MAX6301ESA+T,MAX6301ESA+T pdf中文资料,MAX6301ESA+T引脚图,MAX6301ESA+T电路-Datasheet-电子工程世界

文档预览

19-1078; Rev 4; 9/10

+5V, Low-Power µP Supervisory Circuits

with Adjustable Reset/Watchdog

_______________General Description

The MAX6301–MAX6304* low-power microprocessor

(µP) supervisory circuits provide maximum adjustability

for reset and watchdog functions. The reset threshold

can be adjusted to any voltage above 1.22V, using

external resistors. In addition, the reset and watchdog

timeout periods are adjustable using external capaci-

tors. A watchdog select pin extends the watchdog time-

out period to 500x. The reset function features immunity

to power-supply transients.

These four devices differ only in the structure of their reset

outputs (see the

Selector Guide).

The MAX6301–MAX6304

are available in the space-saving 8-pin µMAX

package,

as well as 8-pin PDIP and SO packages.

____________________________Features

Adjustable Reset Threshold

Adjustable Reset Timeout

Adjustable Watchdog Timeout

500x Watchdog Timeout Multiplier

4µA Supply Current

RESET or

RESET

Output Options

Push-Pull or Open-Drain Output Options

Guaranteed

RESET

Asserted At or Above

= 1V (MAX6301/MAX6303)

Power-Supply Transient Immunity

Watchdog Function can be Disabled

PDIP/SO/µMAX Packages Available

MAX6301–MAX6304

Applications

Medical Equipment

Intelligent Instruments

Portable Equipment

Battery-Powered

Computers/Controllers

FEATURE

Active-Low

Reset

Active-High

Reset

Open-Drain

Reset Output

Push-Pull

Reset Output

Pin-Package

MAX6301

√

—

√

—

Embedded Controllers

Critical µP Monitoring

Set-Top Boxes

Computers

Ordering Information

PART

MAX6301CPA

MAX6301CSA

MAX6301CUA

MAX6301EPA

TEMP RANGE

0°C to +70°C

-40°C to +85°C

PIN-PACKAGE

8 PDIP

8 SO

8 µMAX

8 PDIP

Selector Guide

MAX6302

—

√

—

MAX6303

√

—

√

MAX6304

—

√

—

√

MAX6301ESA

-40°C to +85°C

8 SO

Devices are available in both leaded and lead(Pb)-free/RoHS-

compliant packaging. Specify lead-free by adding the “+”

symbol at the end of the part number when ordering.

Ordering Information continued at end of data sheet.

Typical Operating Circuit

MAX6301

ONLY

RESET IN

0.1µF

8-PDIP/SO/ 8-PDIP/SO/ 8-PDIP/SO/ 8-PDIP/SO/

µMAX

Pin Configuration

TOP VIEW

RESET IN

GND

SRT

SWT

RESET (RESET)

WDI

WDS

2 GND

RESET 7

(RESET)

MAX6302

ONLY

I/O

RESET

µP

MAX6301

MAX6302

MAX6303

MAX6304

MAX6301

MAX6302

WDI 6

SRT

MAX6303

SWT

MAX6304

WDS

SRT

SWT

( ) ARE FOR MAX6302/MAX6304.

DIP/SO/µMAX

( ) ARE FOR MAX6302/MAX6304.

WDS = 0 FOR NORMAL MODE

WDS = 1 FOR EXTENDED MODE

µMAX is a registered trademark of Maxim Integrated Products, Inc.

________________________________________________________________

Maxim Integrated Products

For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642,

or visit Maxim’s website at www.maxim-ic.com.

+5V, Low-Power µP Supervisory Circuits

with Adjustable Reset/Watchdog

MAX6301–MAX6304

ABSOLUTE MAXIMUM RATINGS

CC ....................................................................................

-0.3V to +7.0V

RESET IN, SWT, SRT ..................................-0.3V to (V

+ 0.3V)

WDI, WDS..............................................................-0.3V to +7.0V

RESET,

RESET

MAX6301… .......................................................-0.3V to +7.0V

MAX6302/MAX6303/MAX6304...............-0.3V to (V

+ 0.3V)

Input Current

...............................................................................±20mA

GND..............................................................................±20mA

Output Current

RESET,

RESET..............................................................±20mA

Continuous Power Dissipation (T

= +70°C)

PDIP (derate 9.09mW/°C above +70°C) ......................727mW

SO (derate 5.88mW/°C above +70°C) .........................471mW

µMAX (derate 4.10mW/°C above +70°C) ....................330mW

Operating Temperature Range

MAX630_C_A ......................................................0°C to +70°C

MAX630_E_A ...................................................-40°C to +85°C

Storage Temperature Range .............................-65°C to +160°C

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

Soldering Temperature (reflow)

Lead(Pb)-free...............................................................+260°C

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

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

= +2V to +5.5V, T

= T

MIN

to T

MAX

, unless otherwise noted. Typical values are at V

= +5V and T

= +25°C.)

PARAMETER

Operating Voltage Range

(Note 1)

Supply Current (Note 2)

RESET TIMER

Reset Input Threshold Voltage

Reset Input Hysteresis

Reset Input Leakage Current

Reset Output-Voltage High

(MAX6302/MAX6303/MAX6304)

HYST

RESET IN

≥

4.5V, I

SOURCE

= 0.8mA

= 2V, I

SOURCE

= 0.4mA

MAX6302/MAX6304, V

= 1.31V,

= 10kΩ

≥

4.5V, I

SINK

= 3.2mA

= 2V, I

SINK

= 1.6mA

Reset Output-Voltage Low

(MAX6301/MAX6303/MAX6304

MAX6301/

MAX6303

= 1V, I

SINK

= 50µA,

= 0°C to +70°C

= 1.2V, I

SINK

= 100µA,

= -40°C to +85°C

2.8

4.0

5.2

±1

0.3

0.4

0.3

µs

µA

- 0.4

RESET IN

falling, V

= 5.0V

RESET IN

rising, V

= 5.0V

1.195

1.220

1.240

±0.01

±1

1.245

1.265

SYMBOL

CONDITIONS

MAX6301C/MAX6303C

MAX6301E/MAX6303E

MAX6302/MAX6304

No load

MIN

1.00

1.20

1.31

4.0

TYP

MAX

5.50

7.0

µA

UNITS

to Reset Delay

Reset Input Pulse Width

Reset Timeout Period (Note 3)

Reset Output Leakage Current

= falling at 1mV/µs

Comparator overdrive = 50mV

SRT

= 1500pF

MAX6301, V

RESET

= V

MAX6302, V

RESET

= V

GND

_______________________________________________________________________________________

+5V, Low-Power µP Supervisory Circuits

with Adjustable Reset/Watchdog

ELECTRICAL CHARACTERISTICS (continued)

= +2V to +5.5V, T

= T

MIN

to T

MAX

, unless otherwise noted. Typical values are at V

= +5V and T

= +25°C.)

PARAMETER

WATCHDOG TIMER

WDI, WDS Input Threshold

WDI Pulse Width

WDI, WDS Leakage Current

WDI Sink/Source Current (Note 4)

Watchdog Timeout Period

(Note 3)

= 4.5V to 5.5V

= 2V to 4.5V

Extended mode disabled

Extended mode enabled

WDS = GND, C

SWT

= 1500pF

WDS = V

, C

SWT

= 1500pF

2.8

1.4

±70

4.0

2.0

5.2

2.6

±1

0.7 x V

0.3 x V

µA

SYMBOL

CONDITIONS

MIN

TYP

MAX

UNITS

MAX6301–MAX6304

Note 1:

Reset is guaranteed valid from the selected reset threshold voltage down to the minimum V

Note 2:

WDS = V

, WDI unconnected.

Note 3:

Precision timing currents of 500nA are present at both the SRT and SWT pins. Timing capacitors connected to these nodes

must have low leakage consistent with these currents to prevent timing errors.

Note 4:

The sink/source is supplied through a resistor, and is proportional to V

(Figure 8). At V

= 2V, it is typically ±24µA.

__________________________________________Typical Operating Characteristics

SWT

= C

SRT

= 1500pF, T

= +25°C, unless otherwise noted.)

RESET TIMEOUT PERIOD

vs. C

SRT

MAX6301-4 toc01

10,000

EXTENDED-MODE

WATCHDOG TIMEOUT PERIOD vs. C

SWT

(WDS = V

)

MAX6301-4 toc02

NORMAL-MODE

WATCHDOG TIMEOUT PERIOD vs. C

SWT

(WDS = GND)

= 5V

MAX6301-4 toc03

= 5V

10,000

WATCHDOG TIMEOUT PERIOD (s)

= 5V

10,000

WATCHDOG TIMEOUT PERIOD (ms)

RESET TIMEOUT PERIOD (ms)

1000

100

0.001

0.01

0.1

SRT

(nF)

100

1000

0.001

0.01

0.1

SWT

(nF)

100

1000

0.1

0.001

0.01

0.1

SWT

(nF)

100

1000

_______________________________________________________________________________________

+5V, Low-Power µP Supervisory Circuits

with Adjustable Reset/Watchdog

MAX6301–MAX6304

____________________________Typical Operating Characteristics (continued)

SWT

= C

SRT

= 1500pF, T

= +25°C, unless otherwise noted.)

SUPPLY CURRENT

vs. SUPPLY VOLTAGE

MAX6301-4 toc04

RESET AND NORMAL-MODE

WATCHDOG TIMEOUT PERIOD

vs. TEMPERATURE

MAX6301-4 toc05

MAXIMUM TRANSIENT DURATION

vs. RESET THRESHOLD OVERDRIVE (V

RST

)

120

110

100

TRANSIENT DURATION (µs)

RST

= 4.60V

200

400

600

800

1000

RESET OCCURS

ABOVE THE CURVE

SEE THE

NEGATIVE-GOING

TRANSIENTS

SECTION

MAX6301-4 toc06

4.2

4.0

SUPPLY CURRENT (µA)

3.8

RESET DEASSERTED

NO LOAD

4.20

4.15

4.10

(ms)

4.05

4.00

3.95

3.90

3.85

3.80

= 5.0V

3.6

3.4

3.2

3.0

2.8

2.6

1.5

2.0 2.5 3.0 3.5 4.0

4.5 5.0 5.5 6.0

SUPPLY VOLTAGE (V)

-60

-40

-20

100

TEMPERATURE (°C)

RESET THRESHOLD OVERDRIVE (mV)

SUPPLY CURRENT

vs. TEMPERATURE

MAX6301-4 toc07

RESET IN THRESHOLD VOLTAGE

vs. TEMPERATURE

MAX6301-4 toc08

5.00

4.75

4.50

SUPPLY CURRENT (µA)

4.25

4.00

3.75

3.50

3.25

3.00

2.75

2.50

-60

-40

-20

= 2.0V

= 5.0V

RESET DEASSERTED

NO LOAD

1.226

RESET REFERENCE VOLTAGE (V)

1.224

1.222

1.220

1.218

1.216

1.214

-60

100

-40

-20

100

TEMPERATURE (°C)

TO RESET DELAY

vs. TEMPERATURE (V

FALLING)

FALLING AT 1mV/µs

PROPAGATION DELAY (µs)

-60

4.00

MAX6301-4 toc09

RESET AND WATCHDOG

TIMEOUT vs. SUPPLY VOLTAGE

MAX6301-4 toc10

4.16

4.12

(ms)

4.08

4.04

3.96

-40 -20

100

(V)

TEMPERATURE (°C)

_______________________________________________________________________________________

+5V, Low-Power µP Supervisory Circuits

with Adjustable Reset/Watchdog

Pin Description

NAME

RESET IN

GND

SRT

FUNCTION

Reset Input. High-impedance input to the reset comparator. Connect this pin to the center point of an

external resistor voltage-divider network to set the reset threshold voltage. The reset threshold voltage is

calculated as follows: V

RST

= 1.22 x (R1 + R2)/R2 (see the

Typical Operating Circuit).

Ground

Set Reset-Timeout Input. Connect a capacitor between this input and ground to select the reset timeout

period (t

). Determine the period as follows: t

= 2.67 x C

SRT

, with C

SRT

in pF and t

in µs (see the

Typical Operating Circuit).

Set Watchdog-Timeout Input. Connect a capacitor between this input and ground to select the basic

watchdog timeout period (t

). Determine the period as follows: t

= 2.67 x C

SWT

, with C

SWT

in pF and

in µs. The watchdog function can be disabled by connecting this pin to ground.

Watchdog-Select Input. This input selects the watchdog mode. Connect to ground to select normal mode

and the basic watchdog timeout period. Connect to V

to select extended mode, multiplying the basic

timeout period by a factor of 500. A change in the state of this pin resets the watchdog timer to zero.

Watchdog Input. A rising or falling transition must occur on this input within the selected watchdog timeout

period, or a reset pulse will occur. The capacitor value selected for SWT and the state of WDS determine

the watchdog timeout period. The watchdog timer clears and restarts when a transition occurs on WDI or

WDS. The watchdog timer is cleared when reset is asserted and restarted after reset deasserts. In the

extended watchdog mode (WDS = V

), the watchdog function can be disabled by driving WDI with a

three-stated driver or by leaving WDI unconnected.

Open-Drain, Active-Low Reset

Output (MAX6301)

Push-Pull, Active-Low Reset

Output (MAX6303)

RESET

changes from high to low whenever the monitored voltage (V

)

drops below the selected reset threshold (V

RST

RESET

remains low as

long as V

is below V

RST

. Once V

exceeds V

RST

RESET

remains low

for the reset timeout period and then goes high. The watchdog timer

triggers a reset pulse (t

) whenever the watchdog timeout period (t

)

is exceeded.

MAX6301–MAX6304

SWT

WDS

WDI

RESET

(MAX6301/

MAX6303)

RESET

(MAX6302/

MAX6304

RESET changes from low to high whenever the monitored voltage (V

)

Open-Drain, Active-High Reset drops below the selected reset threshold (V

RST

). RESET remains high as

Output (MAX6302)

long as V

is below V

RST

. Once V

exceeds V

RST

, RESET remains high

for the reset timeout period and then goes low. The watchdog timer

Push-Pull, Active-High Reset

triggers a reset pulse (t

) whenever the watchdog timeout period (t

)

Output (MAX6304)

is exceeded.

Supply Voltage. Bypass to ground with a 0.1µF capacitor placed as close as possible to the pin.

_______________________________________________________________________________________

型号	MAX6301ESA+T	MAX6302	MAX6303	MAX6304	MAX6301	MAX6303EPA+	MAX6303CSA+T	MAX6301CSA+TCL0	MAX6301CSA+T	MAX6301CSA+CL0
描述		1-CHANNEL POWER SUPPLY SUPPORT CKT, PDIP8	1-CHANNEL POWER SUPPLY SUPPORT CKT, PDIP8	1-CHANNEL POWER SUPPLY SUPPORT CKT, PDIP8	1-CHANNEL POWER SUPPLY SUPPORT CKT, PDIP8	Power Supply Management Circuit, Adjustable, 1 Channel, CMOS, PDIP8, LEAD FREE, PLASTIC, DIP-8	IC SUPERVISOR MPU 8-SOIC	IC SUPERVISOR MPU 8-SOIC	IC SUPERVISOR MPU 8-SOIC	IC SUPERVISORY CIRC 5V LP 8-SOIC
可调阈值	NO	YES	YES	YES	YES	YES	NO	-	NO	-
功能数量	1	1	1	1	1	1	1	-	1	-
端子数量	8	8	8	8	8	8	8	-	8	-
表面贴装	YES	NO	NO	NO	NO	NO	YES	-	YES	-
温度等级	INDUSTRIAL	INDUSTRIAL	INDUSTRIAL	INDUSTRIAL	INDUSTRIAL	INDUSTRIAL	COMMERCIAL	-	COMMERCIAL	-
端子形式	GULL WING	THROUGH-HOLE	THROUGH-HOLE	THROUGH-HOLE	THROUGH-HOLE	THROUGH-HOLE	GULL WING	-	GULL WING	-
端子位置	DUAL	DUAL	DUAL	DUAL	DUAL	DUAL	DUAL	-	DUAL	-

有人用过2440的ADC么?请教下.不能启动转换.大家帮我分析下.: 部分程序如下: pADCreg- rADCCON = (1 14)|(200 6)|(0 3); a...; ronc 嵌入式系统

我想使用模拟器，可是虚拟网卡安装不上？: 求助！！！！！我想使用模拟器，可是虚拟网卡安装不上？在XP里有虚拟网卡的,或者链接到Intern...; wide 嵌入式系统

【把玩LPC810 mini】MRT，以及LPCopen下可怜的810 ROM: 本帖最后由 johnrey 于 2015-7-15 21:23 编辑 LPC810带的定时器...; johnrey NXP MCU

【求助】用单片机驱动8欧姆喇叭: 如题，应该如何驱动呢？我上网查了查，没找到相关的电路图orz。。。。告诉我怎么查也可以：）我想用两...; zgyzsq 嵌入式系统

2011年全国大学生电子设计竞赛试题: 本帖最后由 paulhyde 于 2014-9-15 04:26 编辑 2011年全国大学生电...; 謃塰电子竞赛

【转】全美经典电路: 全美经典电路【转】全美经典电路十分不错的资料，对理解电子方面有一定的帮助，谢谢提供，很...; lixiaohai8211 模拟电子

硬盘插上无线的翅膀后能飞多远？

　　希捷的数字影音体验(D.A.V.E.)技术平台是一个移动无线存储平台，让用户可利用个人选择的设备来下载、存储和播放照片、音乐、视频和商业文件，目前，已有不少成功的客户案例，也浮现了一些与D.A.V.E.平台搭配应用的数字设备。　　创新的无线D.A.V.E.平台是什么样的呢，我们首先来看看它的功能　　D.A.V.E.平台： ·具备60 GB的容量，可存储多达15,000首歌曲；6...[详细]
汽车MCU的特点和要求

MCU作为一颗性能进行裁剪的小芯片，性能指标是一组综合指标，包括产品内核、主频、存储单元、对外接口、控制方式、AD通道数、工作电压、封装方式、引脚数量和温度适应性等指标，用户在使用时还会考虑工具链的可用性、性价比、可靠性等综合因素，MCU比拼的是对应用场景需求理解程度，比拼的是综合的一揽子指标。 MCU的下游是嵌入式开发，嵌入式开发选择的原则：功能特点、可用性、成本和熟悉程度。MCU是一颗应...[详细]
不专注便成仁...惠普的失败经验

导读：MarketWatch专栏作家辛奈尔(John Shinal)认为，惠普要真正让企业和股价走出困境，唯一的选择只能是拆分，而考虑到该公司董事会糟糕的历史表现，他们做出正确决定的可能性极为有限。以下即辛奈尔的评论文章全文：首席执行官惠特曼(Meg Whitman)上任周年之际，惠普(HPQ)的盈利研讨会却成为了华尔街对她集体吐槽的机会，真是令人慨叹。我希望投资者明白，惠普...[详细]
引领32位MCU市场，ST STM32F7系列重磅登场

在嵌入式设备当中，随着对各种各样可连接性和工业控制应用需求的发展，越来越多的处理器对于性能提出更高要求。尤其是在高端MCU、工业控制、传感器中枢、物联网以及汽车电子，这些非常追逐高性能计算的市场。　　为了适应市场不断追求性能的脚步，2014年9月24日，ARM宣布推出最新的32位Cortex-M处理器Cortex-M7，这款处理器相较于目前性能最高的ARM架构微控制器，可大幅提升两倍...[详细]
美光推出全新 Crucial 英睿达 P5 Plus PCIe SSD

美光推出全新 Crucial 英睿达 P5 Plus PCIe SSD 释放第 4 代速度，提升消费者 PC 性能全新 Crucial 英睿达 NVMe SSD 将美光 NAND 和 PCIe Gen4 性能融为一体，适用于密集型工作负载，如视频编辑、内容创建、工程应用和游戏。关键优势： • PCIe® 4.0 NVMe™ 技术，顺序读取速度高达 6600MB/秒 •...[详细]
PLC编程基本九步走，你知道吗

科学的编程步骤其实很简单，但往往大多数工程师就是认为简单而忽略很多细节。细节的忽略，必然会在以后出现问题。想避免日后的问题，只有好好的遵守规则，没有规矩不成方圆，plc编程一样有其自身的规矩。 01阅读产品说明书这绝对不是在忽悠你，第一步最容易被忽视了，即使是工程师也不例外。不要认为这一步是浪费时间，看过说明书反而会为后面的操作省不少时间。首先要阅读安全守则，知道哪些执行机构可能会对人身...[详细]
高电压放大器把库仑计数器范围扩展至 ±270V

库仑计数器能够测量流入或流出电池的电荷，而小的专用 IC 则可直接与约 20V 以下的中低电池电压相连。通过采用一个高电压放大器作为电平移位器，就能把测量电路的输入工作范围扩展至高得多的电压。LT6375 电压差动放大器具备一些可使该电路在极宽电压范围内准确工作的特性。下面就随模拟电子小编一起来了解一下相关内容吧。作者：凌力尔特公司(现隶属 Analog Devices 公司) 信号调理产...[详细]
“十四五”，南方电网建设智能电网这么干！

中国储能网讯：日前，南方电网公司党组成员、副总经理陈允鹏主持召开“十四五”智能电网发展规划推进视频会议。南方电网将统筹规划煤、水、电、油、气、核、新能源等各品种及其开发、配置、储存、消费等各环节，做好功能、结构和建设时序的衔接，推动构建“清洁、经济、多元、协调”的电源发展格局；稳定西电东送，新增北电南送，加强清洁能源问题研究，充分发挥各地区比较优势，推动形成优势互补、高质量发展的区域经济布...[详细]
海信周厚健：互联网电视还没有革命性变化

全球电视业每年高达5000亿美元的市场正遭遇“门口的野蛮人”。　　“传统电视制造业有沦为标准显示终端代工厂的危险。”9月26日，海信集团首席科学家黄卫平对记者表示，在互联网概念的冲击下，传统电视产业链中不管是内容商、运营商，还是终端生产商都有面临颠覆的可能。　　在全球来看，谷歌、苹果对电视业虎视眈眈。而在中国，乐视、小米等跨界者已纷纷推出互联网电视产品，与此同时，创维、TCL...[详细]
华北工控2011年纽伦堡国际嵌入式系统展精彩回顾

　　2011年3月3日，2011年纽伦堡国际嵌入式系统展在纽伦堡顺利闭幕，华北工控借助这个国际舞台展示精湛的生产力和研发实力，此次参展重点展示包括嵌入式主板、网络存储、数字标牌、轨道交通等在内的30多款高品质、个性化的嵌入式计算机产品。丰富的展品吸引众多参观者前来观摩洽谈。华北工控展位　　华北工控展出的嵌入式产品体现出的小体积、低耗高能、创新灵活、稳定可靠及个性化定制等优势让参观者叫...[详细]
汽车半导体安规与封装质检介绍（下）

在上篇中，我们有提到随着汽车所支持的功能越来越多，业内对于车载电子的要求也越来越严苛，这也导致了车规级芯片呈现产业化周期漫长和供应体系门槛高的特点。也简单介绍了针对公司层面的 IATF 16949 质量管理体系与 VDA6.3 标准。本文将介绍针对具体元器件层面的 AEC-Q 标准，并分享长电科技在车载芯片认证领域所做出的努力。 AEC 标准就是目前汽车电子零部件的通用测试规范。AEC，即...[详细]
据传4G牌照11月28日发放概念股受关注

4G 牌照将于11月28号正式发放，受此影响，今日市场4G概念股再次走强，盘中奥维通信(行情,问诊)快速拉升封死涨停，带动硕贝德(行情,问诊)、富春通信(行情,问诊)、三维通信(行情,问诊)、杰赛科技(行情,问诊)、神州泰岳(行情,问诊)、天源迪科(行情,问诊)等个股活跃，盘中硕贝德大涨8%以上，富春通信、三维通信等大涨4%以上，4G概念股市场呈现全线活跃。消息面，据悉此...[详细]
大众ID3汽车的12V补电问题

大众的 MEB 平台的软件也是在逐步修复，在以下的视频里面，非常有趣的展示了大众在解决 12V 电池掉电的问题，还有引发掉电的原因，我们也就目前已知的信息做一些解读。 01、12V 小电池的补电设计如下图所示，这是我们典型的设计情况，在比较小的静态电流下，整车总线处于休眠状态，整体的 12V 电池电压处在缓慢变化的通道，车辆可以停放很久。图 1 典型电动汽车车辆停放 12V ...[详细]
电磁流量计应用中常遇问题总结

一、非轴对称流动造成的错误电磁流量计的速度分布对称分布管轴，生成电极的流体总流量在1统一的电动势力，流量计的液体流量计的平均流体流动速度速度分布的幅度磁场率，但无关，而不是比例。对称轴，即粒子的运动物体，每一个不同的位置电极形状的感应电动势取决于电极的电极，在粒子的速度更大，更贴近，感应电动势较大规模，所产生的是不同的，因此，你需要确保流体流动的对称轴。将导致一个错误，如发生非轴对称管流的分布...[详细]
讲讲我自己对ADC12模块的心得——MSP430f5529

AD部分主要配置ADC12模块的时钟、参考源、采样通道、采样模式、存储和采样保持。我就一个部分一个部分来。第一个是ADC12模块的时钟，这个是模块运行时的时钟，跟采样定时器是两个概念，曾经我有一段时间被迷惑住了。这个由ADC12CTL1里面的ADC12SSEL和ADC12DIV配置，可以选择ADC12OSC/ACLK/SMCLK/MCLK，TI例程里面好像都是选择的ADC12OSC，...[详细]