MAX1718EEI-C71059,MAX1718EEI-C71059 pdf中文资料,MAX1718EEI-C71059引脚图,MAX1718EEI-C71059电路-Datasheet-电子工程世界

文档预览

19-1960; Rev 4; 8/05

Notebook CPU Step-Down Controller for Intel

Mobile Voltage Positioning (IMVP -II)

General Description

The MAX1718 step-down controller is intended for core

CPU DC-DC converters in notebook computers. It fea-

tures a dynamically adjustable output, ultra-fast transient

response, high DC accuracy, and high efficiency need-

ed for leading-edge CPU core power supplies. Maxim’s

proprietary Quick-PWM™ quick-response, constant-on-

time PWM control scheme handles wide input/output

voltage ratios with ease and provides 100ns “instant-on”

response to load transients while maintaining a relatively

constant switching frequency.

The output voltage can be dynamically adjusted through

the 5-bit digital-to-analog converter (DAC) over a 0.6V to

1.75V range. The MAX1718 has an internal multiplexer

that accepts three unique 5-bit VID DAC codes corre-

sponding to Performance, Battery, and Suspend modes.

Precision slew-rate control

†

provides “just-in-time” arrival

at the new DAC setting, minimizing surge currents to

and from the battery.

The internal DAC of the MAX1718B is synchronized to

the slew-rate clock for improved operation under

aggressive power management of newer chipsets and

operating systems that can make incomplete mode tran-

sitions.

A pair of complementary offset control inputs allows

easy compensation for IR drops in PC board traces or

creation of a voltage-positioned power supply. Voltage-

positioning modifies the load-transient response to

reduce output capacitor requirements and total system

power dissipation.

Single-stage buck conversion allows these devices to

directly step down high-voltage batteries for the highest

possible efficiency. Alternatively, two-stage conversion

(stepping down the 5V system supply instead of the bat-

tery) at a higher switching frequency allows the mini-

mum possible physical size.

The MAX1718 is available in a 28-pin QSOP package.

♦

Features

Quick-PWM Architecture

±1% V

OUT

Accuracy Over Line and Load

5-Bit On-Board DAC with Input Muxes

Precision-Adjustable V

OUT

Slew Control

0.6V to 1.75V Output Adjust Range

Precision Offset Control

Supports Voltage-Positioned Applications

2V to 28V Battery Input Range

Requires a Separate 5V Bias Supply

200/300/550/1000kHz Switching Frequency

Over/Undervoltage Protection

Drives Large Synchronous-Rectifier FETs

700µA (typ) I

Supply Current

2µA (typ) Shutdown Supply Current

2V ±1% Reference Output

VGATE Blanking During Transition

Small 28-Pin QSOP Package

MAX1718

Ordering Information

PART

MAX1718EEI

MAX1718BEEI+

MAX1718BEEI

TEMP RANGE

-40°C to +85°C

PIN-PACKAGE

28 QSOP

MAX1718BEEIB+

-40°C to +85°C

+Denotes

lead-free package.

Minimal Operating Circuit

5V INPUT

BATT 2V TO 28V

SKP/SDN

SHUTDOWN

ILIM

V+

BST

MAX1718

DUAL MODE VID

MUX INPUTS

ZMODE

SUS

TIME

REF

TON

VGATE

OVP

NEG

POS

GND

OUTPUT

0.6V TO 1.75V

Applications

IMVP-II™ Notebook Computers

2-Cell to 4-Cell Li+ Battery to CPU Core Supply

Converters

5V to CPU Core Supply Converters

Pin Configuration appears at end of data sheet.

MUX CONTROL

SUSPEND

INPUT

DECODER

VCC

†

Patent pending.

Quick-PWM is a trademark of Maxim Integrated Products, Inc.

IMVP-II is a trademark of Intel Corp.

POWER-GOOD

OUTPUT

________________________________________________________________

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.

Notebook CPU Step-Down Controller for Intel

Mobile Voltage Positioning (IMVP -II)

MAX1718

ABSOLUTE MAXIMUM RATINGS

V+ to GND ..............................................................-0.3V to +30V

, V

to GND .....................................................-0.3V to +6V

D0–D4, ZMODE, VGATE,

OVP,

SUS, to GND .........-0.3V to +6V

SKP/SDN to GND ...................................................-0.3V to +16V

ILIM, CC, REF, POS, NEG, S1, S0,

TON, TIME to GND .................................-0.3V to (V

+ 0.3V)

DL to GND ..................................................-0.3V to (V

+ 0.3V)

BST to GND ............................................................-0.3V to +36V

DH to LX .....................................................-0.3V to (BST + 0.3V)

LX to BST..................................................................-6V to +0.3V

REF Short Circuit to GND ...........................................Continuous

Continuous Power Dissipation

28-Pin QSOP (derate 10.8mW/°C above +70°C).........860mW

Operating Temperature Range ..........................-40°C to +85°C

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

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

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

(Circuit of Figure 1, V+ = 15V, V

= V

= SKP/SDN

= 5V, V

OUT

= 1.25V,

= 0°C to +85°C,

unless otherwise noted.)

PARAMETER

PWM CONTROLLER

Input Voltage Range

Battery voltage, V+

, V

V+ = 4.5V to 28V,

includes load

regulation error

DAC codes from 0.9V to 1.75V

DAC codes from 0.6V to 0.875V

4.5

-1

-1.5

-0.2

0.4

-80

0.81

-8

-12

230

165

320

465

260

190

355

515

400

300

700

SKP/SDN = GND

SKP/SDN = GND, V

= V

= 0V or 5V

= 4.5V to 5.5V, no REF load

1.98

+0.2

2.5

+80

0.91

+12

290

215

390

565

500

375

1200

2.02

5.5

+1.5

µA

V/V

CONDITIONS

MIN

TYP

MAX

UNITS

DC Output Voltage Accuracy

Line Regulation Error

Input Bias Current

POS, NEG Common-Mode Range

POS, NEG Differential Range

POS, NEG Offset Gain

TIME Frequency Accuracy

= 4.5V to 5.5V, V

BATT

= 4.5V to 28V

FB, POS, NEG

POS - NEG

∆V

/ (POS - NEG); POS - NEG = 50mV

150kHz nominal, R

TIME

= 120kΩ

380kHz nominal, R

TIME

= 47kΩ

38kHz nominal, R

TIME

= 470kΩ

V+ = 5V, FB = 1.2V, TON = GND (1000kHz)

TON = REF (550kHz)

V+ = 12V, FB = 1.2V

TON = open (300kHz)

TON = V

(200kHz)

0.86

On-Time (Note 1)

Minimum Off-Time (Note 1)

BIAS AND REFERENCE

Quiescent Supply Current (V

)

Quiescent Supply Current (V

)

Quiescent Battery Supply

Current (V+)

Shutdown Supply Current (V

)

Shutdown Supply Current (V

)

Shutdown Battery Supply

Current (V+)

Reference Voltage

TON = V

, open, or REF (200kHz, 300kHz, or 550kHz)

TON = GND (1000kHz)

Measured at V

, FB forced above the regulation point

Measured at V

, FB forced above the regulation point

µA

_______________________________________________________________________________________

Notebook CPU Step-Down Controller for Intel

Mobile Voltage Positioning (IMVP -II)

ELECTRICAL CHARACTERISTICS (continued)

(Circuit of Figure 1, V+ = 15V, V

= V

= SKP/SDN = 5V, V

OUT

= 1.25V,

= 0°C to +85°C,

unless otherwise noted.)

PARAMETER

Reference Load Regulation

REF Sink Current

FAULT PROTECTION

Overvoltage Trip Threshold

Overvoltage Fault Propagation

Delay

Output Undervoltage Fault

Protection Threshold

Output Undervoltage Fault

Propagation Delay

Output Undervoltage Fault

Blanking Time

Current-Limit Threshold Voltage

(Positive, Default)

Current-Limit Threshold Voltage

(Positive, Adjustable)

Current-Limit Threshold Voltage

(Negative)

Current-Limit Threshold Voltage

(Zero Crossing)

Current-Limit Default

Switchover Threshold

Thermal Shutdown Threshold

Undervoltage Lockout

Threshold

VGATE Lower Trip Threshold

VGATE Upper Trip Threshold

VGATE Propagation Delay

VGATE Output Low Voltage

VGATE Leakage Current

GATE DRIVERS

DH Gate Driver On-Resistance

DL Gate Driver On-Resistance

DH Gate-Driver Source/Sink

Current

DL Gate-Driver Sink Current

BST - LX forced to 5V

DL, high state (pullup)

DL, low state (pulldown)

DH forced to 2.5V, BST - LX forced to 5V

DL forced to 2.5V

1.0

0.4

1.6

3.5

1.0

Ω

Hysteresis = 10°C

Rising edge, hysteresis = 20mV, PWM disabled below

this level

Measured at FB with respect to unloaded output voltage

FB forced 2% outside VGATE trip threshold

SINK

= 1mA

High state, forced to 5.5V

4.1

-12

-10

+10

0.4

Measured at FB

FB forced 2% above trip threshold

With respect to unloaded output voltage

FB forced 2% below trip threshold

From SKP/SDN signal going high, clock speed set by R

TIME

GND - LX, ILIM = V

GND - LX

LX - GND, ILIM = V

GND - LX

= +25°C to +85°C

= 0°C to +85°C

ILIM = 0.5V

ILIM = REF (2V)

165

-140

200

-117

- 1 V

- 0.4

150

4.4

-8

+12

1.95

2.00

256

100

110

115

230

-95

°C

µs

µA

2.05

µs

REF

= 0µA to 50µA

REF in regulation

CONDITIONS

MIN

TYP

MAX

0.01

UNITS

µA

MAX1718

clks

_______________________________________________________________________________________

Notebook CPU Step-Down Controller for Intel

Mobile Voltage Positioning (IMVP -II)

MAX1718

ELECTRICAL CHARACTERISTICS (continued)

(Circuit of Figure 1, V+ = 15V, V

= V

= SKP/SDN = 5V, V

OUT

= 1.25V,

= 0°C to +85°C,

unless otherwise noted.)

PARAMETER

DL Gate-Driver Source Current

Dead Time

LOGIC AND I/O

Logic Input High Voltage

Logic Input Low Voltage

DAC B-Mode Programming

Resistor, Low

DAC B-Mode Programming

Resistor, High

D0–D4 Pullup/Pulldown

Logic Input Current

D0–D4, ZMODE, SUS,

OVP

D0–D4, ZMODE, SUS,

OVP

D0–D4, 0 to 0.4V or 2.6V to 5.5V applied through resistor,

ZMODE = V

D0–D4, 0 to 0.4V or 2.6V to 5.5V applied through resistor,

ZMODE = V

Entering impedance mode

D0–D4, ZMODE = GND

ZMODE, SUS,

OVP

For high

4 Level Input Logic Levels

(TON, S0, S1)

For open

For REF

For low

SKP/SDN, S0, S1, and TON Input

Current

SKP/SDN, S0, S1, TON forced to GND or V

SKP/SDN = logic high (SKIP mode)

SKP/SDN = open (PWM mode)

SKP/SDN = logic low (shutdown mode)

To enable no-fault mode

SKP/SDN

= 0µA

-3

2.8

1.4

1.8

Pullup

Pulldown

-1

- 0.4

3.15

1.65

3.85

2.35

0.5

2.2

0.5

2.2

µA

2.4

0.8

1.05

kΩ

µA

DL forced to 2.5V

DL rising

DH rising

CONDITIONS

MIN

TYP

1.6

MAX

UNITS

SKP/SDN Input Levels

SKP/SDN Float Level

ELECTRICAL CHARACTERISTICS

(Circuit of Figure 1, V+ = 15V, V

= V

= SKP/SDN = 5V, V

OUT

= 1.25V,

= -40°C to +85°C,

unless otherwise noted.) (Note 2)

PARAMETER

PWM CONTROLLER

DC Output Voltage Accuracy

V+ = 4.5V to 28V,

includes load

regulation error

DAC codes from 0.9V to 1.75V

DAC codes from 0.6V to 0.875V

-1.5

-2.0

-8

-12

230

165

320

465

+1.5

+2.0

+12

290

215

390

565

CONDITIONS

MIN

TYP

MAX

UNITS

150kHz nominal, R

TIME

= 120kΩ

TIME Frequency Accuracy

380kHz nominal, R

TIME

= 47kΩ

38kHz nominal, R

TIME

= 470kΩ

V+ = 5V, FB = 1.2V, TON = GND (1000kHz)

On-Time (Note 1)

TON = REF (550kHz)

V+ = 12V, FB = 1.2V

TON = open (300kHz)

TON = V

(200kHz)

_______________________________________________________________________________________

Notebook CPU Step-Down Controller for Intel

Mobile Voltage Positioning (IMVP -II)

ELECTRICAL CHARACTERISTICS (continued)

(Circuit of Figure 1, V+ = 15V, V

= V

= SKP/SDN = 5V, V

OUT

= 1.25V,

= -40°C to +85°C,

unless otherwise noted.) (Note 2)

PARAMETER

Minimum Off-Time (Note 1)

BIAS AND REFERENCE

Quiescent Supply Current (V

)

Quiescent Supply Current (V

)

Quiescent Battery Supply

Current (V+)

Shutdown Supply Current (V

)

Shutdown Supply Current (V

)

Shutdown Battery Supply

Current (V+)

Reference Voltage

FAULT PROTECTION

Overvoltage Trip Threshold

Output Undervoltage Protection

Threshold

Current-Limit Threshold Voltage

(Positive, Default)

Current-Limit Threshold Voltage

(Positive, Adjustable)

Current-Limit Threshold Voltage

(Negative)

Undervoltage Lockout

Threshold

VGATE Lower Trip Threshold

VGATE Upper Trip Threshold

GATE DRIVERS

DH Gate Driver On-Resistance

DL Gate Driver On-Resistance

BST - LX forced to 5V

DL, high state (pullup)

DL, low state (pulldown)

3.5

1.0

Ω

Measured at FB

With respect to unloaded output voltage

GND - LX, ILIM = V

GND - LX

LX - GND, ILIM = V

Rising edge, hysteresis = 20mV, PWM disabled below this

level

Measured at FB with respect to unloaded output voltage

ILIM = 0.5V

ILIM = REF (2V)

1.95

160

-145

4.1

-12.5

+7.5

2.05

115

240

-90

4.4

-7.5

+12.5

SKP/SDN = 0

SKP/SDN = 0, V

= V

= 0 or 5V

= 4.5V to 5.5V, no REF load

1.98

Measured at V

, FB forced above the regulation point

Measured at V

, FB forced above the regulation point

1300

2.02

µA

CONDITIONS

TON = V

, open, or REF (200kHz, 300kHz, or 550kHz)

TON = GND (1000kHz)

MIN

TYP

MAX

500

375

UNITS

MAX1718

_______________________________________________________________________________________

型号	MAX1718EEI-C71059	MAX1718BEEI-T	MAX1718EEI+T
描述	Switching Controller, Current-mode, 1000kHz Switching Freq-Max, PDSO28, 0.150 INCH, 0.025 INCH PITCH, MO-137AD, QSOP-28	Switching Controller, Current-mode, 1000kHz Switching Freq-Max, PDSO28, 0.150 INCH, 0.025 INCH PITCH, MO-137AD, QSOP-28	Switching Controller, Current-mode, 1000kHz Switching Freq-Max, CMOS, PDSO28, 0.150 INCH, 0.025 INCH PITCH, LEAD FREE, MO-137AD, QSOP-28
是否无铅	含铅	含铅	不含铅
是否Rohs认证	不符合	不符合	符合
厂商名称	Maxim(美信半导体)	Maxim(美信半导体)	Maxim(美信半导体)
零件包装代码	SSOP	SSOP	SSOP
包装说明	0.150 INCH, 0.025 INCH PITCH, MO-137AD, QSOP-28	0.150 INCH, 0.025 INCH PITCH, MO-137AD, QSOP-28	0.150 INCH, 0.025 INCH PITCH, LEAD FREE, MO-137AD, QSOP-28
针数	28	28	28
Reach Compliance Code	not_compliant	not_compliant	compliant
ECCN代码	EAR99	EAR99	EAR99
其他特性	ALSO REQUIRES A 2V TO 28V BATTERY INPUT VOLTAGE	ALSO REQUIRES A 2V TO 28V BATTERY INPUT VOLTAGE	ALSO REQUIRES A 2V TO 28V BATTERY INPUT VOLTAGE
模拟集成电路 - 其他类型	SWITCHING CONTROLLER	SWITCHING CONTROLLER	SWITCHING CONTROLLER
控制模式	CURRENT-MODE	CURRENT-MODE	CURRENT-MODE
控制技术	PULSE WIDTH MODULATION	PULSE WIDTH MODULATION	PULSE WIDTH MODULATION
最大输入电压	5.5 V	5.5 V	5.5 V
最小输入电压	4.5 V	4.5 V	4.5 V
标称输入电压	5 V	5 V	5 V
JESD-30 代码	R-PDSO-G28	R-PDSO-G28	R-PDSO-G28
JESD-609代码	e0	e0	e3
长度	9.89 mm	9.89 mm	9.89 mm
湿度敏感等级	1	1	1
功能数量	1	1	1
端子数量	28	28	28
最高工作温度	85 °C	85 °C	85 °C
最低工作温度	-40 °C	-40 °C	-40 °C
封装主体材料	PLASTIC/EPOXY	PLASTIC/EPOXY	PLASTIC/EPOXY
封装代码	SSOP	SSOP	SSOP
封装形状	RECTANGULAR	RECTANGULAR	RECTANGULAR
封装形式	SMALL OUTLINE, SHRINK PITCH	SMALL OUTLINE, SHRINK PITCH	SMALL OUTLINE, SHRINK PITCH
峰值回流温度（摄氏度）	245	240	260
认证状态	Not Qualified	Not Qualified	Not Qualified
座面最大高度	1.73 mm	1.73 mm	1.75 mm
表面贴装	YES	YES	YES
切换器配置	PUSH-PULL	PUSH-PULL	PUSH-PULL
最大切换频率	1000 kHz	1000 kHz	1000 kHz
温度等级	INDUSTRIAL	INDUSTRIAL	INDUSTRIAL
端子面层	Tin/Lead (Sn85Pb15)	Tin/Lead (Sn85Pb15)	Matte Tin (Sn)
端子形式	GULL WING	GULL WING	GULL WING
端子节距	0.635 mm	0.635 mm	0.635 mm
端子位置	DUAL	DUAL	DUAL
处于峰值回流温度下的最长时间	NOT SPECIFIED	20	30
宽度	3.9 mm	3.9 mm	3.9 mm
封装等效代码	-	SSOP28,.25	SSOP28,.25

stm32系统滴答定时器溢出？: stm32设置系统滴答计时器每10ms中断一次，给系统提供时基 void SysTick_Handl...; yl20084784 stm32/stm8

请问下面这个元件是什么呀: 请问这个元件是什么呀，有没有什么资料，上面的丝印是E5 请问下面这个元件是什么呀 ERA-5 这...; jinger0311 模拟电子

针对恶劣工业环境选择以太网的三大注意事项: 自问世以来，以太网取得了突飞猛进的发展，现已在商业和企业市场上得到了大量的应用。由于它具有定义明确...; alan000345 TI技术论坛

EEWORLD大学堂----直播回放: TI Matter 解决方案助力智能家居创新: ...; hi5 综合技术交流

关于示波器的十个问题和十个答案: 示波器数字示波器一直是工程师设计、调试产品的好帮手。但随着计算机、半导体和通信技术的发展，电路系统的...; emily DIY/开源硬件专区

当访问16位接口SRAM: 时，为了能访问8位、16位、32位的变量，STM32的地址线和SRAM的地址线应该怎么连接？附图...; onlinesh stm32/stm8

传恩智浦关闭中国区APS研发部门

据微信号Analog_Dialogue爆料，恩智浦已经宣布关闭中国区APS（Advanced Power System 先进电源系统）研发部门。此次变动影响仅限工作地点在中国大陆地区的研发人员，该产线其他地区的研发人员将保留在原部门，原中国区承担的研发任务后续也将转移到中国台湾地区和国外。研发人员安置方案为与公司内其他部门进行双向匹配，双向选择匹配成功的员工进行内部调动，除此之外...[详细]
集成电路材料任重道远

2018年，对中国的集成电路而言，是不平静、也是不平凡的一年。有中美贸易战爆发的震惊和思考，也有AI和5G等推进的振奋和憧憬；有芯片业的紧迫和焦灼，也有社会力量和资本的关注和热捧……告别2018，迎来2019，集微网特推出「盘点2018」和「展望2019」两大系列专题，将围绕技术、投资、产业（包含台湾IC）等多个维度展开。集微网消息（文/春夏）材料一直以来都是我国集成电路产业链里主要的短板...[详细]
第十六课 C51指针的使用

指针就是指变量或数据所在的存储区地址。如一个字符型的变量 STR 存放在内存单元DATA 区的 51H 这个地址中，那么 DATA 区的 51H 地址就是变量 STR 的指针。在 C 语言中指针是一个很重要的概念，正确有效的使用指针类型的数据，能更有效的表达复杂的数据结构，能更有效的使用数组或变量，能方便直接的处理内存或其它存储区。指针之所以能这么有效的操作数据，是因为无论程序的指令、常量...[详细]
乐金大举进军车市　宁做博世不做Tesla

乐金集团(LG Group)旗下子公司积极发展车用电子事业，零组件产品多样化令人眼花撩乱，说可组成一整台电动车也不夸张，引发外界关注乐金是否也将跨足电动车制造。据韩联社报导，乐金电子(LG Electronics)生产电动车驱动马达、变频器、电池包(Pack)，最近决定在美国密西根州投资285亿韩元(约2,530万美元)，兴建电池包与马达工厂，并且推动购并奥地利汽车灯具业者ZKW。其...[详细]
基于SOPC的任意波形发生器设计

目前波形合成技术主要有两种通用的方法，一种是使用专用的DDS 芯片，一种是基于CPLD/FPGA的解决方案。虽然专用DDS芯片的功能也比较多，但控制方式却是固定的，控制不灵活，而利用FPGA 则可以根据需要利用Verilog/VHDL 语言来实现各种比较复杂的调频、调相和调幅功能，具有良好的实用性。 1 DDS技术及其原理任意波形发生器目前主要有两种实现方法：一种是传统的任意波形发生器，...[详细]
珞石机器人智慧缝制引领鞋服企业智能变革

广告摘要声明广告随着全球劳动力成本持续上升、新一轮科技革命的开展以及新冠疫情的冲击，越来越多鞋服企业、家具家纺企业意识到加速智能化转型升级已是大势所趋。未来将诞生越来越多适应小单快反柔性生产的智慧车间、智慧工厂，以智慧缝制为主要路径，向着柔性化、智能化、信息化方向稳步前行。机器人技术赋能智慧缝制作为新一代智能机器人专家，珞石机器人一直致力于推动中国制造业转型升级，通过机器人技术把人...[详细]
ADS1232之STM32程序——STM32测试高精度ADC篇（一）

1．ADS1232概述 ADS1232是TI早期推出一款高精度低速率的ADC，性能参数如下 •24位Σ-Δ型双差分模拟输入ADC、完整的桥传感器前端 •高达23.5个有效位 •低噪PGA、19.2-bit的无噪声分辨率（PGA= 64） •同时抑制50 Hz/60 Hz、10sps或80sps数据率 •供电范围：2.7V至5.3v 性价比很高，非常适用于静态变量的测试，如电子秤、应变计、压力...[详细]
海底捞首家“无人火锅店”开张，科技感能取代人文关怀的服务体验吗？

无微不至的热情服务是许多人走进海底捞的一大理由，眼镜布、橡皮筋、衣服、袜子、尿布、无籽火龙果应有尽有，很多情况下，你无需眼神知会便有服务人员贴心的为你准备好一切。如今，这家主打“家文化”和“变态服务”的餐厅，第一家无人餐厅在北京正式营业，智能机器人取代昔日穿梭不息的服务员，洗菜、配菜、传菜、汤底等被智能机械臂和算法取代。海底捞首席战略官周兆呈曾表示：作为首家智慧餐厅，技术与场景的落地磨合、设...[详细]
STM32F407 串口配置步骤

介绍STM32F407串口配置步骤，完成串口的数据发送与接收、实现中断接收，支持printf重定向。 STM32F407 串口配置说明 STM32F4 的串口资源相当丰富的，功能也相当强劲，STM32F407ZGT6 最多可提供 6 路串口，有分数波特率发生器、支持同步单线通信和半双工单线通讯、支持 LIN、支持调制解调器操作、智能卡协议和 IrDA SIR ENDEC 规范、具有 DM...[详细]
针对高功率LED灯泡替换应用的LED驱动器设计

本文介绍了一款针对高功率LED灯泡替换应用的LED驱动器参考设计。该驱动器可为100W A19白炽灯泡的LED替换灯提供所需的功率，它是一款非隔离式、高效率（约93%）、高功率因数（PF） LED驱动器，该驱动器可恰好放入A19灯泡内，不仅符合EN61000-3-2 C（D）标准，还可轻松达到THD限值要求。功率因数（PF）值超过0.95，因此既适用于商业应用，也适用于消费类应用。　　据测算...[详细]
我国百公里油耗在6.3L以下乘用车分析

89款车型或将继续享有补贴政策　　工信部公布了最新节能汽车推广补贴政策，将入围产品的平均油耗门槛由百公里6.9L提升至6.3L，单车补贴3000元标准不变，该政策将于今年10月1日正式实行。根据盖世汽车网整理的工信部发布的轻型汽车燃料消耗量通告，截止至2011年8月31日，符合油耗在6.3L以下的我国在售乘用车（包括进口车和微客）有89款车型。其中，自主品牌占有61款，占油耗在6.3L以下...[详细]
JamTech推出新型数字音频放大器,制定市场竞争新规则

JM2020的上市使PWM 技术在消费电子产品中的应用成为现实　　　　全球领先的混合信号半导体公司 JamTech 日前宣布推出新产品—— JM2020 True Fidelity 分段脉冲宽度调制（ PWM ）数字音频放大器，由此将会在消费电子产品音频放大器市场建立新的竞争规则。 JM2020 能够提供高品质的 16 位音频信号，同时具有 98dB 的线性范围，使消费电子产品的音...[详细]
FPSO常用液位计的选型及安装注意事项

一、常用液位计选型比较对各型液位计测量原理的基本介绍，可以看出各常用类型的液位计都能比较精确地测得液位值，并且理论上都能应用于FPSO的液位遥测系统。但是由于精度、测量环境的适用性等因素的限制，目前在FPSO的液位遥测系统中主要采用的还是压力式液位计、雷达液位计、超声波液位计来进行液位测量，这三种液位计成为目前液位遥测系统中的主流液位计。现针对这三种液位计的测量方法进行比较，比较结果如表1所示...[详细]
佩奇：Android对谷歌很重要但非关键资产

谷歌首席执行官拉里佩奇（Larry Page）周三在法庭听证会上称，Android移动操作系统是谷歌的一项非常重要的资产，但并非关键资产。甲骨文于2010年8月对谷歌提出起诉，指控谷歌的Android移动操作系统侵犯了其Java编程语言的技术专利。谷歌回应称自己并非侵权，并且声称甲骨文不能以开源Java软件语言的特定部分申请专利。谷歌首席执行官拉里佩奇在接受甲骨文代表律师的...[详细]
艾迈斯欧司朗推出全新UV-C LED，提升UV-C消毒与处理解决方案效率

卓越的光输出功率与电光转化效率（WPE）：典型值为115mW，效率达5.3％；极致杀菌效能：峰值发射波长265nm；紧凑耐用设计：卓越的R70B50寿命，超过20,000小时。中国上海，2024年11月8日—— 全球领先的光学解决方案供应商艾迈斯欧司朗今日宣布，正式推出全新OSLON® UV 3535 。这款创新型UV-C LED旨在满足市场对无汞、高效UV-C消毒及治疗解...[详细]