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3 V, Parallel Input

Micropower 10-/12-Bit DACs

AD7392/AD7393

FEATURES

Micropower: 100 μA

0.1 μA typical power shutdown

Single-supply 2.7 V to 5.5 V operation

AD7392: 12-bit resolution

AD7393: 10-bit resolution

0.9 LSB differential nonlinearity error

FUNCTIONAL BLOCK DIAGRAM

AD7392

REF

12-BIT

DAC

DAC REGISTER

DGND CS

D0 TO D11

OUT

SHDN

AGND

01121-001

APPLICATIONS

Automotive 0.5 V to 4.5 V output span voltage

Portable communications

Digitally controlled calibration

PC peripherals

Figure 1.

GENERAL DESCRIPTION

The AD7392/AD7393 comprise a set of pin-compatible

10-/12-bit voltage output, digital-to-analog converters. The

parts are designed to operate from a single 3 V supply. Built

using a CBCMOS process, these monolithic DACs offer low

cost and ease of use in single-supply 3 V systems. Operation is

guaranteed over the supply voltage range of 2.7 V to 5.5 V,

making this device ideal for battery-operated applications.

The full-scale voltage output is determined by the external ref-

erence input voltage applied. The rail-to-rail REF

to DAC

OUT

allows a full-scale voltage equal to the positive supply V

any value in between. The voltage outputs are capable of sourc-

ing 5 mA.

A data latch load of 12 bits with a 45 ns write time eliminates

wait states when interfacing to the fastest processors. Addition-

ally, an asynchronous RS input sets the output to a zero scale at

power-on or upon user demand.

Both parts are offered with similar pinouts, which allows users

to select the amount of resolution appropriate for their applica-

tions without changing the circuit card.

The AD7392/AD7393 are specified for operation over the

extended industrial temperature range of −40°C to +85°C.

The AD7393AR is specified for the automotive temperature

range of −40°C to +125°C. The AD7392/AD7393 are available

in 20-lead PDIP and 20-lead SOIC packages.

For serial data input, 8-lead packaged versions, see the AD7390

and AD7391.

Rev. C

Information furnished by Analog Devices is believed to be accurate and reliable. However, no

responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other

rights of third parties that may result from its use. Specifications subject to change without notice. No

license is granted by implication or otherwise under any patent or patent rights of Analog Devices.

Trademarks and registered trademarks are the property of their respective owners.

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.

Tel: 781.329.4700

www.analog.com

AD7392/AD7393

TABLE OF CONTENTS

Features .............................................................................................. 1

Applications....................................................................................... 1

Functional Block Diagram .............................................................. 1

General Description ......................................................................... 1

Revision History ............................................................................... 2

Specifications..................................................................................... 3

Electrical Characteristics............................................................. 3

Timing Diagram ........................................................................... 5

Absolute Maximum Ratings............................................................ 6

ESD Caution.................................................................................. 6

Pin Configurations and Function Descriptions ........................... 7

Typical Performance Characteristics ............................................. 8

Theory of Operation ...................................................................... 12

Digital-to-Analog Converters................................................... 12

Amplifier Section ....................................................................... 12

Reference Input........................................................................... 12

Power Supply............................................................................... 13

Input Logic Levels ...................................................................... 13

Digital Interface.......................................................................... 13

Reset Pin (RS) ............................................................................. 14

Power Shutdown (SHDN)......................................................... 14

Unipolar Output Operation...................................................... 14

Bipolar Output Operation......................................................... 15

Outline Dimensions ....................................................................... 16

Ordering Guide .......................................................................... 17

REVISION HISTORY

8/07—Rev. B to Rev. C

Changes to Specifications Section.................................................. 3

Changes to Table 3............................................................................ 6

Changes to Theory of Operation Section.................................... 12

Changes to Figure 29...................................................................... 13

Changes to Figure 32...................................................................... 14

Changes to Figure 33...................................................................... 15

Updated Outline Dimensions ....................................................... 16

Changes to Ordering Guide .......................................................... 17

6/04—Changed from Rev. A to Rev. B

Removed TSSOP.................................................................Universal

Changes to Ordering Guide .......................................................... 17

3/99—Changed from Rev. 0 to Rev. A

11/96—Revision 0: Initial Version

Rev. C | Page 2 of 20

AD7392/AD7393

SPECIFICATIONS

ELECTRICAL CHARACTERISTICS

At V

REF

= 2.5 V, −40°C < T

< +85°C, unless otherwise noted.

Table 1. AD7392

Parameter

STATIC PERFORMANCE

Resolution

Relative Accuracy

Differential Nonlinearity

Zero-Scale Error

Full-Scale Voltage Error

Full-Scale Temperature Coefficient

REFERENCE INPUT

REF

Range

Input Resistance

Input Capacitance

ANALOG OUTPUT

Current (Source)

Output Current (Sink)

Capacitive Load

LOGIC INPUTS

Logic Input Low Voltage

Logic Input High Voltage

Input Leakage Current

Input Capacitance

INTERFACE TIMING

3, 5

Chip Select Write Width

Data Setup

Data Hold

Reset Pulse Width

AC CHARACTERISTICS

Output Slew Rate

Settling Time

Shutdown Recovery Time

DAC Glitch

Digital Feedthrough

Feedthrough

SUPPLY CHARACTERISTICS

Power Supply Range

Positive Supply Current

Shutdown Supply Current

Power Dissipation

Power Supply Sensitivity

Symbol

INL

DNL

ZSE

FSE

TCV

REF

OUT

SDR

Conditions

3 V ± 10%

±1.8

±3

±0.9

±1

4.0

8.0

±8

±20

0/V

2.5

5 V ± 10%

±1.8

±3

±0.9

±1

4.0

8.0

±8

±20

0/V

2.5

100

0.8

− 0.6

0.05

−63

Unit

Bits

LSB max

mV max

ppm/°C typ

V min/max

MΩ typ

pF typ

mA typ

pF typ

V max

V min

μA max

pF max

ns min

V/μs typ

μs typ

nV/s typ

dB typ

= +25°C

= −40°C, +85°C

= +25°C, monotonic

Monotonic

Data = 0x000, T

= +25°C, +85°C

Data = 0x000, T

= −40°C

= +25°C, +85°C, data = 0xFFF

= −40°C, data = 0xFFF

Data = 0x800, ∆ V

OUT

= 5 LSB

Data = 0x800, ∆ V

OUT

= 5 LSB

No oscillation

100

0.5

− 0.6

Data = 0x000 to 0xFFF to 0x000

To ±0.1% of full scale

Code 0x7FF to Code 0x800 to Code 0x7FF

0.05

−63

OUT

REF

= 1.5 V dc + 1 V p-p, data = 0x000,

f = 100 kHz

DNL < ±1 LSB

= 0 V, no load

SHDN = 0, V

= 0 V, no load

Δ V

= ±5%

DD RANGE

DD-SD

DISS

PSS

2.7/5.5

55/100

0.1/1.5

300

0.006

2.7/5.5

55/100

0.1/1.5

500

0.006

V min/max

μA typ/max

μW max

%/% max

One LSB = V

REF

/4096 V for the 12-bit AD7392.

The first two codes (0x000, 0x001) are excluded from the linearity error measurement.

These parameters are guaranteed by design and not subject to production testing.

Typicals represent average readings measured at +25°C.

All input control signals are specified with t

= t

= 2 ns (10% to 90% of 13 V) and timed from a voltage level of 1.6 V.

The settling time specification does not apply for negative going transitions within the last 3 LSBs of ground.

Rev. C | Page 3 of 20

AD7392/AD7393

At V

REF

= 2.5 V, −40°C < T

< +85°C, unless otherwise noted.

Table 2. AD7393

Parameter

STATIC PERFORMANCE

Resolution

Relative Accuracy

Differential Nonlinearity

Zero-Scale Error

Full-Scale Voltage Error

Full-Scale Temperature Coefficient

REFERENCE INPUT

REF IN

Range

Input Resistance

Input Capacitance

ANALOG OUTPUT

Output Current (Source)

Output Current (Sink)

Capacitive Load

LOGIC INPUTS

Logic Input Low Voltage

Logic Input High Voltage

Input Leakage Current

Input Capacitance

INTERFACE TIMING

3, 5

Chip Select Write Width

Data Setup

Data Hold

Reset Pulse Width

AC CHARACTERISTICS

Output Slew Rate

Settling Time

Shutdown Recovery Time

DAC Glitch

Digital Feedthrough

Feedthrough

SUPPLY CHARACTERISTICS

Power Supply Range

Positive Supply Current

Shutdown Supply Current

Power Dissipation

Power Supply Sensitivity

Symbol

INL

DNL

ZSE

FSE

TCV

REF

OUT

SDR

Conditions

3 V ± 10%

±1.75

±2.0

±0.8

9.0

±32

±42

0/V

2.5

5 V ± 10%

±1.75

±2.0

±0.8

9.0

±32

±42

0/V

2.5

100

0.8

− 0.6

0.05

−63

2.7/5.5

100

0.1/1.5

500

0.006

Unit

Bits

LSB max

mV max

ppm/°C typ

V min/max

MΩ typ

pF typ

mA typ

pF typ

V max

V min

μA max

pF max

V/μs typ

μs typ

nV/s typ

dB typ

V min/max

μA typ

μA max

μA typ/max

μW max

%/% max

= +25°C

= −40°C, +85°C, +125°C

Monotonic

Data = 0x000

= +25°C, +85°C, +125°C, data = 0x3FF

= −40°C, data = 0x3FF

Data = 0x200, Δ V

OUT

= 5 LSB

Data = 0x200, Δ V

OUT

= 5 LSB

No oscillation

100

0.5

− 0.6

Data = 0x000 to 0x3FF to 0x000

To ±0.1% of full scale

Code 0x7FF to Code 0x800 to Code 0x7FF

0.05

−63

2.7/5.5

100

0.1/1.5

300

0.006

OUT

REF

DD RANGE

DD-SD

DISS

PSS

REF

= 1.5 V dc 11 V p-p, data = 0x000, f = 100 kHz

DNL < ±1 LSB

= 0 V, no load, T

= +25°C

= 0 V, no load

SHDN = 0, V

= 0 V, no load

Δ V

= ±5%

One LSB = V

REF

/1024 V for the 10-bit AD7393.

The first two codes (0x000, 0x001) are excluded from the linearity error measurement.

These parameters are guaranteed by design and not subject to production testing.

Typicals represent average readings measured at +25°C.

All input control signals are specified with t

= t

= 2 ns (10% to 90% of 13 V) and timed from a voltage level of 1.6 V.

The settling time specification does not apply for negative going transitions within the last 3 LSBs of ground.

Rev. C | Page 4 of 20

参数对比

与AD7393AN相近的元器件有：AD7393AR、AD7393AR-REEL、AD7392AN、AD7392ANZ、AD7392AR、AD7392AR-REEL。描述及对比如下：

型号	AD7393AN	AD7393AR	AD7393AR-REEL	AD7392AN	AD7392ANZ	AD7392AR	AD7392AR-REEL
描述	PARALLEL, WORD INPUT LOADING, 70 us SETTLING TIME, 10-BIT DAC, PDIP20, PLASTIC, MS-001, DIP-20	PARALLEL, WORD INPUT LOADING, 70 us SETTLING TIME, 10-BIT DAC, PDSO20, MS-013AC, SOIC-20	PARALLEL, WORD INPUT LOADING, 70us SETTLING TIME, 10-BIT DAC, PDSO20, MS-013AC, SOIC-20	PARALLEL, WORD INPUT LOADING, 70us SETTLING TIME, 12-BIT DAC, PDIP20, PLASTIC, MS-001, DIP-20	PARALLEL, WORD INPUT LOADING, 70 us SETTLING TIME, 12-BIT DAC, PDIP20, ROHS COMPLIANT, PLASTIC, MS-001, DIP-20	PARALLEL, WORD INPUT LOADING, 70 us SETTLING TIME, 12-BIT DAC, PDSO20, MS-013AC, SOIC-20	PARALLEL, WORD INPUT LOADING, 70us SETTLING TIME, 12-BIT DAC, PDSO20, MS-013AC, SOIC-20
是否无铅	含铅	含铅	含铅	含铅	不含铅	含铅	含铅
是否Rohs认证	不符合	不符合	不符合	不符合	符合	不符合	不符合
零件包装代码	DIP	SOIC	SOIC	DIP	DIP	SOIC	SOIC
包装说明	DIP,	SOP,	SOP,	PLASTIC, MS-001, DIP-20	DIP,	SOP,	SOP,
针数	20	20	20	20	20	20	20
Reach Compliance Code	unknown	unknown	unknown	unknown	unknown	unknown	unknown
最大模拟输出电压	5 V	5 V	5 V	5 V	5 V	5 V	5 V
最小模拟输出电压	-5 V	-5 V	-5 V	-5 V	-5 V	-5 V	-5 V
转换器类型	D/A CONVERTER	D/A CONVERTER	D/A CONVERTER	D/A CONVERTER	D/A CONVERTER	D/A CONVERTER	D/A CONVERTER
输入位码	BINARY	BINARY	BINARY	BINARY	BINARY	BINARY	BINARY
输入格式	PARALLEL, WORD	PARALLEL, WORD	PARALLEL, WORD	PARALLEL, WORD	PARALLEL, WORD	PARALLEL, WORD	PARALLEL, WORD
JESD-30 代码	R-PDIP-T20	R-PDSO-G20	R-PDSO-G20	R-PDIP-T20	R-PDIP-T20	R-PDSO-G20	R-PDSO-G20
JESD-609代码	e0	e0	e0	e0	e3	e0	e0
长度	26.16 mm	12.8 mm	12.8 mm	26.16 mm	26.16 mm	12.8 mm	12.8 mm
最大线性误差 (EL)	0.293%	0.1758%	0.1758%	0.0732%	0.0732%	0.0732%	0.0732%
湿度敏感等级	NOT SPECIFIED	3	3	NOT SPECIFIED	NOT SPECIFIED	3	NOT APPLICABLE
位数	10	10	10	12	12	12	12
功能数量	1	1	1	1	1	1	1
端子数量	20	20	20	20	20	20	20
最高工作温度	85 °C	125 °C	125 °C	85 °C	85 °C	85 °C	85 °C
最低工作温度	-40 °C	-40 °C	-40 °C	-40 °C	-40 °C	-40 °C	-40 °C
封装主体材料	PLASTIC/EPOXY	PLASTIC/EPOXY	PLASTIC/EPOXY	PLASTIC/EPOXY	PLASTIC/EPOXY	PLASTIC/EPOXY	PLASTIC/EPOXY
封装代码	DIP	SOP	SOP	DIP	DIP	SOP	SOP
封装形状	RECTANGULAR	RECTANGULAR	RECTANGULAR	RECTANGULAR	RECTANGULAR	RECTANGULAR	RECTANGULAR
封装形式	IN-LINE	SMALL OUTLINE	SMALL OUTLINE	IN-LINE	IN-LINE	SMALL OUTLINE	SMALL OUTLINE
峰值回流温度（摄氏度）	NOT APPLICABLE	240	240	NOT SPECIFIED	NOT SPECIFIED	240	220
认证状态	COMMERCIAL	COMMERCIAL	COMMERCIAL	COMMERCIAL	COMMERCIAL	COMMERCIAL	COMMERCIAL
座面最大高度	5.33 mm	2.65 mm	2.65 mm	5.33 mm	5.33 mm	2.65 mm	2.65 mm
标称安定时间 (tstl)	70 µs	70 µs	70 µs	70 µs	70 µs	70 µs	70 µs
标称供电电压	3 V	3 V	3 V	3 V	3 V	3 V	3 V
表面贴装	NO	YES	YES	NO	NO	YES	YES
技术	BIPOLAR	BIPOLAR	BIPOLAR	BIPOLAR	BIPOLAR	BIPOLAR	BIPOLAR
温度等级	INDUSTRIAL	AUTOMOTIVE	AUTOMOTIVE	INDUSTRIAL	INDUSTRIAL	INDUSTRIAL	INDUSTRIAL
端子面层	TIN LEAD	TIN LEAD	TIN LEAD	TIN LEAD	MATTE TIN	TIN LEAD	TIN LEAD
端子形式	THROUGH-HOLE	GULL WING	GULL WING	THROUGH-HOLE	THROUGH-HOLE	GULL WING	GULL WING
端子节距	2.54 mm	1.27 mm	1.27 mm	2.54 mm	2.54 mm	1.27 mm	1.27 mm
端子位置	DUAL	DUAL	DUAL	DUAL	DUAL	DUAL	DUAL
处于峰值回流温度下的最长时间	NOT APPLICABLE	30	NOT SPECIFIED	NOT SPECIFIED	NOT SPECIFIED	30	30
宽度	7.62 mm	7.5 mm	7.5 mm	7.62 mm	7.62 mm	7.5 mm	7.5 mm
厂商名称	Rochester Electronics	Rochester Electronics	Rochester Electronics	-	-	-	Rochester Electronics
Base Number Matches	1	1	1	1	1	1	-

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ROHM开发出内置步行检测及计步功能的加速度传感器“KX126”

ROHM集团旗下的Kionix, Inc.,（总部位于美国纽约州伊萨卡）开发出非常适用于智能手机和可穿戴式设备的计步器功能的3轴加速度传感器“KX126”。本产品在传感器中内置了步行检测及计步算法，无需再为了计步器功能而单独设计电路，有助于减轻客户的设计负担。另外，利用优化的ROHM独有低功耗算法，新增计步器功能仅需100nA，有助于应用的低功耗化（普通加速度传感器的功耗约为150u...[详细]
一步步写STM32 OS【四】OS基本框架

一、上篇回顾上一篇文章中，我们完成了两个任务使用PendSV实现了互相切换的功能，下面我们接着其思路往下做。这次我们完成OS基本框架，即实现一个非抢占式（已经调度的进程执行完成,然后根据优先级调度等待的进程）的任务调度系统，至于抢占式的，就留给大家思考了。上次代码中Task_Switch实现了两个任务的切换，代码如下： void Task_Switch() { if(g_OS_Tcb_Cu...[详细]
4000亿美元！智能家居或成为下个十年风口

据前瞻产业研究院此前发布的《中国智能家居设备行业市场前瞻与投资策略规划报告》数据显示，2016年，我国智能家居市场规模达605.7亿元，同比增长率50.15%。预计未来几年内智能家居将迎来爆发式增长，到2018年，智能家居市场规模将达1396亿元。　　另外，来自科尔尼管理咨询公司的最新报告预计，到2020年全球智能家居的整体规模将由目前的100亿美元增长至500亿美元，并有望在2030年上...[详细]
技术文章—电路中VCC、VDD、VEE、VSS都是啥意思

DCpower一般是指带实际电压的源，其他的都是标号(在有些仿真软件中默认的把标号和源相连的)VDD:电源电压(单极器件);电源电压(4000系列数字电路);漏极电压(场效应管)VCC：电源电压(双极器件);电源电压(74系列数字电路);声控载波(VoiceControlledCarrier)VSS:地或电源负极VEE：负电压供电;场效应管的源极(S)VPP：编程/擦除电压。 VCC：C=...[详细]
致远电子推出CPT充电桩测试系统

致远电子充电桩测试系统网页正式上线，致远电子旨在推动国内充电桩行业飞速发展，有着多年做桩的经验积累，通过深入挖掘行业痛点，凭借公司在仪器和系统集成领域深厚的积累，推出具有划时代意义的CPT充电桩测试系统，推动国内的充电桩测试水平进入全新的时代，为新能源时代的充电安全保驾护航。认证机构/企业研发型充电桩测试系统如何满足充电桩时代大量认证需求？做好的桩该如何通过认证又如何确保稳定无误地运行？...[详细]
依图科技发明疫情资讯智能交互方案

2020年新冠疫情肆虐全球，对全球的经济和生态都造成了不可估量的影响，而为了让人们可以更好的了解疫情咨询以及相关的知识，不少线上平台都推出了相关内容的查询功能。目前，在利用一些传统技术进行重大传染病疫情信息处理基础上，例如新冠肺炎、鼠疫、高致病流感、埃博拉等重大传染病疫情，在防控工作的实施中常会出现以下问题： 1）在使用传统的搜索引擎了解疫情资讯时，由于检索规则简单，返回的结果并不能准确的匹配...[详细]
二极管用于调频收音机AGC电路

二极管用于调频收音机AGC电路调频收音机中自动增益控制电路的原理和调幅收音机中的相似，但目的有些不同。调频收单机的AGC电路，通常是从中频放大器的某一级取出信号，经过整流变成直流。反馈到高放管的基极，去控制高放管的直流工作点，如果这个包馈的附加偏置电流的方向和高放管原来的直流偏置的方向相反，称为反向AGC，如果相同，则称为正向AGC。图A所示的是反向AGC电路。在无信号时，电阻R1，R...[详细]
瑞和智电荣获“2016年中国充电桩新能源汽车产业推动奖”

　　近日，由工信和信息化部赛迪研究院主办，新能源汽车报社和中国软件测评中心等单位承办的“首届中国充电桩创新峰会”在京隆重召开，工信和信息化部赛迪研究院副院长黄子河、中国电力企业联合会标准化管理中心副主任刘永东、北京新能源汽车发展促进中心主任牛近明等领导出席大会做了精彩的演讲，同期到会的还有企业、研究机构和媒体等各界同仁达370余人。大会为推动新能源汽车行业发展呈现了一场行业交流盛宴。 ...[详细]
智能制造兴起人机合作共融是未来方向

李刚委员。张海峰　摄你听过一场由机器人指挥的交响音乐会吗？你吃过机器人包的饺子吗？这些，ABB 机器人业务中国区总裁李刚都亲身体验过。从无到有，这位新任政协委员亲历机器人行业在中国的兴起和发展。“机器人进入了灿烂的年华。”他说，它方便了我们的衣食住行，也必将助力中国的智能制造。 “我们要留住制造业，向智能制造发展。”今年两会，李刚关注智能制造的话题。在他看来，数字化与智能化是产业升级转型的...[详细]
利用自动化技术赋能中国基础设施现代化

许多中国基础设施和运营（I&O）领导者在实施基础设施现代化项目时，希望利用自动化技术来简化和加快IT基础设施资源的配置、管理和扩展。但是，中国企业的技术团队往往各自为政，而技术专家又倾向于将自动化仅仅视为现有技术的延伸，导致自动化优先任务之间的相互竞争，各团队间的协作受到限制，削弱了自动化对业务结果的改善作用。中国的I&O领导者应通过创建自动化技术的管理框架，在推进基础设施现代化项目的同...[详细]