Bits 0 and 23 of SYSREF_POS are always be set to 1 because there is insufficient information to determine if

these settings are close to a timing violation, although the actual valid window can extend beyond these sampling

positions. The value programmed into SYSREF_SEL is the decimal number representing the desired bit location

in SYSREF_POS. 表 6 lists some example SYSREF_POS readings and the optimal SYSREF_SEL settings.

Although 24 sampling positions are provided by the SYSREF_POS status register, SYSREF_SEL only allows

selection of the first 16 sampling positions, corresponding to SYSREF_POS bits 0 to 15. The additional

SYSREF_POS status bits are intended only to provide additional knowledge of the SYSREF valid window. In

general, lower values of SYSREF_SEL are selected because of delay variation over supply voltage, however in

the fourth example a value of 15 provides additional margin and can be selected instead.

表 6. Examples of SYSREF_POS Readings and SYSREF_SEL Selections

SYSREF_POS[23:0]

OPTIMAL SYSREF_SEL

0x02E[7:0]

(Largest Delay)

0x02C[7:0]⁽¹⁾

(Smallest Delay)

0x02D[7:0]⁽¹⁾

SETTING

b10000000

b10011000

b10000000

b10001100

b01100000

b00000000

b01100000

b00000011

b01100011

b00011001

b00110001

b00000001

b00011001

8 or 9

12

6 or 7

4 or 15

6

(1) Red coloration indicates the bits that are selected, as given in the last column of this table.

7.3.6.3.2 Automatic SYSREF Calibration

The ADC08DJ3200 has an automatic SYSREF calibration feature to alleviate the often challenging setup and

hold times associated with capturing SYSREF for giga-sample data converters. Automatic SYSREF calibration

uses the t_ADadjust feature to shift the device clock to maximize the SYSREF setup and hold times or to align the

sampling instance based on the SYSREF rising edge.

The ADC08DJ3200 must have a proper device clock applied and be programmed for normal operation before

starting the automatic SYSREF calibration. When ready to initiate automatic SYSREF calibration, a continuous

SYSREF signal must be applied. SYSREF must be a continuous (periodic) signal when using the automatic

SYSREF calibration. Start the calibration process by setting SRC_EN high in the SYSREF calibration enable

register after configuring the automatic SYSREF calibration using the SRC_CFG register. Upon setting SRC_EN

high, the ADC08DJ3200 searches for the optimal t_ADadjust setting until the device clock falling edge is internally

aligned to the SYSREF rising edge. TAD_DONE in the SYSREF calibration status register can be monitored to

ensure that the SYSREF calibration has finished. By aligning the device clock falling edge with the SYSREF

rising edge, automatic SYSREF calibration maximizes the internal SYSREF setup and hold times relative to the

device clock and also sets the sampling instant based on the SYSREF rising edge. After the automatic SYSREF

calibration finishes, the rest of the startup procedure can be performed to finish bringing up the system.

For multi-device synchronization, the SYSREF rising edge timing must be matched at all devices and therefore

trace lengths must be matched from a common SYSREF source to each ADC08DJ3200. Any skew between the

SYSREF rising edge at each device results in additional error in the sampling instance between devices,

however repeatable deterministic latency from system startup to startup through each device must still be

achieved. No other design requirements are needed in order to achieve multi-device synchronization as long as

a proper elastic buffer release point is chosen in the JESD2048 receiver.

图 64 provides a timing diagram of the SYSREF calibration procedure. The optimized setup and hold times are

shown as t_SU(OPT)and t_H(OPT), respectively. Device clock and SYSREF are referred to as internal in this diagram

because the phase of the internal signals are aligned within the device and not to the external (applied) phase of

the device clock or SYSREF.

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Sampled Input Signal

Internal Unadjusted

Device Clock

Internal Calibrated

Device Clock

t_TAD(SRC)

Internal SYSREF

t_CAL(SRC)

t_H(OPT)

t_SU(OPT)

Before calibration, device clock falling edge does

not align with SYSREF rising edge

SRC_EN

(SPI register bit)

Calibration

enabled

After calibration, device clock falling edge

aligns with SYSREF rising edge

TAD_DONE

(SPI register bit)

Calibration

finished

图 64. SYSREF Calibration Timing Diagram

When finished, the t_ADadjust setting found by the automatic SYSREF calibration can be read from SRC_TAD in

the SYSREF calibration status register. After calibration, the system continues to use the calibrated t_ADadjust

setting for operation until the system is powered down. However, if desired, the user can then disable the

SYSREF calibration and fine-tune the t_ADadjust setting according to the systems needs. Alternatively, the use of

the automatic SYSREF calibration can be done at product test (or periodic recalibration) of the optimal t_ADadjust

setting for each system. This value can be stored and written to the TAD register (TAD_INV, TAD_COARSE, and

TAD_FINE) upon system startup.

Do not run the SYSREF calibration when the ADC calibration (foreground or background) is running. If

background calibration is the desired use case, disable the background calibration when the SYSREF calibration

is used, then reenable the background calibration after TAD_DONE goes high. SYSREF_SEL in the clock control

register 0 must be set to 0 when using SYSREF calibration.

SYSREF calibration searches the TAD_COARSE delays using both noninverted (TAD_INV = 0) and inverted

clock polarity (TAD_INV = 1) to minimize the required TAD_COARSE setting in order to minimize loss on the

clock path to reduce aperture jitter (t_AJ).

7.3.7 JESD204B Interface

The ADC08DJ3200 uses the JESD204B high-speed serial interface for data converters to transfer data from the

ADC to the receiving logic device. The ADC08DJ3200 serialized lanes are capable of operating up to 12.8 Gbps,

slightly above the JESD204B maximum lane rate. A maximum of 16 lanes can be used to allow lower lane rates

for interfacing with speed-limited logic devices. 图 65 shows a simplified block diagram of the JESD204B

interface protocol.

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ADC

JESD204B Block

JESD204B

TRANSPORT

LAYER

SCRAMBLER

(Optional)

JESD204B

LINK LAYER

8b/10b

ENCODER

JESD204B

TX

ADC

ANALOG

CHANNEL

Logic Device

JESD204B Block

JESD204B

TRANSPORT

LAYER

APPLICATION

LAYER

DESCRAMBLE

(Optional)

JESD204B

LINK LAYER

8b/10b

DECODER

JESD204B

RX

图 65. Simplified JESD204B Interface Diagram

The various signals used in the JESD204B interface and the associated ADC08DJ3200 pin names are

summarized briefly in 表 7 for reference.

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表 7. Summary of JESD204B Signals

SIGNAL NAME

ADC08DJ3200 PIN NAMES

DESCRIPTION

High-speed serialized data after 8b,

10b encoding

Data

DA[7:0]+, DA[7:0]–, DB[7:0]+, DB[7:0]–)

Link initialization signal, toggles low to

start code group synchronization

(CGS) process

SYNC

SYNCSE, TMSTP+, TMSTP–

ADC sampling clock, also used for

clocking digital logic and output

serializers

Device clock

SYSREF

CLK+, CLK–

System timing reference used to

deterministically reset the internal local

multiframe counters in each

JESD204B device

SYSREF+, SYSREF–

7.3.7.1 Transport Layer

The transport layer takes samples from the ADC output and maps the samples into octets, frames, multiframes,

and lanes. Sample mapping is defined by the JESD204B mode that is used, defined by parameters such as L,

M, F, S, N, N', CF, and so forth. There are a number of predefined transport layer modes in the ADC08DJ3200

that are defined in 表 10. The high level configuration parameters for the transport layer in the ADC08DJ3200 are

described in 表 8. For simplicity, the transport layer mode is chosen by simply setting the JMODE parameter and

the desired K value. For reference, the various configuration parameters for JESD204B are defined in 表 9.

7.3.7.2 Scrambler

An optional data scrambler can be used to scramble the octets before transmission across the channel.

Scrambling is recommended in order to remove the possibility of spectral peaks in the transmitted data. The

JESD204B receiver automatically synchronizes its descrambler to the incoming scrambled data stream. The

initial lane alignment sequence (ILA) is never scrambled. Scrambling can be enabled by setting SCR (in the

JESD204B control register).

7.3.7.3 Link Layer

The link layer serves multiple purposes in JESD204B, including establishing the code boundaries (see the Code

Group Synchronization (CGS) section), initializing the link (see the Initial Lane Alignment Sequence (ILAS)

section), encoding the data (see the 8b, 10b Encoding section), and monitoring the health of the link (see the

Frame and Multiframe Monitoring section).

7.3.7.3.1 Code Group Synchronization (CGS)

The first step in initializing the JESD204B link, after SYSREF is processed, is to achieve code group

synchronization. The receiver first asserts the SYNC signal when ready to initialize the link. The transmitter

responds to the request by sending a stream of K28.5 characters. The receiver then aligns its character clock to

the K28.5 character sequence. Code group synchronization is achieved after receiving four K28.5 characters

successfully. The receiver deasserts SYNC on the next local multiframe clock (LMFC) edge after CGS is

achieved and waits for the transmitter to start the initial lane alignment sequence.

7.3.7.3.2 Initial Lane Alignment Sequence (ILAS)

After the transmitter detects the SYNC signal deassert, the transmitter waits until its next LMFC edge to start

sending the initial lane alignment sequence. The ILAS consists of four multiframes each containing a

predetermined sequence. The receiver searches for the start of the ILAS to determine the frame and multiframe

boundaries. As the ILAS reaches the receiver for each lane, the lane starts to buffer its data until all receivers

have received the ILAS and subsequently release the ILAS from all lanes at the same time in order to align the

lanes. The second multiframe of the ILAS contains configuration parameters for the JESD204B that can be used

by the receiver to verify that the transmitter and receiver configurations match.

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7.3.7.3.3 8b, 10b Encoding

The data link layer converts the 8-bit octets from the transport layer into 10-bit characters for transmission across

the link using 8b, 10b encoding. 8b, 10b encoding provides DC balance for AC-coupling of the SerDes links and

a sufficient number of edge transitions for the receiver to reliably recover the data clock. 8b, 10b also provides

some amount of error detection where a single bit error in a character likely results in either not being able to find

the 10-bit character in the 8b, 10b decoder lookup table or incorrect character disparity.

7.3.7.3.4 Frame and Multiframe Monitoring

The ADC08DJ3200 supports frame and multiframe monitoring for verifying the health of the JESD204B link. If

the last octet of a frame matches the last octet of the previous frame, then the last octet in the second frame is

replaced with an /F/ (/K28.7/) character. If the second frame is the last frame of a multiframe, then an /A/

(/K28.3/) character is used instead. When scrambling is enabled, if the last octet of a frame is 0xFC then the

transmitter replaces the octet with an /F/ (/K28.7/) character. With scrambling, if the last octet of a multiframe is

0x7C then the transmitter replaces the octet with an /A/ (/K28.3/) character. When the receiver detects an /F/ or

/A/ character, the receiver checks if the character occurs at the end of a frame or multiframe, and replaces that

octet with the appropriate data character. The receiver can report an error if the alignment characters occur in

the incorrect place and trigger a link realignment.

7.3.7.4 Physical Layer

The JESD204B physical layer consists of a current mode logic (CML) output driver and receiver. The receiver

consists of a clock detection and recovery (CDR) unit to extract the data clock from the serialized data stream

and can contain an equalizer to correct for the low-pass response of the physical transmission channel. Likewise,

the transmitter can contain pre-equalization to account for frequency dependent losses across the channel. The

total reach of the SerDes links depends on the data rate, board material, connectors, equalization, noise and

jitter, and required bit-error performance. The SerDes lanes do not have to be matched in length because the

receiver aligns the lanes during the initial lane alignment sequence.

7.3.7.4.1 SerDes Pre-Emphasis

The ADC08DJ3200 high-speed output drivers can pre-equalize the transmitted data stream by using pre-

emphasis in order to compensate for the low-pass response of the transmission channel. Configurable pre-

emphasis settings allow the output drive waveform to be optimized for different PCB materials and signal

transmission distances. The pre-emphasis setting is adjusted through the serializer pre-emphasis setting

SER_PE (in the serializer pre-emphasis control register). Higher values increase the pre-emphasis to

compensate for more lossy PCB materials. This adjustment is best used in conjunction with an eye-diagram

analysis capability in the receiver. Adjust the pre-emphasis setting to optimize the eye-opening for the specific

hardware configuration and line rates needed.

7.3.7.5 JESD204B Enable

The JESD204B interface must be disabled through JESD_EN (in the JESD204B enable register) while any of the

other JESD204B parameters are being changed. When JESD_EN is set to 0 the block is held in reset and the

serializers are powered down. The clocks for this section are also gated off to further save power. When the

parameters are set as desired, the JESD204B block can be enabled (JESD_EN is set to 1).

7.3.7.6 Multi-Device Synchronization and Deterministic Latency

JESD204B subclass 1 outlines a method to achieve deterministic latency across the serial link. If two devices

achieve the same deterministic latency then they can be considered synchronized. This latency must be

achieved from system startup to startup to be deterministic. There are two key requirements to achieve

deterministic latency. The first is proper capture of SYSREF for which the ADC08DJ3200 provides a number of

features to simplify this requirement at giga-sample clock rates (see the SYSREF Capture for Multi-Device

Synchronization and Deterministic Latency section for more information).

The second requirement is to choose a proper elastic buffer release point in the receiver. Because the

ADC08DJ3200 is an ADC, the ADC08DJ3200 is the transmitter (TX) in the JESD204B link and the logic device

is the receiver (RX). The elastic buffer is the key block for achieving deterministic latency, and does so by

absorbing variations in the propagation delays of the serialized data as the data travels from the transmitter to

the receiver. A proper release point is one that provides sufficient margin against delay variations. An incorrect

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release point results in a latency variation of one LMFC period. Choosing a proper release point requires

knowing the average arrival time of data at the elastic buffer, referenced to an LMFC edge, and the total

expected delay variation for all devices. With this information the region of invalid release points within the LMFC

period can be defined, which stretches from the minimum to maximum delay for all lanes. Essentially, the

designer must ensure that the data for all lanes arrives at all devices before the release point occurs.

图 66 provides a timing diagram that demonstrates this requirement. In this figure, the data for two ADCs is

shown. The second ADC has a longer routing distance (t_PCB) and results in a longer link delay. First, the invalid

region of the LMFC period is marked off as determined by the data arrival times for all devices. Then, the release

point is set by using the release buffer delay (RBD) parameter to shift the release point an appropriate number of

frame clocks from the LMFC edge so that the release point occurs within the valid region of the LMFC cycle. In

the case of 图 66, the LMFC edge (RBD = 0) is a good choice for the release point because there is sufficient

margin on each side of the valid region.

Nominal Link Delay

Link Delay

(Arrival at Elastic Buffer)

Variation

ADC 1 Data

Propagation

t_TX

t_PCB

t_RX-DESER

ADC 2 Data

Propagation

t_TX

t_PCB

t_RX-DESER

Choose LMFC

edge as release

point (RBD = 0)

Release point

margin

TX LMFC

RX LMFC

Time

Invalid Region

of LMFC

Valid Region

of LMFC

图 66. LMFC Valid Region Definition for Elastic Buffer Release Point Selection

The TX and RX LMFCs do not necessarily need to be phase aligned, but knowledge of their phase is important

for proper elastic buffer release point selection. Also, the elastic buffer release point occurs within every LMFC

cycle, but the buffers only release when all lanes have arrived. Therefore, the total link delay can exceed a single

LMFC period; see JESD204B multi-device synchronization: Breaking down the requirements for more

information.

7.3.7.7 Operation in Subclass 0 Systems

The ADC08DJ3200 can operate with subclass 0 compatibility provided that multi-ADC synchronization and

deterministic latency are not required. With these limitations, the device can operate without the application of

SYSREF. The internal local multiframe clock is automatically self-generated with unknown timing. SYNC is used

as normal to initiate the CGS and ILA.

7.3.8 Alarm Monitoring

A number of built-in alarms are available to monitor internal events. Several types of alarms and upsets are

detected by this feature:

1. Serializer PLL is not locked

2. JESD204B link is not transmitting data (not in the data transmission state)

3. SYSREF causes internal clocks to be realigned

4. An upset that impacts the internal clocks

When an alarm occurs, a bit for each specific alarm is set in ALM_STATUS. Each alarm bit remains set until the

host system writes a 1 to clear the alarm. If the alarm type is not masked (see the alarm mask register), then the

alarm is also indicated by the ALARM register. The CALSTAT output pin can be configured as an alarm output

that goes high when an alarm occurs; see the CAL_STATUS_SEL bit in the calibration pin configuration register.

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7.3.8.1 Clock Upset Detection

The CLK_ALM register bit indicates if the internal clocks have been upset. The clocks in channel A are

continuously compared to channel B. If the clocks differ for even one DEVCLK / 2 cycle, the CLK_ALM register

bit is set and remains set until cleared by the host system by writing a 1. For the CLK_ALM register bit to function

properly, follow these steps:

1. Program JESD_EN = 0

2. Ensure the part is configured to use both channels (PD_ACH = 0, PD_BCH = 0)

3. Program JESD_EN = 1

4. Write CLK_ALM = 1 to clear CLK_ALM

5. Monitor the CLK_ALM status bit or the CALSTAT output pin if CAL_STATUS_SEL is properly configured

6. When exiting global power-down (via MODE or the PD pin), the CLK_ALM status bit may be set and must be

cleared by writing a 1 to CLK_ALM

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7.4 Device Functional Modes

The ADC08DJ3200 can be configured to operate in a number of functional modes. These modes are described

in this section.

7.4.1 Dual-Channel Mode

The ADC08DJ3200 can be used as a dual-channel ADC where the sampling rate is equal to the clock frequency

(f_S= f_CLK) provided at the CLK+ and CLK– pins. The two inputs, INA± and INB±, serve as the respective inputs

for each channel in this mode. This mode is chosen simply by setting JMODE to the appropriate setting for the

desired configuration as described in 表 10. The analog inputs can be swapped by setting DUAL_INPUT (see the

input mux control register)

7.4.2 Single-Channel Mode (DES Mode)

The ADC08DJ3200 can also be used as a single-channel ADC where the sampling rate is equal to two times the

clock frequency (f_S= 2 × f_CLK) provided at the CLK+ and CLK– pins. This mode effectively interleaves the two

ADC channels together to form a single-channel ADC at twice the sampling rate. This mode is chosen simply by

setting JMODE to the appropriate setting for the desired configuration as described in 表 10. Either analog input,

INA± or INB±, can serve as the input to the ADC, however INA± is recommended for best performance. The

analog input can be selected using SINGLE_INPUT (see the input mux control register). The digital down-

converters cannot be used in single-channel mode.

注

INA± is strongly recommended to be used as the input to the ADC for optimized

performance in single-channel mode.

7.4.3 JESD204B Modes

The ADC08DJ3200 can be programmed as a single-channel or dual-channel ADC and a number JESD204B

output formats. 表 8 summarizes the basic operating mode configuration parameters and whether they are user

configured or derived.

注

Powering down high-speed data outputs (DA0± ... DA7±, DB0± ... DB7±) for extended

times can reduce performance of the output serializers, especially at high data rates. For

information regarding reliable serializer operation, see the Power-Down Modes section.

表 8. ADC08DJ3200 Operating Mode Configuration Parameters

USER CONFIGURED

PARAMETER

DESCRIPTION

VALUE

OR DERIVED

JESD204B operating mode, automatically

derives the rest of the JESD204B

parameters, single-channel or dual-channel

mode

Set by JMODE (see the JESD204B mode

register)

JMODE

User configured

D

Decimation factor

Derived

See 表 10

1 = single-channel mode, 0 = dual-channel

mode

DES

Number of bits transmitted per lane per

DEVCLK cycle. The JESD204B line rate is

the DEVCLK frequency times R. This

parameter sets the SerDes PLL

multiplication factor or controls bypassing of

the SerDes PLL.

R

Derived

See 表 10

Links

K

Number of JESD204B links used

Derived

Set by KM1 (see the JESD204B K

parameter register), see the allowed values

in 表 10

Number of frames per multiframe

User configured

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There are a number of parameters required to define the JESD204B format, all of which are sent across the link

during the initial lane alignment sequence. In the ADC08DJ3200, most parameters are automatically derived

based on the selected JMODE; however, a few are configured by the user. 表 9 describes these parameters.

表 9. JESD204B Initial Lane Alignment Sequence Parameters

USER CONFIGURED

PARAMETER

ADJCNT

DESCRIPTION

VALUE

OR DERIVED

LMFC adjustment amount (not applicable)

LMFC adjustment direction (not applicable)

Bank ID

Derived

Always 0

ADJDIR

BID

Derived

CF

Number of control words per frame

Always set to 0 in ILAS, see 表 10 for actual

usage

CS

DID

F

Control bits per sample

Derived

Set by DID (see the JESD204B DID

parameter register), see 表 11

Device identifier, used to identify the link

User configured

Derived

Number of octets (bytes) per frame (per

lane)

See 表 10

High-density format (samples split between

lanes)

HD

Derived

Always 0

Always 1

JESDV

K

JESD204 standard revision

Derived

Set by the KM1 register, see the JESD204B

K parameter register

Number of frames per multiframe

User configured

L

Number of serial output lanes per link

Lane identifier for each lane

Derived

See 表 10

See 表 11

LID

Number of converters used to determine

lane bit packing; may not match number of

ADC channels in the device

M

Derived

See 表 10

Sample resolution (before adding control

and tail bits)

N

N'

S

Derived

See 表 10

Bits per sample after adding control and tail

bits

Number of samples per converter (M) per

frame

SCR

Scrambler enabled

Device subclass version

Reserved field 1

User configured

Derived

Set by the JESD204B control register

SUBCLASSV

RES1

Always 1

Always 0

Derived

RES2

Reserved field 2

Derived

Checksum for ILAS checking (sum of all

above parameters modulo 256)

CHKSUM

Derived

Computed based on parameters in this table

Configuring the ADC08DJ3200 is made easy by using a single configuration parameter called JMODE (see the

JESD204B mode register). Using 表 10, the correct JMODE value can be found for the desired operating mode.

The modes listed in 表 10 are the only available operating modes. This table also gives a range and allowable

step size for the K parameter (set by KM1, see the JESD204B K parameter register), which sets the multiframe

length in number of frames.

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The ADC08DJ3200 has a total of 16 high-speed output drivers that are grouped into two 8-lane JESD204B links.

Most operating modes use two links with up to eight lanes per link. The lanes and their derived configuration

parameters are described in 表 11. For a specified JMODE, the lowest indexed lanes for each link are used and

the higher indexed lanes for each link are automatically powered down. Always route the lowest indexed lanes to

the logic device.

表 11. ADC08DJ3200 Lane Assignment and Parameters

DEVICE PIN

DESIGNATION

LINK

DID (User Configured)

LID (Derived)

DA0±

0

1

2

3

4

5

6

7

0

1

2

3

4

5

6

7

DA1±

DA2±

Set by DID (see the JESD204B DID parameter

register), the effective DID is equal to the DID register

setting (DID)

DA3±

A

DA4±

DA5±

DA6±

DA7±

DB0±

DB1±

DB2±

Set by DID (see the JESD204B DID parameter

register), the effective DID is equal to the DID register

setting plus 1 (DID+1)

DB3±

B

DB4±

DB5±

DB6±

DB7±

7.4.3.1 JESD204B Output Data Formats

Output data are formatted in a specific optimized fashion for each JMODE setting. The following tables show the

specific mapping formats for a single frame. In all mappings the tail bits (T) are 0 (zero). In 表 12 to 表 17, the

single-channel format samples are defined as Sn, where n is the sample number within the frame. In the dual-

channel output formats, the samples are defined as An and Bn, where An are samples from channel A and Bn

are samples from channel B. All samples are formatted as MSB first, LSB last.

表 12. JMODE 4 (8-Bit, Decimate-by-1, Single-Channel, 4 Lanes)

OCTET

NIBBLE

DA0

0

1

S0

S2

S1

S3

DA1

DB0

DB1

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表 13. JMODE 5 (8-Bit, Decimate-by-1, Single-Channel, 8 Lanes)

OCTET

NIBBLE

DA0

0

1

S0

S2

S4

S6

S1

S3

S5

S7

DA1

DA2

DA3

DB0

DB1

DB2

DB3

表 14. JMODE 6 (8-Bit, Decimate-by-1, Dual-Channel, 4 Lanes)

OCTET

NIBBLE

DA0

0

1

A0

A1

B0

B1

DA1

DB0

DB1

表 15. JMODE 7 (8-Bit, Decimate-by-1, Dual-Channel, 8 Lanes)

OCTET

NIBBLE

DA0

0

1

A0

A1

A2

A3

B0

B1

B2

B3

DA1

DA2

DA3

DB0

DB1

DB2

DB3

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表 16. JMODE 17 (8-bit, Decimate-by-1, Single-Channel, 16 lanes)

OCTET

NIBBLE

DA0

DA1

DA2

DA3

DA4

DA5

DA6

DA7

DB0

DB1

DB2

DB3

DB4

DB5

DB6

DB7

0

1

S0

S2

S4

S6

S8

S10

S12

S14

S1

S3

S5

S7

S9

S11

S13

S15

表 17. JMODE 18 (8-Bit, Decimate-by-1, Dual-Channel, 16 Lanes)

OCTET

NIBBLE

DA0

DA1

DA2

DA3

DA4

DA5

DA6

DA7

DB0

DB1

DB2

DB3

DB4

DB5

DB6

DB7

0

1

A0

A1

A2

A3

A4

A5

A6

A7

B0

B1

B2

B3

B4

B5

B6

B7

7.4.4 Power-Down Modes

The PD input pin allows the ADC08DJ3200 devices to be entirely powered down. Power-down can also be

controlled by MODE (see the device configuration register). The serial data output drivers are disabled when PD

is high. When the device returns to normal operation, the JESD204 link must be re-established, and the ADC

pipeline contain meaningless information so the system must wait a sufficient time for the data to be flushed. If

power-down for power savings is desired, the system must power down the supply voltages regulators for VA19,

VA11, and VD11 rather than make use of the PD input or MODE settings.

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CAUTION

Powering down the high-speed data outputs (DA0± ... DA7±, DB0± ... DB7±) for

extended times may damage the output serializers, especially at high data rates.

Powering down the serializers occurs when the PD pin is held high, the MODE register

is programmed to a value other than 0x00 or 0x01, the PD_ACH or PD_BCH registers

settings are programmed to 1, or when the JMODE register setting is programmed to a

mode that uses less than the 16 total lanes that the device allows. For instance,

JMODE 0 uses eight total lanes and therefore the four highest-indexed lanes for each

JESD204B link (DA4± ... DA7±, DB4± ... DB7±) are powered down in this mode. When

the PD pin is held high or the MODE register is programmed to a value other than

0x00 or 0x01, all output serializers are powered down. When the PD_ACH or PD_BCH

register settings are programmed to 1, the associated ADC channel and lanes are

powered down. To prevent unreliable operation, the PD pin and MODE register must

only be used for brief periods of time to measure temperature diode offsets and not

used for long-term power savings. Furthermore, using a JMODE that uses fewer than

16 lanes results in unreliable operation of the unused lanes. If the system never uses

the unused lanes during the lifetime of the device, then the unused lanes do not cause

issues and can be powered down. If the system may make use of the unused lanes at

a later time, the reliable operation of the serializer outputs can be maintained by

enabling JEXTRA_A and JEXTRA_B, which results in the VD11 power consumption to

increase and the output serializers to toggle.

7.4.5 Test Modes

A number of device test modes are available. These modes insert known patterns of information into the device

data path for assistance with system debug, development, or characterization.

7.4.5.1 Serializer Test-Mode Details

Test modes are enabled by setting JTEST (see the JESD204B test pattern control register) to the desired test

mode. Each test mode is described in detail in the following sections. Regardless of the test mode, the serializer

outputs are powered up based on JMODE. Only enable the test modes when the JESD204B link is disabled. 图

67 provides a diagram showing the various test mode insertion points.

ADC

JESD204B Block

JESD204B

TRANSPORT

LAYER

JESD204B

LINK

LAYER

Active Lanes and

Serial Rates

Set by JMODE

SCRAMBLER

(Optional)

8b/10b

ENCODER

JESD204B

TX

ADC

Long/Short Transport

Octet Ramp

Test Mode Enable

Repeated ILA

Modified RPAT

Test Mode Enable

PRBS

D21.5

K28.5

Serial Outputs High/Low

Test Mode Enable

图 67. Test Mode Insertion Points

7.4.5.2 PRBS Test Modes

The PRBS test modes bypass the 8b, 10b encoder. These test modes produce pseudo-random bit streams that

comply with the ITU-T O.150 specification. These bit streams are used with lab test equipment that can self-

synchronize to the bit pattern and, therefore, the initial phase of the pattern is not defined.

The sequences are defined by a recursive equation. For example, 公式 3 defines the PRBS7 sequence.

y[n] = y[n – 6]⊕y[n – 7]

where

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•

bit n is the XOR of bit [n – 6] and bit [n – 7], which are previously transmitted bits

(3)

表 18 lists equations and sequence lengths for the available PRBS test modes. The initial phase of the pattern is

unique for each lane.

表 18. PBRS Mode Equations

PRBS TEST MODE

PRBS7

SEQUENCE

y[n] = y[n – 6]⊕y[n – 7]

y[n] = y[n – 14]⊕y[n – 15]

y[n] = y[n – 18]⊕y[n – 23]

SEQUENCE LENGTH (bits)

127

PRBS15

PRBS23

32767

8388607

7.4.5.3 Ramp Test Mode

In the ramp test mode, the JESD204B link layer operates normally, but the transport layer is disabled and the

input from the formatter is ignored. After the ILA sequence, each lane transmits an identical octet stream that

increments from 0x00 to 0xFF and repeats.

7.4.5.4 Short and Long Transport Test Mode

JESD204B defines both short and long transport test modes to verify that the transport layers in the transmitter

and receiver are operating correctly. The ADC08DJ3200 only supports the short transport test pattern.

7.4.5.4.1 Short Transport Test Pattern

Short transport test patterns send a predefined octet format that repeats every frame. In the ADC08DJ3200, all

JMODE configurations that have an N' value of 8 use the short transport test pattern. 表 19 define the short

transport test patterns for N' values of 8. All applicable lanes are shown, however only the enabled lanes (lowest

indexed) for the configured JMODE are used.

表 19. Short Transport Test Pattern for N' = 8 Modes (Length = 2 Frames)

FRAME

DA0

DA1

DA2

DA3

DB0

DB1

DB2

DB3

0

1

0x00

0x01

0x02

0x03

0x00

0x01

0x02

0x03

0xFF

0xFE

0xFD

0xFC

0xFF

0xFE

0xFD

0xFC

7.4.5.5 D21.5 Test Mode

In this test mode, the controller transmits a continuous stream of D21.5 characters (alternating 0s and 1s).

7.4.5.6 K28.5 Test Mode

In this test mode, the controller transmits a continuous stream of K28.5 characters.

7.4.5.7 Repeated ILA Test Mode

In this test mode, the JESD204B link layer operates normally, except that the ILA sequence (ILAS) repeats

indefinitely instead of starting the data phase. Whenever the receiver issues a synchronization request, the

transmitter initiates code group synchronization. Upon completion of code group synchronization, the transmitter

repeatedly transmits the ILA sequence.

7.4.5.8 Modified RPAT Test Mode

A 12-octet repeating pattern is defined in INCITS TR-35-2004. The purpose of this pattern is to generate white

spectral content for JESD204B compliance and jitter testing. 表 20 lists the pattern before and after 8b, 10b

encoding.

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表 20. Modified RPAT Pattern Values

20b OUTPUT OF 8b, 10b ENCODER

OCTET NUMBER

Dx.y NOTATION

8-BIT INPUT TO 8b, 10b ENCODER

(Two Characters)

0

1

D30.5

D23.6

D3.1

0xBE

0xD7

0x23

0x47

0x6B

0x8F

0xB3

0x14

0x5E

0xFB

0x35

0x59

0x86BA6

2

0xC6475

0xD0E8D

0xCA8B4

0x7949E

0xAA665

3

D7.2

4

D11.3

D15.4

D19.5

D20.0

D30.2

D27.7

D21.1

D25.2

5

6

7

8

9

10

11

7.4.6 Calibration Modes and Trimming

The ADC08DJ3200 has two calibration modes available: foreground calibration and background calibration.

When foreground calibration is initiated the ADCs are automatically taken offline and the output data becomes

mid-code (0x000 in 2's complement) while a calibration is occurring. Background calibration allows the ADC to

continue normal operation while the ADC cores are calibrated in the background by swapping in a different ADC

core to take its place. Additional offset calibration features are available in both foreground and background

calibration modes. Further, a number of ADC parameters can be trimmed to optimize performance in a user

system.

The ADC08DJ3200 consists of a total of six sub-ADCs, each referred to as a bank, with two banks forming an

ADC core. The banks sample out-of-phase so that each ADC core is two-way interleaved. The six banks form

three ADC cores, referred to as ADC A, ADC B, and ADC C. In foreground calibration mode, ADC A samples

INA± and ADC B samples INB± in dual-channel mode and both ADC A and ADC B sample INA± (or INB±) in

single-channel mode. In the background calibration modes, the third ADC core, ADC C, is swapped in

periodically for ADC A and ADC B so that they can be calibrated without disrupting operation. 图 68 provides a

diagram of the calibration system including labeling of the banks that make up each ADC core. When calibration

is performed the linearity, gain, and offset voltage for each bank are calibrated to an internally generated

calibration signal. The analog inputs can be driven during calibration, both foreground and background, except

that when offset calibration (OS_CAL or BGOS_CAL) is used there must be no signals (or aliased signals) near

DC for proper estimation of the offset (see the Offset Calibration section).

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ADC A

ADC C

ADC B

Bank 0

Bank 1

MUX

Calibration

Signal

INA+

INAœ

ADC A

MUX

Output

Calibration

Engine

Bank 2

Bank 3

Calibration

Engine

MUX

Calibration

Signal

Calibration

Engine

ADC B

MUX

Output

INB+

Bank 4

Bank 5

INBœ

MUX

Calibration

Engine

Calibration

Signal

Calibration

Engine

图 68. ADC08DJ3200 Calibration System Block Diagram

In addition to calibration, a number of ADC parameters are user controllable to provide trimming for optimal

performance. These parameters include input offset voltage, ADC gain, interleaving timing, and input termination

resistance. The default trim values are programmed at the factory to unique values for each device that are

determined to be optimal at the test system operating conditions. The user can read the factory-programmed

values from the trim registers and adjust as desired. The register fields that control the trimming are labeled

according to the input that is being sampled (INA± or INB±), the bank that is being trimmed, or the ADC core that

is being trimmed. The user is not expected to change the trim values as operating conditions change, however

optimal performance can be obtained by doing so. Any custom trimming must be done on a per device basis

because of process variations, meaning that there is no global optimal setting for all parts. See the Trimming

section for information about the available trim parameters and associated registers.

7.4.6.1 Foreground Calibration Mode

Foreground calibration requires the ADC to stop converting the analog input signals during the procedure.

Foreground calibration always runs on power-up and the user must wait a sufficient time before programming the

device to ensure that the calibration is finished. Foreground calibration can be initiated by triggering the

calibration engine. The trigger source can be either the CAL_TRIG pin or CAL_SOFT_TRIG (see the calibration

software trigger register) and is chosen by setting CAL_TRIG_EN (see the calibration pin configuration register).

7.4.6.2 Background Calibration Mode

Background calibration mode allows the ADC to continuously operate, with no interruption of data. This

continuous operation is accomplished by activating an extra ADC core that is calibrated and then takes over

operation for one of the other previously active ADC cores. When that ADC core is taken off-line, that ADC is

calibrated and can in turn take over to allow the next ADC to be calibrated. This process operates continuously,

ensuring the ADC cores always provide the optimum performance regardless of system operating condition

changes. Because of the additional active ADC core, background calibration mode has increased power

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consumption in comparison to foreground calibration mode. The low-power background calibration (LPBG) mode

discussed in the Low-Power Background Calibration (LPBG) Mode section provides reduced average power

consumption in comparison with the standard background calibration mode. Background calibration can be

enabled by setting CAL_BG (see the calibration configuration 0 register). CAL_TRIG_EN must be set to 0 and

CAL_SOFT_TRIG must be set to 1.

Great care has been taken to minimize effects on converted data as the core switching process occurs, however,

small brief glitches may still occur on the converter data as the cores are swapped. See the Typical

Characteristics section for examples of possible glitches in sine-wave and DC signals.

7.4.6.3 Low-Power Background Calibration (LPBG) Mode

Low-power background calibration (LPBG) mode reduces the power-overhead of enabling the additional ADC

core while still allowing background calibration of the ADC cores to maintain optimal performance as operating

conditions change. LPBG calibration modifies the background calibration procedure by powering down the spare

ADC core until it is ready to be calibrated. Set LP_EN = 1 to enable the low-power background calibration

feature. Calibration and swapping of ADC cores can be controlled either automatically by the device or manually

by the system by setting LP_TRIG appropriately. Manual control (LP_TRIG=1) allows the system to trigger

calibration in order to limit the number of calibration cycles that occur to avoid unnecessary core swaps or to

keep power consumption at a minimum. For instance, the user may decide to run calibration only when the

system temperature changes by some fixed temperature. If manual control is not necessary the automatic

calibration control can be enabled (LP_TRIG=0) to calibrate at fixed time intervals.

In automatic calibration mode (LP_TRIG=0) the spare ADC core sleep time can be controlled by the

LP_SLEEP_DLY register setting. LP_SLEEP_DLY is used to adjust the amount of time an ADC sleeps before

waking up for calibration (when LP_EN=1 and LP_TRIG = 0). LP_WAKE_DLY sets how long the core is allowed

to stabilize after being awoken before calibration begins. In automatic calibration control mode the freshly

calibrated core is swapped in for an active core as soon as calibration finishes and the new spare core is

powered down for the sleep duration before waking up and calibrating.

Manual calibration control is enabled by setting LP_TRIG high in order to use the calibration trigger

(CAL_SOFT_TRIG or CALTRIG) to trigger calibrations and core swaps. When manual control is enabled

(LP_TRIG=1) the spare ADC is held in sleep mode while the calibration trigger is high. Setting the calibration

trigger low then wakes up the spare ADC core and starts the calibration routine after waiting for the specified

wake delay (LP_WAKE_DLY). The spare ADC core is swapped in for an active core once calibration is complete

and the calibration trigger is set high again. If the calibration trigger is held low, then the spare ADC core

calibrates and remains powered until the calibration trigger goes high; therefore consuming power. can report

when the spare ADC finishes calibration on the CALSTAT output pin by setting the CALSTAT pin to output the

CAL_STOPPED signal (CAL_STATUS_SEL = 1). For lowest power consumption, set the calibration trigger high

before calibration finishes to allow the spare ADC to swap in for an active ADC core as soon as calibration

finishes. Otherwise, the ADC core swap can be timed manually by setting the calibration trigger high at the

desired time to minimize system impact of potential glitches caused by the swapping procedure.

In LPBG mode there is an increase in power consumption during the ADC core calibration. The longer the spare

ADC is held asleep the lower the average power consumption, however large shifts in operating conditions

during the sleep cycle may cause degraded ADC performance due to non-optimized calibration data for the

active ADC core. The power consumption roughly alternates between the power consumption in foreground

calibration when the spare ADC core is sleeping to the power consumption in background calibration when the

spare ADC is being calibrated. Design the power-supply network to handle the transient power requirements for

this mode, including bulk capacitance after any power supply filtering network to help regulate the supply voltage

during the supply transient.

7.4.7 Offset Calibration

Foreground calibration and background calibration modes inherently calibrate the offsets of the ADC cores;

however, the input buffers sit outside of the calibration loop and therefore their offsets are not calibrated by the

standard calibration process. In both dual-channel mode and single-channel mode, uncalibrated input buffer

offsets result in a shift in the mid-code output (DC offset) with no input. Further, in single-channel mode

uncalibrated input buffer offsets can result in a fixed spur at f_S/ 2. A separate calibration is provided to correct

the input buffer offsets.

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There must be no signals at or near DC or aliased signals that fall at or near DC in order to properly calibration

the offsets, requiring the system to ensure this condition during normal operation or have the ability to mute the

input signal during calibration. Foreground offset calibration is enabled via CAL_OS and only performs the

calibration one time as part of the foreground calibration procedure. Background offset calibration is enabled via

CAL_BGOS and continues to correct the offset as part of the background calibration routine to account for

operating condition changes. When CAL_BGOS is set, the system must ensure that there are no DC or near DC

signals or aliased signals that fall at or near DC during normal operation. Offset calibration can be performed as

a foreground operation when using background calibration by setting CAL_OS to 1 before setting CAL_EN, but

does not correct for variations as operating conditions change.

The offset calibration correction uses the input offset voltage trim registers (see 表 21) to correct the offset and

therefore must not be written by the user when offset calibration is used. The user can read the calibrated values

by reading the OADJ_x_VINy registers, where x is the ADC core and y is the input (INA± or INB±), after

calibration is completed. Only read the values when FG_DONE is read as 1 when using foreground offset

calibration (CAL_OS = 1) and do not read the values when using background offset calibration (CAL_BGOS = 1).

Setting CAL_OS to 1 and CAL_BG to 1 performs an offset calibration of all three ADC cores during the

foreground calibration process.

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7.4.8 Trimming

表 21 lists the parameters that can be trimmed and the associated registers. User trimming is limited to

foreground (FG) calibration only.

表 21. Trim Register Descriptions

TRIM PARAMETER

Band-gap reference

TRIM REGISTER

NOTES

BG_TRIM

Measurement on BG output pin.

RTRIM_x,

where x = A for INA± or B for INB±)

The device must be powered on with a clock

applied.

Input termination resistance

Input offset adjustment in dual channel mode

consists of changing OADJ_A_VINA for

channel A and OADJ_B_VINB for channel B.

In single channel mode, OADJ_A_VINx and

OADJ_B_VINx must be adjusted together to

trim the input offset or adjusted separate to

compensate the f_S/2 offset spur.

OADJ_x_VINy,

where x = ADC core (A or B)

and y = A for INA± or B for INB±)

Input offset voltage

Set FS_RANGE_A and FS_RANGE_B to

default values before trimming the input. Use

FS_RANGE_A and FS_RANGE_B to adjust

the full-scale input voltage. To trim the gain

of ADC core A, change GAIN_B0 and

GAIN_B1 together in the same direction. To

trim the gain of ADC core B, change

GAIN_B4 and GAIN_B5 together in the same

direction. To trim the gain of the two banks

within ADC A, change GAIN_B0 and

GAIN_B1 in opposite directions. To trim the

gain of the two banks within ADC B, change

GAIN_B4 and GAIN_B5 in opposite

GAIN_TRIM_x,

where x = A for INA± or B for INB±)

INA± and INB± gain

directions.

Full-scale input voltage adjustment for each

input. The default value is effected by

GAIN_TRIM_x (x = A or B). Trim

GAIN_TRIM_x with FS_RANGE_x set to the

default value. FS_RANGE_x can then be

used to trim the full-scale input voltage.

FS_RANGE_x,

where x = A for INA± or B for INB±)

INA± and INB± full-scale input voltage

Trims the timing between the two banks of

an ADC core (ADC A or B). The 0° clock

phase is used for dual channel mode and for

ADC B in single channel mode. The –90°

clock phase is used only for ADC A in single-

channel mode. A mismatch in the timing

between the two banks of an ADC core can

result in an f_S/2-f_INspur in dual channel

mode or f_S/4±f_INspurs in single channel

mode.

Bx_TIME_y,

where x = bank number (0, 1, 4 or 5)

and y = 0° or –90° clock phase

Intra-ADC core timing (bank timing)

The suffix letter (A or B) indicates the ADC

core that is being trimmed. Changing either

TADJ_A or TADJ_B adjusts the sampling

instance of ADC A relative to ADC B in dual

channel mode.

Inter-ADC core timing (dual-channel mode)

Inter-ADC core timing (single-channel mode)

TADJ_A, TADJ_B

These trim registers are used to adjust the

timing of ADC core A relative to ADC core B

in single channel mode. A mismatch in the

timing results in an f_S/2-f_INspur that is signal

dependent. Changing either TADJ_A_FG90

or TADJ_B_FG0 changes the relative timing

of ADC core A relative to ADC core B in

single channel mode. These registers are

trimmed at production to optimize

TADJ_A_FG90, TADJ_B_FG0

performance for INA±.

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7.4.9 Offset Filtering

The ADC08DJ3200 has an additional feature that can be enabled to reduce offset-related interleaving spurs at f_S

/ 2 and f_S/ 4 (single input mode only). Offset filtering is enabled via CAL_OSFILT. The OSFILT_BW and

OSFILT_SOAK parameters can be adjusted to tradeoff offset spur reduction with potential impact on information

in the mission mode signal being processed. Set these two parameters to the same value under most situations.

The DC_RESTORE setting is used to either retain or filter out all DC-related content in the signal. This feature

implements a notch filter at f_S/ 2 and f_S/ 4 (single input mode only) and also filters out signals that fall at these

frequency locations. Reducing the notch filter bandwidth using OSFILT_BW can reduce the range of signals that

are filtered by this feature.

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7.5 Programming

7.5.1 Using the Serial Interface

The serial interface is accessed using the following four pins: serial clock (SCLK), serial data in (SDI), serial data

out (SDO), and serial interface chip-select (SCS). Register access is enabled through the SCS pin.

7.5.1.1 SCS

This signal must be asserted low to access a register through the serial interface. Setup and hold times with

respect to the SCLK must be observed.

7.5.1.2 SCLK

Serial data input is accepted at the rising edge of this signal. SCLK has no minimum frequency requirement.

7.5.1.3 SDI

Each register access requires a specific 24-bit pattern at this input. This pattern consists of a read-and-write

(R/W) bit, register address, and register value. The data are shifted in MSB first and multi-byte registers are

always in little-endian format (least significant byte stored at the lowest address). Setup and hold times with

respect to the SCLK must be observed (see the Timing Requirements table).

7.5.1.4 SDO

The SDO signal provides the output data requested by a read command. This output is high impedance during

write bus cycles and during the read bit and register address portion of read bus cycles.

As shown in 图 69, each register access consists of 24 bits. The first bit is high for a read and low for a write.

The next 15 bits are the address of the register that is to be written to. During write operations, the last eight bits

are the data written to the addressed register. During read operations, the last eight bits on SDI are ignored and,

during this time, the SDO outputs the data from the addressed register. 图 69 shows the serial protocol details.

Single Register Access

SCS

1

8

16

17

24

SCLK

SDI

Command Field

Data Field

R/W A14 A13 A12 A11 A10 A9

A8

A7

A6

A5

A4

A3

A2

A1 A0

D7

D6

D5

D4

D3

D2

D1 D0

Data Field

High Z

SDO

(read mode)

D7

D6

D5

D4

D3 D2

D1

D0

图 69. Serial Interface Protocol: Single Read/Write

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Programming (接下页)

7.5.1.5 Streaming Mode

The serial interface supports streaming reads and writes. In this mode, the initial 24 bits of the transaction

specifics the access type, register address, and data value as normal. Additional clock cycles of write or read

data are immediately transferred, as long as the SCS input is maintained in the asserted (logic low) state. The

register address auto increments (default) or decrements for each subsequent 8-bit transfer of the streaming

transaction. The ADDR_ASC bit (register 000h, bits 5 and 2) controls whether the address value ascends

(increments) or descends (decrements). Streaming mode can be disabled by setting the ADDR_HOLD bit (see

the user SPI configuration register). 图 70 shows the streaming mode transaction details.

Multiple Register Access

SCS

1

8

16

17

24

25

32

SCLK

SDI

Command Field

Data Field (write mode)

D4 D3 D2 D1

Data Field (write mode)

D5 D4 D3 D2

A1

1

R/W A14 A13 A12

A10 A9

A8

A7

A6

A5

A4

A3

A2

A1

A0

D7

D6

D5

D0

D7

D6

D1

D0

Data Field

D4 D3 D2

Data Field

D3 D2

High Z

SDO

(read mode)

D7

D6

D5

D4

D1

D0

D7

D6

D5

D1

D0

图 70. Serial Interface Protocol: Streaming Read/Write

See the Register Maps section for detailed information regarding the registers.

注

The serial interface must not be accessed during ADC calibration. Accessing the serial

interface during this time impairs the performance of the device until the device is

calibrated correctly. Writing or reading the serial registers also reduces dynamic ADC

performance for the duration of the register access time.

7.6 Register Maps

The Memory Map lists all the ADC08DJ3200 registers.

Memory Map

ADDRESS

RESET

ACRONYM

TYPE

REGISTER NAME

STANDARD SPI-3.0 (0x000 to 0x00F)

0x000

0x001

0x30

Undefined

0x00

CONFIG_A

RESERVED

DEVICE_CONFIG

CHIP_TYPE

CHIP_ID

R/W

R

Configuration A Register

RESERVED

0x002

R/W

R

Device Configuration Register

Chip Type Register

Chip ID Registers

Chip Version Register

RESERVED

0x003

0x03

0x004-0x005

0x006

0x0020

0x0A

R

CHIP_VERSION

RESERVED

VENDOR_ID

RESERVED

R

0x007-0x00B

0x00C-0x00D

0x00E-0x00F

Undefined

0x0451

Undefined

R

Vendor Identification Register

RESERVED

R

USER SPI CONFIGURATION (0x010 to 0x01F)

0x010

0x00

USR0

R/W

R

User SPI Configuration Register

RESERVED

0x011-0x01F

Undefined

RESERVED

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Register Maps (continued)

Memory Map (continued)

ADDRESS

RESET

ACRONYM

TYPE

REGISTER NAME

MISCELLANEOUS ANALOG REGISTERS (0x020 to 0x047)

0x020-0x028

0x029

Undefined

0x00

RESERVED

CLK_CTRL0

CLK_CTRL1

RESERVED

SYSREF_POS

RESERVED

FS_RANGE_A

FS_RANGE_B

RESERVED

BG_BYPASS

RESERVED

TMSTP_CTRL

RESERVED

R

R/W

R

RESERVED

Clock Control Register 0

Clock Control Register 1

RESERVED

0x02A

0x20

0x02B

Undefined

0xA000

Undefined

0x00

0x02C-0x02E

0x02F

R

SYSREF Capture Position Register

RESERVED

R

0x030-0x031

0x032-0x033

0x034-0x037

0x038

R/W

R

INA Full-Scale Range Adjust Register

INB Full-Scale Range Adjust Register

RESERVED

R/W

R

Internal Reference Bypass Register

RESERVED

0x039-0x03A

0x03B

Undefined

0x00

R/W

R

TMSTP± Control Register

RESERVED

0x03C-0x047

Undefined

SERIALIZER REGISTERS (0x048 to 0x05F)

0x048

0x00

SER_PE

R/W

R

Serializer Pre-Emphasis Control Register

RESERVED

0x049-0x05F

Undefined

RESERVED

CALIBRATION REGISTERS (0x060 to 0x0FF)

0x060

0x061

0x01

INPUT_MUX

CAL_EN

R/W

R

Input Mux Control Register

Calibration Enable Register

Calibration Configuration 0 Register

RESERVED

0x01

0x062

0x01

CAL_CFG0

RESERVED

CAL_STATUS

CAL_PIN_CFG

CAL_SOFT_TRIG

RESERVED

CAL_LP

0x063-0x069

0x06A

Undefined

0x00

R

Calibration Status Register

Calibration Pin Configuration Register

Calibration Software Trigger Register

RESERVED

0x06B

R/W

R

0x06C

0x01

0x06D

Undefined

0x88

0x06E

R/W

R

Low-Power Background Calibration Register

RESERVED

0x06F

Undefined

0x00

RESERVED

CAL_DATA_EN

CAL_DATA

RESERVED

GAIN_TRIM_A

GAIN_TRIM_B

BG_TRIM

0x070

R/W

R

Calibration Data Enable Register

Calibration Data Register

RESERVED

0x071

Undefined

0x072-0x079

0x07A

R/W

R

Channel A Gain Trim Register

Channel B Gain Trim Register

Band-Gap Reference Trim Register

RESERVED

0x07B

0x07C

0x07D

RESERVED

RTRIM_A

0x07E

R/W

VINA Input Resistor Trim Register

VINB Input Resistor Trim Register

0x07F

RTRIM_B

Timing Adjustment for A-ADC, Single-Channel Mode,

Foreground Calibration Register

0x080

0x081

0x082

0x083

0x084

Undefined

TADJ_A_FG90

TADJ_B_FG0

TADJ_A_BG90

TADJ_C_BG0

TADJ_C_BG90

R/W

Timing Adjustment for B-ADC, Single-Channel Mode,

Foreground Calibration Register

Timing Adjustment for A-ADC, Single-Channel Mode,

Background Calibration Register

Timing Adjustment for C-ADC, Single-Channel Mode,

Background Calibration Register

Timing Adjustment for C-ADC, Single-Channel Mode,

Background Calibration Register

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Register Maps (continued)

Memory Map (continued)

ADDRESS

0x085

RESET

ACRONYM

TADJ_B_BG0

TADJ_A

TYPE

REGISTER NAME

Timing Adjustment for B-ADC, Single-Channel Mode,

Background Calibration Register

Undefined

R/W

0x086

Timing Adjustment for A-ADC, Dual-Channel Mode Register

Timing Adjustment for C-ADC Acting for A-ADC, Dual-

Channel Mode Register

0x087

TADJ_CA

Timing Adjustment for C-ADC Acting for B-ADC, Dual-

Channel Mode Register

0x088

Undefined

TADJ_CB

R/W

0x089

Undefined

0x00

TADJ_B

R/W

R

Timing Adjustment for B-ADC, Dual-Channel Mode Register

Offset Adjustment for A-ADC and INA Register

Offset Adjustment for A-ADC and INB Register

Offset Adjustment for C-ADC and INA Register

Offset Adjustment for C-ADC and INB Register

Offset Adjustment for B-ADC and INA Register

Offset Adjustment for B-ADC and INB Register

RESERVED

0x08A-0x08B

0x08C-0x08D

0x08E-0x08F

0x090-0x091

0x092-0x093

0x094-0x095

0x096

OADJ_A_INA

OADJ_A_INB

OADJ_C_INA

OADJ_C_INB

OADJ_B_INA

OADJ_B_INB

RESERVED

OSFILT0

0x097

R/W

R

Offset Filtering Control 0

0x098

0x33

OSFILT1

Offset Filtering Control 1

0x099-0x0FF

Undefined

RESERVED

ADC BANK REGISTERS (0x100 to 0x15F)

0x100-0x101

0x102

Undefined

RESERVED

B0_TIME_0

B0_TIME_90

RESERVED

B1_TIME_0

B1_TIME_90

RESERVED

B2_TIME_0

B2_TIME_90

RESERVED

B3_TIME_0

B3_TIME_90

RESERVED

B4_TIME_0

B4_TIME_90

RESERVED

B5_TIME_0

B5_TIME_90

RESERVED

R

RESERVED

R/W

R

Timing Adjustment for Bank 0 (0° Clock) Register

Timing Adjustment for Bank 0 (–90° Clock) Register

RESERVED

0x103

0x104-0x111

0x112

R/W

R

Timing Adjustment for Bank 1 (0° Clock) Register

Timing Adjustment for Bank 1 (–90° Clock) Register

RESERVED

0x113

0x114-0x121

0x122

R/W

R

Timing Adjustment for Bank 2 (0° Clock) Register

Timing Adjustment for Bank 2 (–90° Clock) Register

RESERVED

0x123

0x124-0x131

0x132

R/W

R

Timing Adjustment for Bank 3 (0° Clock) Register

Timing Adjustment for Bank 3 (–90° Clock) Register

RESERVED

0x133

0x134-0x141

0x142

R/W

R

Timing Adjustment for Bank 4 (0° Clock) Register

Timing Adjustment for Bank 4 (–90° Clock) Register

RESERVED

0x143

0x144-0x151

0x152

R/W

R

Timing Adjustment for Bank 5 (0° Clock) Register

Timing Adjustment for Bank 5 (–90° Clock) Register

RESERVED

0x153

0x154-0x15F

LSB CONTROL REGISTERS (0x160 to 0x1FF)

0x160

0x00

ENC_LSB

R/W

R

LSB Control Bit Output Register

RESERVED

0x161-0x1FF

Undefined

RESERVED

JESD204B REGISTERS (0x200 to 0x20F)

0x200

0x201

0x202

0x203

0x204

0x01

0x02

0x1F

0x01

0x02

JESD_EN

JMODE

KM1

R/W

JESD204B Enable Register

JESD204B Mode (JMODE) Register

JESD204B K Parameter Register

JESD204B Manual SYNC Request Register

JESD204B Control Register

JSYNC_N

JCTRL

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Register Maps (continued)

Memory Map (continued)

ADDRESS

0x205

RESET

0x00

ACRONYM

JTEST

TYPE

REGISTER NAME

R/W

R

JESD204B Test Pattern Control Register

JESD204B DID Parameter Register

JESD204B Frame Character Register

JESD204B, System Status Register

JESD204B Channel Power-Down

JESD204B Extra Lane Enable (Link A)

JESD204B Extra Lane Enable (Link B)

RESERVED

0x206

0x00

DID

0x207

0x00

FCHAR

0x208

Undefined

0x00

JESD_STATUS

PD_CH

0x209

0x20A

0x00

JEXTRA_A

JEXTRA_B

RESERVED

0x20B

0x00

0x20C-0x210

Undefined

DIGITAL DOWN CONVERTER REGISTERS (0x210-0x2AF)

0x211

0x212

0xF2

0xAB

OVR_T0

OVR_T1

R/W

R

Overrange Threshold 0 Register

Overrange Threshold 1 Register

Overrange Configuration Register

RESERVED

0x213

0x07

OVR_CFG

RESERVED

SPIN_ID

0x214-0x296

0x297

Undefined

R

Spin Identification Value

RESERVED

0x298-0x2AF

RESERVED

R

SYSREF CALIBRATION REGISTERS (0x2B0 to 0x2BF)

0x2B0

0x2B1

0x00

0x05

SRC_EN

SRC_CFG

SRC_STATUS

TAD

R/W

R

SYSREF Calibration Enable Register

SYSREF Calibration Configuration Register

SYSREF Calibration Status

0x2B2-0x2B4

0x2B5-0x2B7

0x2B8

Undefined

0x00

R/W

R

DEVCLK Aperture Delay Adjustment Register

DEVCLK Timing Adjust Ramp Control Register

RESERVED

0x00

TAD_RAMP

RESERVED

0x2B9-0x2BF

Undefined

ALARM REGISTERS (0x2C0 to 0x2C2)

0x2C0

0x2C1

0x2C2

Undefined

0x1F

ALARM

R

Alarm Interrupt Status Register

Alarm Status Register

ALM_STATUS

ALM_MASK

R/W

0x1F

Alarm Mask Register

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7.6.1 Register Descriptions

Table 22 lists the access codes for the ADC08DJ3200 registers.

Table 22. ADC08DJ3200 Access Type Codes

Access Type

Code

R

Description

Read

R

R-W

W

R/W

W

Read or write

Write

-n

Value after reset or the default

value

7.6.1.1 Standard SPI-3.0 (0x000 to 0x00F)

Table 23. Standard SPI-3.0 Registers

ADDRESS

0x000

RESET

0x30

ACRONYM

REGISTER NAME

Configuration A Register

RESERVED

SECTION

CONFIG_A

RESERVED

Configuration A Register (address = 0x000) [reset = 0x30]

—

0x001

Undefined

0x00

0x002

DEVICE_CONFIG Device Configuration Register

Device Configuration Register (address = 0x002) [reset =

0x00]

0x003

0x03

CHIP_TYPE

CHIP_ID

Chip Type Register

Chip ID Registers

Chip Type Register (address = 0x003) [reset = 0x03]

0x004-0x005

0x0020

Chip ID Register (address = 0x004 to 0x005) [reset =

0x0020]

0x006

0x0A

Undefined

0x0451

CHIP_VERSION Chip Version Register

Chip Version Register (address = 0x006) [reset = 0x01]

—

0x007-0x00B

0x00C-0x00D

RESERVED

VENDOR_ID

RESERVED

Vendor Identification Register

Vendor Identification Register (address = 0x00C to

0x00D) [reset = 0x0451]

0x00E-0x00F

Undefined

RESERVED

—

7.6.1.1.1 Configuration A Register (address = 0x000) [reset = 0x30]

Figure 71. Configuration A Register (CONFIG_A)

7

6

5

4

3

2

1

0

SOFT_RESET

R/W-0

RESERVED

R-0

ADDR_ASC

R/W-1

SDO_ACTIVE

R-1

RESERVED

R-0000

Table 24. CONFIG_A Field Descriptions

Bit

Field

SOFT_RESET

Type

Reset

Description

7

R/W

0

Setting this bit results in a full reset of the device. This bit is self-

clearing. After writing this bit, the device may take up to 750 ns

to reset. During this time, do not perform any SPI transactions.

6

5

RESERVED

ADDR_ASC

R

0

1

RESERVED

R/W

0: Descend – decrement address while streaming reads/writes

1: Ascend – increment address while streaming reads/writes

(default)

4

SDO_ACTIVE

RESERVED

R

1

Always returns 1, indicating that the device always uses 4-wire

SPI mode.

3-0

0000

RESERVED

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7.6.1.1.2 Device Configuration Register (address = 0x002) [reset = 0x00]

Figure 72. Device Configuration Register (DEVICE_CONFIG)

7

6

5

4

3

2

1

0

RESERVED

R-0000 00

MODE

R/W-00

Table 25. DEVICE_CONFIG Field Descriptions

Bit

7-2

1-0

Field

Type

R

Reset

0000 00

00

Description

RESERVED

MODE

RESERVED

R/W

The SPI 3.0 specification lists 1 as the low-power functional

mode, 2 as the low-power fast resume, and 3 as power-down.

This device does not support these modes.

0: Normal operation – full power and full performance (default)

1: Normal operation – full power and full performance

2: Power down - everything is powered down. Only use this

setting for brief periods of time to calibrate the on-chip

temperature diode measurement. See the Recommended

Operating Conditions table for more information.

3: Power down - everything is powered down. Only use this

setting for brief periods of time to calibrate the on-chip

temperature diode measurement. See the Recommended

Operating Conditions table for more information.

7.6.1.1.3 Chip Type Register (address = 0x003) [reset = 0x03]

Figure 73. Chip Type Register (CHIP_TYPE)

7

6

5

4

3

2

1

0

RESERVED

R-0000

CHIP_TYPE

R-0011

Table 26. CHIP_TYPE Field Descriptions

Bit

7-4

3-0

Field

Type

R

Reset

0000

0011

Description

RESERVED

CHIP_TYPE

R

Always returns 0x3, indicating that the device is a high-speed

ADC.

7.6.1.1.4 Chip ID Register (address = 0x004 to 0x005) [reset = 0x0020]

Figure 74. Chip ID Register (CHIP_ID)

15

14

13

12

11

10

9

1

8

0

CHIP_ID[15:8]

R-0x00h

7

6

5

4

3

2

CHIP_ID[7:0]

R-0x20h

Table 27. CHIP_ID Field Descriptions

Bit

15-0

Field

Type

Reset

Description

CHIP_ID

R

0x0020h

Always returns 0x0020, indicating that this device is part of the

ADC08DJxx00 family.

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7.6.1.1.5 Chip Version Register (address = 0x006) [reset = 0x01]

Figure 75. Chip Version Register (CHIP_VERSION)

7

6

5

4

3

2

1

0

CHIP_VERSION

R-0000 1010

Table 28. CHIP_VERSION Field Descriptions

Bit

Field

CHIP_VERSION

Type

Reset

Description

7-0

R

0000 1010 Chip version, returns 0x0A.

7.6.1.1.6 Vendor Identification Register (address = 0x00C to 0x00D) [reset = 0x0451]

Figure 76. Vendor Identification Register (VENDOR_ID)

15

14

13

12

VENDOR_ID[15:8]

R-0x04h

11

10

9

1

8

0

7

6

5

4

3

2

VENDOR_ID[7:0]

R-0x51h

Table 29. VENDOR_ID Field Descriptions

Bit

15-0

Field

VENDOR_ID

Type

Reset

Description

R

0x0451h

Always returns 0x0451 (TI vendor ID).

7.6.1.2 User SPI Configuration (0x010 to 0x01F)

Table 30. User SPI Configuration Registers

ADDRESS

RESET

ACRONYM

REGISTER NAME

SECTION

0x010

0x00

USR0

User SPI Configuration Register

User SPI Configuration Register (address = 0x010) [reset

= 0x00]

0x011-0x01F

Undefined

RESERVED

—

7.6.1.2.1 User SPI Configuration Register (address = 0x010) [reset = 0x00]

Figure 77. User SPI Configuration Register (USR0)

7

6

5

4

3

2

1

0

RESERVED

R-0000 000

ADDR_HOLD

R/W-0

Table 31. USR0 Field Descriptions

Bit

7-1

0

Field

Type

R/W

Reset

Description

RESERVED

0000 000 RESERVED

ADDR_HOLD

0

0: Use the ADDR_ASC bit to define what happens to the

address during streaming (default)

1: Address remains static throughout streaming operation; this

setting is useful for reading/writing calibration vector information

at the CAL_DATA register

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7.6.1.3 Miscellaneous Analog Registers (0x020 to 0x047)

Table 32. Miscellaneous Analog Registers

ADDRESS

0x020-0x028

0x029

RESET

Undefined

0x00

ACRONYM

REGISTER NAME

SECTION

RESERVED

CLK_CTRL0

CLK_CTRL1

RESERVED

SYSREF_POS

RESERVED

—

Clock Control Register 0

Clock Control Register 1

RESERVED

Clock Control Register 0 (address = 0x029) [reset = 0x00]

0x02A

0x20

Clock Control Register 1 (address = 0x02A) [reset = 0x00]

—

0x02B

Undefined

0x02C-0x02E

SYSREF Capture Position Register

SYSREF Capture Position Register (address = 0x02C-

0x02E) [reset = Undefined]

0x02F

Undefined

0xA000

RESERVED

—

0x030-0x031

FS_RANGE_A

INA Full-Scale Range Adjust Register INA Full-Scale Range Adjust Register (address = 0x030-

0x031) [reset = 0xA000]

0x032-0x033

0xA000

FS_RANGE_B

INB Full-Scale Range Adjust Register INB Full-Scale Range Adjust Register (address = 0x032-

0x033) [reset = 0xA000]

0x034-0x037

0x038

Undefined

0x00

RESERVED

BG_BYPASS

RESERVED

—

Internal Reference Bypass Register

Internal Reference Bypass Register (address = 0x038)

[reset = 0x00]

0x039-0x03A

0x03B

Undefined

0x00

RESERVED

SYNC_CTRL

RESERVED

—

TMSTP± Control Register

TMSTP± Control Register (address = 0x03B) [reset =

0x00]

0x03C-0x047

Undefined

RESERVED

—

7.6.1.3.1 Clock Control Register 0 (address = 0x029) [reset = 0x00]

Figure 78. Clock Control Register 0 (CLK_CTRL0)

7

6

5

4

3

2

1

0

RESERVED

R/W-0

SYSREF_PROC_EN SYSREF_RECV_EN

R/W-0 R/W-0

SYSREF_ZOOM

R/W-0

SYSREF_SEL

R/W-0000

Table 33. CLK_CTRL0 Field Descriptions

Bit

Field

Type

R/W

Reset

Description

7

6

RESERVED

0

RESERVED

SYSREF_PROC_EN

This bit enables the SYSREF processor. This bit must be set to

allow the device to process SYSREF events.

SYSREF_RECV_EN must be set before setting

SYSREF_PROC_EN.

5

4

SYSREF_RECV_EN

SYSREF_ZOOM

R/W

0

Set this bit to enable the SYSREF receiver circuit.

Set this bit to zoom in the SYSREF strobe status (affects

SYSREF_POS).

3-0

SYSREF_SEL

R/W

0000

Set this field to select which SYSREF delay to use. Set this field

based on the results returned by SYSREF_POS. Set this field to

0 to use SYSREF calibration.

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7.6.1.3.2 Clock Control Register 1 (address = 0x02A) [reset = 0x00]

Figure 79. Clock Control Register 1 (CLK_CTRL1)

7

6

5

4

3

2

1

0

RESERVED

R/W-0010 0

DEVCLK_LVPECL_EN SYSREF_LVPECL_EN SYSREF_INVERTED

R/W-0 R/W-0 R/W-0

Table 34. CLK_CTRL1 Field Descriptions

Bit

7-3

2

Field

RESERVED

Type

R/W

Reset

Description

0010 0

RESERVED

DEVCLK_LVPECL_EN

SYSREF_LVPECL_EN

SYSREF_INVERTED

0

Activate low-voltage PECL mode for DEVCLK.

Activate low-voltage PECL mode for SYSREF.

Inverts the SYSREF signal used for alignment.

1

0

7.6.1.3.3 SYSREF Capture Position Register (address = 0x02C-0x02E) [reset = Undefined]

Figure 80. SYSREF Capture Position Register (SYSREF_POS)

23

15

7

22

14

6

21

13

5

20

19

18

10

2

17

9

16

SYSREF_POS[23:16]

R-Undefined

12

11

8

0

SYSREF_POS[15:8]

R-Undefined

4

3

1

SYSREF_POS[7:0]

R-Undefined

Table 35. SYSREF_POS Field Descriptions

Bit

23-0

Field

SYSREF_POS

Type

Reset

Description

R

Undefined This field returns a 24-bit status value that indicates the position

of the SYSREF edge with respect to DEVCLK. Use this field to

program SYSREF_SEL.

7.6.1.3.4 INA Full-Scale Range Adjust Register (address = 0x030-0x031) [reset = 0xA000]

Figure 81. INA Full-Scale Range Adjust Register (FS_RANGE_A)

15

14

13

12

11

10

9

1

8

0

FS_RANGE_A[15:8]

R/W-0xA0h

7

6

5

4

3

2

FS_RANGE_A[7:0]

R/W-0x00h

Table 36. FS_RANGE_A Field Descriptions

Bit

15-0

Field

FS_RANGE_A

Type

Reset

Description

R/W

0xA000h

This field enables adjustment of the analog full-scale range for

INA.

0x0000: Settings below 0x2000 may result in degraded device

performance

0x2000: 500 mV_PP- Recommended minimum setting

0xA000: 800 mV_PP(default)

0xFFFF: 1000 mV_PP

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7.6.1.3.5 INB Full-Scale Range Adjust Register (address = 0x032-0x033) [reset = 0xA000]

Figure 82. INB Full Scale Range Adjust Register (FS_RANGE_B)

15

14

13

12

11

10

9

1

8

0

FS_RANGE_B[15:8]

R/W-0xA0

7

6

5

4

3

2

FS_RANGE_B[7:0]

R/W-0x00

Table 37. FS_RANGE_B Field Descriptions

Bit

15-0

Field

FS_RANGE_B

Type

Reset

Description

R/W

0xA000h

This field enables adjustment of the analog full-scale range for

INB.

0x0000: Settings below 0x2000 may result in degraded device

performance

0x2000: 500 mV_PP- Recommended minimum setting

0xA000: 800 mV_PP(default)

0xFFFF: 1000 mV_PP

7.6.1.3.6 Internal Reference Bypass Register (address = 0x038) [reset = 0x00]

Figure 83. Internal Reference Bypass Register (BG_BYPASS)

7

6

5

4

3

2

1

0

RESERVED

R/W-0000 000

BG_BYPASS

R/W-0

Table 38. BG_BYPASS Field Descriptions

Bit

Field

Type

R/W

Reset

Description

7-1

0

RESERVED

BG_BYPASS

0000 000 RESERVED

0

When set, VA11 is used as the voltage reference instead of the

internal reference.

7.6.1.3.7 TMSTP± Control Register (address = 0x03B) [reset = 0x00]

Figure 84. TMSTP± Control Register (TMSTP_CTRL)

7

6

5

4

3

2

1

0

RESERVED

R/W-0000 00

TMSTP_LVPECL_EN

R/W-0

TMSTP_RECV_EN

R/W-0

Table 39. TMSTP_CTRL Field Descriptions

Bit

7-2

1

Field

Type

R/W

Reset

0000 00

0

Description

RESERVED

TMSTP_LVPECL_EN

When set, this bit activates the low-voltage PECL mode for the

differential TMSTP± input.

0

TMSTP_RECV_EN

R/W

0

This bit enables the differential TMSTP± input.

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7.6.1.4 Serializer Registers (0x048 to 0x05F)

Table 40. Serializer Registers

ADDRESS

RESET

ACRONYM

REGISTER NAME

SECTION

0x048

0x00

SER_PE

Serializer Pre-Emphasis Control

Register

Serializer Pre-Emphasis Control Register (address =

0x048) [reset = 0x00]

0x049-0x05F

Undefined

RESERVED

—

7.6.1.4.1 Serializer Pre-Emphasis Control Register (address = 0x048) [reset = 0x00]

Figure 85. Serializer Pre-Emphasis Control Register (SER_PE)

7

6

5

4

3

2

1

0

RESERVED

R/W-0000

SER_PE

R/W-0000

Table 41. SER_PE Field Descriptions

Bit

7-4

3-0

Field

Type

R/W

Reset

0000

Description

RESERVED

SER_PE

RESERVED

This field sets the pre-emphasis for the serial lanes to

compensate for the low-pass response of the PCB trace. This

setting is a global setting that affects all 16 lanes.

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7.6.1.5 Calibration Registers (0x060 to 0x0FF)

Table 42. Calibration Registers

ADDRESS

RESET

ACRONYM

REGISTER NAME

SECTION

0x060

0x01

INPUT_MUX

Input Mux Control Register

Input Mux Control Register (address = 0x060) [reset =

0x01]

0x061

0x062

0x01

CAL_EN

Calibration Enable Register

Calibration Enable Register (address = 0x061) [reset =

0x01]

CAL_CFG0

Calibration Configuration 0 Register

Calibration Configuration 0 Register (address = 0x062)

[reset = 0x01]

0x063-0x069

0x06A

Undefined

RESERVED

—

CAL_STATUS

Calibration Status Register

Calibration Status Register (address = 0x06A) [reset =

Undefined]

0x06B

0x06C

0x00

0x01

CAL_PIN_CFG

Calibration Pin Configuration

Register

Calibration Pin Configuration Register (address = 0x06B)

[reset = 0x00]

CAL_SOFT_TRIG Calibration Software Trigger Register

Calibration Software Trigger Register (address = 0x06C)

[reset = 0x01]

0x06D

0x06E

Undefined

0x88

RESERVED

CAL_LP

RESERVED

—

Low-Power Background Calibration

Register

Low-Power Background Calibration Register (address =

0x06E) [reset = 0x88]

0x06F

0x070

Undefined

0x00

RESERVED

—

CAL_DATA_EN Calibration Data Enable Register

Calibration Data Enable Register (address = 0x070) [reset

= 0x00]

0x071

Undefined

CAL_DATA

Calibration Data Register

Calibration Data Register (address = 0x071) [reset =

Undefined]

0x072-0x079

0x07A

Undefined

RESERVED

—

GAIN_TRIM_A

Channel A Gain Trim Register

Channel A Gain Trim Register (address = 0x07A) [reset =

Undefined]

0x07B

0x07C

Undefined

GAIN_TRIM_B

BG_TRIM

Channel B Gain Trim Register

Channel B Gain Trim Register (address = 0x07B) [reset =

Undefined]

Band-Gap Reference Trim Register

Band-Gap Reference Trim Register (address = 0x07C)

[reset = Undefined]

0x07D

0x07E

Undefined

RESERVED

RTRIM_A

RESERVED

—

VINA Input Resistor Trim Register

VINA Input Resistor Trim Register (address = 0x07E)

[reset = Undefined]

0x07F

0x080

Undefined

RTRIM_B

VINB Input Resistor Trim Register

VINB Input Resistor Trim Register (address = 0x07F)

[reset = Undefined]

TADJ_A_FG90

Timing Adjustment for A-ADC,

Single-Channel Mode, Foreground

Calibration Register

Timing Adjust for A-ADC, Single-Channel Mode,

Foreground Calibration Register (address = 0x080) [reset

= Undefined]

0x081

0x082

0x083

0x084

0x085

Undefined

TADJ_B_FG0

TADJ_A_BG90

TADJ_C_BG0

TADJ_C_BG90

TADJ_B_BG0

Timing Adjustment for B-ADC,

Single-Channel Mode, Foreground

Calibration Register

Timing Adjust for B-ADC, Single-Channel Mode,

Foreground Calibration Register (address = 0x081) [reset

= Undefined]

Timing Adjustment for A-ADC,

Single-Channel Mode, Background

Calibration Register

Timing Adjust for A-ADC, Single-Channel Mode,

Background Calibration Register (address = 0x082) [reset

= Undefined]

Timing Adjustment for C-ADC,

Single-Channel Mode, Background

Calibration Register

Timing Adjust for C-ADC, Single-Channel Mode,

Background Calibration Register (address = 0x084) [reset

= Undefined]

Timing Adjustment for C-ADC,

Single-Channel Mode, Background

Calibration Register

Timing Adjust for C-ADC, Single-Channel Mode,

Background Calibration Register (address = 0x084) [reset

= Undefined]

Timing Adjustment for B-ADC,

Single-Channel Mode, Background

Calibration Register

Timing Adjust for B-ADC, Single-Channel Mode,

Background Calibration Register (address = 0x085) [reset

= Undefined]

0x086

0x087

Undefined

TADJ_A

Timing Adjustment for A-ADC, Dual-

Channel Mode Register

Timing Adjust for A-ADC, Dual-Channel Mode Register

(address = 0x086) [reset = Undefined]

TADJ_CA

Timing Adjustment for C-ADC Acting Timing Adjust for C-ADC Acting for A-ADC, Dual-Channel

for A-ADC, Dual-Channel Mode

Register

Mode Register (address = 0x087) [reset = Undefined]

0x088

Undefined

TADJ_CB

Timing Adjustment for C-ADC Acting Timing Adjust for C-ADC Acting for B-ADC, Dual-Channel

for B-ADC, Dual-Channel Mode

Register

Mode Register (address = 0x088) [reset = Undefined]

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Table 42. Calibration Registers (continued)

ADDRESS

RESET

ACRONYM

REGISTER NAME

SECTION

0x089

Undefined

TADJ_B

Timing Adjustment for B-ADC, Dual-

Channel Mode Register

Timing Adjust for B-ADC, Dual-Channel Mode Register

(address = 0x089) [reset = Undefined]

0x08A-0x08B

0x08C-0x08D

0x08E-0x08F

0x090-0x091

0x092-0x093

0x094-0x095

Undefined

OADJ_A_INA

OADJ_A_INB

OADJ_C_INA

OADJ_C_INB

OADJ_B_INA

OADJ_B_INB

Offset Adjustment for A-ADC and INA Offset Adjustment for A-ADC and INA Register (address =

Register 0x08A-0x08B) [reset = Undefined]

Offset Adjustment for A-ADC and INB Offset Adjustment for A-ADC and INB Register (address =

Register

0x08C-0x08D) [reset = Undefined]

Offset Adjustment for C-ADC and

INA Register

Offset Adjustment for C-ADC and INA Register (address =

0x08E-0x08F) [reset = Undefined]

Offset Adjustment for C-ADC and

INB Register

Offset Adjustment for C-ADC and INB Register (address =

0x090-0x091) [reset = Undefined]

Offset Adjustment for B-ADC and INA Offset Adjustment for B-ADC and INA Register (address =

Register 0x092-0x093) [reset = Undefined]

Offset Adjustment for B-ADC and INB Offset Adjustment for B-ADC and INB Register (address =

Register

0x094-0x095) [reset = Undefined]

0x096

0x097

Undefined

0x00

RESERVED

0SFILT0

RESERVED

—

Offset Filtering Control 0

Offset Filtering Control 0 Register (address = 0x097)

[reset = 0x00]

0x098

0x33

OSFILT1

Offset Filtering Control 1

RESERVED

Offset Filtering Control 1 Register (address = 0x098)

[reset = 0x33]

0x099-0x0FF

Undefined

RESERVED

—

7.6.1.5.1 Input Mux Control Register (address = 0x060) [reset = 0x01]

Figure 86. Input Mux Control Register (INPUT_MUX)

7

6

5

4

3

2

1

0

RESERVED

R/W-000

DUAL_INPUT

R/W-0

RESERVED

R/W-00

SINGLE_INPUT

R/W-01

Table 43. INPUT_MUX Field Descriptions

Bit

7-5

4

Field

Type

R/W

Reset

000

0

Description

RESERVED

DUAL_INPUT

This bit selects inputs for dual-channel modes. If JMODE is

selecting a single-channel mode, this register has no effect.

0: A channel samples INA, B channel samples INB (no swap,

default)

1: A channel samples INB, B channel samples INA (swap)

3-2

1-0

RESERVED

R/W

00

01

RESERVED

SINGLE_INPUT

Thid field defines which input is sampled in single-channel

mode. If JMODE is not selecting a single-channel mode, this

register has no effect.

0: Reserved

1: INA is used (default)

2: INB is used

3: Reserved

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7.6.1.5.2 Calibration Enable Register (address = 0x061) [reset = 0x01]

Figure 87. Calibration Enable Register (CAL_EN)

7

6

5

4

3

2

1

0

RESERVED

R/W-0000 000

CAL_EN

R/W-1

Table 44. CAL_EN Field Descriptions

Bit

7-1

0

Field

Type

R/W

Reset

Description

RESERVED

CAL_EN

0000 000 RESERVED

1

Calibration enable. Set this bit high to run calibration. Set this bit

low to hold the calibration in reset to program new calibration

settings. Clearing CAL_EN also resets the clock dividers that

clock the digital block and JESD204B interface.

Some calibration registers require clearing CAL_EN before

making any changes. All registers with this requirement contain

a note in their descriptions. After changing the registers, set

CAL_EN to re-run calibration with the new settings.

Always set CAL_EN before setting JESD_EN. Always clear

JESD_EN before clearing CAL_EN.

7.6.1.5.3 Calibration Configuration 0 Register (address = 0x062) [reset = 0x01]

Only change this register when CAL_EN is 0.

Figure 88. Calibration Configuration 0 Register (CAL_CFG0)

7

6

5

4

3

2

1

0

RESERVED

R/W-000

CAL_OSFILT

R/W-0

CAL_BGOS

R/W-0

CAL_OS

R/W-0

CAL_BG

R/W-0

CAL_FG

R/W-1

Table 45. CAL_CFG0 Field Descriptions

Bit

7-5

4

Field

Type

R/W

Reset

0000

0

Description

RESERVED

CAL_OSFILT

CAL_BGOS

RESERVED

Enable offset filtering by setting this bit high.

3

0

0 : Disables background offset calibration (default)

1: Enables background offset calibration (requires CAL_BG to

be set).

2

CAL_OS

R/W

0

0 : Disables foreground offset calibration (default)

1: Enables foreground offset calibration (requires CAL_FG to be

set)

1

0

CAL_BG

CAL_FG

R/W

0

1

0 : Disables background calibration (default)

1: Enables background calibration

0 : Resets calibration values, skips foreground calibration

1: Resets calibration values, then runs foreground calibration

(default)

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7.6.1.5.4 Calibration Status Register (address = 0x06A) [reset = Undefined]

Figure 89. Calibration Status Register (CAL_STATUS)

7

6

5

4

3

2

1

0

FG_DONE

R

RESERVED

R

CAL_STOPPED

R

Table 46. CAL_STATUS Field Descriptions

Bit

7-2

1

Field

Type

R

Reset

Description

RESERVED

CAL_STOPPED

R

This bit returns a 1 when the background calibration has

successfully stopped at the requested phase. This bit returns a 0

when calibration starts operating again. If background calibration

is disabled, this bit is set when foreground calibration is

completed or skipped.

0

FG_DONE

R

This bit is set high when the foreground calibration completes.

7.6.1.5.5 Calibration Pin Configuration Register (address = 0x06B) [reset = 0x00]

Figure 90. Calibration Pin Configuration Register (CAL_PIN_CFG)

7

6

5

4

3

2

1

0

RESERVED

R/W-0000 0

CAL_STATUS_SEL

R/W-00

CAL_TRIG_EN

R/W-0

Table 47. CAL_PIN_CFG Field Descriptions

Bit

Field

Type

R/W

Reset

0000 0

00

Description

7-3

2-1

RESERVED

CAL_STATUS_SEL

0: CALSTAT output pin matches FG_DONE

1: RESERVED

2: CALSTAT output pin matches ALARM

3: CALSTAT output pin is always low

0

CAL_TRIG_EN

R/W

0

Choose the hardware or software trigger source with this bit.

0: Use the CAL_SOFT_TRIG register for the calibration trigger;

the CAL_TRIG input is disabled (ignored)

1: Use the CAL_TRIG input for the calibration trigger; the

CAL_SOFT_TRIG register is ignored

7.6.1.5.6 Calibration Software Trigger Register (address = 0x06C) [reset = 0x01]

Figure 91. Calibration Software Trigger Register (CAL_SOFT_TRIG)

7

6

5

4

3

2

1

0

RESERVED

R/W-0000 000

CAL_SOFT_TRIG

R/W-1

Table 48. CAL_SOFT_TRIG Field Descriptions

Bit

Field

Type

R/W

Reset

Description

7-1

0

RESERVED

0000 000 RESERVED

CAL_SOFT_TRIG

1

CAL_SOFT_TRIG is a software bit to provide functionality of the

CAL_TRIG input. Program CAL_TRIG_EN = 0 to use

CAL_SOFT_TRIG for the calibration trigger. If no calibration

trigger is needed, leave CAL_TRIG_EN = 0 and

CAL_SOFT_TRIG = 1 (trigger is set high).

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7.6.1.5.7 Low-Power Background Calibration Register (address = 0x06E) [reset = 0x88]

Figure 92. Low-Power Background Calibration Register (CAL_LP)

7

6

5

4

3

2

1

0

LP_SLEEP_DLY

R/W-010

LP_WAKE_DLY

R/W-01

RESERVED

R/W-0

LP_TRIG

R/W-0

LP_EN

R/W-0

Table 49. CAL_LP Field Descriptions

Bit

Field

LP_SLEEP_DLY

Type

Reset

Description

7-5

R/W

010

Adjust how long an ADC sleeps before waking up for calibration

(only applies when LP_EN = 1 and LP_TRIG = 0). Values below

4 are not recommended because of limited overall power

reduction benefits.

0: Sleep delay = (2³+ 1) × 256 × t_DEVCLK

1: Sleep delay = (2¹⁵+ 1) × 256 × t_DEVCLK

2: Sleep delay = (2¹⁸+ 1) × 256 × t_DEVCLK

3: Sleep delay = (2²¹+ 1) × 256 × t_DEVCLK

4: Sleep delay = (2²⁴+ 1) × 256 × t_DEVCLK: default is

approximately 1338 ms with a 3.2-GHz clock

5: Sleep delay = (2²⁷+ 1) × 256 × t_DEVCLK

6: Sleep delay = (2³⁰+ 1) × 256 × t_DEVCLK

7: Sleep delay = (2³³+ 1) × 256 × t_DEVCLK

4-3

LP_WAKE_DLY

R/W

01

Adjust how much time is given up for settling before calibrating

an ADC after wake-up (only applies when LP_EN = 1). Values

lower than 1 are not recommended because there is insufficient

time for the core to stabilize before calibration begins.

0:Wake Delay = (2³+ 1) × 256 × t_DEVCLK

1: Wake Delay = (2¹⁸+ 1) × 256 × t_DEVCLK: default is

approximately 21 ms with a 3.2-GHz clock

2: Wake Delay = (2²¹+ 1) × 256 × t_DEVCLK

3: Wake Delay = (2²⁴+ 1) × 256 × t_DEVCLK

2

1

RESERVED

LP_TRIG

R/W

0

RESERVED

0: ADC sleep duration is set by LP_SLEEP_DLY (autonomous

mode)

1: ADCs sleep until woken by a trigger; an ADC is awoken when

the calibration trigger (CAL_SOFT_TRIG bit or CAL_TRIG input)

is low

0

LP_EN

R/W

0

0: Disables low-power background calibration (default)

1: Enables low-power background calibration (only applies when

CAL_BG = 1)

7.6.1.5.8 Calibration Data Enable Register (address = 0x070) [reset = 0x00]

Figure 93. Calibration Data Enable Register (CAL_DATA_EN)

7

6

5

4

3

2

1

0

RESERVED

R/W-0000 000

CAL_DATA_EN

R/W-0

Table 50. CAL_DATA_EN Field Descriptions

Bit

Field

Type

R/W

Reset

Description

7-1

0

RESERVED

0000 000 RESERVED

CAL_DATA_EN

0

Set this bit to enable the CAL_DATA register to enable reading

and writing of calibration data; see the calibration data register

for more information.

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7.6.1.5.9 Calibration Data Register (address = 0x071) [reset = Undefined]

Figure 94. Calibration Data Register (CAL_DATA)

7

6

5

4

3

2

1

0

CAL_DATA

R/W

Table 51. CAL_DATA Field Descriptions

Bit

Field

Type

Reset

Description

7-0

CAL_DATA

R/W

Undefined After setting CAL_DATA_EN, repeated reads of this register

return all calibration values for the ADCs. Repeated writes of this

register input all calibration values for the ADCs. To read the

calibration data, read the register 673 times. To write the vector,

write the register 673 times with previously stored calibration

data.

To speed up the read/write operation, set ADDR_HOLD = 1 and

use the streaming read or write process.

Accessing the CAL_DATA register when CAL_STOPPED = 0

corrupts the calibration. Also, stopping the process before

reading or writing 673 times leaved the calibration data in an

invalid state.

7.6.1.5.10 Channel A Gain Trim Register (address = 0x07A) [reset = Undefined]

Figure 95. Channel A Gain Trim Register (GAIN_TRIM_A)

7

6

5

4

3

2

1

0

GAIN_TRIM_A

R/W

Table 52. GAIN_TRIM_A Field Descriptions

Bit

Field

GAIN_TRIM_A

Type

Reset

Description

7-0

R/W

Undefined This register enables gain trim of channel A. After reset, the

factory-trimmed value can be read and adjusted as required.

7.6.1.5.11 Channel B Gain Trim Register (address = 0x07B) [reset = Undefined]

Figure 96. Channel B Gain Trim Register (GAIN_TRIM_B)

7

6

5

4

3

2

1

0

GAIN_TRIM_B

R/W

Table 53. GAIN_TRIM_B Field Descriptions

Bit

Field

GAIN_TRIM_B

Type

Reset

Description

7-0

R/W

Undefined This register enables gain trim of channel B. After reset, the

factory-trimmed value can be read and adjusted as required.

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7.6.1.5.12 Band-Gap Reference Trim Register (address = 0x07C) [reset = Undefined]

Figure 97. Band-Gap Reference Trim Register (BG_TRIM)

7

6

5

4

3

2

1

0

RESERVED

R/W-0000

BG_TRIM

R/W

Table 54. BG_TRIM Field Descriptions

Bit

7-4

3-0

Field

Type

R/W

Reset

Description

RESERVED

BG_TRIM

0000

RESERVED

Undefined This register enables the internal band-gap reference to be

trimmed. After reset, the factory-trimmed value can be read and

adjusted as required.

7.6.1.5.13 VINA Input Resistor Trim Register (address = 0x07E) [reset = Undefined]

Figure 98. VINA Input Resistor Trim Register (RTRIM_A)

7

6

5

4

3

2

1

0

RTRIM

R/W

Table 55. RTRIM_A Field Descriptions

Bit

Field

Type

Reset

Description

7-0

RTRIM_A

R/W

Undefined This register controls the VINA ADC input termination trim. After

reset, the factory-trimmed value can be read and adjusted as

required.

7.6.1.5.14 VINB Input Resistor Trim Register (address = 0x07F) [reset = Undefined]

Figure 99. VINB Input Resistor Trim Register (RTRIM_B)

7

6

5

4

3

2

1

0

RTRIM

R/W

Table 56. RTRIM_B Field Descriptions

Bit

Field

Type

Reset

Description

7-0

RTRIM_B

R/W

Undefined This register controls the VINB ADC input termination trim. After

reset, the factory-trimmed value can be read and adjusted as

required.

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7.6.1.5.15 Timing Adjust for A-ADC, Single-Channel Mode, Foreground Calibration Register (address = 0x080) [reset

= Undefined]

Figure 100. Register (TADJ_A_FG90)

7

6

5

4

3

2

1

0

TADJ_A_FG90

R/W

Table 57. TADJ_A_FG90 Field Descriptions

Bit

Field

TADJ_A_FG90

Type

Reset

Description

7-0

R/W

Undefined This register (and other subsequent TADJ* registers) are used

to adjust the sampling instant of each ADC core. Different TADJ

registers apply to different ADCs under different modes or

phases of background calibration. After reset, the factory-

trimmed value can be read and adjusted as required.

7.6.1.5.16 Timing Adjust for B-ADC, Single-Channel Mode, Foreground Calibration Register (address = 0x081) [reset

= Undefined]

Figure 101. Register (TADJ_B_FG0)

7

6

5

4

3

2

1

0

TADJ_B_FG0

R/W

Table 58. TADJ_B_FG0 Field Descriptions

Bit

Field

TADJ_B_FG0

Type

Reset

Description

7-0

R/W

Undefined This register (and other subsequent TADJ* registers) are used

to adjust the sampling instant of each ADC core. Different TADJ

registers apply to different ADCs under different modes or

phases of background calibration. After reset, the factory-

trimmed value can be read and adjusted as required.

7.6.1.5.17 Timing Adjust for A-ADC, Single-Channel Mode, Background Calibration Register (address = 0x082)

[reset = Undefined]

Figure 102. Register (TADJ_A_BG90)

7

6

5

4

3

2

1

0

TADJ_A_BG90

R/W

Table 59. TADJ_B_FG0 Field Descriptions

Bit

Field

TADJ_A_BG90

Type

Reset

Description

7-0

R/W

Undefined This register (and other subsequent TADJ* registers) are used

to adjust the sampling instant of each ADC core. Different TADJ

registers apply to different ADCs under different modes or

phases of background calibration. After reset, the factory-

trimmed value can be read and adjusted as required.

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7.6.1.5.18 Timing Adjust for C-ADC, Single-Channel Mode, Background Calibration Register (address = 0x083)

[reset = Undefined]

Figure 103. Timing Adjust for C-ADC, Single-Channel Mode, Background Calibration Register

(TADJ_C_BG0)

7

6

5

4

3

2

1

0

TADJ_C_BG0

R/W

Table 60. TADJ_B_FG0 Field Descriptions

Bit

Field

TADJ_C_BG0

Type

Reset

Description

7-0

R/W

Undefined This register (and other subsequent TADJ* registers) are used

to adjust the sampling instant of each ADC core. Different TADJ

registers apply to different ADCs under different modes or

phases of background calibration. After reset, the factory-

trimmed value can be read and adjusted as required.

7.6.1.5.19 Timing Adjust for C-ADC, Single-Channel Mode, Background Calibration Register (address = 0x084)

[reset = Undefined]

Figure 104. Timing Adjust for C-ADC, Single-Channel Mode, Background Calibration Register

(TADJ_C_BG90)

7

6

5

4

3

2

1

0

TADJ_C_BG90

R/W

Table 61. TADJ_B_FG0 Field Descriptions

Bit

Field

TADJ_C_BG90

Type

Reset

Description

7-0

R/W

Undefined This register (and other subsequent TADJ* registers) are used

to adjust the sampling instant of each ADC core. Different TADJ

registers apply to different ADCs under different modes or

phases of background calibration. After reset, the factory-

trimmed value can be read and adjusted as required.

7.6.1.5.20 Timing Adjust for B-ADC, Single-Channel Mode, Background Calibration Register (address = 0x085)

[reset = Undefined]

Figure 105. Timing Adjust for B-ADC, Single-Channel Mode, Background Calibration Register

(TADJ_B_BG0)

7

6

5

4

3

2

1

0

TADJ_B_BG0

R/W

Table 62. TADJ_B_FG0 Field Descriptions

Bit

Field

TADJ_B_BG0

Type

Reset

Description

7-0

R/W

Undefined This register (and other subsequent TADJ* registers) are used

to adjust the sampling instant of each ADC core. Different TADJ

registers apply to different ADCs under different modes or

phases of background calibration. After reset, the factory-

trimmed value can be read and adjusted as required.

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7.6.1.5.21 Timing Adjust for A-ADC, Dual-Channel Mode Register (address = 0x086) [reset = Undefined]

Figure 106. Timing Adjust for A-ADC, Dual-Channel Mode Register (TADJ_A)

7

6

5

4

3

2

1

0

TADJ_A

R/W

Table 63. TADJ_A Field Descriptions

Bit

Field

Type

Reset

Description

7-0

TADJ_A

R/W

Undefined This register (and other subsequent TADJ* registers) are used

to adjust the sampling instant of each ADC core. Different TADJ

registers apply to different ADCs under different modes or

phases of background calibration. After reset, the factory-

trimmed value can be read and adjusted as required.

7.6.1.5.22 Timing Adjust for C-ADC Acting for A-ADC, Dual-Channel Mode Register (address = 0x087) [reset =

Undefined]

Figure 107. Timing Adjust for C-ADC Acting for A-ADC, Dual-Channel Mode Register (TADJ_CA)

7

6

5

4

3

2

1

0

TADJ_CA

R/W

Table 64. TADJ_CA Field Descriptions

Bit

Field

Type

Reset

Description

7-0

TADJ_CA

R/W

Undefined This register (and other subsequent TADJ* registers) are used

to adjust the sampling instant of each ADC core. Different TADJ

registers apply to different ADCs under different modes or

phases of background calibration. After reset, the factory-

trimmed value can be read and adjusted as required.

7.6.1.5.23 Timing Adjust for C-ADC Acting for B-ADC, Dual-Channel Mode Register (address = 0x088) [reset =

Undefined]

Figure 108. Timing Adjust for C-ADC Acting for B-ADC, Dual-Channel Mode Register (TADJ_CB)

7

6

5

4

3

2

1

0

TADJ_CB

R/W

Table 65. TADJ_CB Field Descriptions

Bit

Field

Type

Reset

Description

7-0

TADJ_CB

R/W

Undefined This register (and other subsequent TADJ* registers) are used

to adjust the sampling instant of each ADC core. Different TADJ

registers apply to different ADCs under different modes or

phases of background calibration. After reset, the factory-

trimmed value can be read and adjusted as required.

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7.6.1.5.24 Timing Adjust for B-ADC, Dual-Channel Mode Register (address = 0x089) [reset = Undefined]

Figure 109. Timing Adjust for B-ADC, Dual-Channel Mode Register (TADJ_B)

7

6

5

4

3

2

1

0

TADJ_B

R/W

Table 66. TADJ_B Field Descriptions

Bit

Field

Type

Reset

Description

7-0

TADJ_B

R/W

Undefined This register (and other subsequent TADJ* registers) are used

to adjust the sampling instant of each ADC core. Different TADJ

registers apply to different ADCs under different modes or

phases of background calibration. After reset, the factory-

trimmed value can be read and adjusted as required.

7.6.1.5.25 Offset Adjustment for A-ADC and INA Register (address = 0x08A-0x08B) [reset = Undefined]

Figure 110. Offset Adjustment for A-ADC and INA Register (OADJ_A_INA)

15

14

13

12

11

10

9

8

0

RESERVED

R/W-0000

OADJ_A_INA[11:8]

R/W

7

6

5

4

3

2

1

OADJ_A_INA[7:0]

R/W

Table 67. OADJ_A_INA Field Descriptions

Bit

Field

Type

R/W

Reset

Description

15-12

11-0

RESERVED

0000

RESERVED

OADJ_A_INA

Undefined Offset adjustment value for ADC0 (A-ADC) applied when ADC0

samples INA. The format is unsigned. After reset, the factory-

trimmed value can be read and adjusted as required.

Important notes:

•

Never write OADJ* registers while foreground calibration is

underway

Never write OADJ* registers if CAL_BG and CAL_BGOS

are set

If CAL_OS = 1 and CAL_BGOS = 0, only read OADJ*

registers if FG_DONE = 1

If CAL_BG = 1 and CAL_BGOS = 1, only read OADJ*

register if CAL_STOPPED = 1

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7.6.1.5.26 Offset Adjustment for A-ADC and INB Register (address = 0x08C-0x08D) [reset = Undefined]

Figure 111. Offset Adjustment for A-ADC and INB Register (OADJ_A_INB)

15

14

13

12

11

10

9

8

0

RESERVED

R/W-0000

OADJ_A_INB[11:8]

R/W

7

6

5

4

3

2

1

OADJ_A_INB[7:0]

R/W

Table 68. OADJ_A_INB Field Descriptions

Bit

Field

Type

R/W

Reset

Description

15-12

11-0

RESERVED

0000

RESERVED

OADJ_A_INB

Undefined Offset adjustment value for ADC0 (A-ADC) applied when ADC0

samples INB. The format is unsigned. After reset, the factory-

trimmed value can be read and adjusted as required.

Important notes:

•

Never write OADJ* registers while foreground calibration is

underway

Never write OADJ* registers if CAL_BG and CAL_BGOS

are set

If CAL_OS = 1 and CAL_BGOS = 0, only read OADJ*

registers if FG_DONE = 1

If CAL_BG = 1 and CAL_BGOS = 1, only read OADJ*

register if CAL_STOPPED = 1

7.6.1.5.27 Offset Adjustment for C-ADC and INA Register (address = 0x08E-0x08F) [reset = Undefined]

Figure 112. Offset Adjustment for C-ADC and INA Register (OADJ_C_INA)

15

14

13

12

11

10

9

8

0

RESERVED

R/W-0000

OADJ_C_INA[11:8]

R/W

7

6

5

4

3

2

1

OADJ_C_INA[7:0]

R/W

Table 69. OADJ_C_INA Field Descriptions

Bit

Field

Type

R/W

Reset

Description

15-12

11-0

RESERVED

0000

RESERVED

OADJ_C_INA

Undefined Offset adjustment value for ADC1 (A-ADC) applied when ADC1

samples INA. The format is unsigned. After reset, the factory-

trimmed value can be read and adjusted as required.

Important notes:

•

Never write OADJ* registers while foreground calibration is

underway

Never write OADJ* registers if CAL_BG and CAL_BGOS

are set

If CAL_OS = 1 and CAL_BGOS = 0, only read OADJ*

registers if FG_DONE = 1

If CAL_BG = 1 and CAL_BGOS = 1, only read OADJ*

register if CAL_STOPPED = 1

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7.6.1.5.28 Offset Adjustment for C-ADC and INB Register (address = 0x090-0x091) [reset = Undefined]

Figure 113. Offset Adjustment for C-ADC and INB Register (OADJ_C_INB)

15

14

13

12

11

10

9

8

0

RESERVED

R/W-0000

OADJ_C_INB[11:8]

R/W

7

6

5

4

3

2

1

OADJ_C_INB[7:0]

R/W

Table 70. OADJ_C_INB Field Descriptions

Bit

Field

Type

R/W

Reset

Description

15-12

11-0

RESERVED

0000

RESERVED

OADJ_C_INB

Undefined Offset adjustment value for ADC1 (A-ADC) applied when ADC1

samples INB. The format is unsigned. After reset, the factory-

trimmed value can be read and adjusted as required.

Important notes:

•

Never write OADJ* registers while foreground calibration is

underway

Never write OADJ* registers if CAL_BG and CAL_BGOS

are set

If CAL_OS = 1 and CAL_BGOS = 0, only read OADJ*

registers if FG_DONE = 1

If CAL_BG = 1 and CAL_BGOS = 1, only read OADJ*

register if CAL_STOPPED = 1

7.6.1.5.29 Offset Adjustment for B-ADC and INA Register (address = 0x092-0x093) [reset = Undefined]

Figure 114. Offset Adjustment for B-ADC and INA Register (OADJ_B_INA)

15

14

13

12

11

10

9

8

0

RESERVED

R/W-0000

OADJ_B_INA[11:8]

R/W

7

6

5

4

3

2

1

OADJ_B_INA[7:0]

R/W

Table 71. OADJ_B_INA Field Descriptions

Bit

Field

Type

R/W

Reset

Description

15-12

11-0

RESERVED

0000

RESERVED

OADJ_B_INA

Undefined Offset adjustment value for ADC2 (B-ADC) applied when ADC2

samples INA. The format is unsigned. After reset, the factory-

trimmed value can be read and adjusted as required.

Important notes:

•

Never write OADJ* registers while foreground calibration is

underway

Never write OADJ* registers if CAL_BG and CAL_BGOS

are set

If CAL_OS = 1 and CAL_BGOS = 0, only read OADJ*

registers if FG_DONE = 1

If CAL_BG = 1 and CAL_BGOS = 1, only read OADJ*

register if CAL_STOPPED = 1

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7.6.1.5.30 Offset Adjustment for B-ADC and INB Register (address = 0x094-0x095) [reset = Undefined]

Figure 115. Offset Adjustment for B-ADC and INB Register (OADJ_B_INB)

15

14

13

12

11

10

9

8

0

RESERVED

R/W-0000

OADJ_B_INB[11:8]

R/W

7

6

5

4

3

2

1

OADJ_B_INB[7:0]

R/W

Table 72. OADJ_B_INB Field Descriptions

Bit

Field

Type

R/W

Reset

Description

15-12

11-0

RESERVED

0000

RESERVED

OADJ_B_INB

Undefined Offset adjustment value for ADC2 (B-ADC) applied when ADC2

samples INB. The format is unsigned. After reset, the factory-

trimmed value can be read and adjusted as required.

Important notes:

•

Never write OADJ* registers while foreground calibration is

underway

Never write OADJ* registers if CAL_BG and CAL_BGOS

are set

If CAL_OS

registers if FG_DONE = 1

If CAL_BG and CAL_BGOS=1, only read OADJ*

register if CAL_STOPPED = 1

= 1 and CAL_BGOS=0, only read OADJ*

=

1

7.6.1.5.31 Offset Filtering Control 0 Register (address = 0x097) [reset = 0x00]

Figure 116. Offset Filtering Control 0 Register (OSFILT0)

7

6

5

4

3

2

1

0

RESERVED

R/W-0000 000

DC_RESTORE

R/W

Table 73. OSFILT0 Field Descriptions

Bit

Field

Type

R/W

Reset

Description

7-1

0

RESERVED

0000 000 RESERVED

DC_RESTORE

0

When set, the offset filtering feature (enabled by CAL_OSFILT)

filters only the offset mismatch across ADC banks and does not

remove the frequency content near DC. When cleared, the

feature filters all offsets from all banks, thus filtering all DC

content in the signal; see the Offset Filtering section.

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7.6.1.5.32 Offset Filtering Control 1 Register (address = 0x098) [reset = 0x33]

Figure 117. Offset Filtering Control 1 Register (OSFILT1)

7

6

5

4

3

2

1

0

OSFILT_BW

R/W-0011

OSFILT_SOAK

R/W-0011

Table 74. OSFILT1 Field Descriptions

Bit

Field

Type

Reset

Description

7-4

OSFILT_BW

R/W

0011

This field adjusts the IIR filter bandwidth for the offset filtering

feature (enabled by CAL_OSFILT). More bandwidth suppresses

more flicker noise from the ADCs and reduces the offset spurs.

Less bandwidth minimizes the impact of the filters on the

mission mode signal.

OSFILT_BW: IIR coefficient: –3-dB bandwidth (single sided)

0: Reserved

1: 2^-10: 609e-9 × F_DEVCLK

2: 2^-11: 305e-9 × F_DEVCLK

3: 2^-12: 152e-9 × F_DEVCLK

4: 2^-13: 76e-9 × F_DEVCLK

5: 2^-14: 38e-9 × F_DEVCLK

6-15: Reserved

3-0

OSFILT_SOAK

R/W

0011

This field adjusts the IIR soak time for the offset filtering feature.

This field applies when offset filtering and background calibration

are both enabled. This field determines how long the IIR filter is

allowed to settle when first connected to an ADC after the ADC

is calibrated. After the soak time completes, the ADC is placed

online using the IIR filter. Set OSFILT_SOAK = OSFILT_BW.

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7.6.1.6 ADC Bank Registers (0x100 to 0x15F)

Table 75. ADC Bank Registers

ADDRESS

0x100-0x101

0x102

RESET

ACRONYM

RESERVED

B0_TIME_0

REGISTER NAME

RESERVED

SECTION

Undefined

—

Timing Adjustment for Bank 0 (0°

Clock) Register

Timing Adjustment for Bank 0 (0° Clock) Register

(address = 0x102) [reset = Undefined]

0x103

Undefined

B0_TIME_90

Timing Adjustment for Bank 0 (–90°

Clock) Register

Timing Adjustment for Bank 0 (–90° Clock) Register

(address = 0x103) [reset = Undefined]

0x104-0x111

0x112

Undefined

RESERVED

B1_TIME_0

RESERVED

—

Timing Adjustment for Bank 1 (0°

Clock) Register

Timing Adjustment for Bank 1 (0° Clock) Register

(address = 0x112) [reset = Undefined]

0x113

Undefined

B1_TIME_90

Timing Adjustment for Bank 1 (–90°

Clock) Register

Timing Adjustment for Bank 1 (–90° Clock) Register

(address = 0x113) [reset = Undefined]

0x114-0x121

0x122

Undefined

RESERVED

B2_TIME_0

RESERVED

—

Timing Adjustment for Bank 2 (0°

Clock) Register

Timing Adjustment for Bank 2 (0° Clock) Register

(address = 0x122) [reset = Undefined]

0x123

Undefined

B2_TIME_90

Timing Adjustment for Bank 2 (–90°

Clock) Register

Timing Adjustment for Bank 2 (–90° Clock) Register

(address = 0x123) [reset = Undefined]

0x124-0x131

0x132

Undefined

RESERVED

B3_TIME_0

RESERVED

—

Timing Adjustment for Bank 3 (0°

Clock) Register

Timing Adjustment for Bank 3 (0° Clock) Register

(address = 0x132) [reset = Undefined]

0x133

Undefined

B3_TIME_90

Timing Adjustment for Bank 3 (–90°

Clock) Register

Timing Adjustment for Bank 3 (–90° Clock) Register

(address = 0x133) [reset = Undefined]

0x134-0x141

0x142

Undefined

RESERVED

B4_TIME_0

RESERVED

—

Timing Adjustment for Bank 4 (0°

Clock) Register

Timing Adjustment for Bank 4 (0° Clock) Register

(address = 0x142) [reset = Undefined]

0x143

Undefined

B4_TIME_90

Timing Adjustment for Bank 4 (–90°

Clock) Register

Timing Adjustment for Bank 4 (–90° Clock) Register

(address = 0x143) [reset = Undefined]

0x144-0x151

0x152

Undefined

RESERVED

B5_TIME_0

RESERVED

—

Timing Adjustment for Bank 5 (0°

Clock) Register

Timing Adjustment for Bank 5 (0° Clock) Register

(address = 0x152) [reset = Undefined]

0x153

Undefined

B5_TIME_90

RESERVED

Timing Adjustment for Bank 5 (–90°

Clock) Register

Timing Adjustment for Bank 5 (–90° Clock) Register

(address = 0x153) [reset = Undefined]

0x154-0x15F

RESERVED

—

7.6.1.6.1 Timing Adjustment for Bank 0 (0° Clock) Register (address = 0x102) [reset = Undefined]

Figure 118. Timing Adjustment for Bank 0 (0° Clock) Register (B0_TIME_0)

7

6

5

4

3

2

1

0

B0_TIME_0

R/W

Table 76. B0_TIME_0 Field Descriptions

Bit

Field

Type

Reset

Description

7-0

B0_TIME_0

R/W

Undefined Time adjustment for bank 0 (applied when the ADC is configured

for 0° clock phase). After reset, the factory-trimmed value can be

read and adjusted as required.

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7.6.1.6.2 Timing Adjustment for Bank 0 (–90° Clock) Register (address = 0x103) [reset = Undefined]

Figure 119. Timing Adjustment for Bank 0 (–90° Clock) Register (B0_TIME_90)

7

6

5

4

3

2

1

0

B0_TIME_90

R/W

Table 77. B0_TIME_90 Field Descriptions

Bit

Field

B0_TIME_90

Type

Reset

Description

7-0

R/W

Undefined Time adjustment for bank 0 (applied when the ADC is configured

for –90° clock phase). After reset, the factory-trimmed value can

be read and adjusted as required.

7.6.1.6.3 Timing Adjustment for Bank 1 (0° Clock) Register (address = 0x112) [reset = Undefined]

Figure 120. Timing Adjustment for Bank 1 (0° Clock) Register (B1_TIME_0)

7

6

5

4

3

2

1

0

B1_TIME_0

R/W

Table 78. B1_TIME_0 Field Descriptions

Bit

Field

Type

Reset

Description

7-0

B1_TIME_0

R/W

Undefined Time adjustment for bank 1 (applied when the ADC is configured

for 0° clock phase). After reset, the factory-trimmed value can be

read and adjusted as required.

7.6.1.6.4 Timing Adjustment for Bank 1 (–90° Clock) Register (address = 0x113) [reset = Undefined]

Figure 121. Timing Adjustment for Bank 1 (–90° Clock) Register (B1_TIME_90)

7

6

5

4

3

2

1

0

B1_TIME_90

R/W

Table 79. B1_TIME_90 Field Descriptions

Bit

Field

B1_TIME_90

Type

Reset

Description

7-0

R/W

Undefined Time adjustment for bank 1 (applied when the ADC is configured

for –90° clock phase). After reset, the factory-trimmed value can

be read and adjusted as required.

7.6.1.6.5 Timing Adjustment for Bank 2 (0° Clock) Register (address = 0x122) [reset = Undefined]

Figure 122. Timing Adjustment for Bank 2 (0° Clock) Register (B2_TIME_0)

7

6

5

4

3

2

1

0

B2_TIME_0

R/W

Table 80. B2_TIME_0 Field Descriptions

Bit

Field

Type

Reset

Description

7-0

B2_TIME_0

R/W

Undefined Time adjustment for bank 2 (applied when the ADC is configured

for 0° clock phase). After reset, the factory-trimmed value can be

read and adjusted as required.

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7.6.1.6.6 Timing Adjustment for Bank 2 (–90° Clock) Register (address = 0x123) [reset = Undefined]

Figure 123. Timing Adjustment for Bank 2 (–90° Clock) Register (B2_TIME_90)

7

6

5

4

3

2

1

0

B2_TIME_90

R/W

Table 81. B2_TIME_90 Field Descriptions

Bit

Field

B2_TIME_90

Type

Reset

Description

7-0

R/W

Undefined Time adjustment for bank 2 (applied when the ADC is configured

for –90° clock phase). After reset, the factory-trimmed value can

be read and adjusted as required.

7.6.1.6.7 Timing Adjustment for Bank 3 (0° Clock) Register (address = 0x132) [reset = Undefined]

Figure 124. Timing Adjustment for Bank 3 (0° Clock) Register (B3_TIME_0)

7

6

5

4

3

2

1

0

B3_TIME_0

R/W

Table 82. B3_TIME_0 Field Descriptions

Bit

Field

Type

Reset

Description

7-0

B3_TIME_0

R/W

Undefined Time adjustment for bank 3 (applied when the ADC is configured

for 0° clock phase). After reset, the factory-trimmed value can be

read and adjusted as required.

7.6.1.6.8 Timing Adjustment for Bank 3 (–90° Clock) Register (address = 0x133) [reset = Undefined]

Figure 125. Timing Adjustment for Bank 3 (–90° Clock) Register (B3_TIME_90)

7

6

5

4

3

2

1

0

B3_TIME_90

R/W

Table 83. B3_TIME_90 Field Descriptions

Bit

Field

B3_TIME_90

Type

Reset

Description

7-0

R/W

Undefined Time adjustment for bank 3 (applied when the ADC is configured

for –90° clock phase). After reset, the factory-trimmed value can

be read and adjusted as required.

7.6.1.6.9 Timing Adjustment for Bank 4 (0° Clock) Register (address = 0x142) [reset = Undefined]

Figure 126. Timing Adjustment for Bank 4 (0° Clock) Register (B4_TIME_0)

7

6

5

4

3

2

1

0

B4_TIME_0

R/W

Table 84. B4_TIME_0 Field Descriptions

Bit

Field

Type

Reset

Description

7-0

B4_TIME_0

R/W

Undefined Time adjustment for bank 4 (applied when the ADC is configured

for 0° clock phase). After reset, the factory-trimmed value can be

read and adjusted as required.

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7.6.1.6.10 Timing Adjustment for Bank 4 (–90° Clock) Register (address = 0x143) [reset = Undefined]

Figure 127. Timing Adjustment for Bank 4 (–90° Clock) Register (B4_TIME_90)

7

6

5

4

3

2

1

0

B4_TIME_90

R/W

Table 85. B4_TIME_90 Field Descriptions

Bit

Field

B4_TIME_90

Type

Reset

Description

7-0

R/W

Undefined Time adjustment for bank 4 (applied when the ADC is configured

for –90° clock phase). After reset, the factory-trimmed value can

be read and adjusted as required.

7.6.1.6.11 Timing Adjustment for Bank 5 (0° Clock) Register (address = 0x152) [reset = Undefined]

Figure 128. Timing Adjustment for Bank 5 (0° Clock) Register (B5_TIME_0)

7

6

5

4

3

2

1

0

B5_TIME_0

R/W

Table 86. B5_TIME_0 Field Descriptions

Bit

Field

Type

Reset

Description

7-0

B5_TIME_0

R/W

Undefined Time adjustment for bank 5 (applied when the ADC is configured

for 0° clock phase). After reset, the factory-trimmed value can be

read and adjusted as required.

7.6.1.6.12 Timing Adjustment for Bank 5 (–90° Clock) Register (address = 0x153) [reset = Undefined]

Figure 129. Timing Adjustment for Bank 5 (–90° Clock) Register (B5_TIME_90)

7

6

5

4

3

2

1

0

B5_TIME_90

R/W

Table 87. B5_TIME_90 Field Descriptions

Bit

Field

B5_TIME_90

Type

Reset

Description

7-0

R/W

Undefined Time adjustment for bank 5 (applied when the ADC is configured

for –90° clock phase). After reset, the factory-trimmed value can

be read and adjusted as required.

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7.6.1.7 LSB Control Registers (0x160 to 0x1FF)

Table 88. LSB Control Registers

ADDRESS

RESET

ACRONYM

REGISTER NAME

SECTION

0x160

0x00

ENC_LSB

LSB Control Bit Output Register

LSB Control Bit Output Register (address = 0x160) [reset

= 0x00]

0x161-0x1FF

Undefined

RESERVED

—

7.6.1.7.1 LSB Control Bit Output Register (address = 0x160) [reset = 0x00]

Figure 130. LSB Control Bit Output Register (ENC_LSB)

7

6

5

4

3

2

1

0

RESERVED

R/W-0000 000

TIMESTAMP_EN

R/W-0

Table 89. ENC_LSB Field Descriptions

Bit

Field

Type

R/W

Reset

Description

7-1

0

RESERVED

0000 000 RESERVED

TIMESTAMP_EN

0

When set, the transport layer transmits the timestamp signal on

the LSB of the output samples. TIMESTAMP_EN has priority

over CAL_STATE_EN. TMSTP_RECV_EN must also be set

high when using timestamp. The latency of the timestamp signal

(through the entire device) matches the latency of the analog

ADC inputs.

The control bit enabled by this register is never advertised in the

ILA (the CS field is 0 in the ILA).

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7.6.1.8 JESD204B Registers (0x200 to 0x20F)

Table 90. JESD204B Registers

ADDRESS

RESET

ACRONYM

REGISTER NAME

SECTION

0x200

0x01

JESD_EN

JESD204B Enable Register

JESD204B Enable Register (address = 0x200) [reset =

0x01]

0x201

0x202

0x02

0x1F

JMODE

KM1

JESD204B Mode Register

JESD204B Mode Register (address = 0x201) [reset =

0x02]

JESD204B K Parameter Register

JESD204B K Parameter Register (address = 0x202)

[reset = 0x1F]

0x203

0x01

JSYNC_N

JCTRL

JESD204B Manual SYNC Request

Register

JESD204B Manual SYNC Request Register (address =

0x203) [reset = 0x01]

0x204

0x02

JESD204B Control Register

JESD204B Control Register (address = 0x204) [reset =

0x02]

0x205

0x00

JTEST

JESD204B Test Pattern Control

Register

JESD204B Test Pattern Control Register (address =

0x205) [reset = 0x00]

0x206

0x00

DID

JESD204B DID Parameter Register

JESD204B DID Parameter Register (address = 0x206)

[reset = 0x00]

0x207

0x00

FCHAR

JESD204B Frame Character

Register

JESD204B Frame Character Register (address = 0x207)

[reset = 0x00]

0x208

Undefined

0x00

JESD_STATUS

PD_CH

JESD204B, System Status Register

JESD204B, System Status Register (address = 0x208)

[reset = Undefined]

0x209

JESD204B Channel Power-Down

JESD204B Channel Power-Down Register (address =

0x209) [reset = 0x00]

0x20A

0x00

JEXTRA_A

JEXTRA_B

RESERVED

JESD204B Extra Lane Enable (Link

A)

JESD204B Extra Lane Enable (Link A) Register (address

= 0x20A) [reset = 0x00]

0x20B

0x00

JESD204B Extra Lane Enable (Link

B)

JESD204B Extra Lane Enable (Link B) Register (address

= 0x20B) [reset = 0x00]

0x20C-0x210

Undefined

RESERVED

—

7.6.1.8.1 JESD204B Enable Register (address = 0x200) [reset = 0x01]

Figure 131. JESD204B Enable Register (JESD_EN)

7

6

5

4

3

2

1

0

RESERVED

JESD_EN

R/W-1

R/W-0000 000

Table 91. JESD_EN Field Descriptions

Bit

7-1

0

Field

Type

R/W

Reset

0000 000 RESERVED

0 : Disables JESD204B interface

1 : Enables JESD204B interface

Description

RESERVED

JESD_EN

1

Before altering other JESD204B registers, JESD_EN must be

cleared. When JESD_EN is 0, the block is held in reset and the

serializers are powered down. The clocks are gated off to save

power. The LMFC counter is also held in reset, so SYSREF

does not align the LMFC.

Always set CAL_EN before setting JESD_EN.

Always clear JESD_EN before clearing CAL_EN.

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7.6.1.8.2 JESD204B Mode Register (address = 0x201) [reset = 0x02]

Figure 132. JESD204B Mode Register (JMODE)

7

6

5

4

3

2

1

0

RESERVED

R/W-000

JMODE

R/W-0001 0

Table 92. JMODE Field Descriptions

Bit

7-5

4-0

Field

Type

R/W

Reset

000

Description

RESERVED

JMODE

RESERVED

0001 0

Specify the JESD204B output mode.

Only change this register when JESD_EN = 0 and CAL_EN = 0.

7.6.1.8.3 JESD204B K Parameter Register (address = 0x202) [reset = 0x1F]

Figure 133. JESD204B K Parameter Register (KM1)

7

6

5

4

3

2

1

0

RESERVED

R/W-000

KM1

R/W-1111 1

Table 93. KM1 Field Descriptions

Bit

7-5

4-0

Field

Type

R/W

Reset

000

Description

RESERVED

KM1

RESERVED

1111 1

K is the number of frames per multiframe and this register must

be programmed as K-1. Depending on the JMODE setting, there

are constraints on the legal values of K. (default: KM1 = 31, K =

32).

Only change this register when JESD_EN is 0.

7.6.1.8.4 JESD204B Manual SYNC Request Register (address = 0x203) [reset = 0x01]

Figure 134. JESD204B Manual SYNC Request Register (JSYNC_N)

7

6

5

4

3

2

1

0

RESERVED

R/W-0000 000

JSYNC_N

R/W-1

Table 94. JSYNC_N Field Descriptions

Bit

7-1

0

Field

Type

R/W

Reset

Description

RESERVED

JSYNC_N

0000 000 RESERVED

1

Set this bit to 0 to request JESD204B synchronization

(equivalent to the SYNCSE pin being asserted). For normal

operation, leave this bit set to 1.

The JSYNC_N register can always generate a synchronization

request, regardless of the SYNC_SEL register. However, if the

selected sync pin is stuck low, the synchronization request

cannot be de-asserted unless SYNC_SEL = 2 is programmed.

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7.6.1.8.5 JESD204B Control Register (address = 0x204) [reset = 0x02]

Figure 135. JESD204B Control Register (JCTRL)

7

6

5

4

3

2

1

0

RESERVED

R/W-0000

SYNC_SEL

R/W-00

SFORMAT

R/W-1

SCR

R/W-0

Table 95. JCTRL Field Descriptions

Bit

7-4

3-2

Field

Type

R/W

Reset

0000

00

Description

RESERVED

SYNC_SEL

RESERVED

0: Use the SYNCSE input for the SYNC~ function (default)

1: Use the TMSTP± differential input for the SYNC~ function;

TMSTP_RECV_EN must also be set

2: Do not use any sync input signal (use software SYNC~

through JSYNC_N)

1

0

SFORMAT

SCR

R/W

1

0

Output sample format for JESD204B samples.

0: Offset binary

1: Signed 2’s complement (default)

0: Scrambler disabled (default)

1: Scrambler enabled

Only change this register when JESD_EN is 0.

7.6.1.8.6 JESD204B Test Pattern Control Register (address = 0x205) [reset = 0x00]

Figure 136. JESD204B Test Pattern Control Register (JTEST)

7

6

5

4

3

2

1

0

RESERVED

R/W-0000

JTEST

R/W-0000

Table 96. JTEST Field Descriptions

Bit

7-4

3-0

Field

Type

R/W

Reset

0000

Description

RESERVED

JTEST

RESERVED

0: Test mode disabled; normal operation (default)

1: PRBS7 test mode

2: PRBS15 test mode

3: PRBS23 test mode

4: Ramp test mode

5: Transport layer test mode

6: D21.5 test mode

7: K28.5 test mode

8: Repeated ILA test mode

9: Modified RPAT test mode

10: Serial outputs held low

11: Serial outputs held high

12–15: Reserved

Only change this register when JESD_EN is 0.

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7.6.1.8.7 JESD204B DID Parameter Register (address = 0x206) [reset = 0x00]

Figure 137. JESD204B DID Parameter Register (DID)

7

6

5

4

3

2

1

0

DID

R/W-0000 0000

Table 97. DID Field Descriptions

Bit

Field

Type

Reset

Description

7-0

DID

R/W

0000 0000 Specifies the device ID (DID) value that is transmitted during the

second multiframe of the JESD204B ILA. Link A transmits DID,

and link B transmits DID+1. Bit 0 is ignored and always returns 0

(if an odd number is programmed, that number is decremented

to an even number).

Only change this register when JESD_EN is 0.

7.6.1.8.8 JESD204B Frame Character Register (address = 0x207) [reset = 0x00]

Figure 138. JESD204B Frame Character Register (FCHAR)

7

6

5

4

3

2

1

0

RESERVED

R/W-0000 00

FCHAR

R/W-00

Table 98. FCHAR Field Descriptions

Bit

7-2

1-0

Field

Type

R/W

Reset

0000 00

00

Description

RESERVED

FCHAR

RESERVED

Specify which comma character is used to denote end-of-frame.

This character is transmitted opportunistically (see the Frame

and Multiframe Monitoring section).

0: Use K28.7 (default, JESD204B compliant)

1: Use K28.1 (not JESD204B compliant)

2: Use K28.5 (not JESD204B compliant)

3: Reserved

When using a JESD204B receiver, always use FCHAR = 0.

When using a general-purpose 8b, 10b receiver, the K28.7

character may cause issues. When K28.7 is combined with

certain data characters, a false, misaligned comma character

can result, and some receivers realign to the false comma. To

avoid this condition, program FCHAR to 1 or 2.

Only change this register when JESD_EN is 0.

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7.6.1.8.9 JESD204B, System Status Register (address = 0x208) [reset = Undefined]

Figure 139. JESD204B, System Status Register (JESD_STATUS)

7

RESERVED

R

6

LINK_UP

R

5

4

3

2

1

0

RESERVED

R

SYNC_STATUS

R

REALIGNED

R/W

ALIGNED

R/W

PLL_LOCKED

R

Table 99. JESD_STATUS Field Descriptions

Bit

7

Field

Type

R

Reset

Description

RESERVED

LINK_UP

Undefined RESERVED

6

R

Undefined When set, this bit indicates that the JESD204B link is up.

5

SYNC_STATUS

REALIGNED

ALIGNED

R

Undefined Returns the state of the JESD204B SYNC~ signal.

0: SYNC~ asserted

1: SYNC~ de-asserted

4

3

R/W

Undefined When high, this bit indicates that an internal digital clock, frame

clock, or multiframe (LMFC) clock phase was realigned by

SYSREF. Write a 1 to clear this bit.

Undefined When high, this bit indicates that the multiframe (LMFC) clock

phase has been established by SYSREF. The first SYSREF

event after enabling the JESD204B encoder will set this bit.

Write a 1 to clear this bit.

2

PLL_LOCKED

RESERVED

R

Undefined When high, this bit indicates that the PLL is locked.

Undefined RESERVED

1-0

7.6.1.8.10 JESD204B Channel Power-Down Register (address = 0x209) [reset = 0x00]

Figure 140. JESD204B Channel Power-Down Register (PD_CH)

7

6

5

4

3

2

1

0

RESERVED

R/W-0000 00

PD_BCH

R/W-0

PD_ACH

R/W-0

Table 100. PD_CH Field Descriptions

Bit

7-2

1

Field

Type

R/W

Reset

0000 00

0

Description

RESERVED

PD_BCH

RESERVED

When set, the B ADC channel is powered down. The ADC

channel B SerDes lanes are also powered down when PD_BCH

is set.

Important notes:

Set JESD_EN = 0 before changing PD_CH.

To power-down both ADC channels, use MODE.

If both channels are powered down, then the entire JESD204B

subsystem (including the PLL and LMFC) are powered down

If the selected JESD204B mode transmits A and B data on link

A, and the B digital channel is disabled, link A remains

operational, but the B-channel samples are undefined.

0

PD_ACH

R/W

0

When set, the A ADC channel is powered down. The ADC

channel A SerDes lanes are also powered down when PD_ACH

is set.

Important notes:

Set JESD_EN = 0 before changing PD_CH.

To power-down both ADC channels, use MODE.

If both channels are powered down, then the entire JESD204B

subsystem (including the PLL and LMFC) are powered down

If the selected JESD204B mode transmits A and B data on link

A, and the B digital channel is disabled, link A remains

operational, but the B-channel samples are undefined.

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7.6.1.8.11 JESD204B Extra Lane Enable (Link A) Register (address = 0x20A) [reset = 0x00]

Figure 141. JESD204B Extra Lane Enable (Link A) Register (JEXTRA_A)

7

6

5

4

3

2

1

0

EXTRA_LANE_A

R/W-0000 000

EXTRA_SER_A

R/W-0

Table 101. JESD204B Extra Lane Enable (Link A) Field Descriptions

Bit

Field

Type

Reset

Description

7-1

EXTRA_LANE_A

R/W

0000 000 Program these register bits to enable extra lanes (even if the

selected JMODE does not require the lanes to be enabled).

EXTRA_LANE_A(n) enables An (n = 1 to 7). This register

enables the link layer clocks for the affected lanes. To also

enable the extra serializes set EXTRA_SER_A = 1.

0

EXTRA_SER_A

R/W

0

0: Only the link layer clocks for extra lanes are enabled.

1: Serializers for extra lanes are also enabled. Use this mode to

transmit data from the extra lanes.

Important notes:

Only change this register when JESD_EN = 0.

The bit-rate and mode of the extra lanes are set by the JMODE

and JTEST parameters.

This register does not override the PD_CH register, so ensure

that the link is enabled to use this feature.

To enable serializer n, the lower number lanes 0 to n-1 must

also be enabled, otherwise serializer n does not receive a clock.

7.6.1.8.12 JESD204B Extra Lane Enable (Link B) Register (address = 0x20B) [reset = 0x00]

Figure 142. JESD204B Extra Lane Enable (Link B) Register (JEXTRA_B)

7

6

5

4

3

2

1

0

EXTRA_LANE_B

R/W-0000 000

EXTRA_SER_B

R/W-0

Table 102. JESD204B Extra Lane Enable (Link B) Field Descriptions

Bit

Field

Type

Reset

Description

7-1

EXTRA_LANE_B

R/W

0000 000 Program these register bits to enable extra lanes (even if the

selected JMODE does not require the lanes to be enabled).

EXTRA_LANE_B(n) enables Bn (n = 1 to 7). This register

enables the link layer clocks for the affected lanes. To also

enable the extra serializes set EXTRA_SER_B = 1.

0

EXTRA_SER_B

R/W

0

0: Only the link layer clocks for extra lanes are enabled.

1: Serializers for extra lanes are also enabled. Use this mode to

transmit data from the extra lanes.

Important notes:

Only change this register when JESD_EN = 0.

The bit-rate and mode of the extra lanes are set by the JMODE

and JTEST parameters.

This register does not override the PD_CH register, so ensure

that the link is enabled to use this feature.

To enable serializer n, the lower number lanes 0 to n-1 must

also be enabled, otherwise serializer n does not receive a clock.

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7.6.1.9 Digital Down Converter Registers (0x210-0x2AF)

Table 103. Overrange Registers

ADDRESS

RESET

ACRONYM

REGISTER NAME

Overrange Threshold 0 Register

SECTION

0x211

0xF2

OVR_T0

Overrange Threshold 0 Register (address = 0x211) [reset

= 0xF2]

0x212

0x213

0xAB

0x07

OVR_T1

Overrange Threshold 1 Register

Overrange Configuration Register

Overrange Threshold 1 Register (address = 0x212) [reset

= 0xAB]

OVR_CFG

Overrange Configuration Register (address = 0x213)

[reset = 0x07]

0x214-0x296

0x297

Undefined

RESERVED

SPIN_ID

RESERVED

—

Spin Identification Value

Spin Identification Register (address = 0x297) [reset =

Undefined]

0x298-0x2AF

Undefined

RESERVED

—

7.6.1.9.1 Overrange Threshold 0 Register (address = 0x211) [reset = 0xF2]

Figure 143. Overrange Threshold 0 Register (OVR_T0)

7

6

5

4

3

2

1

0

OVR_T0

R/W-1111 0010

Table 104. OVR_T0 Field Descriptions

Bit

Field

Type

Reset

Description

7-0

OVR_T0

R/W

1111 0010 Overrange threshold 0. This parameter defines the absolute

sample level that causes control bit 0 to be set. The detection

level in dBFS (peak) is:

20_log10(OVR_T0 / 256)

Default: 0xF2 = 242 → –0.5 dBFS.

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7.6.1.9.2 Overrange Threshold 1 Register (address = 0x212) [reset = 0xAB]

Figure 144. Overrange Threshold 1 Register (OVR_T1)

7

6

5

4

3

2

1

0

OVR_T1

R/W-1010 1011

Table 105. OVR_T1 Field Descriptions

Bit

Field

Type

Reset

Description

7-0

OVR_T1

R/W

1010 1011 Overrange threshold 1. This parameter defines the absolute

sample level that causes control bit 1 to be set. The detection

level in dBFS (peak) is:

20_log10(OVR_T1 / 256)

Default: 0xAB = 171 → –3.5 dBFS.

7.6.1.9.3 Overrange Configuration Register (address = 0x213) [reset = 0x07]

Figure 145. Overrange Configuration Register (OVR_CFG)

7

6

5

4

3

2

1

0

RESERVED

R/W-0000

OVR_EN

R/W-0

OVR_N

R/W-111

Table 106. OVR_CFG Field Descriptions

Bit

7-4

3

Field

Type

R/W

Reset

0000 0

0

Description

RESERVED

OVR_EN

RESERVED

Enables overrange status output pins when set high. The ORA0,

ORA1, ORB0, and ORB1 outputs are held low when OVR_EN is

set low. This register only effects the overrange output pins

(ORxx) and not the overrange status embedded in the data

samples.

2-0

OVR_N⁽¹⁾

R/W

111

Program this register to adjust the pulse extension for the ORA0,

ORA1 and ORB0, ORB1 outputs. The minimum pulse duration

of the overrange outputs is 8 × 2^OVR_NDEVCLK cycles.

Incrementing this field doubles the monitoring period.

(1) Changing the OVR_N setting while JESD_EN=1 may cause the phase of the monitoring period to change.

7.6.1.10 Spin Identification Register (address = 0x297) [reset = Undefined]

Figure 146. Spin Identification Register (SPIN_ID)

7

6

5

4

3

2

SPIN_ID

R

1

0

RESERVED

R-000

Table 107. SPIN_ID Field Descriptions

Bit

7-5

4-0

Field

Type

R

Reset

000

2

Description

RESERVED

SPIN_ID

RESERVED

R

Spin identification value.

2 : ADC08DJ3200

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7.6.2 SYSREF Calibration Registers (0x2B0 to 0x2BF)

Table 108. SYSREF Calibration Registers

ADDRESS

RESET

ACRONYM

REGISTER NAME

SECTION

0x2B0

0x00

SRC_EN

SYSREF Calibration Enable Register

SYSREF Calibration Enable Register (address = 0x2B0)

[reset = 0x00]

0x2B1

0x05

Undefined

0x00

SRC_CFG

SRC_STATUS

TAD

SYSREF Calibration Configuration

Register

SYSREF Calibration Configuration Register (address =

0x2B1) [reset = 0x05]

0x2B2-0x2B4

0x2B5-0x2B7

0x2B8

SYSREF Calibration Status

SYSREF Calibration Status Register (address = 0x2B2 to

0x2B4) [reset = Undefined]

DEVCLK Aperture Delay Adjustment

Register

DEVCLK Aperture Delay Adjustment Register (address =

0x2B5 to 0x2B7) [reset = 0x000000]

0x00

TAD_RAMP

RESERVED

DEVCLK Timing Adjust Ramp

Control Register

DEVCLK Timing Adjust Ramp Control Register (address

= 0x2B8) [reset = 0x00]

0x2B9-0x2BF

Undefined

RESERVED

—

7.6.2.1 SYSREF Calibration Enable Register (address = 0x2B0) [reset = 0x00]

Figure 147. SYSREF Calibration Enable Register (SRC_EN)

7

6

5

4

3

2

1

0

RESERVED

R/W-0000 000

SRC_EN

R/W-0

Table 109. SRC_EN Field Descriptions

Bit

7-1

0

Field

Type

R/W

Reset

Description

RESERVED

SRC_EN

0000 000 RESERVED

0

0: SYSREF calibration disabled; use the TAD register to

manually control the TAD[16:0] output and adjust the DEVCLK

delay (default)

1: SYSREF calibration enabled; the DEVCLK delay is

automatically calibrated; the TAD register is ignored

A 0-to-1 transition on SRC_EN starts the SYSREF calibration

sequence. Program SRC_CFG before setting SRC_EN. Ensure

that ADC calibration is not currently running before setting

SRC_EN.

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7.6.2.2 SYSREF Calibration Configuration Register (address = 0x2B1) [reset = 0x05]

Figure 148. SYSREF Calibration Configuration Register (SRC_CFG)

7

6

5

4

3

2

1

0

RESERVED

R/W-0000

SRC_AVG

R/W-01

SRC_HDUR

R/W-01

Table 110. SRC_CFG Field Descriptions

Bit

7-4

3-2

Field

Type

R/W

Reset

0000 00

01

Description

RESERVED

SRC_AVG

RESERVED

Specifies the amount of averaging used for SYSREF calibration.

Larger values increase calibration time and reduce the variance

of the calibrated value.

0: 4 averages

1: 16 averages

2: 64 averages

3: 256 averages

1-0

SRC_HDUR

R/W

01

Specifies the duration of each high-speed accumulation for

SYSREF Calibration. If the SYSREF period exceeds the

supported value, the calibration fails. Larger values increase

calibration time and support longer SYSREF periods. For a

given SYSREF period, larger values also reduce the variance of

the calibrated value.

0: 4 cycles per accumulation, max SYSREF period of 85

DEVCLK cycles

1: 16 cycles per accumulation, max SYSREF period of 1100

DEVCLK cycles

2: 64 cycles per accumulation, max SYSREF period of 5200

DEVCLK cycles

3: 256 cycles per accumulation, max SYSREF period of 21580

DEVCLK cycles

Max duration of SYSREF calibration is bounded by:

T_SYSREFCAL(in DEVCLK cycles) = 256 × 19 × 4^{(SRC_AVG +}

SRC_HDUR + 2)

7.6.2.3 SYSREF Calibration Status Register (address = 0x2B2 to 0x2B4) [reset = Undefined]

Figure 149. SYSREF Calibration Status Register (SRC_STATUS)

23

15

7

22

14

6

21

13

5

20

19

18

10

2

17

SRC_DONE

R

16

SRC_TAD[16]

R

RESERVED

R

12

11

9

8

SRC_TAD[15:8]

R

4

3

1

0

SRC_TAD[7:0]

R

Table 111. SRC_STATUS Field Descriptions

Bit

Field

Type

R

Reset

Description

23-18

17

RESERVED

SRC_DONE

Undefined RESERVED

R

Undefined This bit returns a 1 when SRC_EN = 1 and SYSREF calibration

is complete.

16-0

SRC_TAD

R

Undefined This field returns the value for TAD[16:0] computed by the

SYSREF calibration. This field is only valid if SRC_DONE = 1.

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7.6.2.4 DEVCLK Aperture Delay Adjustment Register (address = 0x2B5 to 0x2B7) [reset = 0x000000]

Figure 150. DEVCLK Aperture Delay Adjustment Register (TAD)

23

15

7

22

14

6

21

13

5

20

19

11

18

10

2

17

9

16

RESERVED

R/W-0000 000

TAD_INV

R/W-0

12

8

TAD_COARSE

R/W-0000 0000

4

3

1

0

TAD_FINE

R/W-0000 0000

Table 112. TAD Field Descriptions

Bit

Field

Type

R/W

Reset

0000 000 RESERVED

Invert DEVCLK by setting this bit equal to 1.

Description

23-17

16

RESERVED

TAD_INV

0

15-8

TAD_COARSE

0000 0000 This register controls the DEVCLK aperture delay adjustment

when SRC_EN = 0. Use this register to manually control the

DEVCLK aperture delay when SYSREF calibration is disabled. If

ADC calibration or JESD204B is running, TI recommends

gradually increasing or decreasing this value (1 code at a time)

to avoid clock glitches. See the Switching Characteristics table

for TAD_COARSE resolution.

7-0

TAD_FINE

R/W

0000 0000 See the Switching Characteristics table for TAD_FINE

resolution.

7.6.2.5 DEVCLK Timing Adjust Ramp Control Register (address = 0x2B8) [reset = 0x00]

Figure 151. DEVCLK Timing Adjust Ramp Control Register (TAD_RAMP)

7

6

5

4

3

2

1

0

RESERVED

R/W-0000 00

TAD_RAMP_RATE

R/W-0

TAD_RAMP_EN

R/W-0

Table 113. TAD_RAMP Field Descriptions

Bit

7-2

1

Field

Type

R/W

Reset

0000 00

0

Description

RESERVED

TAD_RAMP_RATE

Specifies the ramp rate for the TAD[15:8] output when the

TAD[15:8] register is written when TAD_RAMP_EN = 1.

0: TAD[15:8] ramps up or down one code per 256 DEVCLK

cycles.

1: TAD[15:8] ramps up or down 4 codes per 256 DEVCLK

cycles.

0

TAD_RAMP_EN

R/W

0

TAD ramp enable. Set this bit if coarse TAD adjustments are

desired to ramp up or down instead of changing abruptly.

0: After writing the TAD[15:8] register the aperture delay is

updated within 1024 DEVCLK cycles

1: After writing the TAD[15:8] register the aperture delay ramps

up or down until the aperture delay matches the TAD[15:8]

register

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7.6.3 Alarm Registers (0x2C0 to 0x2C2)

Table 114. Alarm Registers

ADDRESS

RESET

ACRONYM

REGISTER NAME

SECTION

0x2C0

Undefined

ALARM

Alarm Interrupt Status Register

Alarm Interrupt Register (address = 0x2C0) [reset =

Undefined]

0x2C1

0x2C2

0x1F

ALM_STATUS

ALM_MASK

Alarm Status Register

Alarm Mask Register

Alarm Status Register (address = 0x2C1) [reset = 0x1F]

Alarm Mask Register (address = 0x2C2) [reset = 0x1F]

7.6.3.1 Alarm Interrupt Register (address = 0x2C0) [reset = Undefined]

Figure 152. Alarm Interrupt Register (ALARM)

7

6

5

4

RESERVED

R

3

2

1

0

ALARM

R

Table 115. ALARM Field Descriptions

Bit

7-1

0

Field

Type

R

Reset

Description

RESERVED

ALARM

Undefined RESERVED

R

Undefined This bit returns a 1 whenever any alarm occurs that is

unmasked in the ALM_STATUS register. Use ALM_MASK to

mask (disable) individual alarms. CAL_STATUS_SEL can be

used to drive the ALARM bit onto the CALSTAT output pin to

provide a hardware alarm interrupt signal.

7.6.3.2 Alarm Status Register (address = 0x2C1) [reset = 0x1F]

Figure 153. Alarm Status Register (ALM_STATUS)

7

6

5

4

3

2

1

0

RESERVED

R/W-000

PLL_ALM

R/W-1

LINK_ALM

R/W-1

REALIGNED_ALM

R/W-1

RESERVED

R/W-1

CLK_ALM

R/W-1

Table 116. ALM_STATUS Field Descriptions

Bit

7-5

4

Field

Type

R/W

Reset

000

1

Description

RESERVED

PLL_ALM

RESERVED

PLL lock lost alarm. This bit is set whenever the PLL is not

locked. Write a 1 to clear this bit.

3

2

LINK_ALM

R/W

1

Link alarm. This bit is set whenever the JESD204B link is

enabled, but is not in the DATA_ENC state. Write a 1 to clear

this bit.

REALIGNED_ALM

Realigned alarm. This bit is set whenever SYSREF causes the

internal clocks (including the LMFC) to be realigned. Write a 1 to

clear this bit.

1

0

RESERVED

CLK_ALM

R/W

1

RESERVED

Clock alarm. This bit can be used to detect an upset to the

digital block and JESD204B clocks. This bit is set whenever the

internal clock dividers for the A and B channels do not match.

Write a 1 to clear this bit.

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7.6.3.3 Alarm Mask Register (address = 0x2C2) [reset = 0x1F]

Figure 154. Alarm Mask Register (ALM_MASK)

7

6

5

4

3

2

1

0

MASK_REALIGNED_

ALM

RESERVED

R/W-000

MASK_PLL_ALM

R/W-1

MASK_LINK_ALM

R/W-1

MASK_NCO_ALM

R/W-1

MASK_CLK_ALM

R/W-1

Table 117. ALM_MASK Field Descriptions

Bit

7-5

4

Field

RESERVED

Type

R/W

Reset

000

1

Description

RESERVED

MASK_PLL_ALM

When set, PLL_ALM is masked and does not impact the ALARM

register bit.

3

2

1

0

MASK_LINK_ALM

MASK_REALIGNED_ALM

MASK_NCO_ALM

MASK_CLK_ALM

R/W

1

When set, LINK_ALM is masked and does not impact the

ALARM register bit.

When set, REALIGNED_ALM is masked and does not impact

the ALARM register bit.

When set, NCO_ALM is masked and does not impact the

ALARM register bit.

When set, CLK_ALM is masked and does not impact the

ALARM register bit.

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8 Application and Implementation

注

Information in the following applications sections is not part of the TI component

specification, and TI does not warrant its accuracy or completeness. TI’s customers are

responsible for determining suitability of components for their purposes. Customers should

validate and test their design implementation to confirm system functionality.

8.1 Application Information

The ADC08DJ3200 can be used in a wide range of applications including radar, satellite communications, test

equipment (communications testers and oscilloscopes), and software-defined radios (SDRs). The wide input

bandwidth enables direct RF sampling to at least 8 GHz and the high sampling rate allows signal bandwidths of

greater than 2 GHz. The Typical Applications section describes one configuration that meets the needs of a

number of these applications.

8.2 Typical Applications

8.2.1 Wideband RF Sampling Receiver

Up to 16 Lanes

JESD204B

LNA

Antialias BPF

JESD

204B

ADC A

DDC

SYNC~

LNA

Antialias BPF

JESD

204B

ADC B

DDC

FPGA or ASIC

Clocking

Subsystem

User Control

Logic

SPI

LMK04832

Device Clock

÷

SYSREF

10-MHz

Reference

N÷

R÷

Device Clock

SYSREF

图 155. Typical Configuration for Wideband RF Sampling

8.2.1.1 Design Requirements

8.2.1.1.1 Input Signal Path

Use appropriate band-limiting filters to reject unwanted frequencies in the input signal path.

A 1:2 balun transformer is needed to convert the 50-Ω, single-ended signal to 100-Ω differential for input to the

ADC. The balun outputs can be either AC-coupled, or directly connected to the ADC differential inputs, which are

terminated internally to GND.

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Typical Applications (接下页)

Drivers must be selected to provide any needed signal gain and that have the necessary bandwidth capabilities.

Baluns must be selected to cover the needed frequency range, have a 1:2 impedance ratio, and have acceptable

gain and phase balance over the frequency range of interest. 表 118 lists a number of recommended baluns for

different frequency ranges.

表 118. Recommended Baluns

PART NUMBER

BAL-0009SMG

BAL-0208SMG

TCM2-43X+

MANUFACTURER⁽¹⁾

Marki Microwave

Mini-Circuits

MINIMUM FREQUENCY (MHz) MAXIMUM FREQUENCY (MHz)

0.5

2000

10

9000

8000

4000

3000

TCM2-33WX+

B0430J50100AHF

Mini-Circuits

10

Anaren

400

(1) See the Third-Party Products Disclaimer section.

8.2.1.1.2 Clocking

The ADC08DJ3200 clock inputs must be AC-coupled to the device to ensure rated performance. The clock

source must have extremely low jitter (integrated phase noise) to enable rated performance. Recommended

clock synthesizers include the LMX2594, LMX2592, and LMX2582.

The JESD204B data converter system (ADC plus FPGA) requires additional SYSREF and device clocks. The

LMK04828, LMK04826, and LMK04821 devices are suitable to generate these clocks. Depending on the ADC

clock frequency and jitter requirements, this device may also be used as the system clock synthesizer or as a

device clock and SYSREF distribution device when multiple ADC08DJ3200 devices are used in a system.

8.2.1.2 Detailed Design Procedure

Certain component values used in conjunction with the ADC08DJ3200 must be calculated based on system

parameters. Those items are covered in this section.

8.2.1.2.1 Calculating Values of AC-Coupling Capacitors

AC-coupling capacitors are used in the input CLK± and JESD204B output data pairs. The capacitor values must

be large enough to address the lowest frequency signals of interest, but not so large as to cause excessively

long startup biasing times, or unwanted parasitic inductance.

The minimum capacitor value can be calculated based on the lowest frequency signal that is transferred through

the capacitor. Given a 50-Ω single-ended clock or data path impedance, good practice is to set the capacitor

impedance to be <1 Ω at the lowest frequency of interest. This setting ensures minimal impact on signal level at

that frequency. For the CLK± path, the minimum-rated clock frequency is 800 MHz. Therefore, the minimum

capacitor value can be calculated from:

Z_C= 1/ 2 ´ p ´ ¦

(

´ C

)

CLK

(4)

Setting Z_c= 1 Ω and rearranging gives:

C = 1/ 2 ´ p ´ 800 MHz ´ 1 W = 199 pF

)

(

(5)

Therefore, a capacitance value of at least 199 pF is needed to provide the low-frequency response for the CLK±

path. If the minimum clock frequency is higher than 800 MHz, this calculation can be revisited for that frequency.

Similar calculations can be done for the JESD204B output data capacitors based on the minimum frequency in

that interface. Capacitors must also be selected for good response at high frequencies, and with dimensions that

match the high-frequency signal traces they are connected to. Capacitors of the 0201 size are frequently well

suited to these applications.

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8.2.1.3 Application Curves

The ADC08DJ3200 can be used in a number of different operating modes to suit multiple applications. 图 156 to

图 157 describe operation with a 497.77-MHz input signal in the following configurations:

•

6.4-GSPS, single-input mode, JMODE5

6.4-GSPS, dual-input mode, JMODE7

图 156. FFT for 497.77-MHz Input Signal, 6.4 GSPS,

图 157. FFT for 497.77-MHz Input Signal, 3.2 GSPS,

JMODE5

JMODE7

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8.2.2 Reconfigurable Dual-Channel 2.5-GSPS or Single-Channel 5.0-Gsps Oscilloscope

This section demonstrates the use of the ADC08DJ3200 in a reconfigurable oscilloscope. The oscilloscope can

operate as a dual-channel oscilloscope running at 2.5 GSPS or can be reconfigured through SPI programming

as a single-channel, 5-GSPS oscilloscope. This reconfigurable setup allows users to trade off the number of

channels and the sampling rate of the oscilloscope as needed without changing the hardware. Set the input

bandwidth to the desired maximum signal bandwidth through the use of an antialiasing, low-pass filter. Digital

filtering can then be used to reconfigure the analog bandwidth as required. For instance, the maximum

bandwidth can be set to 1 GHz for use during pulsed transient detection and then reconfigured to 100 MHz

through digital filtering for low-noise, sine-wave observation. 图 158 shows the application block diagram.

Up to 16 Lanes

JESD204B

LMH5401

LMH6401

Antialias LPF

Front Panel

Channel A

Programmable

Termination

JESD

204B

ADC A

DC Offset

Adjustment

DAC

SYNC~

LMH6559

OPA703

DAC8560

LMH6401

LMH5401

Antialias LPF

Front Panel

Channel B

Programmable

Termination

JESD

204B

ADC B

FPGA or ASIC

DC Offset

Adjustment

DAC

Clocking

Subsystem

User Control

Logic

LMH6559

OPA703

DAC8560

SPI

LMK04832

Device Clock

÷

SYSREF

10-MHz

Reference

N÷

R÷

Device Clock

SYSREF

图 158. Typical Configuration for Reconfigurable Oscilloscope

8.2.2.1 Design Requirements

8.2.2.1.1 Input Signal Path

Most oscilloscopes are required to be DC-coupled in order to monitor DC or low-frequency signals. This

requirement forces the design to use DC-coupled, fully differential amplifiers to convert from single-ended

signaling at the front panel to differential signaling at the ADC. This design uses two differential amplifiers. The

first amplifier shown in 图 158 is the LMH5401 that converts from single-ended to differential signaling. The

LMH5401 interfaces with the front panel through a programmable termination network and has an offset

adjustment input. The amplifier has an 8-GHz, gain-bandwidth product that is sufficient to support a 1-GHz

bandwidth oscilloscope. A second amplifier, the LMH6401, comes after the LMH5401 to provide a digitally

programmable gain control for the oscilloscope. The LMH6401 supports a gain range from –6 dB to 26 dB in 1-

dB steps. If gain control is not necessary or is performed in a different location in the signal chain, then this

amplifier can be replaced with a second LMH5401 for additional fixed gain or omitted altogether.

The input of the oscilloscope contains a programmable termination block that is not covered in detail here. This

block enables the front-panel input termination to be programmed. For instance, many oscilloscopes allow the

termination to be programmed as either 50-Ω or 1-MΩ to meet the needs of various applications. A 75-Ω

termination can also be desired to support cable infrastructure use cases. This block can also contain an option

for DC blocking to remove the DC component of the external signal and therefore pass only AC signals.

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A precision DAC is used to configure the offset of the oscilloscope front-end to prevent saturation of the analog

signal chain for input signals containing large DC offsets. The DAC8560 is shown in 图 158 along with signal-

conditioning amplifiers OPA703 and LMH6559. The first differential amplifier, LMH5401, is driven by the front

panel input circuitry on one input, and the DC offset bias on the second input. The impedance of these driving

signals must be matched at DC and over frequency to ensure good even-order harmonic performance in the

single-ended to differential conversion operation. The high bandwidth of the LMH6559 allows the device to

maintain low impedance over a wide frequency range.

An antialiasing, low-pass filter is positioned at the input of the ADC to limit the bandwidth of the input signal into

the ADC. This amplifier also band-limits the front-end noise to prevent aliased noise from degrading the signal-to-

noise ratio of the overall system. Design this filter for the maximum input signal bandwidth specified by the

oscilloscope. The input bandwidth can then be reconfigured through the use of digital filters in the FPGA or ASIC

to limit the oscilloscope input bandwidth to a bandwidth less than the maximum.

8.2.2.1.2 Clocking

The ADC08DJ3200 clock inputs must be AC-coupled to the device to ensure rated performance. The clock

source must have extremely low jitter (integrated phase noise) to enable rated performance. Recommended

clock synthesizers include the LMX2594, LMX2592, and LMX2582.

The JESD204B data converter system (ADC plus FPGA) requires additional SYSREF and device clocks. The

LMK04832, LMK04828, LMK04826, and LMK04821 devices are suitable to generate these clocks. Depending on

the ADC clock frequency and jitter requirements, this device can also be used as the system clock synthesizer or

as a device clock and SYSREF distribution device when multiple ADC08DJ3200 devices are used in a system.

8.2.2.1.3 ADC08DJ3200

The ADC08DJ3200 is ideally suited for oscilloscope applications. The ability to tradeoff channel count and

sampling speed allows designers to build flexible hardware to meet multiple needs. This flexibility saves

development time and cost, allows hardware reuse for various projects and enables software upgrade paths for

additional functionality. The low code-error rate eliminates concerns about undesired time domain glitches or

sparkle codes. This rate makes the ADC08DJ3200 a perfect fit for long-duration transient detection

measurements and reduces the probability of false triggers. The input common-mode voltage of 0 V allows the

driving amplifiers to use equal split power supplies that center the amplifier output common-mode voltage at 0 V

and eliminates the need for common-mode voltage shifting before the ADC inputs. The high input bandwidth of

the ADC08DJ3200 simplifies the design of the driving amplifier circuit and antialiasing, low-pass filter. The use of

dual-edge sampling (DES) in single-channel mode eliminates the need to change the clock frequency when

switching between dual- and single-channel modes and simplifies synchronization by relaxing the setup and hold

timing requirements of SYSREF. The t_ADadjust circuit allows the user to time-align the sampling instances of

multiple ADC08DJ3200 devices.

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8.2.2.2 Application Curves

The following application curves demonstrate performance and results only of the ADC. The amplifier front-end is

not included in these measurements. The following configurations and measurements are shown in 图 159 to 图

165:

•

8-bit, 5-GSPS, single-channel oscilloscope using JMODE4 (4 lanes at 12.5 Gbps)

–

Idle-channel noise (no input)

40-MHz, square-wave time domain

200-MHz, sine-wave time domain

200-MHz, sine-wave frequency domain (FFT)

•

8-bit, 2.5-GSPS, dual-channel oscilloscope using JMODE6 (4 lanes at 12.5 Gbps)

–

Idle-channel noise (no input)

40-MHz, square-wave (channel B) and 200-MHz, sine-wave (channel A) time domain

40-MHz, square-wave (channel B) time domain and 200-MHz, sine-wave (channel A) frequency domain

(FFT)

图 159. Idle-Channel Noise (No Input) for 5-GSPS, Single-

图 160. 40-MHz, Square-Wave Time Domain for 5-GSPS,

Channel Oscilloscope

Single-Channel Oscilloscope

图 161. 200-MHz, Sine-Wave Time Domain for 5-GSPS,

图 162. 200-MHz, Sine-Wave Frequency Domain (FFT) for

Single-Channel Oscilloscope

5-GSPS, Single-Channel Oscilloscope

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图 163. Idle-Channel Noise (No Input) for 2.5-GSPS, Dual-

Channel Oscilloscope

图 164. 200-MHz, Sine-Wave (Channel A) and 40-MHz,

Square-Wave (Channel B) Time Domain for 5-GSPS,

Single-Channel Oscilloscope

图 165. 200-MHz, Sine-Wave (Channel A) Frequency Domain (FFT) and 40-MHz, Square-Wave (Channel B) Time Domain for 5-

GSPS, Single-Channel Oscilloscope

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8.3 Initialization Set Up

The device and JESD204 interface require a specific startup and alignment sequence. The general order of that

sequence is listed in the following steps.

1. Power-up or reset the device.

2. Apply a stable device CLK signal at the desired frequency.

3. Program JESD_EN = 0 to stop the JESD204B state machine and allow setting changes.

4. Program CAL_EN = 0 to stop the calibration state machine and allow setting changes.

5. Program the desired JMODE.

6. Program the desired KM1 value. KM1 = K–1.

7. Program SYNC_SEL as needed. Choose SYNCSE or timestamp differential inputs.

8. Configure device calibration settings as desired. Select foreground or background calibration modes and

offset calibration as needed.

9. Program CAL_EN = 1 to enable the calibration state machine.

10. Enable overrange via OVR_EN and adjust settings if desired.

11. Program JESD_EN = 1 to re-start the JESD204B state machine and allow the link to restart.

12. The JESD204B interface operates in response to the applied SYNC signal from the receiver.

13. Program CAL_SOFT_TRIG = 0.

14. Program CAL_SOFT_TRIG = 1 to initiate a calibration.

9 Power Supply Recommendations

The device requires two different power-supply voltages. 1.9 V DC is required for the VA19 power bus and 1.1 V

DC is required for the VA11 and VD11 power buses.

The power-supply voltages must be low noise and provide the needed current to achieve rated device

performance.

There are two recommended power supply architectures:

1. Step down using high-efficiency switching converters, followed by a second stage of regulation to provide

switching noise reduction and improved voltage accuracy.

2. Directly step down the final ADC supply voltage using high-efficiency switching converters. This approach

provides the best efficiency, but care must be taken to ensure switching noise is minimized to prevent

degraded ADC performance.

TI WEBENCH^®Power Designer can be used to select and design the individual power supply elements needed:

see the WEBENCH® Power Designer

Recommended switching regulators for the first stage include the TPS62085, TPS82130, TPS62130A, and

similar devices.

Recommended Low Drop-Out (LDO) linear regulators include the TPS7A7200, TPS74401, and similar devices.

For the switcher only approach, the ripple filter must be designed with a notch frequency that aligns with the

switching ripple frequency of the DC-DC converter. Make a note of the switching frequency reported from

WEBENCH® and design the EMI filter and capacitor combination to have the notch frequency centered as

needed. 图 166 and 图 167 illustrate the two approaches.

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2.2 V

1.9 V

47 ꢀF

VA19

5 V - 12 V

Buck

LDO

FB

47 ꢀF

10 ꢀF 0.1 ꢀF 0.1 ꢀF

+

œ

Power

Good

GND

1.4 V

1.1 V

47 ꢀF

VA11

Buck

LDO

FB

47 ꢀF

10 ꢀF 0.1 ꢀF 0.1 ꢀF

GND

VD11

FB

10 ꢀF 0.1 ꢀF 0.1 ꢀF

GND

NOTE: FB = ferrite bead filter.

图 166. LDO Linear Regulator Approach Example

Ripple Filter

VA19

5 V - 12 V

1.9 V

Buck

FB

10 ꢀF 10 ꢀF 10 ꢀF

10 ꢀF 0.1 ꢀF 0.1 ꢀF

+

œ

Power

Good

GND

Ripple Filter

VA11

1.1 V

Buck

FB

10 ꢀF 10 ꢀF 10 ꢀF

10 ꢀF 0.1 ꢀF 0.1 ꢀF

GND

VD11

FB

10 ꢀF 0.1 ꢀF 0.1 ꢀF

GND

NOTE: Ripple filter notch frequency to match the fs of the buck converter.

NOTE: FB = ferrite bead filter.

图 167. Switcher-Only Approach Example

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9.1 Power Sequencing

The voltage regulators must be sequenced using the power-good outputs and enable inputs to ensure that the

Vx11 regulator is enabled after the VA19 supply is good. Similarly, as soon as the VA19 supply drops out of

regulation on power-down, the Vx11 regulator is disabled.

The general requirement for the ADC is that VA19 ≥ Vx11 during power-up, operation, and power-down.

TI also recommends that VA11 and VD11 are derived from a common 1.1-V regulator. This recommendation

ensures that all 1.1-V blocks are at the same voltage, and no sequencing problems exist between these supplies.

Also use ferrite bead filters to isolate any noise on the VA11 and VD11 buses from affecting each other.

10 Layout

10.1 Layout Guidelines

There are many critical signals that require specific care during board design:

1. Analog input signals

2. CLK and SYSREF

3. JESD204B data outputs:

1. Lower eight pairs operating at up to 12.8 Gbit per second

2. Upper eight pairs operating at up to 6.4 Gbit per second

4. Power connections

5. Ground connections

Items 1, 2, and 3 must be routed for excellent signal quality at high frequencies. Use the following general

practices:

1. Route using loosely coupled 100-Ω differential traces. This routing minimizes impact of corners and length-

matching serpentines on pair impedance.

2. Provide adequate pair-to-pair spacing to minimize crosstalk.

3. Provide adequate ground plane pour spacing to minimize coupling with the high-speed traces.

4. Use smoothly radiused corners. Avoid 45- or 90-degree bends.

5. Incorporate ground plane cutouts at component landing pads to avoid impedance discontinuities at these

locations. Cut-out below the landing pads on one or multiple ground planes to achieve a pad size or stackup

height that achieves the needed 50-Ω, single-ended impedance.

6. Avoid routing traces near irregularities in the reference ground planes. Irregularities include ground plane

clearances associated with power and signal vias and through-hole component leads.

7. Provide symmetrically located ground tie vias adjacent to any high-speed signal vias.

8. When high-speed signals must transition to another layer using vias, transition as far through the board as

possible (top to bottom is best case) to minimize via stubs on top or bottom of the vias. If layer selection is

not flexible, use back-drilled or buried, blind vias to eliminate stubs.

In addition, TI recommends performing signal quality simulations of the critical signal traces before committing to

fabrication. Insertion loss, return loss, and time domain reflectometry (TDR) evaluations should be done.

The power and ground connections for the device are also very important. These rules must be followed:

1. Provide low-resistance connection paths to all power and ground pins.

2. Use multiple power layers if necessary to access all pins.

3. Avoid narrow isolated paths that increase connection resistance.

4. Use a signal, ground, or power circuit board stackup to maximum coupling between the ground and power

planes.

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10.2 Layout Example

图 168 to 图 170 provide examples of the critical traces routed on the device evaluation module (EVM).

图 168. Top Layer Routing: Analog Inputs, CLK and SYSREF, DA0-3, DB0-3

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Layout Example (接下页)

图 169. GND1 Cutouts to Optimize Impedance of Component Pads

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Layout Example (接下页)

图 170. Bottom Layer Routing: Additional CLK Routing, DA4-7, DB4-7

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11 器件和文档支持

11.1 器件支持

11.1.1 第三方产品免责声明

TI 发布的与第三方产品或服务有关的信息，不能构成与此类产品或服务或保修的适用性有关的认可，不能构成此类

产品或服务单独或与任何 TI 产品或服务一起的表示或认可。

11.1.2 开发支持

WEBENCH® 电源设计器

11.2 文档支持

11.2.1 相关文档

请参阅如下相关文档：

•

德州仪器 (TI)，《JESD204B 多器件同步：将要求进行分解》

德州仪器 (TI)，《采用 SMBus 接口和 TruTherm™ 技术的 LM95233 双路远程二极管和本地温度传感器》

德州仪器 (TI)，《提供相位同步功能和 JESD204B 支持的 LMX2594 15GHz 宽带 PLLatinum™ 射频合成器》

德州仪器 (TI)，《具有集成型 VCO 的 LMX2592 高性能宽带 PLLatinum™ 射频合成器》

德州仪器 (TI)，《具有集成型 VCO 的 LMX2582 高性能宽带 PLLatinum™ 射频合成器》

德州仪器 (TI)，《具有双环路 PLL 且符合 JESD204B 标准的 LMK0482x 超低噪声时钟抖动消除器》

德州仪器 (TI)，《采用 2 × 2 QFN 封装且具有断续短路保护功能的 TPS6208x 3A 降压转换器》

德州仪器 (TI)，《具有集成电感器的 TPS82130 17V 输入电压、3A 降压转换器 MicroSiP™ 模块》

德州仪器 (TI)，《采用 3 x 3 QFN 封装的 TPS6213x 3V 至 17V、3A 降压转换器》

德州仪器 (TI)，《TPS7A7200 2A 快速瞬变低压降稳压器》

德州仪器 (TI)，《具有可编程软启动功能的 TPS74401 3.0A 超级 LDO》

德州仪器 (TI)，《采用 ADC12DJ3200 且适用于 L、S、C 和 X 带的直接射频采样雷达接收器参考设计》

德州仪器 (TI)，《ADC12DJ2700 评估模块》用户指南

德州仪器 (TI)，《适用于 DSO、雷达和 5G 无线测试器的多通道 JESD204B 15GHz 时钟参考设计》

德州仪器 (TI)，《LMH5401 8GHz 低噪声、低功耗全差分放大器》

德州仪器 (TI)，《LMH6401 直流至 4.5GHz、全差分数字可变增益放大器》

德州仪器 (TI)，《具有 2.5V、2ppm/°C 内部基准的 DAC8560 16 位、超低干扰、电压输出数模转换器》

德州仪器 (TI)，《OPA70x CMOS 轨至轨 I/O 运算放大器》

德州仪器 (TI)，《LMH6559 高速闭环缓冲器》

德州仪器 (TI)，《具有双环路 PLL 的 LMK04832 超低噪声且符合 JESD204B 标准的时钟抖动清除器》

11.3 接收文档更新通知

要接收文档更新通知，请导航至 ti.com.cn 上的器件产品文件夹。单击右上角的通知我进行注册，即可每周接收产

品信息更改摘要。有关更改的详细信息，请查看任何已修订文档中包含的修订历史记录。

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11.4 支持资源

TI E2E™ support forums are an engineer's go-to source for fast, verified answers and design help — straight

from the experts. Search existing answers or ask your own question to get the quick design help you need.

Linked content is provided "AS IS" by the respective contributors. They do not constitute TI specifications and do

not necessarily reflect TI's views; see TI's Terms of Use.

11.5 商标

E2E is a trademark of Texas Instruments.

WEBENCH is a registered trademark of Texas Instruments.

All other trademarks are the property of their respective owners.

11.6 静电放电警告

这些装置包含有限的内置 ESD 保护。存储或装卸时，应将导线一起截短或将装置放置于导电泡棉中，以防止 MOS 门极遭受静电损

伤。

11.7 Glossary

SLYZ022 — TI Glossary.

This glossary lists and explains terms, acronyms, and definitions.

12 机械、封装和可订购信息

以下页面包含机械、封装和可订购信息。这些信息是指定器件的最新可用数据。数据如有变更，恕不另行通知，且

不会对此文档进行修订。如需获取此数据表的浏览器版本，请查阅左侧的导航栏。

121

PACKAGE OUTLINE

AAV0144A

FCBGA - 1.91 mm max height

SCALE 1.400

BALL GRID ARRAY

10.15

9.85

A

B

BALL A1 CORNER

10.15

9.85

(

8)

(0.67)

1.91

1.70

(0.5)

C

SEATING PLANE

NOTE 4

BALL TYP

0.405

0.325

TYP

0.1 C

8.8 TYP

SYMM

(0.6) TYP

0.8 TYP

M

L

K

J

H

G

F

SYMM

8.8

TYP

E

D

C

B

A

0.51

0.41

144X

0.15

0.08

C A B

NOTE 3

C

1

2

3

4

5

6

7

8

9

10

11

12

0.8 TYP

4219578/C 05/2022

NOTES:

1. All linear dimensions are in millimeters. Any dimensions in parenthesis are for reference only. Dimensioning and tolerancing

per ASME Y14.5M.

2. This drawing is subject to change without notice.

3. Dimension is measured at the maximum solder ball diameter, parallel to primary datum C.

4. Primary datum C and seating plane are defined by the spherical crowns of the solder balls.

www.ti.com

EXAMPLE BOARD LAYOUT

AAV0144A

FCBGA - 1.91 mm max height

BALL GRID ARRAY

(0.8) TYP

1

3

5

6

7

8

9

10 11

4

12

2

A

B

(0.8) TYP

C

D

E

F

144X ( 0.4)

SYMM

G

H

J

K

L

M

SYMM

LAND PATTERN EXAMPLE

EXPOSED METAL SHOWN

SCALE:8X

(

0.4)

0.05 MAX

METAL UNDER

SOLDER MASK

0.05 MIN

METAL

EXPOSED

METAL

EXPOSED

METAL

(

0.4)

SOLDER MASK

OPENING

SOLDER MASK

OPENING

NON-SOLDER MASK

DEFINED

SOLDER MASK

DEFINED

(PREFERRED)

SOLDER MASK DETAILS

NOT TO SCALE

4219578/C 05/2022

NOTES: (continued)

5. Final dimensions may vary due to manufacturing tolerance considerations and also routing constraints.

For more information, see Texas Instruments literature number SPRU811 (www.ti.com/lit/spru811).

www.ti.com

EXAMPLE STENCIL DESIGN

AAV0144A

FCBGA - 1.91 mm max height

BALL GRID ARRAY

(0.8) TYP

144X ( 0.4)

10 11

1

3

5

6

7

8

9

4

12

2

A

B

(0.8) TYP

C

D

E

F

SYMM

G

H

J

K

L

M

SYMM

SOLDER PASTE EXAMPLE

BASED ON 0.15 mm THICK STENCIL

SCALE:8X

4219578/C 05/2022

NOTES: (continued)

6. Laser cutting apertures with trapezoidal walls and rounded corners may offer better paste release.

www.ti.com

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型号：	ADC08DJ3200
厂家：	TEXAS INSTRUMENTS
描述：	8 位双通道 3.2GSPS 或单通道 6.4GSPS 射频采样模数转换器 (ADC) 射频转换器模数转换器
文件：	总128页 (文件大小：2266K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

ADC08DJ3200 [TI]

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