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参数资料
| 型号: | IXBD4410SI |
| 厂商: | IXYS |
| 文件页数: | 8/11页 |
| 文件大小: | 0K |
| 描述: | IC LOW SIDE DRIVER 16SOIC |
| 产品变化通告: | Discontinuation Notice 15/Jun/2010 |
| 标准包装: | 46 |
| 系列: | ISOSMART™ |
| 配置: | 低端 |
| 输入类型: | 非反相 |
| 延迟时间: | 110ns |
| 电流 - 峰: | 2A |
| 配置数: | 1 |
| 输出数: | 1 |
| 高端电压 - 最大(自引导启动): | 1200V |
| 电源电压: | 10 V ~ 20 V |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 16-SOIC(0.295",7.50mm 宽) |
| 供应商设备封装: | 16-SOIC |
| 包装: | 管件 |
��
�
�IXBD4410�
�IXBD4411�
�terminals� (C7,� C11),� and� an� output�
�reservoir� capacitor� between� V� EE� and�
�GND� (C10,� C14).� A� 0.1� μ� F� charge�
�a�
�b�
�c�
�pump� capacitor� (C7,� C11)� is� recom-�
�mended.� The� voltage� regulation�
�method� used� in� the� IXBD4410/4411�
�allows� a� 1� to� 2� V� ripple� frequency�
�depends� on� the� size� of� the� V� EE� output�
�reservoir� capacitor� (C10,� C14)� and� the�
�average� load� current.� The� minimum�
�recommended� output� reservoir� (C10,�
�C14)� is� 4.7� μ� F� tantalum,� or� 10� μ� F� if�
�IM�
�R� s�
�KG�
�GND�
�With� Current� Mirror�
�IM�
�R� s�
�KG�
�GND�
�With� Standard�
�MOSFET/IGBT�
�IM�
�R� s�
�KG�
�GND�
�Desaturation� Detection�
�with� Standard�
�MOSFET/IGBT�
�aluminium� electrolytic� construction� is�
�chosen.� Note� that� this� reservoir�
�capacitor� is� in� addition� to� a� good�
�Fig.� 7:� Alternative� overcurrent� protection� circuits�
�quality� high� frequency� bypass� capaci-�
�tor� (0.1� μ� F)� that� should� be� placed� from�
�VEE� to� GND� (C9,� C13).�
�A� small� resistor� in� series� with� the�
�charge� pump� capacitor,� (R7,� R8)�
�reduces� the� peak� charging� currents� of�
�the� charge� pump.� A� value� or� 68� ?� or�
�greater� is� recommended,� as� illustrated�
�in� the� applications� example� in� Fig.� 6.�
�Current� Sense� /� Desaturation�
�Detection� Circuit�
�All� members� of� the� ISOSMART?�
�driver� family� provide� a� very� flexible�
�overcurrent/short� circuit� protection�
�capability� that� works� with� both� standard�
�three-terminal� power� transistors,� and�
�with� 4-� and� 5-terminal� current� sensing�
�power� devices.� Overcurrent� detection�
�is� accomplished� as� illustrated� in� Fig.� 7a�
�(for� a� current� mirror� power� device)� and�
�Fig.� 7b� (for� a� standard� three� terminal�
�power� transistor).� Desaturation�
�detection� is� accomplished� with� the�
�same� internal� circuits� by� measuring� the�
�voltage� across� the� power� transistor� in�
�the� on-state� with� an� external� resistor�
�divider� (Fig.� 7c).�
�The� IM� input� trip� point� V� TIM� ,� typically�
�300� mV,� is� referenced� to� the� Kelvin�
�ground� pin� KG.�
�Current� Mirror� MOSFET� and� IGBT� allow�
�good� control� of� peak� let-through�
�currents� and� excellent� short� circuit�
�protection� when� combined� with� the�
�ISOSMART?� driver� family� of� devices.�
�The� sense� resistor� is� chosen� to�
�develop� 300� mV� at� the� desired� peak�
�transistor� current,� assuming� a� mirror�
�ration� of� 1400:1,� and� a� trip� point� of� 30�
�A� is� desired:�
�R� s� =� 300� mV� ?� 1400/30� A� =� 14� ?�
�(use� 15� ?� CC).�
�It� is� important� to� realize� that� C� oss� per�
�unit� area� of� the� mirror� cells� is� much�
�larger� that� C� oss� per� unit� area� of� the� bulk�
�of� the� chip� due� to� periphery� effects.�
�This� causes� a� large� transient� current�
�pulse� at� the� mirror� output� whenever� the�
�transistor� switches� (C� ?� dv/dt� currents),�
�which� can� cause� false� overcurrent�
�trigger.� The� RC� filter� indicated� in� Fig.�
�7a� will� eliminate� this� problem.�
�Standard� three-terminal� MOSFET� and�
�IGBT� devices� (in� discrete� as� well� as�
�modern� industrial� single� transistor� and�
�phase-leg� modules)� can� also� be�
�protected� from� short� circuit� with� the�
�ISOSMART?� driver� family� devices.� In�
�discrete� device� designs,� where� the�
�source/emitter� terminal� is� available,�
�overcurrent� protection� with� an� external�
�power� resistor� can� be� implemented.�
�The� resistor� is� placed� in� series� with� the�
�device� emitter,� with� the� full� device�
�current� flowing� through� it� (Fig.� 7b).� The�
�sense� resistor� is� again� selected� to�
�develop� 300� mV� at� the� desired� peak�
�transistor� current,� assuming� a� trip� point�
�of� 30� A� is� desired:�
�R� s� =� 300� mV� /� 30� A� =� 10� m� ?�
�(use� 10� m� ?� ,� noninductive�
�current� sense� resistor).�
�It� is� important� to� recognize� that�
�"noninductive"� is� a� relative� term,�
�especially� when� applied� to� current�
�sense� resistor� construction� and�
�characterization.� There� is� always�
�significant� series� inductance� inserted�
�with� the� sense� resistor,� and� L� ?� di/dt�
�voltage� transients� can� cause� false�
�overcurrent� trigger.�
�The� RC� filter� indicated� in� Figure� 7b� will�
�eliminate� this� problem.� Choosing� the�
�RC� pole� at� the� current� sense� resistor�
�RL� zero� should� exactly� compensate� for�
�series� inductance.� Because� the� exact�
�value� is� not� normally� known� (and� can�
�vary� depending� on� PC� layout� and�
�component� lead� dress)� this� is� not�
�normally� a� good� idea.� Usually,� the� RC�
�time� constant� should� be� two� to� ten�
�times� longer� than� the� suspected� RL�
�time� constant.�
�Desaturation� detection� as� in� Figure� 7c�
�is� probably� the� most� common� method�
�of� short� circuit� protection� in� use� today.�
�While� not� strictly� an� "overcurrent"�
�detector,� if� the� power� transistor� gain,�
�and� consequently� short� circuit� let-�
�through� current,� is� well� controlled� (as�
�with� modern� MOSFET� and� IGBT)� this�
�methodology� offers� very� effective�
�protection.�
�The� IXBD4410/4411� half-bridge� circuits�
�in� Fig.� 6� uses� desaturation� detection.� In�
�Fig.� 6,� the� voltage� across� the� two�
�power� MOSFET� devices� (or� IGBTs)� are�
�monitored� by� two� sets� of� voltage-�
�divider� networks,� R10� and� R11� for� the�
�high-side� gate� driver,� and� R13� and� R14�
�for� the� low-side� gate� driver.� The�
�dividers� are� set� to� trip� the� IM� input�
�comparators� when� either� Power�
�MOSFET� device� V� DS� exceeds� a�
�reasonable� value,� perhaps� 50� V�
�(usually� a� value� of� 10� %� of� the� nominal�
�DC� bus� voltage� works� well).� R10� or�
�R13� are� chosen� to� tolerate� the� applied�
�steady� state� DC� bus� voltage� at� an�
�acceptable� power� dissipation.�
�Dielectric� withstand� capability,� power�
�handling,� temperature� rise,� and� PC�
�board� creep� and� strike� spacings,� must�
�all� be� carefully� considered� in� the�
�design� of� the� voltage-divider� networks.�
�In� the� off-state,� the� voltage� across� the�
�Power� MOSFET� device� may� go� as� high�
�as� the� DC� bus� potential.� To� keep� this�
�normal� condition� from� setting� the�
�internal� fault� flip-flop� of� the� IXBD4410�
�or� the� IXBD4411,� an� internal� CMOS�
�switch� is� turned� on� and� placed� across�
�lM� and� KG� pins� shorting� them� together.�
�This� effectively� discharges� C8� or� C12�
�in� Fig.� 6� and� maintains� zero� potential�
�?� 2004� IXYS� All� rights� reserved�
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相关代理商/技术参数 |
参数描述 |
|---|---|
| IXBD4411 | 制造商:IXYS 制造商全称:IXYS Corporation 功能描述:ISOSMART Half Bridge Driver Chipset |
| IXBD4411PC | 制造商:未知厂家 制造商全称:未知厂家 功能描述:Interface IC |
| IXBD4411PI | 功能描述:功率驱动器IC 1/2Bridge2A RoHS:否 制造商:Micrel 产品:MOSFET Gate Drivers 类型:Low Cost High or Low Side MOSFET Driver 上升时间: 下降时间: 电源电压-最大:30 V 电源电压-最小:2.75 V 电源电流: 最大功率耗散: 最大工作温度:+ 85 C 安装风格:SMD/SMT 封装 / 箱体:SOIC-8 封装:Tube |
| IXBD4411SI | 功能描述:功率驱动器IC 1/2Bridge2A RoHS:否 制造商:Micrel 产品:MOSFET Gate Drivers 类型:Low Cost High or Low Side MOSFET Driver 上升时间: 下降时间: 电源电压-最大:30 V 电源电压-最小:2.75 V 电源电流: 最大功率耗散: 最大工作温度:+ 85 C 安装风格:SMD/SMT 封装 / 箱体:SOIC-8 封装:Tube |
| IXBD4412PC | 制造商:未知厂家 制造商全称:未知厂家 功能描述:Interface IC |
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