PS8602中文资料
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SP8602 500MHz 42SP8604 300MHz 42DS3658-1·2The SP8602 and SP8604 are emitter coupled logic dividers which feature ECL10K compatible outputs when used with external pulldown resistors. The inputs are AC coupled.FEATURESs ECL Compatible Outputss AC-Coupled Inputs (Internal Bias)QUICK REFERENCE DATAs Supply Voltage: 25·2Vs Power Consumption: 85mW s Temperature Range:255°C to 1125°C (A Grade)230°C to 170°C (B Grade)ORDERING INFORMATIONSP8602 A CM SP8602 B CM SP8604 A CM SP8604 B CM5962-92059 (SMD) (SP8602)ABSOLUTE MAXIMUM RATINGSSupply voltage, V EE Output currentStorage temperature range Max. junction temperature Max. clock input voltageFig. 2 Functional diagram28V 10mA265°C to 1150°C1175°C 2·5V p-pADVANCE INFORMATIONhttps://2SP8602/4Maximum frequency (sinewave input)Minimum frequency (sinewave input)Power supply current Output low voltage Output high voltage Minimum output swingf MAX f MIN I EE V OL V OH V OUT50030021·820·85400Min.Max.401821·420·7ValueNotesMHz MHz MHz mA V V mV33Input = 400-800mV p-p Input = 400-800mV p-p Input = 400-800mV p-p V EE = 25·2V, outputs unloaded V EE = 25·2V V EE = 25·2V V EE = 25·2VELECTRICAL CHARACTERISTICSUnless otherwise stated, the Electrical Characteristics are guaranteed over specified supply, frequency and temperature range Supply voltage, V CC = 0V, V EE = 25·2V 6 0·25VTemperature, T AMB = 255°C to 1125°C (A Grade), 230°C to 170°C (B Grade)Conditions Units Symbol CharacteristicTypeSP8602SP8604Both Both Both Both BothFig. 4 Typical input impedance. Test conditions: supply voltage = 25·2V, ambienttemperature = 25°C, frequencies in MHz, Impedances normalised to 50ΩNOTES1.The temperature coefficients of V OH = 11·63mV/°C, and V OL = 10·34mV/°C but these are not tested.2.The test configuration for dynamic testing is shown in Fig.5.3.Tested at 25°C only.SP8602/4OPERATING NOTES1.The clock inputs (pins 1 and 2) can be driven single ended or differentially and should be capacitively coupled to the signal source. The input signal path is completed by connecting a capacitor from the internal bias decoupling, pin 3, to ground.2.In the absence of a signal the device will self-oscillate. If this is undesirable, it may be prevented by connecting a 15kΩ resistor from the unused input to V EE. This will reduce the input sensitivity by approximately 100mV.3.The circuit will operate down to DC but slew rate must be better than 100V/µs.4.The outputs are compatible with ECLII. There is an internal load of 4kΩ on each output. The outputs can be interfaced to ECL10K by the addition of 1·5kΩ pulldown resistors from the outputs to V EE to increase output voltage swing.5.Input impedance is a function of frequency, See Fig. 4.6.All components should be suitable for the frequency in use.Fig. 6 Typical application showing interfacing34SP8602/4HEADQUARTERS OPERATIONS GEC PLESSEY SEMICONDUCTORS Cheney Manor, Swindon,Wiltshire SN2 2QW, United Kingdom.Tel: (0793) 518000Fax: (0793) 518411GEC PLESSEY SEMICONDUCTORS P.O. Box 6600171500 Green Hills Road,Scotts Valley, CA95067-0017United States of America.Tel (408) 438 2900Fax: (408) 438 5576CUSTOMER SERVICE CENTRESqFRANCE & BENELUX Les Ulis Cedex Tel: (1) 64 46 23 45 Fax : (1) 64 46 06 07q GERMANY Munich Tel: (089) 3609 06-0 Fax : (089) 3609 06-55q ITALY Milan Tel: (02) 66040867 Fax: (02) 66040993q JAPAN Tokyo Tel: (3) 5276-5501 Fax: (3) 5276-5510q NORTH AMERICA Scotts Valley, USA Tel: (408) 438 2900 Fax: (408) 438 7023.q SOUTH EAST ASIA Singapore Tel: (65) 3827708 Fax: (65) 3828872q SWEDEN Stockholm Tel: 46 8 702 97 70 Fax: 46 8 640 47 36q UK, EIRE, DENMARK, FINLAND & NORWAY Swindon Tel: (0793) 518510 Fax : (0793) 518582These are supported by Agents and Distributors in major countries world-wide.© GEC Plessey Semiconductors 1994 Publication No. DS3658 Issue No. 1.2 March 1994This publication is issued to provide information only which (unless agreed by the Company in writing) may not be used, applied or reproduced for any purpose nor form part of any order or contract nor to be regarded as a representation relating to the products or services concerned. No warranty or guarantee express or implied is made regarding the capability, performance or suitability of any product or service. The Company reserves the right to alter without prior knowledge the specification, design or price of any product or service. Information concerning possible methods of use is provided as a guide only and does not constitute any guarantee that such methods of use will be satisfactory in a specific piece of equipment. It is the user's responsibility to fully determine the performance and suitability of any equipment using such information and to ensure that any publication or data used is up to date and has not been superseded. These products are not suitable for use in any medical products whose failure to perform may result in significant injuryor death to the user. All products and materials are sold and services provided subject to the Company's conditions of sale, which are available on request.PACKAGE DETAILShttps://。
光耦选型指南
光电耦合器(简称光耦)是开关电源电路中常用的器件。
光电耦合器分为两种:一种为非线性光耦,另一种为线性光耦。
常用的4N系列光耦属于非线性光耦常用的线性光耦是PC817A—C系列。
非线性光耦的电流传输特性曲线是非线性的,这类光耦适合于弄开关信号的传输,不适合于传输模拟量。
线性光耦的电流传输手特性曲线接进直线,并且小信号时性能较好,能以线性特性进行隔离控制。
开关电源中常用的光耦是线性光耦。
如果使用非线性光耦,有可能使振荡波形变坏,严重时出现寄生振荡,使数千赫的振荡频率被数十到数百赫的低频振荡依次为号调制。
由此产生的后果是对彩电,彩显,VCD,DCD等等,将在图像画面上产生干扰。
同时电源带负载能力下降。
在彩电,显示器等开关电源维修中如果光耦损坏,一定要用线性光耦代换。
常用的4脚线性光耦有PC817A----C。
PC111 TLP521等常用的六脚线性光耦有:TLP632 TLP532 PC614 PC714 PS2031等。
常用的4N25 4N26 4N35 4N36是不适合用于开关电源中的,因为这4种光耦均属于非线性光耦。
经查大量资料后,以下是目前市场上常见的高速光藕型号:100K bit/S:6N138、6N139、PS87031M bit/S:6N135、6N136、CNW135、CNW136、PS8601、PS8602、PS8701、PS9613、PS9713、CNW4502、HCPL-2503、HCPL-4502、HCPL-2530(双路)、HCPL-2531(双路)10M bit/S:6N137、PS9614、PS9714、PS9611、PS9715、HCPL-2601、HCPL-2611、HCPL-2630(双路)、HCPL-2631(双路)光耦合器的增益被称为晶体管输出器件的电流传输比 (CTR),其定义是光电晶体管集电极电流与LED正向电流的比率(ICE/IF)。
光电晶体管集电极电流与VCE有关,即集电极和发射极之间的电压。
光电耦合器件简介
光电耦合器件简介光电偶合器件(简称光耦)是把发光器件(如发光二极体)和光敏器件(如光敏三极管)组装在一起,通过光线实现耦合构成电—光和光—电的转换器件。
光电耦合器分为很多种类,图1所示为常用的三极管型光电耦合器原理图。
当电信号送入光电耦合器的输入端时,发光二极体通过电流而发光,光敏元件受到光照后产生电流,CE导通;当输入端无信号,发光二极体不亮,光敏三极管截止,CE不通。
对于数位量,当输入为低电平“0”时,光敏三极管截止,输出为高电平“1”;当输入为高电平“1”时,光敏三极管饱和导通,输出为低电平“ 0”。
若基极有引出线则可满足温度补偿、检测调制要求。
这种光耦合器性能较好,价格便宜,因而应用广泛。
图一最常用的光电耦合器之部结构图三极管接收型 4脚封装图二光电耦合器之部结构图三极管接收型 6脚封装图三光电耦合器之部结构图双发光二极管输入三极管接收型 4脚封装图四光电耦合器之部结构图可控硅接收型 6脚封装图五光电耦合器之部结构图双二极管接收型 6脚封装光电耦合器之所以在传输信号的同时能有效地抑制尖脉冲和各种杂讯干扰,使通道上的信号杂讯比大为提高,主要有以下几方面的原因:(1)光电耦合器的输入阻抗很小,只有几百欧姆,而干扰源的阻抗较大,通常为105~106Ω。
据分压原理可知,即使干扰电压的幅度较大,但馈送到光电耦合器输入端的杂讯电压会很小,只能形成很微弱的电流,由于没有足够的能量而不能使二极体发光,从而被抑制掉了。
(2)光电耦合器的输入回路与输出回路之间没有电气联系,也没有共地;之间的分布电容极小,而绝缘电阻又很大,因此回路一边的各种干扰杂讯都很难通过光电耦合器馈送到另一边去,避免了共阻抗耦合的干扰信号的产生。
(3)光电耦合器可起到很好的安全保障作用,即使当外部设备出现故障,甚至输入信号线短接时,也不会损坏仪表。
因为光耦合器件的输入回路和输出回路之间可以承受几千伏的高压。
(4)光电耦合器的回应速度极快,其回应延迟时间只有10μs左右,适于对回应速度要求很高的场合。
光耦参数及资料
市场常见光耦内部图:光电耦合器(简称光耦)是开关电源电路中常用的器件。
光电耦合器分为两种:一种为非线性光耦,另一种为线性光耦。
常用的4N系列光耦属于非线性光耦常用的线性光耦是PC817A—C系列。
非线性光耦的电流传输特性曲线是非线性的,这类光耦适合于弄开关信号的传输,不适合于传输模拟量。
线性光耦的电流传输手特性曲线接进直线,并且小信号时性能较好,能以线性特性进行隔离控制。
开关电源中常用的光耦是线性光耦。
如果使用非线性光耦,有可能使振荡波形变坏,严重时出现寄生振荡,使数千赫的振荡频率被数十到数百赫的低频振荡依次为号调制。
由此产生的后果是对彩电,彩显,VCD,DCD等等,将在图像画面上产生干扰。
同时电源带负载能力下降。
在彩电,显示器等开关电源维修中如果光耦损坏,一定要用线性光耦代换。
常用的4脚线性光耦有PC817A----C。
PC111 TLP521等常用的六脚线性光耦有:TLP632 TLP532 PC614 PC714 PS2031等。
常用的4N25 4N26 4N35 4N36是不适合用于开关电源中的,因为这4种光耦均属于非线性光耦。
以下是目前市场上常见的高速光藕型号:100K bit/S:6N138、6N139、PS87031M bit/S:6N135、6N136、CNW135、CNW136、PS8601、PS8602、PS8701、PS9613、PS9713、CNW4502、HCPL-2503、HCPL-4502、HCPL-2530(双路)、HCPL-2531(双路)10M bit/S:6N137、PS9614、PS9714、PS9611、PS9715、HCPL-2601、HCPL-2611、HCPL-2630(双路)、HCPL-2631(双路)光耦合器的增益被称为晶体管输出器件的电流传输比 (CTR),其定义是光电晶体管集电极电流与LED正向电流的比率(ICE/IF)。
光电晶体管集电极电流与VCE有关,即集电极和发射极之间的电压。
常用光耦简介及常见型号
常用光耦简介及常见型号普通的线性光耦有PC111 、TLP521、PC817、TLP632 、TLP532 、PC614 、PC714 、2031等,但要看用在哪里,因为其线性并不能满足各类要求,其优点是价格便宜,货源好.更好的属精密线性光耦如LOC211、HCNR200、HCNR201。
2011-03-24 23:25光电耦合器(简称光耦)是开关电源电路中常用的器件。
光电耦合器分为两种:一种为非线性光耦,另一种为线性光耦。
常用的4N系列光耦属于非线性光耦常用的线性光耦是PC817A—C系列。
非线性光耦的电流传输特性曲线是非线性的,这类光耦适合于弄开关信号的传输,不适合于传输模拟量。
线性光耦的电流传输手特性曲线接进直线,并且小信号时性能较好,能以线性特性进行隔离控制。
开关电源中常用的光耦是线性光耦。
如果使用非线性光耦,有可能使振荡波形变坏,严重时出现寄生振荡,使数千赫的振荡频率被数十到数百赫的低频振荡依次为号调制。
由此产生的后果是对彩电,彩显,VCD,DCD等等,将在图像画面上产生干扰。
同时电源带负载能力下降。
在彩电,显示器等开关电源维修中如果光耦损坏,一定要用线性光耦代换。
常用的4脚线性光耦有PC817A----C。
PC111 TLP521等常用的六脚线性光耦有:TLP632 TLP532 PC614 PC714 PS2031等。
常用的4N25 4N26 4N35 4N36是不适合用于开关电源中的,因为这4种光耦均属于非线性光耦。
经查大量资料后,以下是目前市场上常见的高速光藕型号:100K bit/S:6N138、6N139、PS87031M bit/S:6N135、6N136、CNW135、CNW136、PS8601、PS8602、PS8701、PS9613、PS9713、CNW4502、HCPL-2503、HCPL-4502、HCPL-2530(双路)、HCPL-2531(双路)10M bit/S:6N137、PS9614、PS9714、PS9611、PS9715、HCPL-2601、HCPL-2611、HCPL-2630(双路)、HCPL-2631(双路)光耦合器的增益被称为晶体管输出器件的电流传输比(CTR),其定义是光电晶体管集电极电流与LED正向电流的比率(ICE/IF)。
常用的线性光耦与非线性光耦型号及替代线性光耦问题
常用的线性光耦与非线性光耦型号及替代线性光耦问
题
常用的线性光耦的型号
线性光耦的电流传输特性曲线接近直线,并且小信号时性能较好,能以线性特性进行隔离控制。
开关电源中常用线性光耦,如果使用非线性光耦,有可能使振荡波形变坏,严重时出现寄生振荡,使数千赫的振荡频率被数十到数百赫的低频振荡依次为号调制。
由此产生的后果是对彩电,彩显,VCD,DCD等等,将在图像画面上产生干扰。
同时电源带负载能力下降。
在彩电,显示器等开关电源维修中如果光耦损坏,一定要用线性光耦代换。
常用的4脚线性光耦(无反馈型线性光耦)有PC817A-C、PC111、
TLP521等。
常用的6脚线性光耦有LP632、TLP532、PC614、PC714、PS2031等。
常用的非线性光耦的型号
4N25 晶体管输出
4N25MC 晶体管输出
4N26 晶体管输出
常见光耦型号
4N27 晶体管输出
4N28 晶体管输出
4N29 达林顿输出
4N30 达林顿输出
4N31 达林顿输出。
(完整word版)常用光耦总结
光电耦合器(简称光耦)是开关电源电路中常用的器件。
光电耦合器分为两种:一种为非线性光耦,另一种为线性光耦。
常用的4N系列光耦属于非线性光耦常用的线性光耦是PC817A—C系列。
非线性光耦的电流传输特性曲线是非线性的,这类光耦适合于弄开关信号的传输,不适合于传输模拟量。
线性光耦的电流传输手特性曲线接进直线,并且小信号时性能较好,能以线性特性进行隔离控制。
开关电源中常用的光耦是线性光耦。
如果使用非线性光耦,有可能使振荡波形变坏,严重时出现寄生振荡,使数千赫的振荡频率被数十到数百赫的低频振荡依次为号调制。
由此产生的后果是对彩电,彩显,VCD,DCD等等,将在图像画面上产生干扰。
同时电源带负载能力下降。
在彩电,显示器等开关电源维修中如果光耦损坏,一定要用线性光耦代换。
常用的4脚线性光耦有PC817A----C。
PC111 TLP521等常用的六脚线性光耦有:TLP632 TLP532 PC614 PC714 PS2031等。
常用的4N25 4N26 4N35 4N36是不适合用于开关电源中的,因为这4种光耦均属于非线性光耦。
以下是目前市场上常见的高速光藕型号:100K bit/S:6N138、6N139、PS87031M bit/S:6N135、6N136、CNW135、CNW136、PS8601、PS8602、PS8701、PS9613、PS9713、CNW4502、HCPL-2503、HCPL-4502、HCPL-2530(双路)、HCPL-2531(双路)10M bit/S:6N137、PS9614、PS9714、PS9611、PS9715、HCPL-2601、HCPL-2611、HCPL-2630(双路)、HCPL-2631(双路)光耦合器的增益被称为晶体管输出器件的电流传输比(CTR),其定义是光电晶体管集电极电流与LED正向电流的比率(ICE/IF)。
光电晶体管集电极电流与VCE有关,即集电极和发射极之间的电压。
常用光耦简介及常见型号
常用光耦简介及常见型号常用光耦简介及常见型号光电耦合器(简称光耦)是开关电源电路中常用的器件。
光电耦合器分为两种:一种为非线性光耦,另一种为线性光耦。
常用的4N系列光耦属于非线性光耦常用的线性光耦是PC817A—C系列。
非线性光耦的电流传输特性曲线是非线性的,这类光耦适合于弄开关信号的传输,不适合于传输模拟量。
线性光耦的电流传输手特性曲线接进直线,并且小信号时性能较好,能以线性特性进行隔离控制。
开关电源中常用的光耦是线性光耦。
如果使用非线性光耦,有可能使振荡波形变坏,严重时出现寄生振荡,使数千赫的振荡频率被数十到数百赫的低频振荡依次为号调制。
由此产生的后果是对彩电,彩显,VCD,DCD等等,将在图像画面上产生干扰。
同时电源带负载能力下降。
在彩电,显示器等开关电源维修中如果光耦损坏,一定要用线性光耦代换。
常用的4脚线性光耦有PC817A----C。
PC111 TLP521等常用的六脚线性光耦有:TLP632 TLP532 PC614 PC714 PS2031等。
常用的4N25 4N26 4N35 4N36是不适合用于开关电源中的,因为这4种光耦均属于非线性光耦。
经查大量资料后,以下是目前市场上常见的高速光藕型号:100K bit/S:6N138、6N139、PS87031M bit/S:6N135、6N136、CNW135、CNW136、PS8601、PS8602、PS8701、PS9613、PS9713、CNW4502、HCPL-2503、HCPL-4502、HCPL-2530(双路)、HCPL-2531(双路)10M bit/S:6N137、PS9614、PS9714、PS9611、PS9715、HCPL-2601、HCPL-2611、HCPL-2630(双路)、HCPL-2631(双路)光耦合器的增益被称为晶体管输出器件的电流传输比 (CTR),其定义是光电晶体管集电极电流与LED正向电流的比率(ICE/IF)。
光耦参数及资料
市场常见光耦内部图:光电耦合器(简称光耦)是开关电源电路中常用的器件。
光电耦合器分为两种:一种为非线性光耦,另一种为线性光耦。
常用的4N系列光耦属于非线性光耦常用的线性光耦是PC817/—C系列。
非线性光耦的电流传输特性曲线是非线性的,这类光耦适合于弄开关信号的传输,不适合于传输模拟量。
线性光耦的电流传输手特性曲线接进直线,并且小信号时性能较好,能以线性特性进行隔离控制。
开关电源中常用的光耦是线性光耦。
如果使用非线性光耦,有可能使振荡波形变坏,严重时出现寄生振荡,使数千赫的振荡频率被数十到数百赫的低频振荡依次为号调制。
由此产生的后果是对彩电,彩显,VCD DCD等等,将在图像画面上产生干扰。
同时电源带负载能力下降。
在彩电,显示器等开关电源维修中如果光耦损坏,一定要用线性光耦代换。
常用的4脚线性光耦有PC817A----C °PC111TLP521等常用的六脚线性光耦有:TLP632 TLP532PC614 PC714 PS2031 等。
常用的4N25 4N26 4N35 4N36是不适合用于开关电源中的,因为这4种光耦均属于非线性光耦。
以下是目前市场上常见的高速光藕型号:100K bit/S:6N138、6N139、PS87031M bit/S:6N135、6N136、CNW13、5 CNW13、6 PS8601、PS8602、PS8701、PS9613、PS9713、CNW450、2 HCPL-2503 HCPL-4502、HCPL-2530 (双路)、HCPL-2531 (双路)10M bit/S:6N137、PS9614 PS9714 PS9611、PS9715 HCPL-2601、HCPL-2611、HCPL-2630 (双路)、HCPL- 2631 (双路)光耦合器的增益被称为晶体管输出器件的电流传输比(CTR),其定义是光电晶体管集电极电流与LED正向电流的比率(ICE/IF)。
光耦介绍
光耦2简介:大部分的光耦都是低速光耦最著名的当然是TLP521-1;PC817、814等也是经常使用的光耦;高速光耦最著名也最便宜的是6N137在通讯电路设计中,光耦是经常见到的;TLP521-1可以用到9600~19200;限流电阻是1K; ... 大部分的光耦都是低速光耦最著名的当然是TLP521-1;PC817、814等也是经常使用的光耦;高速光耦最著名也最便宜的是6N137在通讯电路设计中,光耦是经常见到的;TLP521-1可以用到9600~19200;限流电阻是1K;上拉电阻是1K;6N137可以到10M;但是6N137需要按照datasheet来接它的外部电路才能达到10M的速度;6N137的内部和典型电路6N137的内部结构665){this.resized=true;this.style.width=665;}">6N137的测试电路6N137的使用注意点:1、高速光耦的驱动LED的电流要求比较大,LED的压降也比较大,在5V情况下,限流电阻我选择的是680欧姆;2、上拉电阻需要调整到1K或者更小才能达到10M的速度;(印象记忆中)还有一种特殊的光耦,内部有2个发光管665){this.resized=true;this.style.width=665;}">常见之高速光藕型号常见之高速光藕型号[zt]经查大量资料后,总结出目前市场上常见之高速光藕型号供大家选择:100K bit/S:6N138、6N139、PS87031M bit/S:6N135、6N136、CNW135、CNW136、PS8601、PS8602、PS8701、PS9613、PS9713、CNW4502、HCPL-2503、HCPL-4502、HCPL-2530(双路)、HCPL-2531(双路)10M bit/S:6N137、PS9614、PS9714、PS9611、PS9715、HCPL-2601、HCPL-2611、HCPL-2630(双路)、HCPL-2631(双路)另外,台湾COSMO公司的KP7010在RL选值为300欧左右时,我根据其数据手册所载数值计算,速率可达100Kbit/S,且为6脚封装,比同级的6N138、6N139小巧,价格也较低。
常用光耦简介及常见型号及参数
常用光耦简介及常见型号及参数Document number:PBGCG-0857-BTDO-0089-PTT1998【转】常用光耦简介及常见型号及参数2010-10-15 21:52转载自最终编辑常用光耦简介及常见型号???? 光电耦合器(简称光耦)是开关电源电路中常用的器件。
光电耦合器分为两种:一种为非线性光耦,另一种为线性光耦。
常用的4N系列光耦属于非线性光耦,常用的线性光耦是PC817A—C系列。
????? 非线性光耦的电流传输特性曲线是非线性的,这类光耦适合于弄开关信号的传输,不适合于传输模拟量。
????? 线性光耦的电流传输手特性曲线接进直线,并且小信号时性能较好,能以线性特性进行隔离控制。
开关电源中常用的光耦是线性光耦。
如果使用非线性光耦,有可能使振荡波形变坏,严重时出现寄生振荡,使数千赫的振荡频率被数十到数百赫的低频振荡依次为号调制。
由此产生的后果是对彩电,彩显,VCD,DCD等等,将在图像画面上产生干扰。
同时电源带负载能力下降。
在彩电,显示器等开关电源维修中如果光耦损坏,一定要用线性光耦代换。
常用的4脚线性光耦有PC817A----C。
PC111 TLP521等常用的六脚线性光耦有:TLP632 TLP532 PC614 PC714 PS2031等。
常用的4N25 4N26 4N35 4N36是不适合用于开关电源中的,因为这4种光耦均属于非线性光耦。
经查大量资料后,以下是目前市场上常见的高速光藕型号:100K bit/S:6N138、6N139、PS87031M bit/S:6N135、6N136、CNW135、CNW136、PS8601、PS8602、PS8701、PS9613、PS9713、CNW4502、HCPL-2503、HCPL-4502、HCPL-2530(双路)、HCPL-2531(双路)10M bit/S:6N137、PS9614、PS9714、PS9611、PS9715、HCPL-2601、HCPL-2611、HCPL-2630(双路)、HCPL-2631(双路)光耦合器的增益被称为晶体管输出器件的电流传输比 (CTR),其定义是光电晶体管集电极电流与LED正向电流的比率(ICE/IF)。
光耦参数及资料
光电耦合器 ( 光耦 ) 参数及资料市场常见光耦内部图:4-Pin Phototransistor Output; GaAs InputCTR @BV BV V t / tOFF型号CEO CBO CE (sat)ON V 厂牌10 mA I F (%)(V)(V)(V)(uS)ISO (规格 )AC[RMS]min max min max max maxTLP521-1TOSHIBA506005570.42/3 2.5kV TLP521-2TOSHIBA506005570.42/3 2.5kV TLP521-4TOSHIBA1006005570.42/3 2.5kV TLP621-1TOSHIBA506005570.42/310kV TLP721TOSHIBA506005570.43/3 4.0kV PS2501NEC806008070.33/5 5.0kV PS2561NEC804008070.33/5 5.0kV 817(KP1010)COSMO506003560.218/18 5.0kV PC817SHARP506003560.218/18 5.0kVPC817A SHARP801603560.218/18 5.0kV PC817B SHARP1302603560.218/18 5.0kV PC817C SHARP2004003560.218/18 5.0kV PC817D SHARP3006003560.218/18 5.0kV H11A817FSC506003560.218/18 5.3 kV H11A817A FSC801603560.218/18 5.3 kV H11A817B FSC1302603560.218/18 5.3 kV H11A817C FSC2004003560.218/18 5.3 kV H11A817D FSC3006003560.218/18 5.3 kV 4-Pin Phototransistor Output; GaAs AC InputCTR @BV BV V t / tOFFPart CEO CBO CE (sat)ON V ISO厂牌10 mA I(%)(V)(V)(V)(uS)Number F AC[RMS]min max min min max maxTLP320TOSHIBA20805570.43/3 5.0KVTLP620TOSHIBA506005570.43/3 5.0kVPC814SHARP203003560.24/18 5.0kVPC814A SHARP501503560.24/18 5.0kVH11AA814QT203003560.2-- 5.3 kVH11AA814A QT501503560.2-- 5.3 kV光电耦合器(简称光耦)是开关电源电路中常用的器件。
常见之高速光藕型号
MOC3041 过零触发可控硅输出
MOC3061 过零触发可控硅输出
MOC3081 过零触发可控硅输出
TLP521-1 单光耦
TLP521-2 双光耦
TLP521-4 四光耦
TLP621 四光耦
TIL113 达林顿输出
TIL117 TTL逻辑输出
标签: 无标签
常见之高速光藕型号
经查大量资料后,总结出目前市场上常见之高速光藕型号供大家选择:
100K bit/S:
6N138、6N139、PS8703
1M bit/S:
6N135、6N136、CNW135、CNW136、PS8601、PS8602、PS8701、PS9613、PS9713、CNW4502、HCPL-2503、HCPL-4502、HCPL-2530(双路)、HCPL-2531(双路)
4N26 晶体管输出
4N27 晶体管输出
4N28 晶体管输出
4N29 达林顿输出
4N30 达林顿输出
4N31 达林顿输出
4N32 达林顿输出
4N33 达林顿输出
4N33MC 达林顿输出
4N35 达林顿输出
4N36 晶体管输出
例如:moc3063的负载能力是100mA;IL420是300mA;
光耦的部分型号
产品名称 型号规格 性能说明
光电耦合
4N25 晶体管输出
4N25MC 晶体管输出
4N26 晶体管输出
4N27 晶体管输出
4N28 晶体管输出
4N29 达林顿输出
CTR的定义
光耦合器的增益被称为晶体管输出器件的电流传输比 (CTR),其定义是光电晶体管集电极电流与LED正向电流的比率(ICE/IF)。光电晶体管集电极电流与VCE有关,即集电极和发射极之间的电压。
MOC3061 过零触发可控硅输出
MOC3081 过零触发可控硅输出
TLP521-1 单光耦
TLP521-2 双光耦
TLP521-4 四光耦
TLP621 四光耦
TIL113 达林顿输出
TIL117 TTL逻辑输出
标签: 无标签
常见之高速光藕型号
经查大量资料后,总结出目前市场上常见之高速光藕型号供大家选择:
100K bit/S:
6N138、6N139、PS8703
1M bit/S:
6N135、6N136、CNW135、CNW136、PS8601、PS8602、PS8701、PS9613、PS9713、CNW4502、HCPL-2503、HCPL-4502、HCPL-2530(双路)、HCPL-2531(双路)
4N26 晶体管输出
4N27 晶体管输出
4N28 晶体管输出
4N29 达林顿输出
4N30 达林顿输出
4N31 达林顿输出
4N32 达林顿输出
4N33 达林顿输出
4N33MC 达林顿输出
4N35 达林顿输出
4N36 晶体管输出
例如:moc3063的负载能力是100mA;IL420是300mA;
光耦的部分型号
产品名称 型号规格 性能说明
光电耦合
4N25 晶体管输出
4N25MC 晶体管输出
4N26 晶体管输出
4N27 晶体管输出
4N28 晶体管输出
4N29 达林顿输出
CTR的定义
光耦合器的增益被称为晶体管输出器件的电流传输比 (CTR),其定义是光电晶体管集电极电流与LED正向电流的比率(ICE/IF)。光电晶体管集电极电流与VCE有关,即集电极和发射极之间的电压。
TPCP8602资料
TOSHIBA Transistor Silicon PNP Epitaxial TypeTPCP8602High-Speed Switching Applications DC-DC Converter Applications Strobe Flash Applications• High DC current gain: h FE = 200 to 500 (I C = −0.3 A) • Low collector-emitter saturation: V CE (sat) = −0.2 V (max) • High-speed switching: t f = 90 ns (typ.)Absolute Maximum Ratings (Ta = 25°C)Characteristic Symbol Rating UnitCollector-base voltage V CBO −50 V Collector-emitter voltage V CEO −50 V Emitter-base voltage V EBO −7 V DC (Note 1) I C −2.5 Collector current Pulse (Note 1 )I CP −4.0ABase current I B −0.25 A t = 10s 3.0 Collector powerdissipation (t = 10s) DC P C (Note 2)1.25WJunction temperature T j 150 °C Storage temperature rangeT stg−55 to 150°CNote 1: Ensure that the junction temperature does not exceed 150°C during use of this device. Note 2: Mounted on an FR4 board (glass epoxy, 1.6 mm thick, Cu area: 645 mm 2)Note 3: Using continuously under heavy loads (e.g. the application of high temperature/current/voltage and thesignificant change in temperature, etc.) may cause this product to decrease in the reliability significantly even if the operating conditions (i.e. operating temperature/current/voltage, etc.) are within the absolute maximum ratings.Please design the appropriate reliability upon reviewing the Toshiba Semiconductor Reliability Handbook (“Handling Precautions”/Derating Concept and Methods) and individual reliability data (i.e. reliability test report and estimated failure rate, etc).Unit: mmWeight: 0.017 g (typ.)Figure 1. Circuit Configuration (top view)Figure 2. Marking (Note 4)Note 4: ● on the lower left of the marking indicates Pin 1* Weekly code (three digits):Electrical Characteristics (Ta = 25°C)Characteristic Symbol Test ConditionMin Typ. Max Unit Collector cut-off current I CBO V CB = −50 V, I E = 0 ⎯ ⎯ −100nA Emitter cut-off currentI EBO V EB = −7 V, I C = 0 ⎯ ⎯ −100nACollector-emitter breakdown voltage V (BR) CEO I C = −10 mA, I B = 0 −50 ⎯⎯Vh FE (1) V CE= −2 V, I C = −0.3 A 200 ⎯500DC current gainh FE (2) V CE = −2 V, I C = −1.0 A 100 ⎯ ⎯ Collector-emitter saturation voltage V CE (sat) I C = −1 A, I B = −33 mA ⎯ ⎯ −0.2V Base-emitter saturation voltage V BE (sat) I C = −1 A, I B = −33 mA ⎯ ⎯ −1.1V Collector output capacitanceC ob V CB = 10 V, I E = 0, f = 1MHz ⎯20⎯pFRise timet r ⎯ 60 ⎯ Storage time t stg ⎯ 250 ⎯ Switching timeFall timet fSee Figure 3 circuit diagramV CC ∼ − 30 V, R L = 30 Ω I B1 = −I B2 = −33 mA⎯ 90 ⎯nsFigure 3. Switching Time Test Circuit & Timing ChartDuty cycle <1%I B120μsI B21 2 3 48 7 6 5(weekly code)87 6 5Week of manufacture(01 for the first week of the year, continuing up to 52 or 53) Year of manufacture(lowest-order digit of the calendar year)0.001 110000.010.10.00110100.010.10.001 110.01 0.10 −0.4 −1.2 −1.6−−2.5CollectorcurrentIC(A)Base−emittersaturationvoltage−VBE(sat)(V)Collector−emitter voltage V CE (V)I C – V CECollectorcurrentIC(A)Collector current −I C (A)h FE – I CDCcurrentgainhFECollector current −I C (A)V CE (sat) – I CCollector−emittersaturationvoltage−VCE(sat)(V)Collector current −I C (A)V BE (sat) – I CBase−emitter voltage V BE (V)I C – V BE−−−1.2−0.4−−0.8Common emitter1010 1−−T r a n s i e n t t h e r m a l i m p ed a n ce rt h (j -a) (°C /W )r th – t wPulse width t w (s)Collector −emitter voltage −V CE (V)Safe operating areaC o l l e c t o r c u r r e n t −I C (A )RESTRICTIONS ON PRODUCT USE20070701-EN •The information contained herein is subject to change without notice.•TOSHIBA is continually working to improve the quality and reliability of its products. Nevertheless, semiconductor devices in general can malfunction or fail due to their inherent electrical sensitivity and vulnerability to physical stress. It is the responsibility of the buyer, when utilizing TOSHIBA products, to comply with the standards of safety in making a safe design for the entire system, and to avoid situations in which a malfunction or failure of such TOSHIBA products could cause loss of human life, bodily injury or damage to property.In developing your designs, please ensure that TOSHIBA products are used within specified operating ranges as set forth in the most recent TOSHIBA products specifications. Also, please keep in mind the precautions and conditions set forth in the “Handling Guide for Semiconductor Devices,” or “TOSHIBA Semiconductor Reliability Handbook” etc.• The TOSHIBA products listed in this document are intended for usage in general electronics applications (computer, personal equipment, office equipment, measuring equipment, industrial robotics, domestic appliances, etc.).These TOSHIBA products are neither intended nor warranted for usage in equipment that requires extraordinarily high quality and/or reliability or a malfunction or failure of which may cause loss of human life or bodily injury (“Unintended Usage”). Unintended Usage include atomic energy control instruments, airplane or spaceship instruments, transportation instruments, traffic signal instruments, combustion control instruments, medical instruments, all types of safety devices, etc.. Unintended Usage of TOSHIBA products listed in his document shall be made at the customer’s own risk.•The products described in this document shall not be used or embedded to any downstream products of which manufacture, use and/or sale are prohibited under any applicable laws and regulations.• The information contained herein is presented only as a guide for the applications of our products. No responsibility is assumed by TOSHIBA for any infringements of patents or other rights of the third parties which may result from its use. No license is granted by implication or otherwise under any patents or other rights of TOSHIBA or the third parties.• Please contact your sales representative for product-by-product details in this document regarding RoHS compatibility. Please use these products in this document in compliance with all applicable laws and regulations that regulate the inclusion or use of controlled substances. Toshiba assumes no liability for damage or losses occurring as a result of noncompliance with applicable laws and regulations.。
常用光耦总结
光电耦合器(简称光耦)是开关电源电路中常用的器件。
光电耦合器分为两种:一种为非线性光耦,另一种为线性光耦。
常用的4N系列光耦属于非线性光耦常用的线性光耦是PC817A—C系列。
非线性光耦的电流传输特性曲线是非线性的,这类光耦适合于弄开关信号的传输,不适合于传输模拟量。
线性光耦的电流传输手特性曲线接进直线,并且小信号时性能较好,能以线性特性进行隔离控制。
开关电源中常用的光耦是线性光耦。
如果使用非线性光耦,有可能使振荡波形变坏,严重时出现寄生振荡,使数千赫的振荡频率被数十到数百赫的低频振荡依次为号调制。
由此产生的后果是对彩电,彩显,VCD,DCD等等,将在图像画面上产生干扰。
同时电源带负载能力下降。
在彩电,显示器等开关电源维修中如果光耦损坏,一定要用线性光耦代换。
常用的4脚线性光耦有PC817A----C。
PC111 TLP521等常用的六脚线性光耦有:TLP632 TLP532 PC614 PC714 PS2031等。
常用的4N25 4N26 4N35 4N36是不适合用于开关电源中的,因为这4种光耦均属于非线性光耦。
以下是目前市场上常见的高速光藕型号:100K bit/S:6N138、6N139、PS87031M bit/S:6N135、6N136、CNW135、CNW136、PS8601、PS8602、PS8701、PS9613、PS9713、CNW4502、HCPL-2503、HCPL-4502、HCPL-2530(双路)、HCPL-2531(双路)10M bit/S:6N137、PS9614、PS9714、PS9611、PS9715、HCPL-2601、HCPL-2611、HCPL-2630(双路)、HCPL-2631(双路)光耦合器的增益被称为晶体管输出器件的电流传输比(CTR),其定义是光电晶体管集电极电流与LED正向电流的比率(ICE/IF)。
光电晶体管集电极电流与VCE有关,即集电极和发射极之间的电压。
光耦参数及资料电子教案
光耦参数及资料光电耦合器(光耦)参数及资料市场常见光耦内部图:4-Pin Phototransistor Output; GaAs Input型号(规格) 厂牌CTR @10 mA IF(%)BVCEO(V)minBVCBO(V)maxVCE (sat)(V)maxtON/ tOFF(uS)maxVISOAC[RMS] min maxTLP521-1 TOSHIBA 50 600 55 7 0.4 2/3 2.5kV TLP521-2 TOSHIBA 50 600 55 7 0.4 2/3 2.5kV TLP521-4 TOSHIBA 100 600 55 7 0.4 2/3 2.5kV TLP621-1 TOSHIBA 50 600 55 7 0.4 2/3 10kV TLP721 TOSHIBA 50 600 55 7 0.4 3/3 4.0kV PS2501 NEC 80 600 80 7 0.3 3/5 5.0kV PS2561 NEC 80 400 80 7 0.3 3/5 5.0kV光电耦合器(简称光耦)是开关电源电路中常用的器件。
光电耦合器分为两种:一种为非线性光耦,另一种为线性光耦。
常用的4N系列光耦属于非线性光耦常用的线性光耦是PC817A—C系列。
非线性光耦的电流传输特性曲线是非线性的,这类光耦适合于弄开关信号的传输,不适合于传输模拟量。
线性光耦的电流传输手特性曲线接进直线,并且小信号时性能较好,能以线性特性进行隔离控制。
开关电源中常用的光耦是线性光耦。
如果使用非线性光耦,有可能使振荡波形变坏,严重时出现寄生振荡,使数千赫的振荡频率被数十到数百赫的低频振荡依次为号调制。
由此产生的后果是对彩电,彩显,VCD,DCD等等,将在图像画面上产生干扰。
同时电源带负载能力下降。
在彩电,显示器等开关电源维修中如果光耦损坏,一定要用线性光耦代换。
常用的4脚线性光耦有PC817A----C。
PC111 TLP521等常用的六脚线性光耦有:TLP632 TLP532 PC614 PC714 PS2031等。
光耦简介及常见型号
光耦简介及常见型号常⽤光耦简介及常见型号光电耦合器(简称光耦)是开关电源电路中常⽤的器件。
光电耦合器分为两种:⼀种为⾮线性光耦,另⼀种为线性光耦。
常⽤的4N系列光耦属于⾮线性光耦常⽤的线性光耦是PC817A—C系列。
⾮线性光耦的电流传输特性曲线是⾮线性的,这类光耦适合于弄开关信号的传输,不适合于传输模拟量。
线性光耦的电流传输⼿特性曲线接进直线,并且⼩信号时性能较好,能以线性特性进⾏隔离控制。
开关电源中常⽤的光耦是线性光耦。
如果使⽤⾮线性光耦,有可能使振荡波形变坏,严重时出现寄⽣振荡,使数千赫的振荡频率被数⼗到数百赫的低频振荡依次为号调制。
由此产⽣的后果是对彩电,彩显,VCD,DCD等等,将在图像画⾯上产⽣⼲扰。
同时电源带负载能⼒下降。
在彩电,显⽰器等开关电源维修中如果光耦损坏,⼀定要⽤线性光耦代换。
常⽤的4脚线性光耦有PC817A----C。
PC111 TLP521等常⽤的六脚线性光耦有:TLP632 TLP532 PC614 PC714 PS2031等。
常⽤的4N25 4N26 4N35 4N36是不适合⽤于开关电源中的,因为这4种光耦均属于⾮线性光耦。
经查⼤量资料后,以下是⽬前市场上常见的⾼速光藕型号:100K bit/S:6N138、6N139、PS87031M bit/S:6N135、6N136、CNW135、CNW136、PS8601、PS8602、PS8701、PS9613、PS9713、CNW4502、HCPL-2503、HCPL-4502、HCPL-2530(双路)、HCPL-2531(双路)10M bit/S:6N137、PS9614、PS9714、PS9611、PS9715、HCPL-2601、HCPL-2611、HCPL-2630(双路)、HCPL-2631(双路)光耦合器的增益被称为晶体管输出器件的电流传输⽐(CTR),其定义是光电晶体管集电极电流与LED正向电流的⽐率(ICE/IF)。
常用光耦简介及常见型号及参数修订版
常用光耦简介及常见型号及参数Document number:PBGCG-0857-BTDO-0089-PTT1998【转】常用光耦简介及常见型号及参数2010-10-15 21:52转载自最终编辑常用光耦简介及常见型号光电耦合器(简称光耦)是开关电源电路中常用的器件。
光电耦合器分为两种:一种为非线性光耦,另一种为线性光耦。
常用的4N系列光耦属于非线性光耦,常用的线性光耦是PC817A—C系列。
非线性光耦的电流传输特性曲线是非线性的,这类光耦适合于弄开关信号的传输,不适合于传输模拟量。
线性光耦的电流传输手特性曲线接进直线,并且小信号时性能较好,能以线性特性进行隔离控制。
开关电源中常用的光耦是线性光耦。
如果使用非线性光耦,有可能使振荡波形变坏,严重时出现寄生振荡,使数千赫的振荡频率被数十到数百赫的低频振荡依次为号调制。
由此产生的后果是对彩电,彩显,VCD,DCD等等,将在图像画面上产生干扰。
同时电源带负载能力下降。
在彩电,显示器等开关电源维修中如果光耦损坏,一定要用线性光耦代换。
常用的4脚线性光耦有PC817A----C。
PC111 TLP521等常用的六脚线性光耦有:TLP632 TLP532 PC614 PC714 PS2031等。
常用的4N25 4N26 4N35 4N36是不适合用于开关电源中的,因为这4种光耦均属于非线性光耦。
经查大量资料后,以下是目前市场上常见的高速光藕型号:100K bit/S:6N138、6N139、PS87031M bit/S:6N135、6N136、CNW135、CNW136、PS8601、PS8602、PS8701、PS9613、PS9713、CNW4502、HCPL-2503、HCPL-4502、HCPL-2530(双路)、HCPL-2531(双路)10M bit/S:6N137、PS9614、PS9714、PS9611、PS9715、HCPL-2601、HCPL-2611、HCPL-2630(双路)、HCPL-2631(双路)光耦合器的增益被称为晶体管输出器件的电流传输比 (CTR),其定义是光电晶体管集电极电流与LED正向电流的比率(ICE/IF)。
高速光耦芯片选型大全
通讯用高速光藕型号大全
100K bit/S:
6N138、6N139、PS8703
1M bit/S:
6N135、6N136、CNW135、CNW136、PS8601、PS8602、PS8701、PS9613、PS9713、CNW4502、HCPL-2503、HCPL-4502、HCPL-2530(双路)、HCPL-2531(双路)
10M bit/S:
6N137、PS9614、PS9714、PS9611、PS9715、HCPL-2601、HCPL-2611、HCPL-2630(双路)、HCPL-2631(双路)
另外,台湾COSMO公司的KP7010在RL选值为300欧左右时,我根据其数据手册所载数值计算,速率可达100Kbit/S,且为6脚封装,比同级的6N138、6N139小巧,价格也较低。
速度要求不高的情况下,可以用廉价的低速光耦搭配2只廉价的三级管来提高速度。
上次我做一个SPI通信的系统,并且要求不能共地,SPI总线的频率100K左右,我就用一个廉价的TLP521加了一只C1815,一只A1015实现了。
作技术总结时,为了验证通信的可靠性,我将该电路单独搭出来测试,轻松过300K,做了100只光耦,全部通过300K测试。
要看做什么样的通信,如果对边沿要求高的话,可以涮掉好大一部分.。
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The mark <R> shows major revised points.The revised points can be easily searched by copying an "<R>" in the PDF file and specifying it in the "Find what:" field.DATA SHEETThe information in this document is subject to change without notice. Before using this document, pleaseconfirm that this is the latest version.Not all products and/or types are available in every country. Please check with an NEC Electronics sales representative for availability and additional information.Document No. PN10263EJ02V0DS (2nd edition)Date Published May 2006 NS CP(K) Printed in Japan1995, 2006DESCRIPTIONThe PS8602 and PS8602L are 8-pin high speed photocouplers containing a GaAIAs LED on input side and a P-N photodiode and a high speed amplifier transistor on output side on one chip. The PS8602 is in a plastic DIP (Dual In-line Package). The PS8602L is lead bending type (Gull wing) for surface mount. The PS8602L1 is lead bending type for long creepage distance.The PS8602L2 is lead bending type for long creepage distance (Gull-wing) for surface mount.FEATURES• High common mode transient immunity (CM H , CM L = ±2 000 kV/µs MIN.) • High supply voltage (V CC = 35 V MAX.) • High speed response (t PHL , t PLH = 0.8 µs MAX.) • High isolation voltage (BV = 5 000 V r.m.s.) • TTL, CMOS compatible with a resistor • For Infrared reflow soldering• Ordering number of tape product : PS8602L-E3, E4: 1 000 pcs/reel: PS8602L2-E3, E4: 1 000 pcs/reel• Safety standards • UL approved: File No. E72422 • BSI approved: No. 8004, 8854• DIN EN60747-5-2 (VDE0884 Part2) approved (Option)APPLICATIONS• Interface for measurement or control equipment • Substitutions for relays and pulse transformers<R><R><R>PACKAGE DIMENSIONS (UNIT: mm)DIP TypeLead Bending Type2Data Sheet PN10263EJ02V0DSLead Bending Type For Long Creepage DistanceData Sheet PN10263EJ02V0DS 3MARKING EXAMPLE4Data Sheet PN10263EJ02V0DSData Sheet PN10263EJ02V0DS 5ORDERING INFORMATIONPart NumberOrder NumberSolder Plating SpecificationPacking StyleSafety StandardApproval ApplicationPart Number *1PS8602 PS8602-A Pb-F ree Magazine case 50 pcs Standard productsPS8602PS8602L PS8602L-A (UL, BSI approved) PS8602L1 PS8602L1-A PS8602L2 PS8602L2-APS8602L-E3 PS8602L-E3-A Embossed Tape 1 000 pcs/reel PS8602L-E4 PS8602L-E4-A PS8602L2-E3 PS8602L2-E3-A PS8602L2-E4 PS8602L2-E4-APS8602-V PS8602-V-A Magazine case 50 pcsDIN EN60747-5-2PS8602L-V PS8602L-V-A (VDE0884 Part2)PS8602L1-V PS8602L1-V-A Approved (Option) PS8602L2-V PS8602L2-V-APS8602L-V-E3 PS8602L-V-E3-A Embossed Tape 1 000 pcs/reel PS8602L-V-E4 PS8602L-V-E4-A PS8602L2-V-E3 PS8602L2-V-E3-A PS8602L2-V-E4 PS8602L2-V-E4-A*1 For the application of the Safety Standard, following part number should be used.ABSOLUTE MAXIMUM RATINGS (TA = 25°C, unless otherwise specified)Parameter Symbol Ratings UnitDiode F orward Current *1I F 25 mA Reverse Voltage V R 5 V Power Dissipation P D 45 mW Detector Supply VoltageV CC 35 V Output Voltage V O 35 V Output CurrentI O 8 mA Power Dissipation *2P C 100 mWIsolation Voltage *3BV 5 000 Vr.m.s. Operating Ambient Temperature T A −55 to +100 °C Storage TemperatureT stg−55 to +150°C*1 Reduced to 0.25 mA/°C at T A = 25°C or more.*2 Applies to output pin V O (collector pin). Reduced to 1.0 mW/°C at T A = 25°C or more. *3 AC voltage for 1 minute at T A = 25°C, RH = 60% between input and output.Pins 1-4 shorted together, 5-8 shorted together.<R><R>ELECTRICAL CHARACTERISTICS (T A = 25 °C)Parameter Symbol Conditions MIN.TYP.*1 MAX. UnitDiodeF orwardVoltage V F I F = 16 mA 1.7 2.2 VReverseCurrent I R V R = 5 V 10 µAForwardVoltageTemperature Coefficent∆V F/∆T I F = 16 mA −1.6 mV/°CTerminalCapacitance C t V = 0 V, f = 1 MHz 30 pF Detector High Level Output Current I OH(1) I F = 0 mA, V CC = V O = 5.5 V 3 500 nA High Level Output Current I OH(2) I F = 0 mA, V CC = V O = 35 V 100 µA Low Level Output Voltage V OL I F = 16 mA, V CC = 4.5 V, I O = 1.2 mA 0.1 0.4 V Low Level Supply Current I CCL I F = 16 mA, V O = Open, V CC = 35 V 50 µA High Level Supply Current I CCH I F = 0 mA, V O = Open, V CC = 35 V 0.01 1 µA Coupled Current Transfer Ratio CTR I F = 16 mA, V CC = 4.5 V, V O = 0.4 V 15 % IsolationResistance R I-O V I-O = 1 kV DC 1011Ω IsolationCapacitance C I-O V = 0 V, f = 1 MHz 0.7 pF Propagation Delay Time t PHL I F = 16 mA, V CC = 5 V, R L = 1.9 kΩ0.50.8µs (H→ L)*2Propagation Delay Time t PLH I F = 16 mA, V CC = 5 V, R L = 1.9 kΩ0.30.8µs (L→ H)*2Common Mode Transient Immunity at High Level Output*3CM H I F = 0 mA, V CM = 400 VR L = 4.1 kΩ−2 000 V/µsCommon Mode Transient Immunity at Low Level Output*3CM L I F = 16 mA, V CM = 400 VR L = 4.1 kΩ2 000 V/µs<R>Data Sheet PN10263EJ02V0DS 6*1Typical values at T A = 25°C*2Test circuit for propagation delay time= 5 V(Monitor)V OPulse InputI F MonitorPW = 100 sµ(OL Remark C L includes probe and stray wiring capacitance.*3Test circuit for common mode transient immunityOLIRemark C L includes probe and stray wiring capacitance.USAGE CAUTIONS1. This product is weak for static electricity by designed with high-speed integrated circuit so protect against staticelectricity when handling.2. By-pass capacitor of more than 0.1 µF is used between V CC and GND near device. Also, ensure that thedistance between the leads of the photocoupler and capacitor is no more than 10 mm.3. Avoid storage at a high temperature and high humidity.Data Sheet PN10263EJ02V0DS7Data Sheet PN10263EJ02V0DS8TYPICAL CHARACTERISTICS (T A = 25°C, unless otherwise specified)Forward Voltage V F (V)F o r w a r d C u r r e n t I F (m A )FORWARD CURRENT vs. FORWARD VOLTAGEAmbient Temperature T A (˚C)M a x i m u m F o r w a r d C u r r e n t I F (m A )MAXIMUM FORWARD CURRENT vs. AMBIENT TEMPERATUREAmbient Temperature T A (˚C)D e t e c t o r P o w e r D i s s i p a t i o n P C (m W )DETECTOR POWER DISSIPATION vs. AMBIENT TEMPERATUREOutput Voltage V O (V)O u t p u t C u r r e n t I O (m A )OUTPUT CURRENT vs. OUTPUT VOLTAGEAmbient Temperature T A (˚C)N o r m a l i z e d C u r r e n t T r a n s f e r R a t i o C T RNORMALIZED CURRENT TRANSFER RATIO vs. AMBIENT TEMPERATUREFoward Current I F (mA)C u r r e n t T r a n s f e r R a t i o C T R (%)CURRENT TRANSFER RATIO vs. FOWARD CURRENT30201002550751001251208040025507510012510060200.010.11.010100V CC = 4.5 V,V O = 0.4 V,T A = 25 ˚C504030201000.10.5151050100Normalized to 1.0 at T A = 25 ˚C,I F = 16 mA, V CC = 4.5 V, V O = 0.4 V–75–50–252550751001252.01.81.61.41.21.00.80.60.40.20.0Remark The graphs indicate nominal characteristics.Data Sheet PN10263EJ02V0DS 9Foward Current I F (mA)O u t p u t V o l t a g e V O (V )OUTPUT VOLTAGE vs.FOWARD CURRENTLoad Resistance R L (k Ω)P r o p a g a t i o n D e l a y T i m e t P H L , t P L H( s )PROPAGATION DELAY TIME, vs. LORD RESISTANCEAmbient T emperature T A (˚C)PROPAGATION DELAY TIME, vs. AMBIENT TEMPERATUREAmbient T emperature T A (˚C)H i g h L e v e l O u t p u t C u r r e n t I O H (n A )HIGH LEVEL OUTPUT CURRENT vs. AMBIENT TEMPERATUREP r o p a g a t i o n D e l a y T i m e t P H L , t P L H ( s )t PHLt PLH V CC = 5 V,I F = 16mA,R L = 1.9 k Ω–75–50–252550751001253.02.52.01.51.00.50.0Remark The graphs indicate nominal characteristics.TAPING SPECIFICATIONS (UNIT: mm)10Data Sheet PN10263EJ02V0DS<R>Data Sheet PN10263EJ02V0DS11Data Sheet PN10263EJ02V0DS12NOTES ON HANDLING1. Recommended soldering conditions(1) Infrared reflow soldering • Peak reflow temperature 260°C or below (package surface temperature) • Time of peak reflow temperature 10 seconds or less • Time of temperature higher than 220°C 60 seconds or less • Time to preheat temperature from 120 to 180°C 120±30 s• Number of reflows Three• Flux Rosin flux containing small amount of chlorine (The flux with a maximum chlorine content of 0.2 Wt% is recommended.)P a c k a g e S u r f a c e T e m p e r a t u r e T (˚C )Time (s)Recommended Temperature Profile of Infrared Reflow(2) Wave soldering • Temperature 260°C or below (molten solder temperature) • Time10 seconds or less• Preheating conditions 120°C or below (package surface temperature)• Number of times One (Allowed to be dipped in solder including plastic mold portion.)• Flux Rosin flux containing small amount of chlorine (The flux with a maximum chlorine content of 0.2 Wt% is recommended.)(3) Soldering by soldering iron• Peak temperature (lead part temperature) 350°C or below • Time (each pins)3 seconds or less• Flux Rosin flux containing small amount of chlorine (The flux with a maximum chlorine content of 0.2 Wt% is recommended.)(a) Soldering of leads should be made at the point 1.5 to 2.0 mm from the root of the lead. (b) Please be sure that the temperature of the package would not be heated over 100°C.<R>(4) Cautions• FluxesAvoid removing the residual flux with freon-based and chlorine-based cleaning solvent.2. Cautions regarding noiseBe aware that when voltage is applied suddenly between the photocoupler’s input and output or between collector-emitters at startup, the output transistor may enter the on state, even if the voltage is within the absolute maximum ratings.Data Sheet PN10263EJ02V0DS13SPECIFICATION OF VDE MARKS LICENSE DOCUMENT (VDE0884)Parameter SymbolSpeckUnit Application classification (DIN VDE 0109)for rated line voltages ≤ 300 V r.m.s. for rated line voltages ≤ 600 V r.m.s.IV IIIClimatic test class (DIN IEC 68 Teil 1/09.80) 55/100/21 Dielectric strengthmaximum operating isolation voltageTest voltage (partial discharge test, procedure a for type test and random test) U pr = 1.2 × U IORM, P d < 5 pC U IORMU pr8901 068V peakV peakTest voltage (partial discharge test, procedure b for all devices) U pr = 1.6 × U IORM, P d < 5 pC U pr 1424 V peakHighest permissible overvoltage U TR 8000 V peak Degree of pollution (DIN VDE 0109) 2Clearance distance > 7.0 mm Creepage distance > 7.0 mm Comparative tracking index (DIN IEC 112/VDE 0303 part 1) CTI 175Material group (DIN VDE 0109) III aStorage temperature range T stg–55 to +150 °C Operating temperature range T A–55 to +100 °C Isolation resistance, minimum valueV IO = 500 V dc at T A = 25 °CV IO = 500 V dc at T A MAX. at least 100 °C Ris MIN.Ris MIN.10121011ΩΩSafety maximum ratings (maximum permissible in case of fault, see thermal derating curve)Package temperatureCurrent (input current I F, Psi = 0)Power (output or total power dissipation) Isolation resistanceV IO = 500 V dc at T A = 175 °C (Tsi)TsiIsiPsiRis MIN.175400700109°CmAmWΩData Sheet PN10263EJ02V0DS14Data Sheet PN10263EJ02V0DS15The information in this document is current as of M ay, 2006. 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