EKK-LM3S2965电路

AOC冠捷LM729液晶显示器电源电路的工作原理AOC冠捷LM729液晶显示器电源电路的工作原理液晶显示器的电源电路一般采用开关电路方式，此电源电路将交流220V输入电压经过整流滤波电路变成直流电压，再由开关管斩波和高频变压器降压，得到高频矩形波电压，最后经整流滤波后输出液晶显示器各个模块所需要的直流电压。

下面以AOCLM729液晶显示器为例讲解液晶显示器电源电路的工作原理。

AOCLM729液晶显示器的电源电路主要由交流滤波电路、桥式整流电路、软启动电路、主开关电路、整流滤波电路、过压保护电路等组成，其电源电路原理图如图b所示。

1.交流滤波电路交流滤波电路的作用是用于滤除由交流输入线引入的噪声，抑制电源内部产生的反馈噪声。

电源内部的噪声主要有共态噪声和正态噪声两种。

对于单相电源，输入侧有2根交流电源线和1根地线。

在电源输入侧2根交流电源线与地线之间产生的噪声为共态噪声；2根交流电源线之间产生的噪声为正态噪声。

交流滤波电路主要用于滤除这两类噪声，另外，还要起到电路过流保护和过压保护。

其中，保险用于过流保护，压敏电阻用于输入电压过压保护。

如图5-3所示为交流滤波电路原理图。

图中，电感L901、L902，电容C904、C903、C902、C901组成了EMI滤波器。

电感L901、L902用于滤除低频共态噪声；C901和C902用于滤除低频正态噪声；C903和C904用于滤除高频共态和正态噪声（高频电磁干扰）；限流电阻R901、R902用于拔下电源插头时对电容起放电作用；保险F901用于过流保护压敏电阻NR901用于输入电压过压保护。

当液晶显示器的电源插头插入电源插座后，220V交流电经过保险管F901、压敏电阻NR901防浪涌冲击后，通过由电容C901、C902、C903、C904，电阻R901、R902，电感L901、L902组成的抗干扰电路后进入桥式整流电路。

2.桥式整流滤波电路桥式整流滤波电路的作用是将220V交流电经过全波整流后转变为直流电压，再经过滤波后将电压变为市电电压的2倍。

康佳Ｓ系列彩电电路分析正当2002 年韩日第17 届（足球）世界杯即将开赛之际，为满足广大环迷观看有中国队参赛的世界杯，康佳隆重推出第二代超级芯片电视机T2975S、T2976S、P2971S /P2960S、T2173S、P2171S/P2572S、T2576S、P2571S、P2571SR/P2971SN、T2975 SR、P2961S、T3476S 等“S”系列。

新的“S”系列较“K”系列又增加了一些功能，如“屏保”功能、“时钟”功能、“日历”功能、“色温”功能、“计算器”功能、“游戏”功能、“绿屏”功能等。

扫描速度调制功能的效果更为明显，“S ”系列中的“P”（镜面管）机设有实时时钟I C（N105）和地磁校正电路。

与“K”系列相比主要区别在于超级芯片本身，K 系列采用的是菲力浦公司的TDA9383，其供电则由N903（TDA8133）电压转换器，将输入的+12V 转换成+5V 和+8V，再将+5V 通过V958、VD959等得到+3.3V 供TDA9383 内部的C PU 电路。

而“S”系列采用的是美国MICRONAS（梦柯）公司的VCT3803A，内部电路（模拟部分为+5V）；数字部分为+3.2V-3.4V 所需供电电源由开关稳压电源输出的+12V 经外部有关电路获得相应电压提供。

VCT3803A 是超薄型的IC，很轻，一块29寸的T297 5S 机的机芯板几乎与普通的21 寸机芯板大小相当。

一、应用的IC (一)、P2971S 与P 2960S ①N101（TDA4472）视频-中频和准伴音并行处理器②N103（VCT3803A）TV 的微控器和视频处理器③N104（24C16）存储器④N105（RS5C372）I2C总线串行实时时钟与CPU 的相互连接⑤N201（MSP3463G）多标准声音处理器（FM 解调/NICAM 解调与解码）⑥N202（TDA2616）音频功放⑦N401（TDA8177F）场驱动输出⑧N907（STR-G8656）开关稳压电源的振荡，调节与控制(二)、T2975S 与T2976S ①N101（STV8223B）多标准视频和声音的中频系统，用于视频和声音的接入开关②N102（TC4052）电子开关③N103（VCT3803A）CPU 与TV 处理器合成IC ④N104（24C06）存储器⑤N202（TDA7056）音频功放⑥N401（TDA8 177F）场驱动输出⑦N909（STR-5653）开关稳压电源需要指出的是：“S”系列各机型虽同用VCT3803A，但该IC 所设的24 个可编程输入/输出（I/O）端口，在具体应用上有所不同，表见表（1）：P2971S/P2960S 所用VCT3803A的引脚功能说明表（1）脚号功能参考电压脚号功能参考电压 1 制式选择（P制/N）5V/0V 64 安全设置输出（正常为L）0V 2 地0V 63 键控信号输入0V 3 供电+5V 62 遥控信号输入3.4V 4 供电地0V 61 灯控入/出4.8V 5 地磁线圈信号输出1.2V 60 I2C串行数据输入/输出3.8V 6 I束/灯丝保护4.9V 59 I2C串行数据输出3.6V 7 电源开/关（遥控）5V 58 复位输入/输出(低电平有效) 4.8V 8 AFT 输入1.8V 57 9 地0 56 晶体输入/输出表笔接上即自动关机10 地0 55 地0 11 模拟视频输出1.6V 54 供电电压3.2V 12 参考电压2.6 53 接地0 13 信号地0 52 接地0 14 地0 51 接地0 15 供电电压5V 50 接地0 16 Cb 分量输入1V 49 接地0 17 C(色度)(1)输入1 48 RGB 和DAC 参考电压2.6V 18 C(2)/Cr 分量输入1.4V 47 DAC 参考电压2.4V 19 模拟视频(1)输入1V 46 地0V 20 模拟视频(2)输入1V 45 供电5V 21 TV 视频输入1.2V 44 B输出4.4V 22 模拟视频(4)输入1V 43 G输出4.3V 23 测试脚(地) 0V 42 R输出4.4V 24 行激励输出0.36V 41 速度调制输出4.57V 25 数字电路供电3.4V 40 ADC 测量范围开关(2) 0V 26 数字电路地0V 39 ADC 测量范围开关(1) 0V 27 接地0V 38 地0V 28 接地0V 37 CRT 检测输入0V 29 接地0V 36 东/西枕校输出3.0V 30 接地0V 35 场”+”输出1.25V 31 场保护输入0V 34 场“-”输出1.25V 32 安全保护输入0V 33 行逆程输入0.3VV T2975S/T297 6S 所用VCT3803A的引脚功能说明表（1）脚号功能脚号功能1 B1（用于制式选择）64 安全信号输出(正常为低电平) 2 B2（用于制式选择）63 键控信号输入3 供电（+ 5V）62 遥控信号输入4 地61 电源指示灯5 空60 串行数据输入/输出6 I束/灯丝过压保护输入59 串行时钟输出7 电源开/关58 复位输入/输出(低电平有效) 8 AFT 输入57 模拟晶体输出9 SYS1（AV 开关）56 模拟晶体输入10 SYS2（静音）55 地11 视频输出54 供电(+3.2V) 12 参考电压53 声音输出(2)（去N202）13 地（信号）52 声音输出(1) 14 地51 模拟声音(3)输入15 供电（+5V）50 模拟声音(2)输入16 CB 输入49 模拟声音(1)输入17 Cr 输入48 RGB 的参考电压输入18 C输入4 7 参考电压输入19 AV1 输入46 地20 AV2 输入45 供电(+5V) 21 TV 视频输入44 B(兰)输出22 AV4 输入43 G(绿)输出23 地42 R(红)输出24 行激励输出41 接供电(+5V) 25 行供电（3.4V）40 测量范围开关2 26 滤波39 测量范围开关1 27 地3 8 地28 地37 CRT 检测输入29 地36 东/西枕校输出30 地35 场”+”输出31 场保护输入34 场“-”输出32 保险装置输入33 行逆程输入二、整机组成方块图(一)、P29 71S 与P2960S 的整机组成图(1)给出了“S”系列中的P2971S 与P2960S 两机型的整机组成方块图。

YL‐291单元电子电路模块培训教材亚龙科技集团有限公司目录亚龙YL-291单元电子电路模块 (4)设备概述 (4)项目一 单元电子电路模块 (5)（一）单片机电路 (5)1．EDM001－MCS51单片机主板 (5)2．EDM002－A VR单片机主板MG32 (6)（二）传感器电路 (9)1．EDM101－声控电路 (9)2．EDM102－温度传感器LM35电路 (10)3．EDM103－温度传感器18B20电路 (10)4．EDM104－秤重传感器电路 (11)5．EDM105－空气质量传感器电路 (12)6．EDM106烟雾传感器电路 (12)7．EDM107－热释电电路 (13)8．EDM108－酒精传感器电路 (14)9．EDM109－PT100测温模块电路 (15)10．EDM110红外非接触测温模块电路 (15)11．EDM111-超声波发射和接收电路 (17)12．EDM112－红外反射 (18)（三）信号采样处理 (19)1．EDM201－电容式触摸按键 (19)2．EDM202－音频功放 (20)3．EDM203－ICL7135AD模数转换 (21)4．EDM204－反相器 (23)（四）接口及其他： (24)1．EDM301倒车音乐 (24)2．EDM302－4种报警音乐 (24)3．EDM303－3位计数器 (25)4．EDM304－FM收音 (26)5．EDM305－单稳态触发器 (26)6．EDM306－双稳态触发器 (27)7．EDM307－脉冲信号发生器 (28)8．EDM308－无线接收 (29)9．EDM309－无线发射 (29)10．EDM310－ISD1760多段语音录放 (30)11．EDM311红外发射 (32)12．EDM312红外接收 (33)13．EDM313－AK040语音 (34)（五）开关和驱动 (36)1．EDM401－电机驱动 (36)2．EDM402－继电器驱动电路 (36)3．EDM403－8按键 (37)4．EDM404－NPN驱动 (37)5．EDM405－PNP驱动 (38)6．EDM406－4*4键盘 (38)（六）执行器件 (40)1．EDM501－风扇 (40)2．EDM502－直流电机 (40)3．EDM503－扬声器 (40)4．EDM504－蜂鸣器 (41)5．EDM505－步进电机 (41)6．EDM506－电阻加热 (42)7．EDM507－半导体制冷片 (43)（七）显示： (44)1．EDM601－64*32点阵LED (44)2．EDM602－交通灯显示 (45)3．EDM603－十进制计数器 (46)4．EDM604－直流灯泡 (47)5．EDM605－四位数码显示 (47)6．EDM606－12864LCD液晶屏 (48)7．EDM607综合显示电路 (49)项目二典型应用电路举例 (50)一、空调电路 (50)二、出租车计价器 (52)三、综合报警系统 (54)项目三拓展电路 (56)一、超声波测距 (56)二、电子称 (58)三、电子语音播放万年历 (60)四、64*32点阵广告屏 (62)五、酒精测试仪 (64)六、频率灯 (66)七、声光控制小灯 (68)亚龙YL­291单元电子电路模块设备概述本设备适合应用型本科院校、高等职业学校、中等职业学校的电子技术、电子信息、机电一体化、自动化、电子电器应用与维修、工业自动化控制、计算机应用等电子专业和非机电类专业的《单片机技术》、《模拟电子技术》、《数字电子技术》、《计算机原理》等课程的教学与实训。

SICK施克继电器技术原理产品系列 W18-3用于高规格工业应用得益于优越的 OES 技术，光学性能同类佳自动对准背景抑制功能和前景抑制功能，带有第二个 LED 发射器纤巧坚固的外壳通过双示教或者电位计可选接口、固件和光学部件，型号丰富多样灵活的传感器设置、监测、扩展诊断功能和可视化产品系列 W24-2多用途的坚固传感器技术不惧严酷的工业环境锌压铸的坚固外壳带有 IP 69K 防护等级操作元件由一个盖子保护漫反射式光电传感器高度的环境光抗扰度切换：PNP/NPN 和亮/暗通开关DC 或 DC/AC 版本带有 UL 证书可选：测试输入，定时器，报警输出污染物警告，前窗加热器以及高性能变型M12 插头或 M16 插头：可以90° 旋转产品系列 W24-2 Ex爆炸性危险场所（气体）检测和安全开关标志：EX II 2 G Ex ia op is IIC T4，符合 2014/34/EX/EU (ATEX) 指令符合类别 2 G开关量输出符合 EN 60947-5-6 （NAMUR）M12 插头或 M16 插头：可以 90° 旋转由压铸锌的坚固外壳精确的背景抑制功能SICK施克原装正品光电传感器产品系列 V180-2不仅经济上实用，技术上也不容小觑经济型圆柱形传感器 M18最远扫描范围如下： 100 mm，400 mm，800 mm（漫反射式光电传感器）；300mm（带背景抑制功能的漫反射式光电传感器）；6 m（漫反射式光电传感器）以及 20 m（对射式光电传感器）明亮的状态显示器360° 可视丰富的产品系列为您提供广泛的应用解决方案开关频率高达 1000 Hz金属或塑料外壳可选光轴轴向或径向（90°）可选圆柱型的 M18-外壳整合低成本激光传感器在圆柱型的 M18 外壳里集成激光发射 LED 灯激光等级 1快速的响应时间轴向或径向的光学输出使用长久金属外壳外壳防护等级 IP67小而可见的光点来检测小物体产品系列 GR18圆型，经济，无与伦比的标杆价格实惠的圆柱型 M18-传感器采用标准的外壳设计可选带直头出线口的塑料和金属外壳类型清晰醒目的 PinPoint-LED 灯醒目的 LED 状态外壳防护等级 IP 67产品系列 GR18S圆型，短小，无与伦比的经济性超短结构的低成本圆柱形 M18-传感器五个不同的外壳设计可选塑料或金属、轴向或径向光学版本清晰醒目的 PinPoint-LED 灯通过电位计开关阈值（视类型而异）特殊的"完全齐平"变型由金属制成醒目的 LED 状态外壳防护等级 IP 67产品系列 W2 Flat微型光电传感器系列产品：超小、超平、超强全球小的按钮不需要外接信号放大器能识别透明或者反光的物体内嵌金属安装螺纹坚固的外壳产品系列 W8 Inox经久耐用、种类丰富，安装轻松坚固的外壳防护等级 IP 69K 不锈钢 1.4404/316L 外壳前窗由高性能抗化学腐蚀耐高温的塑料 PPSU 制成操作元件由机械性能稳定的高性能塑料 PEEK 制成FDA 认证材料通过尖锐醒目的光点随附 M3-固定螺纹和不锈钢安装支架（1.4301/304）产品系列 G6超越标准...PinPoint LED 提供非常明亮和准确的光点带有内螺纹的坚固金属配件SICK-专用集成电路，数十载光电传感器的经验结晶大型易操作的调节螺丝大尺寸高亮 LED 显示外壳防护等级：IP 67产品系列 W4S-3 Glass没有什么东西是传感器所不能识别的在脏污的环境内持续性跟踪开关阈值自动对准单片镜系统通过示教功能和 IO-Link 实现简单的调试PinPoint 技术的光斑细小、醒目、锐利，即使使用小型反光板也具有很大的裕量系数通过 IO-Link 实现便捷的传感器设置，监测，扩展诊断功能和可视化产品系列 W4SL-3适用于细小透明物体的高精度激光准确的激光光斑，激光等级 1通过示教功能按钮可以在透明和不透明物体之间切换测量距离 25 mm 到 60 m新的 SICK 专用集成电路技术和激光技术带有第二个 LED 发射器，实现优异的背景抑制功能和环境光抗扰度可通过示教功能按钮、电位计、电缆或 IO-Link 来设置产品系列 W4SLG-3可以切换所有物体准确的激光光斑，激光等级 1通过示教功能按钮可以在透明和不透明物体之间切换连续阈值适应自动适应光线变化测量距离可达 4.5 m自动对准，没有盲区可通过示教功能按钮、电位计、电缆或 IO-Link 来设置产品系列 W4S-3 Inox Glass可靠的玻璃识别经 ECOLAB 认证，经过 IP 66，IP 67，IP 68 和 IP 69K 测试坚固的不锈钢外壳（316L/1.4404）可抵抗现有的多种清洁剂和消毒剂现代化电气连接，比如 100% 密封的 M12-灌封接口所有变型通过 PinPoint 技术提供类似激光的光斑通过由焊接不锈钢膜片制成的革命性示教功能键进行调节持续的开关阀值跟踪来识别变化条件下的物体产品系列 W4SL-3V光学和机械坚固性的新标杆准确的激光光斑，激光等级 1不锈钢外壳搭配冲洗设计新的 SICK 专用集成电路技术和激光技术带有第二个 LED 发射器，实现优异的背景抑制功能和环境光抗扰度通过示教功能按钮可以在透明和不透明物体之间切换ECOLAB 证书，经过 IP 66，IP 67，IP 68 和 IP 69K 测试IO-Link（可选）产品系列 W4S-3 Inox Hygiene 玻璃可靠的玻璃识别卫生型不锈钢外壳和附件（316L/1.4404）通过 M12-连接螺纹或 D12-连接头实现卫生的安装经 ECOLAB 认证，经过 IP 66，IP 67，IP 68 和 IP 69K 测试可抵抗现有的多种清洁剂和消毒剂所有变型通过 PinPoint 技术提供激光类似的光点通过由焊接不锈钢膜片制成的革命性示教功能键进行调节产品系列 W4SL-3H激光技术和不锈钢的强大组合带有卫生设计的不锈钢外壳准确的激光光斑，激光等级 1新的 SICK 专用集成电路技术和激光技术带有第二个 LED 发射器，实现优异的背景抑制功能和环境光抗扰度通过示教功能按钮可以在透明和不透明物体之间切换ECOLAB 证书，经过 IP 66，IP 67，IP 68 和 IP 69K 测试IO-Link（可选）产品系列 W4SLG-3H在最严苛的环境下检测所有物体带有卫生设计的不锈钢外壳准确的激光光斑，激光等级 1，没有盲区新的 SICK 专用集成电路技术和激光技术带有第二个 LED 发射器，实现优异的背景抑制功能和环境光抗扰度ECOLAB 认证，通过 IP66，IP67，IP68 和 IP69K 测试通过示教功能按钮可以在透明和不透明物体之间切换IO-Link（可选）产品系列 MultiPulse切换到全自动模式物体检测和传感器间隙监测验证物体存在以及传感器故障节省空间的微型外壳允许集成在紧凑的机器空间内无论表面和粗糙度如何，准确的背景抑制功能保证可靠地检测任何类型的物体有效工作范围 3 到 150 mm不同型号可选带或无调节、线性光点和窗口功能 (30 mm ... 150 mm)。

Luminary Micro - EKT- LM3S6965- Evaluation Board Product Overview:The Stellaris® LM3S6965 Ethernet Evaluation Kit is acompact and versatile evaluation platform for the StellarisLM3S6965 ARM® Cortex™-M3-based microcontroller. Theevaluation kit uses the LM3S6965microcontroller’s fullyintegrated 10/100 Ethernet controller to demonstrate anembedded web server.The LM3S6965 evaluation board can be used as anevaluation platform or as a low-cost in-circuit debuginterface (ICDI). In debug interface mode, the on-boardmicrocontroller is bypassed, allowing connection of thedebug signals to an external target. The kit is alsocompatible with high-performance external JTAG debuggers.This evaluation kit enables quick evaluation, prototype development, and creation of application-specific designs for Ethernet networks. The kit also includes extensive source-code examples, allowing you to start building C-code applications quickly.Kit Contents:The evaluation kit contains everything needed to develop and run applications for Stellaris microcontrollers including:∙LM3S6965 evaluation board (EVB)∙Retracting Ethernet cable, USB cable, and 20-pin JTAG/SWD cable∙ CD containing:Complete documentationEvaluation version of the software toolsQuick start guide and source codeStellarisWare® Peripheral Driver Library and example source codeAn evaluation version of one of the following:Keil™ Real View® Microcontroller Development Kit (MDK-ARM)IAR Embedded WorkbenchCode Sourcery GCC development toolsCode Red Technologies Code Suite development toolsKey Features:The evaluation kit includes the following features:∙Stellaris LM3S6965 microcontroller with fully-integrated 10/100 embedded Ethernet∙ controller∙Simple setup: USB cable provides serial communication, debugging, and power∙OLED graphics display∙User LED, navigation switches, and select pushbuttons∙ Magnetic speaker∙LM3S6965 I/O available on labeled break-out pads∙Standard ARM® 20-pin JTAG debug connector with input and output modes∙USB interface for debugging and power supply∙MicroSD card slotOrdering Information:Products:Part Number Manufacturer Farnell P/N Newark P/N EKT-LM3S6965 Luminary Micro 1712253 45P3417Associated Products:Part Number Manufacturer Description Farnell P/N Newark P/NLM3S6965-IQC50-A2 Luminary Micro Stellaris LM3S6965MicrocontrollerIndustrial Temperature100-pin LQFP1494151 45P3687FT2232D/TR FTDI Dual USB UART/FIFO I.C. 1615843 14N9294FAN5331SXFairchildSemiconductorHigh Efficiency Serial LEDDriver and OLED Supplywith 20V Integrated Switch1262717 60J0504LC4032V-75TN48CLatticeSemiconductor3.3V/2.5V/1.8V In-SystemProgrammableSuperFAST High DensityPLDs1291817 24M3321Similar Products:Part Number Manufacturer Description SupportDeviceFarnellP/NNewarkP/NEKK-LM3S6965 Luminary Micro Stellaris LM3S6965Ethernet Evaluation Kitfor Keil™ Real View®MDK-ARM (16 KBcode-size limited)LM3S6965 1494128 45P3411EKI-LM3S6965 Luminary Micro Stellaris LM3S6965Ethernet Evaluation Kitfor IAR SystemsEmbedded Workbench®(32 KB code size limited)LM3S6965 1712247 45P3405EKC-LM3S6965 Luminary Micro Stellaris LM3S6965EthernetEvaluation Kit forCodeSourcery G++GNU (30-day limited)LM3S6965 1494126 45P3399Document List:Datasheets:Part Number Description SizeLM3S6965 LM3S6965 Microcontroller Datasheet -FT2232D/TR Dual USB UART/FIFO I.C. 0.99MBFAN5331SX High Efficiency Serial LED Driver and OLED Supply with 20V Integrated Switch584KBLC4032V-75TN48C 3.3V/2.5V/1.8V In-System Programmable SuperFAST High DensityPLDs364KBApplication Notes:File Name SizeProgramming the On-Chip Flash Memory in a Stellaris Microcontroller -ADC Oversampling Techniques - Clocking options for Stellaris Family Microcontrollers -Using a Stellaris Microcontroller as an I/O Processor -Adding 32KB of Serial SRAM to a Stellaris Microcontroller -Evaluating PeerSec Networks’ MatrixSSL on a Stellaris Microcontroller -Using the Stellaris Microcontroller Analog-to-Digital Converter --Upgrading to Luminary Micro's Stellaris Microcontrollers from Microchip's PICMicrocontrollersMigrating to the New Members of the Stellaris® Family of Microcontrollers -Implementing RS-232 Flow Control on a Stellaris® Microcontroller -Using Schematic Part Libraries and PCB Footprint Libraries for Stellaris® Microcontrollers -Flash Protection for Stellaris® Microcontrollers - Using the Stellaris® Ethernet Controller with Micro IP (uIP) -Using the Stellaris® Ethernet Controller with Lightweight IP (lwIP) -Optimizing Code Performance and Size for Stellaris Microcontrollers -Serial-to-Ethernet Converter for Stellaris Microcontrollers -Using Stellaris Microcontrollers Internal Memory to Emulate EEPROM -Software UART for Stellaris® Microcontrollers --Using the IEC 60730 Standard for Safe and Reliable Operation of Stellaris®MicrocontrollersHardware & Software:File Name SizeLM3S6965 Evaluation Kit Readme First --Stellaris® LM3S2965 Evaluation Board and LM3S6965 Evaluation Board User’s ManualDocumentation AddendumLM3S6965 Evaluation Kit for Code Red Technologies CD -GUI and command line flash programmer - EK-LM3S6965 Firmware Development Package for Revision A boards -EK-LM3S6965 RevC Firmware Development Package -。

基于CAN总线的运动控制系统摘要：通过现阶段流行和稳定的CAN总线传输技术，本文设计了一个基于CAN总线和Cortex-M3采用PID控制算法并配合显示电路的运动控制系统。

关键词：CAN总线数据传输，Cortex-M3，PID运动控制算法。

Abstract: Through the present popular and stable CAN bus transmission technology. This paper designs a based on CAN bus and Cortex-M3 using PID control algorithm and cooperate with show circuit movement control system.Keywords: CAN bus data transmission, Cortex-M3, PID control algorithm movement(1) CAN总线及其发展CAN总线【1】，是一种有效支持分布式控制或实时控制的串行通信局域网络，由于其高性能、高可靠性、实时性好及其独特的设计，已广泛应用于工业自动化、船舶、医疗设备、工业设备的各检测和执行机构之间的数据通信。

CAN 等通信协议的开发，使多种LAN 通过网关进行数据交换得以实现，同时已在工控领域兴起应用热潮。

步进电机作为执行元件，是机电一体化的关键产品之一，广泛应用在各种自动化控制系统中。

随着微电子和计算机技术的发展，步进电机的需求量与日俱增，同时步进电机具有结构紧凑、控制容易、运行稳定、响应快等优异特性，已在数控机床等重要行业中，得到了普遍的应用【2】。

本文所述控制系统是应用于生产现场的分布式实时控制系统中最底层的现场节点系统。

通过它可以独立完成步进电机的实时运动控制。

通过CAN总线、Cortex M3和驱动电路进行数据传输与控制，使步进电机的性能更加稳定，能更好更灵活地地应用于数控系统中。

微波炉的电路原理图这副微波炉电路原理图可以说是微波炉的核心电路。

对分析，维修微波炉至关重要。

具体元器件功能作用分析：F1 保险微波炉常用规格是8A。

外形大号。

限制整机电流。

比较特别的是当S1、S2，损坏，短接。

S3 接通。

烧断保险。

防止微波炉未关闭炉门时候工作。

ST 热保护器。

温度保护。

一般安装在磁控管外壳上面。

监控磁控管温度，防止温度过高损坏磁控管。

S4 定时器开关。

在功率控制总成内。

整个微波炉是否工作的总电源开关。

有电路图分析可知道。

炉灯是好的，旋动定时器。

灯必须亮。

否则功率控制定时器总成坏。

S1、S2 门锁监控开关。

防止微波炉泄漏。

当炉门关闭不严，有异物卡住的时候。

微波部分不工作。

S3 连锁监控开关。

当S1、S2，损坏，短接。

S3 接通。

烧断保险。

防止微波炉未关闭炉门时候工作。

S4、S5 功率控制器内部两个独立开关。

单独受控。

在功率控制时，串联工作。

M1 火力力调节电机。

M1、S4、S5 组成了功率控制总成。

在元器件实物中，还有一个档位调节控制一起组成一个整体，通过M1、220v电压工作电机带动齿轮轮，通过凸轮控制S4、S5的通断。

M2 转盘电机， M3 风扇电机。

由电路图可知，他们和大功率变压器初级L1并联。

也就是说他们和磁控管供电同时通断。

同时工作，和停止。

L1 、L2、L3 组成了大功率升压变压器。

L1大功率变压器初级接220V 交流。

L2大功率变压器次级输出2000V左右交流高压。

其一端接变压器铁芯，也就是外壳，一端单独接高压电容一端。

L3 大功率变压器另外一组次级。

输出4V左右的交流电压。

给磁控管阴极灯丝供电。

C 高压电容。

规格是1uf （有的0.91uf）耐压2100V交流。

内部并联了一个10M欧姆的电阻。

留意这样用万用表测量电容两端阻止时候，不是无穷大。

而是10M欧姆。

VD 高压二级管。

一端通过螺丝接微波炉金属外壳。

一端通过插头接电容一端。

微波炉用高压二极管好坏的判断：微波炉用高压二极管工作环境：2000V交流工作环境。

无私奉献常用的各种电器原理图贴子发表于：2008/7/3 13:43:04燃气热水器的控制电路燃气热水器是常用的小家电。

各种品牌的控制电路大同小异，现以附图的“光辉牌”燃气热水器电路进行剖析，以供读者参考。

LM339是一种电源电压适应范围宽的四电压比较器。

优点是两个输入端电压差大于1 0mv，就能使输出端电压翻转，因此该IC大量使用在燃气热水器控制电路中。

电路中的比较器A1为控制产生高压点火用；A2、A3为启动电磁阀用。

图中的电磁阀线圈L由两线圈串接组成。

A、B之间用中0．1 mm漆包线绕约4000~6000匝，B、C之间用中0．23mm漆包线绕约150-200匝。

要让电磁阀开启，两部分线圈中必须同时都有电流通过；一旦启动后，其维持电流很小。

当开启热水器出水阀门后，足够的水压就可使图中水压联动开关K接通，此时A1的同相输入端(11脚)因C3初始充电，其电压低于⑩脚。

此时输出端(13)脚处于低电位，振荡管Q1振荡，产生高压打火。

由于D3的钳位作用，A3的正相输入端⑤脚为低电位，输出端②脚也为低电位，Q3正偏导通，电磁阀线圈L中有电流通过产生吸力，但不能开启电磁阀；同时A2的同相输入端⑦脚因C2充电初始时处于低电位，因此输出端①脚为低电位，为Q2提供正偏，使Q2导通。

电磁阀B、C线圈中有较大的电流．这两部分线圈产生的吸力叠加，电磁阀才能开启。

一旦点火成功后，熄火保护探针因高温产生离子电流(此时打火已停止．A1输出端已为高电位，D3无钳位)，因此A 3的同相输入端⑤脚仍为低电位，为Q3继续导通提供保证。

经过约5-6秒的高压打火时间后，c3已充足电，A1的输出端(13)脚转变为高电位，振荡打火停止，启动指示LED也熄灭。

当C2充足电，A2正相输入端(7)脚为高电位时，输出端(1)脚转变为高电位，Q2截止，电磁阀线圈中只有Q3提供的；小电流来维持开启。

使用过程中，若出现熄火，离子电流消失，A3的正相输入端⑤脚转变为高电位，输出端②脚为高电位，Q 3截止，将电磁阀关闭，燃烧室中不会充满燃气。

CUSTOMER APPROVAL SHEETCompany Name MODEL CUSTOMER APPROVEDAPPROVAL FOR SPECIFICATIONS ONLY (Spec. Ver. 0.4) APPROVAL FOR SPECIFICATIONS AND ES SAMPLE (Spec. Ver. 0.4) APPROVAL FOR SPECIFICATIONS AND CS SAMPLE (Spec. Ver. 0.4) CUSTOMER REMARK :A060SE02 V2AUO PM : YW Liu P/N : Comment :□ □ □ □1 Li-Hsin Rd. 2. Science-Based Industrial Park Hsinchu 300, Taiwan, R.O.C. Tel: +886-3-500-8899 Fax: +886-3-577-2730Doc. version : 0.4 Total pages : 34 Date : 2009/09/08Product Specification6" EPD with touch panel MODULEModel NamePlanned Lifetime: Phase-out Control: EOL Schedule:FromA060SE02 V22009/Aug. To 2011/Jul. From 2011/Mar. To 2011/Jul. 2011/Jul.< ◆ >Preliminary Specification < >Final SpecificationNote: The content of this specification is subject to change.© 2009 AU Optronics All Rights Reserved, Do Not Copy.ALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.Version: Page: Record of Revision Version 0.0 Revise Date 2009/08/17 Page All 0 0.1 2009/08/18 3 4 0.2 0.3 0.4 2009/8/26 2009/9/4 2009/09/08 4 10 18 18 First Draft. Update front page Correct dimension, weight Update module drawing Update module drawing Update power consumption and VDD Update optical performance Update optical performance Content0.4 1/34ALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.Version: Page:0.4 2/34Contents A. General Information..............................................................................................3 B. Outline Dimension ................................................................................................4 C. Electrical Specifications ........................................................................................51. 2. 3. Pin Assignment .................................................................................................................................................. 5 Touch Panel Pin Assignment ........................................................................................................................... 9 Absolute Maximum Ratings ............................................................................................................................ 9D. Electrical Characteristics .....................................................................................10 E. Input timing AC Characteristics .......................................................................111. Horizontal input timing ...................................................................................................................................... 11 1.1 Relation ship of input data and source output voltage................................................................................ 12 2. Vertical input timing ............................................................................................................................................ 13 3. VCOM voltage definition ................................................................................................................................... 14 4. VCOM relationship.............................................................................................................................................. 14 5. Touch panel timing............................................................................................................................................... 15F.Power On/Off Characteristics............................................................................171. Recommended Power On/off Sequence........................................................................................................ 17G. Optical Specification ...........................................................................................18 H. Reliability Test Items.........................................................................................20 I. Packing and Marking ..........................................................................................221. 2. 3. Packing Form ...................................................................................................................................................... 22 Module/Panel Label Information ................................................................................................................... 23 Carton Label Information................................................................................................................................. 23 Application Circuit............................................................................................................................................ 24J.Application Note ..................................................................................................241. 2. Touch panel pin assign circuit............................................................................................................................ 25L. Touch Panel Command and Register Map ........................................................271. I2C Protocol Definition ....................................................................................................................................... 27 2. Coordinate Register Map .................................................................................................................................... 29 3. Sensitivity .............................................................................................................................................................. 30 4. Interrupt Operation Mode .................................................................................................................................. 30 5. Power Mode ........................................................................................................................................................... 33 6. Calibration ............................................................................................................................................................. 34 7. Power On/Off Sequence...................................................................................................................................... 34ALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.Version: Page:0.4 3/34A. General InformationThis product is for Electric Book application. NO. 1 2 3 4 5 7 8 Item Screen Size Display Resolution Overall Dimension Active Area Dot Pitch Gray level Weight Unit inch dot mm mm mm -g Specification 6 (Diagonal) 800 (H)× 600(V) 131.4(H) × 105.4(V) × (1.86) (T) 122.4(H)×90.6(V) 0.153 (H)x 0.151(V) 16 (52) Note 1 RemarkNote 1: Not include FPC. Refer next page to get further information.ALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.Version: Page:0.4 4/34B. Outline DimensionALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.Version: Page:0.4 5/34C. Electrical Specifications1. Pin AssignmentI/O Structure ---Type2 --Type 3 Dummy pin VCOM polarity output signal VCOM signal setting pin External voltage for VCOMDC power. External voltage for VCOM high power. External voltage for VCOM low power. Global reset pin. Low reset. DC-DC converter shut down pin. 8 SHD_N I Type 3 “0” : Enable.(Panel shut down;Default) “1” : Disable. Power ready output. 9 PWR_RDY O Type 1 When SHD_N from “1” to “0”: PWR_RDY will become “0”. When SHD_N from “0” to “1”: after 100ms, PWR_RDY will become “1”. 10 11 12 13 VCOMIN_0 VCOMIN_1 YOE YCLK I I I I Type 2 Type 2 Type 3 Type 3 Logic Input for VCOM voltage generate. Logic Input for VCOM voltage generate. Vertical output enable pin. Vertical clock. input Vertical (up/down) scan direction. 14 UD I Type 3 U/D = "L": U/D = "H": Shift up to down. Default Shift down to up. Note2 Note2 Note1Recommended connector : FH12-50S-0.5SH.Pin No. 1 2 3 4 5 6 7 Symbol Dummy VCOM VCOM_BOT VCOMDC VCOMH VCOML RST_N I/O -O I P P P I Description RemarkALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.Version: Page:0.4 6/34Vertical start pulse input/output. 15 YDIOD I/O Type 5 These pins are used to input and output shift data. These pins are switched as input or output by setting the UD pin as follow. UD 16 YDIOU I/O Type 5 L H YDIOU Output Input YDIOD Input OutputHorizontal start pulse input/output. 17 XDIOL I/O Type 5 These pins are used to input and output shift data. These pins are switched as input or output by setting the SHL pin as follow. SHL 18 XDIOR I/O Type 5 L H 19 20 21 22 23 24 25 26 27 LD D0 D1 D2 D3 D4 D5 D6 D7 I I I I I I I I I Type 3 Type 3 Type 3 Type 3 Type 3 Type 3 Type 3 Type 3 Type 3 Latch data. Data input, First pixel LSB Data input, First pixel MSB Data input, Second pixel LSB Data input, Second pixel MSB Data input, Third pixel LSB Data input, Third pixel MSB Data input, Forth pixel LSB Data input, Forth pixel MSB Horizontal (left/right) scan direction. 28 SHL I Type 3 SHL = “L”: Shift right to left. SHL = “H”:Shift left to right. Default 29 30 31 32 33 34 35 36 37 38 39 XCLK VREF VR AVDD C1P C1N VSS VSSA VDD I C P C C C P P P Type 3 ----------Horizontal Clock input.. For power setting capactor connected pin. VCOMDC reference voltage For power setting capactor connected pin. For charge pump capactor connected pin. For charge pump capactor connected pin. Digital ground Analog ground. Analog power. For power setting capactor connected pin. For power setting capactor connected pin. Note3 XDIOL Input Output XDIOR Output InputVREF_POS C VREF_NEG CALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.Version: Page: 40 41 42 43 44 45 46 47 48 49 50 VDDX8 NVDDX8 VDD_DRV ADRVU ADRVD VSS_DRV VDPS VDNS VDPG VDNG Dummy P P P O O P P P C C D ---Type 1 Type 1 ------DCDC positive voltage DCDC negative voltage DCDC power. PWM output for DCDC converter. PWM output for DCDC converter. DCDC ground. External voltage for source postive power. External voltage for source negative power. For power setting capactor connected pin. For power setting capactor connected pin. Dummy pin Dummy0.4 7/34Note 1: Please reference chapter F Note 2: Please reference chapter E Note 3: Please reference chapter EALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.：I: Input pin; O:output pin, I/O: Input / Output; P: Power pin; C: capacitor pin; DVersion: Page: I/O Pin Structure:0.4 8/34ALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.Version: Page:0.4 9/342.Pin No. 1 2 3 4 5 6Touch Panel Pin AssignmentSymbol GND VDD_TP TP_INT IICSCL IICSDA RST_TP I/O P P O I I/O I Touch panel ground. Touch panel power. Touched Interrupt Indicator pin. Serial input clock in I2C-Bus interface operation pin. Serial input/output data in I2C-Bus interface operation pin. Touch panel reset pin. Description Remark3.Absolute Maximum RatingsSymbol VDD Condition VSSA=VSS=0 Min. -0.3 -0.3 Max. +5.0 +5.0 +20 -20 -0.3 VDNG+40 +0.3 70 50 Unit V V V V RemarkItem Power voltage Power voltage Source voltageVDD_DRV VSS_DRV=0 VDPS VDNS VSSA=VSS=0 VSSA=VSS=0 VSSA=VSS=0Gate voltage Storage temperature OperatingVDPG VDNG Tstg TopaVSSA=VSS=0 VDPG-40 -25 0ALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.℃ ℃Version: Page:0.4 10/34D. Electrical CharacteristicsItem Supply Voltage Low Level Input Voltage Touch Panel Supply Voltage High Level Input Voltage Operating temperature Symbol VDD Condition VSSA=VSS=VSS_DRV=0V Min. --GND 3.0 0.7xVDD VDD=VDD_DRV=3.3V Operation Power Dissipation VDNS -15V VDPS 15V VCOML -18.5V VDNS 0V VDPS 0V VCOMH 0V Typical 3.3 3.3 3.3 -Max. --0.3xVDD 5.0 VDD V V V ° C Unit VVDD_DRV VSSA=VSS=VSS_DRV=0V Vil VDD_TP Vih Top Digital input pins VSSA=VSS=VSS_DRV=0V Digital input pinsVDD=VDD_DRV=3.3V Standby Power DissipationVCOML 0V2. Touch Panel Power Consumption Mode Active Sleep Deep Sleep Symbol Ptp_a Ptp_s Ptp_dp VDD= 3.0V Condition Min. Typ. (9) (1) (0.7) Max. Unit mA mA mA RemarkALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.，-(11) (14) mAVCOMH 11.5V＝ ， ＝ ＝ ＝＝ ＝ ＝ ＝--(21)(28)mAVersion: Page:0.4 11/34E. Input timing AC Characteristics1. Horizontal input timingFigure 1: LD input timingN=800 Figure 2: Horizontal data Input timingALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.Version: Page:0.4 12/34(VDD=VDD_DRV=3.3V, VSSA=VSS=VSS_DRV=0V, TA=25 ) PARAMETER Clock pulse width Data setup time Data hold time LD pulse width Time from LD to XDIOL/XDIOR SYMBOL TWXDCLK Tsetup Thold TWLD TLD_DIO MIN. 13 2 2 1 5 -1.1 Relation ship of input data and source output voltageThe source driver output voltage will base on input 2 bits data, and the relationship is as below:MSB 0 0 1 1LSB 0 1 0 1Function Source output is 0V Source output is VDPS(+15V) Source output is VDNS(-15V) Source output is floatingALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.℃TYP.MAX.UNIT ns ns ns XCLK XCLKVersion: Page:0.4 13/342. Vertical input timing1 YCLK23NYDIOU/ YDIOD (Input)YOEG1G2G3GN YDIOU/ YDIOD (Output)N=600 Figure 3: Vertical input timingALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.Version: Page:0.4 14/343. VCOM voltage definitionThe VCOM output voltage will base on input pins VCOMIN[1:0], and the relationship is as below:VCOMIN[1 :0] 00 01 10 11Function VCOM output is (-VDC) v VCOM output is (VDPS-VDC) v VCOM output is (VDNS-VDC) v VCOM output is floating4. VCOM relationshipVCOM will change while VOCMIN change Source output will change while LD signal falling edge.ALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.Version: Page:0.4 15/345. Touch panel timing5.1. I2C Timing DiagramNote : Slave address is 1001100.5.2. Register Write Sequence5.3. Register Read SequenceALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.Version: Page:0.4 16/345.4. I2C Timing CharacteristicsItem Working Frequency I2C Clock Low I2C Clock High I2C Data ring time I2C Data falling time I2C Data hold time I2C Data setup time I2C Start Condition hold time I2C Start Condition setup time I2C Stop Condition setup time I2C Bus free timeSymbol Fclk TckL TckH Tr Tf TDatHd TDatSu TStaHd TStaSu TStpSu TBusFreeMin. 1250 1250 0 100 600 600 600 1300Typ. -Max. 400 300 300 -Unit KHz ns ns ns ns ns ns ns ns ns nsALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.℃ ℃ ℃ ℃VDDI=1.65~3.3V, VCI=2.5~3.3V, TA=25Version: Page:0.4 17/34F. Power On/Off Characteristics1. Recommended Power On/off SequenceThe suggested power on/off sequence is below: 1. Power on sequence:2. Power off sequence:ALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.Version: Page:0.4 18/34G. Optical SpecificationAll optical specification is measured under typical condition (Note 1, 2) Item Reflectance Contrast Ratio Symbol R CRrCondition white At optimized viewing angleMin. 27 5Typ. 30 6Max. ---Unit %Remark Note1,4 Note1, 5Response timeNote 2. Reflectance and constrast ratio are measured by KONICA MINOLTA spectrophotometer CM-2600d.ALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.℃Note 1. Ambient temperature =25fT T30V 30V(300) (300)msNote 3Version: Page:0.4 19/34Note 3. Definition of response time: The response time is defined as the time from image load to full updated display. The output signals of photo detector are measured when the input signals are changed from “black” to “white”(raising time) and from “white” to “black”(falling time), respectively. Refer to figure as below."White"Signal (Relative Value) 100 % 90 %"Black""White"0%TfNote 4. Definition of Reflectance: The Reflectance is expressed as: R = Reflectance Factorwhite board x (Lcenter / Lwhite board)TrLcenter is the luminance measured at center in a white area. Lwhite board is the luminance of a standard white board. Note 5. Definition of contrast ratio: The contrast ratio (CR) is the ratio between the reflectance in a full white area (Rl) and reflectance in a dark area (Rd).Contrast ratio (CR) =Rl RdALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.H.ALL RIGHTS STRICTLY RESERVED. ANY PORTION OF THIS PAPER SHALL NOT BE REPRODUCED, COPIED, OR TRANSFORMED TO ANY OTHER FORMS WITHOUT PERMISSION FROM AU OPTRONICS CORP.. s el u s p a c or ci m ot e g a m a d r o e g a k a e r b s s a l g o n - a i r e t i r c s s aPg n i p p a T s u l y tS 7 1 g n ppaT su y S 71 g niii p p a T s u lll y tttS 7 1 g n ppaT su y S 71 e c n a m r o f r eP e c n a m r o f r eP e c n a m r o f r eP e c n a m r o f r eP g nii d n e b CPF 6 1 g n d n e b C PF g nii d n e b CPF g n d n e b C PF htt g n e r ttS h g n er S htt g n e r ttS 5 1 h g n er S g n iir e d ll oS CPF g n r e d oS C PF g n iir e d ll oS CPF g n r e d oS C PF t c e f f E t h g i l n uS 4 1 e g a r o ttS e g ar o S e g a r o ttS 3 1 e g ar o S tt s ett e d u ttiittllA se edu A tt s ett e d u ttiittllA se edu A n oiitt a r e p O n o ar e p O n oiitt a r e p O 2 1 n o ar e p O tt s ett e d u ttiittllA se edu A tt s ett e d u ttiittllA se edu A. d e i f s it a s e b l l a h s s n oi t a ci f i c e p s ,l a ci n a h c e m , c i r t c el e t s e t e h t f o d n e e ht t A . d e i f s it a s e b l l a h s s n oi t a ci f i c e p s ,l a ci n a h c e m , c i r t c el e t s e t e h t f o d n e e ht t A de fs as de fs as .... d e iiiif siiiitttt a s de fs as e b a h s s c s r e c ar a h c a c p O e b a h s s c s r e c ar a h c a c p O e b llllllll a h s s ciiiitttt siiiir e tttt c a r a h c llll a ciiiitttt p O e b a h s s c s r e c ar a h c a c p O 3 5 7 7B SI Js e mit 0 0 5 , 3 1 l at o T c e s / s e m it 5 ： d e e pS f g 0 0 3： d a o L m m 4 . 0 R p o T ： n eP L A T E C A Y L O P ∘ 5 3 1 ± ： el g n a g ni d n e B , f g 0 0 5 t h g i e W m m 0 . 1： s ui d ar et ar g ni d n e B . d o h t e m T IM yl p p A s n o it c e r i d l a ci t r e v d n a l a t n o zi r o h e ht n i g 0 0 5 f o e c r o f a h t i w t r a p d e r e d l o s C PF e h t l l u P d e y al p s i d n e e r c s h t i w s r h 0 5 1 r o f C ∘ 2 - /+ C ∘ 3 6 f o e r u t a r e p m et t a e n o d e b ll a h s t s e t t h gi l n uS s r h 8 4 ) m 0 0 0 , 0 1 = ( aP h 0 6 2 s r h 8 4 ) m 0 0 0 , 3 = ( aP h 0 0 7. d e i f s it a s e b l l a h s s n oi t a ci f i c e p s ,l a ci n a h c e m , c i r t c el e t s e t e h t f o d n e e ht t A . d e i f s it a s e b l l a h s s n oi t a ci f i c e p s ,l a ci n a h c e m , c i r t c el e t s e t e h t f o d n e e ht t A de fs as e b ahs sn o ac f ce ps .. d e ii f s iitt a s e b ll ll a h s s n oii tt a cii f ii c e p s ac nahcem c r ce e ,,ll a cii n a h c e m ,, c ii r tt c ell e t s e t e h t f o d n e e ht t A de fs as e b ahs sn o ac f ce ps de fs as e b ahs sn o ac f ce ps .... d e iiiif s iiiitttt a s e b llllllll a h s s n oiiiitttt a ciiiif iiii c e p s de fs as e b ahs sn o ac f ce ps ac po dna ac nahcem c r ce e ac po dna ac nahcem c r ce e llll a c iiiitttt p o d n a ,,,,llll a ciiii n a h c e m ,,,, c iiiir tttt c ellll e ac po dna ac nahcem c r ce e se eh fo dne eh A se eh fo dne eh A tttts e tttt e h tttt f o d n e e htttt ttttA se eh fo dne eh A0 8 1 2 6 CEI 0 8 1 2 6 CEI 0 8 1 2 6 CEI 0 8 1 2 6 CEI 9 7 1 2 6 CEI 9 7 1 2 6 CEI ,,,, 9 7 1 2 6 C E I 9 7 1 2 6 CEI nemp hs nemp hs tttt n e m p iiii h s nemp hs r o f d e k c a p uF r o f d e k c a p llll uF nemp hs nemp hs ttt n e m p iii h s r o f d e k c a p uF r o f d e k c a p uF r o f d e k c a p llllllll uF r o f d e k c a p uF aS 5 - 2 - 8 6 0 0 6 C E I aS 5 - 2 - 8 6 0 0 6 C E I aS 5 - 2 - 8 6 0 0 6 C E I aS 5 - 2 - 8 6 0 0 6 C E I 4 1- 2 - 8 6 0 0 6 CEI 4 1- 2 - 8 6 0 0 6 CEI 4 1- 2 - 8 6 0 0 6 CEI 4 1- 2 - 8 6 0 0 6 CEI A C 3- 2- 8 6 0 0 6 CEI A C 3- 2- 8 6 0 0 6 CEI A C 3- 2- 8 6 0 0 6 CEI A C 3- 2- 8 6 0 0 6 CEI A C 3- 2- 8 6 0 0 6 CEI A C 3- 2- 8 6 0 0 6 CEI A C 3- 2- 8 6 0 0 6 CEI A C 3- 2- 8 6 0 0 6 CEI b A 2- 2 - 8 6 0 0 6 CEI b A 2- 2 - 8 6 0 0 6 CEI b A 2- 2 - 8 6 0 0 6 CEI b A 2- 2 - 8 6 0 0 6 CEI pB 2- 2 - 8 6 0 0 6 CEI pB 2- 2 - 8 6 0 0 6 CEI pB 2- 2 - 8 6 0 0 6 CEI pB 2- 2 - 8 6 0 0 6 CEI b A 2- 2 - 8 6 0 0 6 CEI b A 2- 2 - 8 6 0 0 6 CEI b A 2- 2 - 8 6 0 0 6 CEI b A 2- 2 - 8 6 0 0 6 CEI pB 2- 2 - 8 6 0 0 6 CEI pB 2- 2 - 8 6 0 0 6 CEI pB 2- 2 - 8 6 0 0 6 CEI pB 2- 2 - 8 6 0 0 6 CEI d o h ttt eM d o h eM d o h eMF p 0 0 2 Ω 0 V 0 5 2 - + ) g n iitt a r e p o - n o n ( F p 0 0 2 Ω 0 V 0 5 2 - + ) g n ar e p o- n o n( F p 0 0 2 ,,,,Ω 0 ,,,,V 0 5 2 - ////+ ) g n iitt a r e p o - n o n ( 1 1 F p 0 0 2 Ω 0 V 0 5 2 - + ) g n ar e p o- n o n( ) e d o m e n h c aM ( e z e b h W c e f f E c iitt a tt s o r tt c ellE ) e d o m e n h c aM ( e z e b h W c e f f E c a s o r c e E )llll e d o m e niiii h c aM ( llll e z e b httttiiiiW tttt c e f f E c iitt a tt s o r tt c ellE ) e d o m e n h c aM ( e z e b h W c e f f E c a s o r c e E h c a e r of p or d e n o s e c af h c a e r of p or d e n o s e c af .... h c a e r o f p o r d e n o s e c a f h c a e r of p or d e n o s e c af 6 ,,,,s e g d e 3 ,,,,r e n r o c 1 ： e c n e u q e s p o r D 6 s e g d e 3 r e nr o c 1 ： e c n e u q e s p or D tt c a p m I 0 1 c a p mI 6 s e g d e 3 r e nr o c 1 ： e c n e u q e s p or D 6 s e g d e 3 r e nr o c 1 ： e c n e u q e s p or D tt c a p m I 0 1 c a p mI 0 1 e c afr u s p o r D e g a k c aP 0 1 .. e c a f r u s p o r D e g a k c aP e er c n o c n o m c 0 0 1 f o h g e h m orf p or D e tt e r c n o c n o m c 0 0 1 f o tt h g ii e h m o r f p o r D n o c e r d h c a e n sr u o h 1 ： n o ar u D n o c e r d h c a e n sr u o h 1 ： n o ar u D n o iiiitttt c e riiii d h c a e niiii s r u o h 1 ： n oiiiitttt a r u D n o c e r d h c a e n sr u o h 1 ： n o ar u D Z ,,,,Y ,,,,X ： n oiiiitttt c e riiii D n oiiiitttt a r b iiiV e g a k c aP 9 Z Y X ： n o c e r D n o a r b V e g a k c aP 9 Z Y X ： n o c e r D n o a r b i V e g a k c aP 9 Z Y X ： n o c e r D n o a r b V e g a k c aP 9 Z H 0 0 5 ~ 0 1 ： y c n e u q e rF G 4 0 1 Z H 0 0 5 ~ 0 1 ： y c n e u q e rF G 4 0 1 Z H 0 0 5 ~ 0 1 ： y c n e u q e rF ,,,,G 4 0 .... 1 Z H 0 0 5 ~ 0 1 ： y c n e u q e rF G 4 0 1 C ∘ 0 4 sr h 8 6 1 r of 2 m W m 5 6 7 C ∘ 0 4 sr h 8 6 1 r of 2 m W m 5 6 7 C ∘ 0 4 ,,,,s r h 8 6 1 r o f 2 m ////W m 5 6 7 C ∘ 0 4 sr h 8 6 1 r of 2 m W m 5 6 7 e c n at si s e R 8 er u s o p x e V U 8 er u s o p x e V U 8 er u s o p x e V U 8s el c y c 0 0 1 ： ] n i m 0 3 C ∘ 0 7+ [ ell c y C e r u tt a r e p m e T 7 e c yC er u ar e p m eT 7 e c yC er u ar e p m eT 7 > - ] n i m 0 3 C ∘ 5 2 - [ ： el c y C 1 ell c y C e r u tt a r e p m e T 7e g a r o ttS e g ar o S e g a r o ttS e g ar o S s r h 0 4 2 r o f % 0 8= H R C ∘ 0 5 += b m a T s r h 0 4 2 r o f % 0 8= H R C ∘ 0 5 += b m a T y ttii dii m u H - h giiH 6 y d m u H- h g H 6 s r h 0 4 2 r o f % 0 8= H R ,,,,C ∘ 0 5+= b m a T s r h 0 4 2 r o f % 0 8= H R C ∘ 0 5 += b m a T y ttii dii m u H - h giiH 6 y d m u H- h g H 6 e r u t a r e p m e T - h giiH er u ar e p m eT- h g H ,,,, e r uttt a r e p m e T - h giiH er u ar e p m eT- h g H n oiitt a r e p O n o ar e p O n oiitt a r e p O n o ar e p O y ttii dii m u H - h giiH 5 y d m u H- h g H 5 y ttii dii m u H - h giiH 5 y d m u H- h g H 5 e r u t a r e p m e T - h giiH er u ar e p m eT- h g H ,,,, e r uttt a r e p m e T - h giiH er u ar e p m eT- h g H s r h 8 6 1 r o f % 0 9= H R C ∘ 0 4 += b m a T s r h 8 6 1 r o f % 0 9= H R C ∘ 0 4 += b m a T s r h 8 6 1 r o f % 0 9= H R ,,,,C ∘ 0 4+= b m a T s r h 8 6 1 r o f % 0 9= H R C ∘ 0 4 += b m a T e g a r o tS 4 s r h 0 4 2 r o f C ∘ 5 2 -= b m a T s r h 0 4 2 r o f C ∘ 5 2 -= b m a T 4 s r h 0 4 2 r o f C ∘ 5 2 -= b m a T s r h 0 4 2 r o f C ∘ 5 2 -= b m a T 4 4 e r ut a r e p m e T - w o L e g a r o tS s r h 0 4 2 r o f % 3 2= H R C ∘ 0 7 += b m a T s r h 0 4 2 r o f % 3 2= H R C ∘ 0 7 += b m a T 3 3 s r h 0 4 2 r o f % 3 2= H R ,,,,C ∘ 0 7+= b m a T s r h 0 4 2 r o f % 3 2= H R C ∘ 0 7 += b m a T 3 3 e r ut a r e p m e T - h gi H n oi t a r e p O s r h 0 4 2 r o f C ∘ 0= b m a T s r h 0 4 2 r o f C ∘ 0= b m a T 2 s r h 0 4 2 r o f C ∘ 0= b m a T e r u t a r e p m e T - w o L 2 s r h 0 4 2 r o f C ∘ 0= b m a T 2 2 n oiitt a r e p O n o ar e p O n o tt a r e pO 1 n O s r h 0 4 2 r o f % 0 3= H R C ∘ 0 5+= b m a T e r u a r e p moiiTa r egp H 1 s r h 0 4 2 r o f % 0 3= H R C ∘ 0 5 += b m a T s r h 0 4 2 r o f % 0 3= H R ,,,,C ∘ 0 5+= b m a T e r utt a r e p m e T - h gi H 1 s r h 0 4 2 r o f % 0 3= H R C ∘ 0 5 += b m a T e -h i 1 n o iiitttiii d n o C no d noC no d noC seT seT ttts e T oN oN ... o Nde fs as e b ahs sn o ac f ce ps de fs as e b ahs sn o ac f ce ps .... d e iiiif s iiiitttt a s e b llllllll a h s s n oiiiitttt a ciiiif iiii c e p s de fs as e b ahs sn o ac f ce ps ac po dna ac nahcem c r ce e ac po dna ac nahcem c r ce e llll a c iiiitttt p o d n a ,,,,llll a ciiii n a h c e m ,,,, c iiiir tttt c ellll e ac po dna ac nahcem c r ce e se eh fo dne eh A se eh fo dne eh A tttts e tttt e h tttt f o d n e e htttt ttttA se eh fo dne eh A de fs as e b ahs sn o ac f ce ps de fs as e b ahs sn o ac f ce ps .... d e iiiif s iiiitttt a s e b llllllll a h s s n oiiiitttt a ciiiif iiii c e p s de fs as e b ahs sn o ac f ce ps ac po dna ac nahcem c r ce e ac po dna ac nahcem c r ce e llll a c iiiitttt p o d n a ,,,,llll a ciiii n a h c e m ,,,, c iiiir tttt c ellll e ac po dna ac nahcem c r ce e se eh fo dne eh A se eh fo dne eh A tttts e tttt e h tttt f o d n e e htttt ttttA se eh fo dne eh A de fs as e b ahs sn o ac f ce ps de fs as e b ahs sn o ac f ce ps .... d e iiiif s iiiitttt a s e b llllllll a h s s n oiiiitttt a ciiiif iiii c e p s de fs as e b ahs sn o ac f ce ps ac nahcem c r ce e ac nahcem c r ce e ,,,,llll a ciiii n a h c e m ,,,, c iiiir tttt c ellll e ac nahcem c r ce e se eh fo dne eh A se eh fo dne eh A tttts e tttt e h tttt f o d n e e htttt ttttA se eh fo dne eh A de fs as e b ahs sn o ac f ce ps de fs as e b ahs sn o ac f ce ps .... d e iiiif s iiiitttt a s e b llllllll a h s s n oiiiitttt a ciiiif iiii c e p s de fs as e b ahs sn o ac f ce ps ac nahcem c r ce e ac nahcem c r ce e ,,,,llll a ciiii n a h c e m ,,,, c iiiir tttt c ellll e ac nahcem c r ce e se eh fo dne eh A se eh fo dne eh A tttts e tttt e h tttt f o d n e e htttt ttttA se eh fo dne eh A de fs as e b ahs sn o ac f ce ps de fs as e b ahs sn o ac f ce ps .... d e iiiif s iiiitttt a s e b llllllll a h s s n oiiiitttt a ciiiif iiii c e p s de fs as e b ahs sn o ac f ce ps ac nahcem c r ce e ac nahcem c r ce e ,,,,llll a ciiii n a h c e m ,,,, c iiiir tttt c ellll e ac nahcem c r ce e se eh fo dne eh A se eh fo dne eh A tttts e tttt e h tttt f o d n e e htttt ttttA se eh fo dne eh A de fs as e b ahs sn o ac f ce ps de fs as e b ahs sn o ac f ce ps .... d e iiiif s iiiitttt a s e b llllllll a h s s n oiiiitttt a ciiiif iiii c e p s de fs as e b ahs sn o ac f ce ps ac po dna ac nahcem c r ce e ac po dna ac nahcem c r ce e llll a c iiiitttt p o d n a ,,,,llll a ciiii n a h c e m ,,,, c iiiir tttt c ellll e ac po dna ac nahcem c r ce e se eh fo dne eh A se eh fo dne eh A tttts e tttt e h tttt f o d n e e htttt ttttA se eh fo dne eh A de fs as e b ahs sn o ac f ce ps de fs as e b ahs sn o ac f ce ps .... d e iiiif s iiiitttt a s e b llllllll a h s s n oiiiitttt a ciiiif iiii c e p s de fs as e b ahs sn o ac f ce ps ac po dna ac nahcem c r ce e ac po dna ac nahcem c r ce e llll a c iiiitttt p o d n a ,,,,llll a ciiii n a h c e m ,,,, c iiiir tttt c ellll e ac po dna ac nahcem c r ce e se eh fo dne eh A se eh fo dne eh A tttts e tttt e h tttt f o d n e e htttt ttttA se eh fo dne eh A de fs as e b ahs sn o ac f ce ps de fs as e b ahs sn o ac f ce ps .... d e iiiif s iiiitttt a s e b llllllll a h s s n oiiiitttt a ciiiif iiii c e p s de fs as e b ahs sn o ac f ce ps ac po dna ac nahcem c r ce e ac po dna ac nahcem c r ce e llll a c iiiitttt p o d n a ,,,,llll a ciiii n a h c e m ,,,, c iiiir tttt c ellll e ac po dna ac nahcem c r ce e se eh fo dne eh A se eh fo dne eh A tttts e tttt e h tttt f o d n e e htttt ttttA se eh fo dne eh A de fs as e b ahs sn o ac f ce ps de fs as e b ahs sn o ac f ce ps ... d e iiif s iiittt a s e b llllll a h s s n oiiittt a ciiif iii c e p s ac po dna ac nahcem c r ce e ac po dna ac nahcem c r ce e llll a c iiiitttt p o d n a ,,,,llll a ciiii n a h c e m ,,,, c iiiir tttt c ellll e ac po dna ac nahcem c r ce e se eh fo dne eh A se eh fo dne eh A tttts e tttt e h tttt f o d n e e htttt ttttA se eh fo dne eh A kr a m e R kr a m e R kr a m e RReliability Test ItemsPage: Version: 20/34 0.4。

苏泊尔电磁炉电路图集TD0303灯板原理图（前锋）TD0303主板电路原理图（前锋）QF-139-08(主)TD0305灯板电路原理图（前锋）TD0305主板电路原理图（前锋）QF-096-05(主) QF-100-08T0306灯板电路原理图（前锋）欧阳体创编 2021.02.03 欧阳美创编 2021.02.03欧阳体创编 2021.02.03 欧阳美创编2021.02.03T0307主板、灯板电路原理图（前锋）QF-101-02(主) QF-078-02TD0309主板、灯板电路原理图（前锋）QF-134-06(主) QF-136-03TD0310主板、灯板电路原理图（前锋）前锋－134－06（主）前锋－136－03TD0322灯板电路原理图（前锋）QF-836TD0322主板电路原理图（前锋）QF-7TD0411灯板电路原理图（前锋）QF-SL395TD0411主板电路原理图（前锋）QF-876-01CTD0412灯板电路原理图（一）（前锋）TD0412主板电路原理图(一) （前锋）TD0413灯板电路原理图（前锋）TD0413主板电路原理图（前锋）TD0418灯板电路原理图（前锋）TD0418主板电路原理图（前锋）TD0418灯板电路原理图（瑞德）TD0418主板电路原理图（瑞德）2005年电路图集TD0501CT、TD0501T灯板（一）电路原理图（前锋）TD0501CT、TD0501T主板（一）电路原理图（前锋QF-1010）TD0501CT、TD0501T主板（一）电路原理图（前锋QF-1042）TD0501CT、TD0501T灯板（二）电路原理图（前锋）TD0501CT、TD0501T主板（二）电路原理图（前锋QF－1058－02）TD0501T、TD0501CT灯板电路原理图（拓邦）TD0501T、TD0501CT主板电路原理图（拓邦）TD0503T灯板电路原理图（前锋）TD0503T主板电路原理图（前锋）TD0504灯板电路原理图（前锋）TD0504主板电路原理图（前锋）TD0504灯板电路原理图（瑞德）。