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MC74HC4066A

Quad Analog Switch/

Multiplexer/Demultiplexer

High−Performance Silicon−Gate CMOS

The MC74HC4066A utilizes silicon−gate CMOS technology to

achieve fast propagation delays, low ON resistances, and low

O F F

−c

h a n n e l l e a k a g e c u r r e n t . T h i s b i l a t e r a l s w i t c h /

multiplexer/demultiplexer controls analog and digital voltages that

may vary across the full power−supply range (from V

to GND).

The HC4066A is identical in pinout to the metal−gate CMOS

MC14016 and MC14066. Each device has four independent switches.

The device has been designed so the ON resistances (R

) are more

linear over input voltage than R

of metal−gate CMOS analog

switches.

The ON/OFF control inputs are compatible with standard CMOS

outputs; with pullup resistors, they are compatible with LSTTL outputs.

For analog switches with voltage−level translators, see the HC4316A.

Features

http://onsemi.com

MARKING

DIAGRAMS

SOIC−14

D SUFFIX

CASE 751A

TSSOP−14

DT SUFFIX

CASE 948G

WL, L

WW, W

G or

= Assembly Location

= Wafer Lot

= Year

= Work Week

= Pb−Free Package

4066A

ALYWG

HC4066AG

AWLYWW

•

Fast Switching and Propagation Speeds

High ON/OFF Output Voltage Ratio

Low Crosstalk Between Switches

Diode Protection on All Inputs/Outputs

Wide Power−Supply Voltage Range (V

−

GND) = 2.0 to 12.0 V

Analog Input Voltage Range (V

−

GND) = 2.0 to 12.0 V

Improved Linearity and Lower ON Resistance over Input Voltage

than the MC14016 or MC14066

Low Noise

Chip Complexity: 44 FETs or 11 Equivalent Gates

These Devices are Pb−Free, Halogen Free and are RoHS Compliant

NLV Prefix for Automotive and Other Applications Requiring

Unique Site and Control Change Requirements; AEC−Q100

Qualified and PPAP Capable

(Note: Microdot may be in either location)

ORDERING INFORMATION

See detailed ordering and shipping information in the package

dimensions section on page 2 of this data sheet.

Semiconductor Components Industries, LLC, 2014

March, 2014

−

Rev. 12

Publication Order Number:

MC74HC4066A/D

MC74HC4066A

PIN ASSIGNMENT

B ON/OFF CONTROL

C ON/OFF CONTROL

LOGIC DIAGRAM

A ON/OFF CONTROL

D ON/OFF CONTROL

B ON/OFF CONTROL

ANALOG

OUTPUTS/INPUTS

GND

C ON/OFF CONTROL

FUNCTION TABLE

On/Off Control

Input

State of

Analog Switch

Off

D ON/OFF CONTROL

ANALOG INPUTS/OUTPUTS = X

, X

PIN 14 = V

PIN 7 = GND

ORDERING INFORMATION

Device

MC74HC4066ADG

MC74HC4066ADR2G

NLV74HC4066ADR2G*

MC74HC4066ADTR2G

NLVHC4066ADTR2G*

Package

SOIC−14

(Pb−Free)

SOIC−14

(Pb−Free)

TSSOP−14

(Pb−Free)

Shipping

†

55 Units / Rail

2500 / Tape & Reel

†For information on tape and reel specifications, including part orientation and tape sizes, please refer to our Tape and Reel Packaging

Specifications Brochure, BRD8011/D.

*NLV Prefix for Automotive and Other Applications Requiring Unique Site and Control Change Requirements; AEC−Q100 Qualified and PPAP

Capable.

http://onsemi.com

MC74HC4066A

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MAXIMUM RATINGS

Symbol

Parameter

Value

Unit

Positive DC Supply Voltage (Referenced to GND)

Analog Input Voltage (Referenced to GND)

Digital Input Voltage (Referenced to GND)

DC Current Into or Out of Any Pin

Power Dissipation in Still Air,

Storage Temperature

– 0.5 to + 14.0

– 0.5 to V

+ 0.5

– 0.5 to V

+ 0.5

500

450

SOIC Package†

TSSOP Package†

°C

stg

– 65 to + 150

260

Lead Temperature, 1 mm from Case for 10 Seconds

(Plastic DIP, SOIC or TSSOP Package)

Stresses exceeding those listed in the Maximum Ratings table may damage the device. If any of

these limits are exceeded, device functionality should not be assumed, damage may occur and

reliability may be affected.

†Derating

−

SOIC Package: – 7 mW/°C from 65° to 125°C

TSSOP Package:

−

6.1 mW/°C from 65° to 125°C

This device contains protection

circuitry to guard against damage

due to high static voltages or electric

fields. However, precautions must

be taken to avoid applications of any

voltage higher than maximum rated

voltages to this high−impedance cir-

cuit. For proper operation, V

and

out

should be constrained to the

range GND

or V

out

)

Unused inputs must always be

tied to an appropriate logic voltage

level (e.g., either GND or V

Unused outputs must be left open.

I/O pins must be connected to a

properly terminated line or bus.

RECOMMENDED OPERATING CONDITIONS

Symbol

Parameter

Min

2.0

Max

Unit

Positive DC Supply Voltage (Referenced to GND)

Analog Input Voltage (Referenced to GND)

Digital Input Voltage (Referenced to GND)

Static or Dynamic Voltage Across Switch

12.0

1.2

GND

−

, t

Operating Temperature, All Package Types

Input Rise and Fall Time, ON/OFF Control

Inputs (Figure 10)

–55

+ 125

1000

600

500

400

250

°C

= 2.0 V

= 3.0 V

= 4.5 V

= 9.0 V

= 12.0 V

Functional operation above the stresses listed in the Recommended Operating Ranges is not implied. Extended exposure to stresses beyond

the Recommended Operating Ranges limits may affect device reliability.

*For voltage drops across the switch greater than 1.2 V (switch on), excessive V

current may be drawn; i.e., the current out of the switch may

contain both V

and switch input components. The reliability of the device will be unaffected unless the Maximum Ratings are exceeded.

DC ELECTRICAL CHARACTERISTIC

Digital Section (Voltages Referenced to GND)

Guaranteed Limit

85°C

1.5

2.1

3.15

6.3

8.4

0.5

0.9

1.35

2.7

3.6

Symbol

Parameter

Test Conditions

– 55 to

25°C

1.5

2.1

3.15

6.3

8.4

0.5

0.9

1.35

2.7

3.6

125°C

1.5

2.1

3.15

6.3

8.4

0.5

0.9

1.35

2.7

3.6

Unit

Minimum High−Level Voltage

ON/OFF Control Inputs

= Per Spec

2.0

3.0

4.5

9.0

12.0

2.0

3.0

4.5

9.0

12.0

Maximum Low−Level Voltage

ON/OFF Control Inputs

= Per Spec

Maximum Input Leakage Current

ON/OFF Control Inputs

= V

or GND

= V

or GND

= 0 V

12.0

0.1

1.0

160

Maximum Quiescent Supply Current

(per Package)

6.0

12.0

http://onsemi.com

MC74HC4066A

DC ELECTRICAL CHARACTERISTICS

Analog Section (Voltages Referenced to GND)

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Guaranteed Limit

85°C

−

160

−

Symbol

Parameter

Test Conditions

– 55 to

25°C

−

120

−

125°C

−

200

100

−

120

−

Unit

Maximum “ON” Resistance

= V

to GND

2.0 mA (Figures 1, 2)

2.0†

3.0†

4.5

9.0

12.0

= V

or GND

(Endpoints)

2.0 mA (Figures 1, 2)

= V

= 1/2 (V

−

GND)

2.0 mA

= V

or GND

Switch Off (Figure 3)

2.0

3.0

4.5

9.0

12.0

2.0

4.5

9.0

12.0

Maximum Difference in “ON”

Resistance Between Any Two

Channels in the Same Package

off

Maximum Off−Channel Leakage

Current, Any One Channel

12.0

0.1

0.5

1.0

Maximum On−Channel Leakage

Current, Any One Channel

= V

or GND

(Figure 4)

12.0

0.1

0.5

1.0

Product parametric performance is indicated in the Electrical Characteristics for the listed test conditions, unless otherwise noted. Product

performance may not be indicated by the Electrical Characteristics if operated under different conditions.

†At supply voltage (V

) approaching 3 V the analog switch−on resistance becomes extremely non−linear. Therefore, for low−voltage

operation, it is recommended that these devices only be used to control digital signals.

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Guaranteed Limit

85°C

Symbol

PLH

PHL

Parameter

– 55 to

25°C

125°C

Unit

Maximum Propagation Delay, Analog Input to Analog Output

(Figures 8 and 9)

2.0

3.0

4.5

9.0

12.0

2.0

3.0

4.5

9.0

12.0

2.0

3.0

4.5

9.0

12.0

−

PLZ

PHZ

Maximum Propagation Delay, ON/OFF Control to Analog Output

(Figures 10 and 11)

110

PZL

PZH

Maximum Propagation Delay, ON/OFF Control to Analog Output

(Figures 10 and 1 1)

100

Maximum Capacitance

ON/OFF Control Input

Control Input = GND

Analog I/O

Feedthrough

1.0

Typical @ 25°C, V

= 5.0 V

Power Dissipation Capacitance (Per Switch) (Figure 13)*

* Used to determine the no−load dynamic power consumption: P

= C

CC2

f + I

AC ELECTRICAL CHARACTERISTICS

= 50 pF, ON/OFF Control Inputs: t

= t

= 6 ns)

http://onsemi.com

MC74HC4066A

ADDITIONAL APPLICATION CHARACTERISTICS

(Voltages Referenced to GND Unless Noted)

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Symbol

Parameter

Test Conditions

Limit*

25°C

54/74HC

150

160

Unit

Maximum On−Channel Bandwidth or

Minimum Frequency Response

(Figure 5)

Off−Channel Feedthrough Isolation

(Figure 6)

= 1 MHz Sine Wave

Adjust f

Voltage to Obtain 0 dBm at V

Increase f

Frequency Until dB Meter Reads – 3 dB

= 50

= 10 pF

Sine Wave

Adjust f

Voltage to Obtain 0 dBm at V

= 10 kHz, R

= 600

= 50 pF

= 1.0 MHz, R

= 50

= 10 pF

4.5

9.0

12.0

4.5

9.0

12.0

4.5

9.0

12.0

4.5

9.0

12.0

4.5

9.0

12.0

4.5

9.0

12.0

4.5

9.0

12.0

MHz

−

130

200

100

−

Feedthrough Noise, Control to

Switch

(Figure 7)

1 MHz Square Wave (t

= t

= 6 ns)

Adjust R

at Setup so that I

= 0 A

= 600

= 50 pF

= 10 kW, C

= 10 pF

−

Crosstalk Between Any Two

Switches

(Figure 12)

Sine Wave

Adjust f

Voltage to Obtain 0 dBm at V

= 10 kHz, R

= 600

= 50 pF

= 1.0 MHz, R

= 50

= 10 pF

– 70

– 80

THD

Total Harmonic Distortion

(Figure 14)

= 1 kHz, R

= 10 kW, C

= 50 pF

THD = THD

Measured

−

THD

Source

= 4.0 V

sine wave

= 8.0 V

sine wave

= 11.0 V

sine wave

4.5

9.0

12.0

0.10

0.06

0.04

*Guaranteed limits not tested. Determined by design and verified by qualification.

http://onsemi.com

ping,telnet,ftp的问题，要疯掉了: 我原来是用天嵌2440的板子，现在硬件工程师重新画了底板网络芯片也由DM9000换成DM9000A...; axiulam1977 嵌入式系统

PCB布局设计检视要素布局的DFM要求: 　　1 已确定优选工艺路线，所有器件已放置PCB板面。　　2 坐标原点为板框左、下延伸线交点，或...; ESD技术咨询 PCB设计

MSP430编程器仿真器JTAG、SBW、BSL接口的区别: 对于MSP430来说，无论仿真还是烧写程序一般可以通过：JTAG、SBW、BSL接口进行。JTAG...; qwqwqw2088 微控制器 MCU

TMS320F240的框架程序是怎样的？: 用C语言表示，谢谢各位了！ TMS320F240的框架程序是怎样的？来打酱油的 kemasz...; 面纱如雾 DSP 与 ARM 处理器

北京某公司招聘DSP工程师，薪资1W起（猎头职位）: DSP算法（视频）工程师 1 在TI的C64X或C64X+内核的DSP上移植过语音或视频算...; yewuyi 嵌入式系统

【2024 DigiKey 创意大赛】+功能: 项目概述和主要工作内容，以下是对项目的详细分析：针对您提出的项目，以下是对软件规划部分的...; meiyao DigiKey得捷技术专区

投资约100亿！孚能科技年产30GWh动力生产基地机电项目开工

　　近日，由中建安装旗下南方公司承建的孚能科技年产30GWh动力生产基地机电项目开工。　　该项目位于广州市黄埔区知识城改革大道以东、人才大道以北，总建筑面积约20万平方米，中建安装建设内容包括电芯车间、化成车间、PACK车间、动力站房等单体的机电安装工程。该项目建成投产后，将实现年产30GWh动力电池的产能，有望带动正极材料、硅碳负极、锂电设备等一批上下游配套产...[详细]
如何实现一种基于STM32单片机的智能浴室水温调控仪设计

一、功能简介本项目使用Proteus8.12仿真STM32单片机控制器，使用LCD1602、DS18B20、继电器加热、电机模块等。系统运行后，LCD1602显示DS18B20采集温度值、温度上限阈值。开启加水，一段时间后开启加热，当水位到达后停止注水，继续加热到设定温度，可通过K1、K2键对温度上限设置，若检测温度大于或等于上限，关闭加热装置；若温度低于上限，开启加热装置；主要功...[详细]
日开发内窥镜手术辅助机器人可模拟手指功能

日本研究人员最新开发出一种机器人，可帮助医生进行内窥镜手术，提高手术效率和精确度。心脏病手术等胸外科手术一般要开胸，不仅会留下较大伤口，还需长期住院恢复。而内窥镜手术伤口小、恢复快，但器械操作精确度受到限制。日本奥林巴斯公司日前说，他们与东京大学合作开发出这种可辅助内窥镜手术的机器人。这种机器人可模拟手指、肘关节等多个部位的功能，灵活地避开肋骨等障碍物进行手术...[详细]
TPS61072 - ThinSOT-23 封装、效率高达90%、可调式600 mA 开关的PFM/PWM升压转换器

TPS6107x 器件为使用单体、双体或三体碱性、镍镉或镍氢电池或者单体锂离子或锂聚合物电池供电的产品提供了出色的电源解决方案。在使用单体碱性电池时，输出电流可高达 75 mA，并且可以将其放电至 0.9 V。此外，使用该器件还可以通过 3.3 V 电源轨或锂离子电池，在 200 mA 的电流下生成 5 V 的电压。升压转换器基于采用同步整流器的固定频率脉宽调制 (PWM) 控制器，以获得最大的效...[详细]
盛大云计算大赛开源作品：开源与商业并不冲突

盛大云计算创意&开发大赛（www.openpk.org）自2011年11月26日开赛以来，涌现了无数开源作品，其中最具代表性的有业已成型的Ruby中文社区、开源力量FocusSNS以及正在开发阶段的Node.js应用平台。谈到为何要选择开源，开发者们的回答各有不同，但共同点是大家都是有意识地进行开源的。如Node.js应用平台项目的开发者小马表示，分享是互联网的核心精神之一。互联网能发展...[详细]
雷军:曾经干掉山寨机,现在干掉山寨店

雷军文/金错刀雷军、马云放话说新零售即将来临，刘强东表示“新零售不就是我一直干的事吗？” 新零售到底是个啥？刀哥最近参加了小米的春季闭门研讨会，雷军说，新零售的本质是互联网带来的效率革命，小米曾经跟国产手机干掉了山寨手机，下一步，干掉山寨店！除了交出新零售答案，雷军说的这三个点也挺让刀哥震惊！小米面临的是1000亿、10000员工的坎，存在多维度的复杂、痛苦！小米之家坪效达到...[详细]
基于SST89C54/58的单片机仿真器的设计

1 概述　　SST89C54／58(简称89C54／58)是美国SST公司推出的多用途51系列单片机，片内集成了20 kB／36 kB的SuperFlashE'PROM程序存储器，分为BLOCK0(16kB／32kB)和BLOCKl(4kB)两块。其中，BLOCKl可以映射(Mapping)到64kB存储空间的最高端或最低端，而且，对于程序计数器来说可以是不可见的。由于其存储结构上独特的优...[详细]
移相全桥ZVS变换器整流桥寄生振荡的抑制

1　引　言　　移相全桥零电压开关PWM变换器(PS-FB- ZVS-PWM converter)利用变压器的漏感或原边串联电感和功率管的寄生电容或外接电容来实现零电压开关,同时又实现了PWM控制。该变换器电路结构简洁,控制电路简单,是中大功率直直变换场合的理想电路拓扑之一。　　但是，传统的移相全桥变换器输出整流二极管不是工作在软开关状态，存在反向恢复过程。在输出整流二极管反向恢复时，由于变...[详细]
小米为何向GoPro抛出橄榄枝？

　　4月12日盘中，美国运动相机厂商 GoPro (NASDAQ:GPRO)股价一度大涨7.2%。因为有传言称，小米有意向收购 GoPro 。下面就随嵌入式小编一起来了解一下相关内容吧。　　01 　　收购传言　　4月12日盘中，美国运动相机厂商 GoPro (NASDAQ:GPRO)股价一度大涨7.2%。因为有传言称，小米有意向收购 GoPro 。　　此前，该公司股价年内一...[详细]
仪器行业这四大发展趋势，你一定要知道

我国的仪器行业起步相对较晚，历经二十余年的摸爬滚打，如今市场规模在不断扩大，市场格局也正在悄然发生改变。“十二五”以来，制造业受到了国家政策的支持和鼓励，仪器行业借时代东风，也取得了相当显著的成就。在科学技术技术迅猛发展的今天，智能化、小型化、专业化、联用化无疑将成为仪器行业未来发展的重要方向。智能化——紧跟时代大势所趋随着现代科技的高速发展和普及，智能化已经逐渐融入到了社会的方方...[详细]
C51软件精确延时(us级)

C语言代码如下： /*---------------------------------------------------------------------- Function: 软件精确延时 Descripton: 一种是利用C51的赋值、比较、自减三个单周期指令实现的软件延时; 另一种是利用C51库函数_nop_()软件延时一个机器周期。系统晶振频率为: 11.0592MHz Au...[详细]
强攻服务器市场　AMD研发64位ARM处理器

超微(AMD)正全力冲刺微型伺服器市场。随着小型资料中心与企业用伺服器市场需求日益增长，微型伺服器商机规模正不断扩大，吸引各家晶片商争相卡位此一市场；其中，超微为提供功耗更低、效能更佳的伺服器晶片，已携手安谋国际(ARM)开发新一代64位元系统单晶片(SoC)，预计于2014下半年开始量产。 AMD企业副总裁暨伺服器业务部门总经理Suresh Gopalakrishnan表示，ARM架...[详细]
USB 总线接口芯片CH375的特点、封装及引脚

1、概述　　CH375 是一个USB总线的通用接口芯片，支持USB-HOST主机方式和USB-DEVICE/SLAVE 设备方式。在本地端，CH375 具有8 位数据总线和读、写、片选控制线以及中断输出，可以方便地挂接到单片机/DSP/MCU/MPU等控制器的系统总线上。在USB 主机方式下，CH375还提供了串行通讯方式，通过串行输入、串行输出和中断输出与单片机/DSP/MCU...[详细]
中兴熊辉：欧洲除手机外市场预计今年增长50%

2月26日消息，中兴通讯高级副总裁熊辉今日在MWC向网易科技表示，自己在接手欧洲、拉美、北美的非手机业务市场后，将在不减少对运营商业务投入的情况下积极拓展其他业务，这块市场预计在欧洲地区2014年营收上同比增长50%。熊辉在中兴做过相当多的职位，研发、手机市场推广、北美终端销售。直到今年初，中兴再次调整架构，他成为了欧美区域除手机终端以外业务的负责人。在这个领域，属于他管辖的业务还包括...[详细]
智能密集架控制系统有哪些

智能密集架控制系统是一种高度自动化的存储设备，广泛应用于图书馆、档案馆、仓库等场所。它通过计算机技术、网络技术、传感器技术等多种技术手段，实现对密集架的智能化控制和管理。一、智能密集架控制系统概述 1.1 智能密集架控制系统定义智能密集架控制系统是一种集成了多种先进技术的自动化存储设备，它能够实现对密集架的自动控制、监控和管理，提高存储效率，降低人工成本，保障存储安全。 1.2 智能密集...[详细]