MAX9951FCCB+,MAX9951FCCB+ pdf中文资料,MAX9951FCCB+引脚图,MAX9951FCCB+电路-Datasheet-电子工程世界

文档预览

MAX9951/MAX9952

Dual Per-Pin Parametric

Measurement Units

General Description

The MAX9951/MAX9952 dual parametric measurement

units (PMUs) feature a small package size, wide force and

measurement range, and high accuracy, making the

devices ideal for automatic test equipment (ATE) and other

instrumentation that requires a PMU per pin or per site.

The MAX9951/MAX9952 force or measure voltages in the

-2V to +7V through -7V to +13V ranges, dependent upon

the supply voltage (V

and V

). The devices handle

supply voltages of up to +30V (V

to V

) and a 20V

device-under-test (DUT) voltage swing at full current. The

MAX9951/MAX9952 also force or measure currents up to

±64mA with a lowest full-scale range of ±2µA. Integrated

support circuitry facilitates use of an external buffer ampli-

fier for current ranges greater than ±64mA.

A voltage proportional to the measured output voltage

or current is provided at the MSR_ output. Integrated

comparators, with externally set voltage thresholds,

provide detection for both voltage and current levels.

The MSR_ and comparator outputs can be placed in a

high-impedance state. Separate FORCE and SENSE

connections are short-circuit protected for voltages

from (V

- 0.3V) to (V

+ 0.3V). The FORCE output

also features a low-leakage, high-impedance state.

Integrated voltage clamps limit the force output to lev-

els set externally. The force-current or the measure-cur-

rent voltage can be offset -0.2V to +4.4V (IOS). This

feature allows for the centering of the control or mea-

sured signal within the external DAC or ADC range.

The MAX9951D/MAX9952D feature an integrated 10kΩ

force-sense resistor between FORCE_ and SENSE_.

The MAX9951F/MAX9952F have no internal force-sense

resistor. These devices are available in a 64-pin, 10mm

x 10mm, 0.5mm pitch TQFP package with an exposed

8mm x 8mm die pad on the top (MAX9951) or the bot-

tom (MAX9952) of the package for efficient heat

removal. The exposed pad is internally connected to

. The MAX9951/MAX9952 are specified over the

commercial 0°C to +70°C temperature range.

Features

Force Voltage/Measure Current (FVMI)

Force Current/Measure Voltage (FIMV)

Force Voltage/Measure Voltage (FVMV)

Force Current/Measure Current (FIMI)

Force Nothing/Measure Voltage (FNMV)

Force Nothing/Measure Current (FNMI,

Range E Only)

Termination/Measure Current

Termination/Measure Voltage

Five Programmable Current Ranges

±2µA

±20µA

±200µA

±2mA

±64mA

-2V to +7V Through -7V to +13V Input-Voltage

Range

Force-Current/Measure-Current Adjustable-

Voltage Offset (IOS)

Programmable Voltage Clamps at Force Output

Low-Leakage, High-Impedance Measure, and

Force States

3-Wire Serial Interface

Low 6mA (max) Quiescent Current per PMU

Ordering Information

PART

MAX9951DCCB+D

MAX9951DCCB+TD

MAX9951DCCB-D

MAX9951DCCB-TD

MAX9951FCCB+

MAX9951FCCB+T

MAX9951FCCB-D

MAX9951FCCB-TD

MAX9952DCCB+

MAX9952DCCB+T

MAX9952DCCB-D

MAX9952DCCB-TD

MAX9952FCCB+

MAX9952FCCB+T

MAX9952FCCB-D

TEMP RANGE

0°C to +70°C

PIN-PACKAGE

64 TQFP-EPR*

64 TQFP-EP**

Applications

Memory Testers

VLSI Testers

System-on-a-Chip Testers

Structural Testers

Pin Configurations and Selector Guide appear at end of

data sheet.

MAX9952FCCB-TD

0°C to +70°C

64 TQFP-EP**

+Denotes

a lead(Pb)-free/RoHS-compliant package.

-Denotes

a package containing lead(Pb).

*EPR

= Top side exposed pad.

D = Dry pack.

**EP

= Exposed pad.

T = Tape and reel.

For pricing, delivery, and ordering information, please contact Maxim Direct

at 1-888-629-4642, or visit Maxim’s website at www.maximintegrated.com.

19-3247; Rev 6; 8/13

MAX9951/MAX9952

Dual Per-Pin Parametric

Measurement Units

ABSOLUTE MAXIMUM RATINGS

MAX9951_CCB (Note 1) ...........................................+2°C/W

to AGND .......................................................................+20V

to AGND.........................................................................-15V

MAX9952_CCB (Note 1) .........................................+23°C/W

to V

...........................................................................+32V

MAX9952_CCB (Note 1) ...........................................+2°C/W

to AGND............................................................................+6V

Junction Temperature ......................................................+150°C

AGND to DGND.....................................................-0.5V to +0.5V

Storage Temperature Range .............................-65°C to +150°C

Digital Inputs/Outputs ..................................-0.3V to (V

+ 0.3V)

Operating Temperature Range (commercial) ........0°C to +70°C

All Other Pins to AGND ....................(V

- 0.3V) to (V

+ 0.3V)

Lead Temperature (soldering, 10s) .................................+300°C

Continuous Power Dissipation (T

= +70°C)

Soldering Temperature (reflow)

MAX9951_CCB (derate 125mW/°C above +70°C) ...10,000mW

Lead(Pb)-Free Packages.............................................+260°C

MAX9952_CCB (derate 43.5mW/°C above +70°C) .....3478mW

Packages Containing Lead(Pb)......................................+240°C

MAX9951_CCB (Note 1) ...........................................+8°C/W

Note 1:

Package thermal resistances were obtained using the method described in JEDEC specification JESD51-7, using a four-layer

board. For detailed information on package thermal considerations, refer to

www.maximintegrated.com/thermal-tutorial.

Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional

operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to

absolute maximum rating conditions for extended periods may affect device reliability.

DC ELECTRICAL CHARACTERISTICS

= +12V, V

= -7V, V

= +3.3V, T

= +25°C, unless otherwise noted. Specifications at T

= T

MIN

and T

= T

MAX

are guaranteed

by design and characterization. Typical values are at T

= +25°C, unless otherwise noted.) (Note 2)

PARAMETER

FORCE VOLTAGE

Force Input Voltage

Range

Forced Voltage

Input Bias Current

Forced-Voltage Offset

Forced-Voltage-Offset

Temperature Coefficient

Forced-Voltage Gain

Error

Forced-Voltage-Gain

Temperature Coefficient

Forced-Voltage Linearity

Error

MEASURE CURRENT

Measure-Current Offset

Measure-Current-Offset

Temperature Coefficient

Measure-Current Gain

Error

Measure-Current-Gain

Temperature Coefficient

Linearity Error

SYMBOL

IN0_

IN1_

DUT

CONDITIONS

MIN

TYP

MAX

UNITS

+ 2.5

DUT current at full scale

DUT current = 0A

= +12V, V

= -7V

= +18V, V

= -12V

-2

-7

+ 2.5

±1

-25

±100

- 2.5

+13

- 2.5

µA

FOS

+25

µV/°C

FGE

Nominal gain of +1

-1

0.005

±10

ppm/°C

FLER

Gain and offset errors calibrated out (Notes 3, 4)

-0.02

+0.02

%FSR

MOS

(Note 3)

-1

±20

%FSR

ppm/°C

MGE

(Note 5)

-1

±20

ppm/°C

MLER

Gain and offset errors calibrated out

(Notes 3, 4, 6)

-0.02

+0.02

%FSR

Maxim Integrated

MAX9951/MAX9952

Dual Per-Pin Parametric

Measurement Units

DC ELECTRICAL CHARACTERISTICS (continued)

= +12V, V

= -7V, V

= +3.3V, T

= +25°C, unless otherwise noted. Specifications at T

= T

MIN

and T

= T

MAX

are guaranteed

by design and characterization. Typical values are at T

= +25°C, unless otherwise noted.) (Note 2)

PARAMETER

Measure-Output-Voltage

Range Over Full-Current

Range

Current-Sense Amp

Offset-Voltage Input

Rejection of Output-

Measure Error Due to

Common-Mode Sense

Voltage

SYMBOL

IOS

= V

DUTGND

MSR_

IOS

= 4V + V

DUTGND

IOS

Relative to V

DUTGND

-0.2

+4.4

CONDITIONS

MIN

-4

TYP

MAX

UNITS

CMVR

LER

(Notes 5 and 7)

+0.001

+0.007

%FSR/V

Range E, R_E = 500kΩ

Range D, R_D = 50kΩ

Measure-Current Range

Range C, R_C = 5kΩ

Range B, R_B = 500Ω

Range A, R_A = 15.6Ω

FORCE CURRENT

Input Voltage Range for

Setting Forced Current

Over Full Range

Current-Sense Amp

Offset-Voltage Input

IOS_ Input Bias Current

Forced-Current Offset

Forced-Current-Offset

Temperature Coefficient

Forced-Current Gain

Error

Forced-Current-Gain

Temperature Coefficient

Forced-Current Linearity

Error

Rejection of Output Error

Due to Common-Mode

Load Voltage

FLER

Gain and offset errors calibrated out

(Notes 3, 4, 6)

(Note 5)

(Note 3)

IN0_,

IN1_

IOS

= V

DUTGND

IOS

= 4V + V

DUTGND

Relative to V

DUTGND

-2

-20

-200

-2

-64

+20

+200

+64

µA

-4

-0.2

±1

-1

±20

-1

±20

-0.02

+4.4

µA

%FSR

ppm/°C

+0.02

%FSR

CMRI

OER

(Notes 5 and 7)

Range E, R_E = 500kΩ

Range D, R_D = 50kΩ

-2

-20

-200

-2

-64

+0.001

+0.007

+20

+200

+64

%FSR/V

µA

Forced-Current Range

Range C, R_C = 5kΩ

Range B, R_B = 500Ω

Range A, R_A = 15.6Ω

Maxim Integrated

MAX9951/MAX9952

Dual Per-Pin Parametric

Measurement Units

DC ELECTRICAL CHARACTERISTICS (continued)

= +12V, V

= -7V, V

= +3.3V, T

= +25°C, unless otherwise noted. Specifications at T

= T

MIN

and T

= T

MAX

are guaranteed

by design and characterization. Typical values are at T

= +25°C, unless otherwise noted.) (Note 2)

PARAMETER

MEASURE VOLTAGE

Measure-Voltage-Offset

Temperature Coefficient

Gain Error

Measure-Voltage-Gain

Temperature Coefficient

Measure-Voltage

Linearity Error

Measure-Output-Voltage

Range Over Full DUT

Voltage

FORCE OUTPUT

Off-State Leakage

Current

Short-Circuit Current

Limit

Force-to-Sense Resistor

SENSE INPUT

Input Voltage Range

Leakage Current

COMPARATOR INPUTS

Input Voltage Range

Offset Voltage

Input Bias Current

VOLTAGE CLAMPS

Input Control Voltage

Clamp Voltage

Accuracy

DIGITAL INPUTS

Input High Voltage

(Note 9)

Input Low Voltage

(Note 9)

Input Current

Input Capacitance

= 5V

= 3.3V

= 2.5V

= 5V or 3.3V

= 2.5V

±1

3.0

+3.5

+2.0

+1.7

+0.8

+0.7

µA

CLLO_

CLHI_

(Note 8)

+ 2.4

-100

- 2.4

+100

+ 2.5

-25

±1

- 2.5

+25

µA

F option only

+ 2.5

-1

- 2.5

LIM-

LIM+

D option only

-1

-92

+65

-65

+92

kΩ

MLER

Gain and offset errors calibrated out

(Notes 3, 4, 6)

DUT current at full scale

DUT current = 0A

= +12V, V

= -7V

= +18V, V

= -12V

-0.02

-2

-7

+ 2.5

MGER

Nominal gain of +1

-1

MOS

-25

±100

±0.005

±10

+0.02

+13

- 2.5

+25

µV/°C

ppm/°C

%FSR

SYMBOL

CONDITIONS

MIN

TYP

MAX

UNITS

MSR

Maxim Integrated

MAX9951/MAX9952

Dual Per-Pin Parametric

Measurement Units

DC ELECTRICAL CHARACTERISTICS (continued)

= +12V, V

= -7V, V

= +3.3V, T

= +25°C, unless otherwise noted. Specifications at T

= T

MIN

and T

= T

MAX

are guaranteed

by design and characterization. Typical values are at T

= +25°C, unless otherwise noted.) (Note 2)

PARAMETER

Output High Voltage

Output Low Voltage

High-Impedance-State

Leakage Current

High-Impedance-State

Output Capacitance

DIGITAL OUTPUTS

Output High Voltage

Output Low Voltage

POWER SUPPLY

Positive Supply

Negative Supply

Total Supply Voltage

Logic Supply

Positive Supply Current

Negative Supply Current

Logic Supply Current

Analog Ground Current

Digital Ground Current

Power-Supply Rejection

Ratio

AGND

DGND

PSRR

No load, clamps enabled

No load, all digital inputs at rails

No load, clamps enabled

No load, all digital inputs at rails

1MHz, measured at force output

60Hz, measured at force output

0.9

1.4

(Note 2)

+10

-15

+2.375

+12

-7

+18

-5

+30

+5.5

10.0

1.2

OUT

= 1mA, V

= +2.375V to +5.5V,

relative to DGND

OUT

= -1mA, V

= +2.375V to +5.5V,

relative to DGND

- 0.25

+0.2

SYMBOL

CONDITIONS

= +2.375V to +5.5V, R

PUP

= 1kΩ

= +2.375V to +5.5V, R

PUP

= 1kΩ

±1

6.0

MIN

- 0.2

+0.4

TYP

MAX

UNITS

µA

COMPARATOR OUTPUTS

- V

(Note 10)

Maxim Integrated

型号	MAX9951FCCB+	MAX9951	MAX9951_09	MAX9952	MAX9952DCCB+T	MAX9952DCCB+	MAX9952FCCB+	MAX9952FCCB+T
描述	Dual Per-Pin Parametric Measurement Units	Dual Per-Pin Parametric Measurement Units	Dual Per-Pin Parametric Measurement Units	Dual Per-Pin Parametric Measurement Units	Dual Per-Pin Parametric Measurement Units	Dual Per-Pin Parametric Measurement Units	Dual Per-Pin Parametric Measurement Units	Dual Per-Pin Parametric Measurement Units

vid pid 具体指的是什么东西？？？？: vid pid 具体指的是什么东西？？？？是由什么确定的？？？？？ vid pid 具体指的是什...; bbslee888 嵌入式系统

通过调节稳压器优化 DSP 功率预算: 系统级节电与功率预算优化是许多应用的关键。例如，数据中心运营商努力控制能耗，便携式设备设计人...; Aguilera 微控制器 MCU

刚贴片回来的PYB Nano: PYBNano，目前最小的MicroPython开发板。这一版加上了加速度传感器，可以直接通过pyb...; dcexpert MicroPython开源版块

【工程源码】ubuntu18.04使用静态ip: 本文和设计代码由FPGA爱好者小梅哥编写，未经作者许可，本文仅允许网络论坛复制转载，且转载时请标明...; 小梅哥 ARM技术

【TI 无线主题征集】+TI无线数据传输模块使用: 接触TI的产品也比较多，无线相对来讲用的少，之前项目中只用过TI的CC1101模块进行数据传...; lywangying 无线连接

【求助】IAR里的C能定义位变量吗?: 【求助】IAR里的C能定义位变量吗? 定义一个变量，取它的BIT来用也是可以的,其实就像标志位一样...; shen001 微控制器 MCU

OPPO Reno7系列配置在发布前全面曝光有三款可选

OPPO正在准备其Reno7系列，与之前的预测相反，OPPO并不会带来一个Reno7 Pro+型号，倒是可以看到低端的Reno7 SE，并使得Reno7 Pro继续处于其系列的顶端。来自西班牙的报道表明，标准版Reno7和Reno7 Pro共享很大一部分硬件：共同采用6.5英寸的OLED面板，但区别在于刷新率，标准版为90Hz而Pro版则拥有120Hz，同样的4500毫安时电池和65W快速...[详细]
IAR no definition for

最近在学STM8L151，在编程的时候遇到了一些问题和大家分享下。代码终于打完之后，make一下直接报错： Error : no definition for TIM2_ClearITPendingBit 错误如上，函数未定义或声明，然后我找到目标源文件和头文件，TIM2_ClearITPendingBit函数是库文件 stm8l15x_tim2.h 里面的函数，然后我在stm...[详细]
拿半导体施压韩国，日韩贸易战准备开打？

美国总统唐纳德·特朗普通过精准打击中兴通讯、华为技术等中国企业，让美国获得了哪些利益，目前无人知晓。美国英特尔、高通等企业比较着急，因为他们马上要丢失最大的用户。所以在G20召开后的6月29日，特朗普通过见记者的方式，宣布暂缓对华为的禁运。在美国还没有正式宣布禁止使用华为等中国企业的产品时，早在2018年12月10日，日本就先声夺人，由官房长官菅义伟亲自宣布禁止企业使用华为等中国企业制造的...[详细]
STM32学习历程之IO口输出方式

推挽输出（PUSH-Pull Output）：在功率放大器电路中大量采用推挽放大器电路，这种电路中用两只三极管构成一级放大器电路，两只三极管分别放大输入信号的正半周和负半周，即用一只三极管放大信号的正半周，用另一只三极管放大信号的负半周，两只三极管输出的半周信号在放大器负载上合并后得到一个完整周期的输出信号。推挽放大器电路中，一只三极管工作在导通、放大状态时，另一只三极管处于截止状态，当输入信...[详细]
想让你的家庭网络更安全智能吗？快来看看

“家庭网络”不断发展，如今物联产品之间可以无缝协作，提供智能又安全的家庭体验。实际上，最新的智能家居和智能语音家庭助理产品内部十分复杂。家庭安全空间是多层分散的，使其互操作性成为挑战。消费者日常选择产品会根据产品的易用性和互操作性，包括网关的可用性，无缝连接、本地和远程监控的能力等。安全服务提供商和安全系统公司都在致力于通过集成安全系统的三大基本构建块来使产品具有开箱即用的互操...[详细]
嵌入式linux软件如何进行数据参数保存

大多数软件开发都会涉及到数据参数的保存与读取，小至运行的单片机的软件，大至操作系统级别的软件（如linux，windows，mac），均会有专门的子程序或者模块进行参数的保存和读取。不同的平台下开发，参数的保存与读取会存在一定的差异化，例如，单片机下，保存参数是写入eeprom或者 rom，windows和linux下的软件则会以配置文件的形式保存参数。下面以我以前在工作中所遇到情况，重点写写嵌...[详细]
MF－TDMA卫星通信网络仿真测试研究

MF-TDMA 卫星网络是由地面主站、备用主站、网控中心、众多从站、卫星转发器等单元组成，系统的主要业务是话音、数据、视频，但各卫通站通信能力大小不同，每个地面站作为主叫或被叫，向网控中心站申请卫星信道资源，因此必须对卫星网络资源与信息进行有效管理与调配，使其可以应对各种复杂的突发情况，适应应用任务、网络本身和外部条件的变化，保证卫星网络稳定、可靠、持续和高效运行。 Rational Rose 工...[详细]
预装Android8.1 中兴新机入网工信部

中兴一款型号为V0900的手机产品在工信部入网，根据其型号来看，这款产品实际上是中兴Blade V9。配置方面，这款产品将采用分辨率为2160 x 1080的5.7英寸TFT屏幕，内置3100mAh，搭载八核心主频为1.8GHz处理器，内存有2GB、3GB以及4GB可选，闪存有32GB、64GB、128GB三个版本，预装Android 8.1的操作系统，前置摄像头为8MP，后置摄像头...[详细]
亚马逊云科技全栈机器学习力

什么是？其实机器学习在我们的现实生活中经常出现。尤其这几年，当我们在酒店入住和餐厅就餐时，已经出现了很多机器人为我们提供基础服务；当我们在各类手机应用查阅内容时，个性化推荐已经大幅提高我们的观看体验；当我们出行时，会给我们带来非常大的便利。无论是智能机器人，个性化推荐，还是自动驾驶都涉及了机器学习。当然机器学习和人工智能的应用场景还有很多，这些逐渐都渗透到我们日常的工作和生活中。 ...[详细]
当工业机器人遇到工业4.0 将会产生微妙的变化

制造业的生产力已经历了三次深刻的变革，第一次是以水和蒸汽动力为核心的变革，也称为工业1.0时代。第二次工业革命是电力时代，机问世，并带来了生产力的飞跃。第三次是时代，计算机技术突破促进了生产自动化的发展。而今天，我们正在迎来第四次工业革命，以信息技术为核心的工业4.0时代。工业4.0或工业指的是将所有设备、计算机、人和产品等所有生产元素连接起来，并从中采集丰富的，然后通对数据分析来指引导...[详细]
2602新型测试仪器如何缩短测试时间

2602型双通道系统源表可降低测试成本的重要参数在本文的前面，介绍过四个降低测试成本的关键因素：缩短测试时间、缩短开发时间、减少测试设备所占的面积和机架的空间大小以及降低系统的保有成本。每个因素都有许多有待研究的方面。缩短测试时间。当DUT装入测试夹具或测试夹具从一个DUT 循环至下一个DUT时，几个不同的时间间隔构成了测试系统总循环时间的绝大部分。这些时间间隔取决于系统设计...[详细]
一种低电压低静态电流LDO的电路设计（一）

随着过去几十年里掌上智能终端快速发展，低压差的线性稳压器(Low Drop-out Regulator,LDO)因其具有低功耗、高的电源抑制比、体积小、电路设计简单等优点得到大量应用。LDO大部分时间工作在低负载应用，因此，其在低负载情况下的静态电流消耗决定着电池的寿命。当今的LDO发展趋势是低电压、低静态电流来延长电池使用寿命。然而，低静态电流会导致不稳定性，带来大的输出电压暂态变化，必须在静...[详细]
东京大学研发新型电解质溶液延长锂离子电池续航时间/增加安全性

据外媒报道，日本东京大学（University of Tokyo）的研究人员首次探索了电能存储的物理和化学特性，并发现了一种改进锂离子电池的新方法。研究人员们不仅成功提高了锂离子电池的电压传输能力，还成功地阻止了危险条件的出现，以免影响到现有电池的电流范围。此种得到改进的锂离子电池能够让电动汽车进行长途旅行成为可能，还能够制成新一代家庭储能装置，而且此两种应用中的锂离子电池的防火安全性都得到...[详细]
背部3颗闪光灯联想VIBE Z3 Pro再曝光

随着MWC 2015即将来临，越来越多的旗舰产品遭到曝光，那就是联想最新旗舰产品VIBE Z3 Pro。近日，有微博网友非精英数码技术男在其微博上曝光了有关联想VIBE Z3 Pro的一系列参数，可谓是相当全面，于此同时，微博用户博数码更是曝出了联想VIBE Z3 Pro的真机图片。　　根据曝光资料显示，联想最新旗舰手机VIBE Z3 Pro的10个细节请看下图。而博数码...[详细]
基于GD32的段码显示器设计

说明一下：选用了IIC驱动方式，硬件连接SCL、SDAIN和SDAOUT引脚，也就是说有应答检测是从SDAOUT引脚返回给MCU的。硬件平台：微控制器选择GD32F103 PCA8538评估板红外遥控器并使用红外遥控器进行控制锐鑫同创提供的示例十分丰富，注释清晰，移植太方便了。 IIC，RTC，DS18B20等驱动完全都不用改，项目完成很顺利。核心代码部分分析：主循环里...[详细]