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MAX9966BGCCQ: 产品描述QUAD COMPARATOR, 100000uV OFFSET-MAX, 1.2ns RESPONSE TIME, PQFP100, 14 X 14 MM, 1 MM HEIGHT, 0.50 MM PITCH, TQFP-100; 产品类别模拟混合信号IC 放大器电路; 文件大小1MB，共27页; 制造商Rochester Electronics; 官网地址https://www.rocelec.com/

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MAX9966BGCCQ概述

QUAD COMPARATOR, 100000uV OFFSET-MAX, 1.2ns RESPONSE TIME, PQFP100, 14 X 14 MM, 1 MM HEIGHT, 0.50 MM PITCH, TQFP-100

MAX9966BGCCQ规格参数

参数名称	属性值
是否无铅	含铅
厂商名称	Rochester Electronics
零件包装代码	QFP
包装说明	14 X 14 MM, 1 MM HEIGHT, 0.50 MM PITCH, TQFP-100
针数	100
Reach Compliance Code	unknown
放大器类型	COMPARATOR
最大平均偏置电流 (IIB)	25 µA
最大输入失调电压	100000 µV
JESD-30 代码	S-PQFP-G100
JESD-609代码	e0
长度	14 mm
湿度敏感等级	3
负供电电压上限	-7 V
标称负供电电压 (Vsup)	-5.25 V
功能数量	4
端子数量	100
最高工作温度	70 °C
最低工作温度
输出类型	OPEN-COLLECTOR
封装主体材料	PLASTIC/EPOXY
封装代码	HTFQFP
封装形状	SQUARE
封装形式	FLATPACK, HEAT SINK/SLUG, THIN PROFILE, FINE PITCH
峰值回流温度（摄氏度）	245
认证状态	COMMERCIAL
标称响应时间	1.2 ns
座面最大高度	1.2 mm
供电电压上限	11.5 V
标称供电电压 (Vsup)	9.75 V
表面贴装	YES
技术	BIPOLAR
温度等级	COMMERCIAL
端子面层	TIN LEAD
端子形式	GULL WING
端子节距	0.5 mm
端子位置	QUAD
处于峰值回流温度下的最长时间	NOT SPECIFIED
宽度	14 mm

MAX9966BGCCQ文档预览

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19-3016; Rev 2; 5/06

Quad Low-Power, 500Mbps

ATE Driver/Comparator

General Description

The MAX9965/MAX9966 four-channel, low-power, high-

speed pin electronics driver and comparator ICs

include for each channel a three-level pin driver, com-

parator, and variable clamps. The MAX9965/MAX9966

are similar to the MAX9963/MAX9964, but with even

lower window comparator dispersion for enhanced

accuracy. The driver features a wide voltage range and

high-speed operation, includes high-Z and active termi-

nation (3rd-level drive) modes, and is highly linear even

at low-voltage swings. The dual bipolar-input compara-

tor provides very low dispersion (timing variation) over a

wide variety of input conditions. The clamps provide

damping of high-speed DUT waveforms when the

device is configured as a high-impedance receiver.

High-speed, differential control inputs compatible with

ECL, LVPECL, LVDS, and GTL levels are provided for

each channel. ECL/LVPECL or flexible open-collector

outputs are available for the comparators.

The A-grade version provides tight matching of gain

and offset for the driver and comparator, allowing refer-

ence levels to be shared across multiple channels in

cost-sensitive systems. For system designs that incor-

porate independent reference levels for each channel,

the B-grade version is available at reduced cost.

Optional internal resistors at the high-speed inputs pro-

vide differential termination of LVDS inputs, while

optional internal resistors provide the pullup voltage

and source termination for open-collector comparator

outputs. These features significantly reduce the dis-

crete component count on the circuit board.

The MAX9965/MAX9966 operating range is -1.5V to

+6.5V, with powerdissipation of only 975mW per channel.

These devices are available in a 100-pin, 14mm x

14mm body, 0.5mm pitch TQFP with an exposed 8mm

x 8mm die pad on the top (MAX9965) or bottom

(MAX9966) of the package for efficient heat removal.

The MAX9965/MAX9966 are specified to operate with

an internal die temperature of +60°C to +100°C, and

feature a die temperature monitor output.

Features

♦

Small Footprint: Four Channels in 0.4in

♦

Low Power Dissipation: 975mW/Channel (typ)

♦

High Speed: 500Mbps at 3V

P-P

♦

Very Low Timing Dispersion

♦

Wide Operating Range: -1.5V to +6.5V

♦

Active Termination (3rd-Level Drive)

♦

Low-Leakage Mode: 15nA Maximum

♦

Integrated Clamps

♦

Interface Easily with Most Logic Families

♦

Digitally Programmable Slew Rate

♦

Internal Logic Termination Resistors

♦

Low Gain and Offset Error

MAX9965/MAX9966

Ordering Information

PART

MAX9965ADCCQ*

MAX9965AKCCQ*

MAX9965AGCCQ*

MAX9965AHCCQ*

MAX9965AJCCQ*

MAX9965BDCCQ*

MAX9965BKCCQ*

MAX9965BGCCQ

MAX9965BHCCQ*

MAX9965BJCCQ

MAX9966ADCCQ*

MAX9966AKCCQ*

MAX9966AGCCQ*

MAX9966AHCCQ*

MAX9966AJCCQ*

MAX9966BDCCQ*

MAX9966BKCCQ*

MAX9966BGCCQ

MAX9966BHCCQ*

TEMP RANGE

0°C to +70°C

PIN-PACKAGE

100 TQFP-EPR***

100 TQFP-EP**

Applications

Memory Testers

Low-Cost Mixed-Signal/System-on-Chip Testers

Structural Testers

Pattern/Data Generators

MAX9966BJCCQ*

0°C to +70°C

100 TQFP-EP**

*Future

product—contact factory for availability.

**EP

= Exposed pad.

***EPR

= Exposed pad reversed.

Pin Configurations and Selector Guide appear at end of data

sheet.

________________________________________________________________

Maxim Integrated Products

For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at

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

Quad Low-Power, 500Mbps

ATE Driver/Comparator

MAX9965/MAX9966

ABSOLUTE MAXIMUM RATINGS

to GND .........................................................-0.3V to +11.5V

to GND............................................................-7.0V to +0.3V

All Other Pins ...................................(V

- 0.3V) to (V

+ 0.3V)

- V

................................................................-0.3V to +18V

DUT_ to GND.........................................................-2.5V to +7.5V

DATA_, NDATA_, RCV_, NRCV_ to GND ................-2.5 to +5.0V

DATA_ to NDATA_ ................................................….……..±1.5V

RCV_ to NRCV_ ....................................................…………±1.5V

CCO_ _

to GND ....................................................…-0.3V to +5V

SCLK, DIN,

CS, RST

to GND ...............................…-1.0V to +5V

DHV_, DLV_, DTV_, CHV_, CLV_ to GND .............-2.5V to +7.5V

CPHV_ to GND ......................................................-2.5V to +8.5V

CPLV_ to GND.......................................................-3.5V to +7.5V

DHV_ to DLV_........................................................…………±10V

DHV_ to DTV_........................................................…………±10V

DLV_ to DTV_ ........................................................…………±10V

CHV_ or CLV_ to DUT_..........................................…………±10V

CH_, NCH_, CL_, NCL_ to GND...............................-2.5V to +5V

Current into DHV_, DLV_, DTV_,

CHV_, CLV_, CPHV_, CPLV_........................................±10mA

Current into TEMP ............................................-0.5mA to +20mA

DUT_ Short Circuit to -1.5V to +6.5V .....................….Continuous

Power Dissipation (T

= +70°C)

MAX9965__CCQ (derate 167mW/°C

above +70°C) ...............................................................13.3W*

MAX9966__CCQ (derate 47.6mW/°C

above +70°C) .................................................................3.8W*

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

Junction Temperature .........................................….……+125°C

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

*Dissipation

wattage values are based on still air with no heat sink for the MAX9965 and slug soldered to board copper for the MAX9966.

Actual maximum power dissipation is a function of users’ heat extraction technique and may be substantially higher.

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.

ELECTRICAL CHARACTERISTICS

= +9.75V, V

= -5.25V, V

CCO_ _

= 2.5V, SC1 = SC0 = 0, V

CPHV_

= 7.2V, V

CPLV_

= -2.2V, T

= +85°C,

unless otherwise noted.

All temperature coefficients are measured at T

= +60°C to +100°C, unless otherwise noted.) (Note 1)

PARAMETER

POWER SUPPLIES

Positive Supply

Negative Supply

Positive Supply

Negative Supply

Power Dissipation

DUT_ CHARACTERISTICS

Operating Voltage Range Max

Leakage Current in High-Z Mode

Leakage Current in Low-Leakage

Mode

Combined Capacitance

Low-Leakage Enable Time

Low-Leakage Disable Time

Low-Leakage Recovery

DUT

(Note 4)

LLEAK = 0, 0

≤

DUT_

≤

LLEAK = 0, V

DUT_

= -1.5V, 6.5V

LLEAK = 1, 0

≤

DUT_

≤

3V, T

< +90°C

DUT

LLEAK = 1, V

DUT_

= -1.5V,T

< +90°C

LLEAK = 1, V

DUT_

= 6.5V, T

< +90°C

DUT

Driver in term mode (DUT_ = DTV_)

Driver in high-Z mode

(Notes 5, 7)

(Notes 6, 7)

Time to return to the specified maximum

leakage after a 3V, 4V/ns step at DUT_

(Note 7)

-1.5

+6.5

±2

±5

±15

±30

µs

µA

(Note 2)

(Notes 2, 3)

9.5

-6.5

9.75

-5.25

200

-370

3.9

10.5

-4.5

225

-425

4.5

SYMBOL

CONDITIONS

MIN

TYP

MAX

UNITS

_______________________________________________________________________________________

Quad Low-Power, 500Mbps

ATE Driver/Comparator

ELECTRICAL CHARACTERISTICS (continued)

= +9.75V, V

= -5.25V, V

CCO_ _

= 2.5V, SC1 = SC0 = 0, V

CPHV_

= 7.2V, V

CPLV_

= -2.2V, T

= +85°C, unless otherwise noted.

All temperature coefficients are measured at T

= +60°C to +100°C, unless otherwise noted.) (Note 1)

PARAMETER

Input Bias Current

Settling Time

Input High Voltage

Input Low Voltage

Differential Input Voltage

Input Resistor

DIFF

MAX996_ _GCCQ, MAX996_ _JCCQ,

between signal and complement

SCLK

CSS0

CSS1

CSH1

CSWH

= +70°C, R

≥

10MΩ

3.5

3.43

+10

SYMBOL

BIAS

To 5mV

-1.6

-2.0

±0.15

+3.5

+3.1

±1.0

104

CONDITIONS

MIN

TYP

MAX

±25

UNITS

µA

µs

MAX9965/MAX9966

LEVEL PROGRAMMING INPUTS

(DHV_, DLV_, DTV_, CHV_, CLV_, CPHV_, CPLV_)

DIFFERENTIAL CONTROL INPUTS

(DATA_, NDATA_, RCV_, NRCV_)

SINGLE-ENDED CONTROL INPUTS

(CS,

RST,

SCLK, DIN)

Input High Voltage

Input Low Voltage

SCLK Frequency

SCLK Pulse Width High

SCLK Pulse Width Low

Low to SCLK High Setup

High to SCLK High Setup

SCLK High to

High Hold

DIN to SCLK High Setup

DIN to SCLK High Hold

Pulse Width High

TEMPERATURE MONITOR

(TEMP)

Nominal Voltage

Temperature Coefficient

Output Resistance

DRIVERS

(Note 8)

DC OUTPUT CHARACTERISTICS

≥

10MΩ )

DHV_, DLV_, DTV_, Output Offset

Voltage

DHV_, DLV_, DTV_, Gain

DHV_, DLV_, DTV_, Output

Voltage Temperature Coefficient

Linearity Error

At DUT_ with V

DHV_

= 3V,

DTV_

= 1.5V, V

DLV_

= 0

Measured with V

DHV_

, V

DLV_

DTV_

at 0 and 4.5V

MAX996_B

0.96

±75

±5

±15

±100

1.001

V/V

µV/°C

mV/°C

kΩ

1.6

-0.1

3.5

+0.9

MHz

SERIAL INTERFACE TIMING

(Figure 5)

Includes both gain and offset temperature

effects

≤

DUT_

≤

3V (Note 9)

Full range (Notes 9, 10)

_______________________________________________________________________________________

Quad Low-Power, 500Mbps

ATE Driver/Comparator

MAX9965/MAX9966

ELECTRICAL CHARACTERISTICS (continued)

= +9.75V, V

= -5.25V, V

CCO_ _

= 2.5V, SC1 = SC0 = 0, V

CPHV_

= 7.2V, V

CPLV_

= -2.2V, T

= +85°C, unless otherwise noted.

All temperature coefficients are measured at T

= +60°C to +100°C, unless otherwise noted.) (Note 1)

PARAMETER

DHV_ to DLV_ Crosstalk

DLV_ to DHV_ Crosstalk

DTV_ to DLV_ and DHV_

Crosstalk

DHV_ to DTV_ Crosstalk

DLV_ to DTV_ Crosstalk

DHV_, DLV_, DTV_

DC Power-Supply Rejection Ratio

Maximum DC Drive Current

DC Output Resistance

DC Output Resistance Variation

PSRR

DUT_

ΔR

DUT_

±30mA

(Note 11)

DUT_

±1.0mA

±40mA

DLV_

= 0, V

DHV_

= 0.1V

Drive Mode Overshoot

Term Mode Overshoot

Settling Time to Within 25mV

Settling Time to Within 5mV

Prop Delay, Data to Output

Prop Delay Match, T

vs. T

Prop Delay Match, Drivers Within

Package

Prop Delay Temperature

Coefficient

Prop Delay Change vs.

Pulse Width

Prop Delay Change vs.

Common-Mode Voltage

Prop Delay, Drive to High-Z

Prop Delay, High-Z to Drive

Prop Delay, Drive to Term

Prop Delay, Term to Drive

PDDZ

PDZD

PDDT

PDTD

P-P

, 40MHz, 2.5ns to 22.5ns pulse width,

relative to 12.5ns pulse width

DHV_

- V

DLV_

= 1V, V

DHV_

= 0 to 6V

DHV_

= 1.0V, V

DLV_

= -1.0V, V

DTV_

= 0

DHV_

= 1.0V, V

DLV_

= -1.0V, V

DTV_

= 0

DHV_

= 3V, V

DLV_

= 0, V

DTV_

= 1.5V

DHV_

= 3V, V

DLV_

= 0, V

DTV_

= 1.5V

0.2 V

P-P

, 20% to 80%

Rise and Fall Time

, t

1 V

P-P

, 10% to 90%

3 V

P-P

, 10% to 90%

5 V

P-P

, 10% to 90%

450

1.1

PDD

P-P

(Note 15)

DLV_

= 0, V

DHV_

= 1V

DLV_

= 0, V

DHV_

= 3V

(Note 12)

3V step (Note 13)

SYMBOL

CONDITIONS

DLV_

= 0, V

DHV_

= 200mV, 6.5V

DHV_

= 5V, V

DLV_

= -1.5V, 4.8V

DHV_

= 3V, V

DLV_

= 0,

DTV_

= -1.5V, +6.5V

DTV_

= 1.5V, V

DLV_

= 0, V

DHV_

=1.6V, 3V

DTV_

= 1.5V, V

DHV_

= 3V, V

DLV_

= 0, 1.4V

and V

independently set to their

min/max values

±60

±50

±60

2.9

2.3

2.0

330

670

1.2

2.0

750

1.4

2.75

ps/°C

±120

2.5

MIN

TYP

MAX

±2

±3

UNITS

DYNAMIC OUTPUT CHARACTERISTICS

= 50Ω)

TIMING CHARACTERISTICS

= 50Ω) (Note 14)

DYNAMIC PERFORMANCE

= 50Ω)

_______________________________________________________________________________________

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语音识别按识别器对使用者的适应情况分类

有限词汇识别按词汇表中字、词或短句个数的多少，大致分为：100以下为小词汇;100-1000为中词汇;1000以上为大词汇。无限词汇识别(全音节识别) 当识别基元为汉语普通话中对应所有汉字的可读音节时，则称其为全音节语音识别(音节字表：Lexicon)。全音节语音识别是实现无限词汇或中文文本输入的基础。 ...[详细]
利用麦克风数组抑制背景噪声

　　概述　　随着手持语音通信设备越来越流行，它们应用在嘈吵环境的机会也越来越高，例如机场、交通繁忙的路段、人多嘈杂的酒吧等。在这种嘈吵的环境下，通话的双方实在难以听清对方所说的话。　　此外，不少通信系统都是采用计算机运行的语音识别、指令及/或响应系统，这些系统均易受到背景噪声的影响，假如噪声过大，便会导致系统出现很大的偏差。因此，有必要改善语音信号对背景声音噪声的比率。　　本文将解释利用麦...[详细]
关于ESD管的叫法，你知道几个?

中国汉字博大精深，关于ESD管的叫法可谓是千奇百样，你知道的有几个呢？据优恩小编所知，目前ESD管的叫法主要有ESD静电保护器、ESD静电保护二极管、ESD防护静电二极管、ESD二极管以及ESD管。叫法虽多，但其作用还是防护电路而生。其实不管是它的叫法，还是原理，都是应当知道的，在了解ESD管的前提基础上，我们其实还要对前身作个大概的知悉，例如电子产品为什么需要防雷过压保护，ESD静电...[详细]
英特尔携手亚马逊云科技，打造云服务新引擎

英特尔 ® 至强 ® 6性能核处理器现已支持亚马逊云科技（AWS）上全新推出的亚马逊EC2 R8i和R8i-flex实例。与基于英特尔处理器的其他云实例相比，这两款新实例能为用户提供更卓越的性能和更快的内存带宽。基于英特尔至强6处理器的亚马逊第八代EC2实例正式发布，在云端为客户提供卓越的性能与更高的内存带宽这两款新实例不仅是英特尔与AWS多年深度合作的丰硕成果，也充分展现了双方正...[详细]
电动汽车跑高速对于续航会有什么影响

随着电动汽车续航里程不断的提高，驾驶电动汽车长途出行已然成为一种趋势，对于高速出行来说，电动汽车在跑高速续航会有多少影响呢？说到高速行驶的时候会有什么影响，对于电动汽车来说，行驶速度和耗电速度是成正相关的。同时也和电机和电池有关，首先从电动汽车的电机来说起，根据电机的特征来说，电机是直接进行动力输出，在高速行驶的时候车速提升的较快，而这个时候就需要车辆的电机来提高车辆的转速，因此高的转速自...[详细]
全国最大高速充电站投运：108台快充桩，40台超充桩“一秒一公里”

8月18日，我国最大规模的高速公路充电站 ——G25长深高速桐庐服务区（南区）光储充一体化智慧充电站正式建成投运。该充电站共设有108台大功率新能源车快充桩，其中包括40台超级充电桩，单桩最高功率可达600kW，实现了“一秒一公里”的充电速度。该服务区的充电桩采用了光伏发电、梯次储能、液冷超充直流快充等先进技术，并借助智能管理系统实现光伏储能与新能源车充电的统一管理与调度。此外，车棚上大...[详细]
英特尔通用快接头互插互换联盟启航，构建液冷生态互操作新标准

今日，英特尔 ® 通用快接头（下称UQD）互插互换联盟正式成立。成立仪式上，英特尔与首批认证合作伙伴——英维克、丹佛斯、立敏达科技、蓝科电气和正北连接这五大液冷生态独立硬件供应商一同分享了UQD互换性认证的技术创新之道，及其对降低数据中心运维复杂度、提升系统可靠性、助力液冷产业规模化的重要性。英特尔数据中心与人工智能集团副总裁兼中国区总经理陈葆立表示：“作为AI模型运行和硬件...[详细]
在选择电动汽车时需要注意哪方面的细节

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汽车传动轴的作用

　　当我们拿到一件陌生的物品，首先想知道的就是它到底是干什么的？传动轴、顾名思义传递动力的轴、它是将发动机输出的经过变速箱减速增扭后的动力传递到汽车驱动轮的传力介质、没有它靠什么来驱动车轮旋转呢、车轮不旋转车怎么跑呢？下面就和电动邦小编一起围观汽车传动轴的作用吧。　　汽车传动轴作为汽车传动系统中的传递动力的重要部件，它可以与变速箱、驱动桥一起将发动机的动力传递给车轮，使汽车产生驱动力。通常...[详细]
为什么电子负载不能串联起来处理高电压产品？

如今，电子产品的电压继续上升到400V，600V甚至1000V，因此，很少有电子负载模型可以处理如此高的电压。许多人考虑串联连接多个电子负载，但是大多数电子负载无法串联。像直流电源一样，电子负载具有正负端子，通常用于在测试电源产品时从电源吸收功率。除了直流电以外，当然也要使用电子负载，例如DC-DC适配器，锂电池，燃料电池和太阳能电池板。为什么不能串联使用电子负载? 测试最大电流为2...[详细]
vocs在线监测设备在化工厂区的应用

随着经济的快速发展，污染源的种类日益增多，特别是化工区、工业集中区及周边环境，污染方式与生态破坏类型日趋复杂，环境污染负荷逐渐增加，环境污染事故时有发生。同时，随着公众环境意识逐渐增强，各类环境污染投诉纠纷日益频繁，因此对环境监测的种类、要求越来越高。 vocs在线监测设备采用挂壁式独立安装，无需调试，直接通电就可开始使用，可修改数据协议，可以对接平台，适合运行在高温、高粉尘、高油气等场合，...[详细]
安森美CEO深度解析：电动汽车与AI服务器双赛道的战略突围

2025年KeyBanc投资者会议上，安森美半导体CEO Hassane S. El-Khoury以全球产业变革为视角，系统阐述了电动汽车与 AI服务器两大高增长赛道的战略布局。其核心观点揭示出：电动汽车的全球化浪潮与 AI服务器的算力革命正在重塑半导体产业格局。安森美凭借在碳化硅技术、电源管理方案及供应链整合能力上的深度积累，正通过技术差异化+生态协同化的双轮驱动模式，...[详细]

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