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参数资料
| 型号: | MIC5014YN |
| 厂商: | Micrel Inc |
| 文件页数: | 5/12页 |
| 文件大小: | 0K |
| 描述: | IC DRIVER MOSFET HI/LO SIDE 8DIP |
| 标准包装: | 50 |
| 配置: | 高端或低端 |
| 输入类型: | 非反相 |
| 延迟时间: | 2.5ms |
| 配置数: | 1 |
| 输出数: | 1 |
| 电源电压: | 2.75 V ~ 30 V |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 通孔 |
| 封装/外壳: | 8-DIP(0.300",7.62mm) |
| 供应商设备封装: | 8-PDIP |
| 包装: | 管件 |
| 产品目录页面: | 1110 (CN2011-ZH PDF) |
| 其它名称: | 576-1234 |
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�
�MIC5014/5015�
�Applications� Information�
�Functional� Description�
�The� MIC5014� is� functionally� and� pin� for� pin� compatible� with�
�the� MIC5011,� except� for� the� omission� of� the� optional� speed-�
�up� capacitor� pins,� which� are� available� on� the� MIC5011.� The�
�MIC5015� is� an� inverting� configuration� of� the� MIC5014.�
�The� internal� functions� of� these� devices� are� controlled� via� a�
�logic� block� (refer� to� block� diagram)� connected� to� the� control�
�input� (pin� 2).� When� the� input� is� off� (low� for� the� MIC5014,� and�
�high� for� the� MIC5015),� all� functions� are� turned� off,� and� the�
�gate� of� the� external� power� MOSFET� is� held� low� via� two� N-�
�channel� switches.� This� results� in� a� very� low� standby� current;�
�15� μ� A� typical,� which� is� necessary� to� power� an� internal� bandgap.�
�When� the� input� is� driven� to� the� “ON”� state,� the� N-channel�
�switches� are� turned� off,� the� charge� pump� is� turned� on,� and� the�
�P-channel� switch� between� the� charge� pump� and� the� gate�
�turns� on,� allowing� the� gate� of� the� power� FET� to� be� charged.�
�The� op� amp� and� internal� zener� form� an� active� regulator� which�
�shuts� off� the� charge� pump� when� the� gate� voltage� is� high�
�enough.� This� is� a� feature� not� found� on� the� MIC5011.�
�The� charge� pump� incorporates� a� 100kHz� oscillator� and� on-�
�chip� pump� capacitors� capable� of� charging� a� 1,000pF� load� in�
�90� μ� s� typical.� In� addition� to� providing� active� regulation,� the�
�internal� 15V� zener� is� included� to� prevent� exceeding� the� V� GS�
�rating� of� the� power� MOSFET� at� high� supply� voltages.�
�The� MIC5014/15� devices� have� been� improved� for� greater�
�ruggedness� and� durability.� All� pins� can� withstand� being�
�pulled� 20V� below� ground� without� sustaining� damage,� and� the�
�supply� pin� can� withstand� an� overvoltage� transient� of� 60V� for�
�1s.� An� overvoltage� shutdown� has� also� been� included,� which�
�turns� off� the� device� when� the� supply� exceeds� 35V.�
�Construction� Hints�
�High� current� pulse� circuits� demand� equipment� and� assembly�
�techniques� that� are� more� stringent� than� normal,� low� current�
�lab� practices.� The� following� are� the� sources� of� pitfalls� most�
�often� encountered� during� prototyping:� Supplies� :� Many� bench�
�power� supplies� have� poor� transient� response.� Circuits� that�
�are� being� pulse� tested,� or� those� that� operate� by� pulse-width�
�modulation� will� produce� strange� results� when� used� with� a�
�supply� that� has� poor� ripple� rejection,� or� a� peaked� transient�
�response.� Always� monitor� the� power� supply� voltage� that�
�appears� at� the� drain� of� a� high� side� driver� (or� the� supply� side�
�of� the� load� for� a� low� side� driver)� with� an� oscilloscope.� It� is� not�
�Micrel,� Inc.�
�not� use� a� socket� for� the� MOSFET.� If� the� MOSFET� is� a� TO-220�
�type� package,� make� high� current� connections� to� the� drain� tab.�
�Wiring� losses� have� a� profound� effect� on� high-current� circuits.�
�A� floating� milliohmeter� can� identify� connections� that� are� con-�
�tributing� excess� drop� under� load.�
�Low� Voltage� Testing�
�As� the� MIC5014/MIC5015� have� relatively� high� output� imped-�
�ances,� a� normal� oscilloscope� probe� will� load� the� device.� This�
�is� especially� pronounced� at� low� voltage� operation.� It� is� recom-�
�mended� that� a� FET� probe� or� unity� gain� buffer� be� used� for� all�
�testing.�
�Circuit� Topologies�
�The� MIC5014� and� MIC5015� are� well� suited� for� use� with�
�standard� power� MOSFETs� in� both� low� and� high� side� driver�
�configurations.� In� addition,� the� lowered� supply� voltage� re-�
�quirements� of� these� devices� make� them� ideal� for� use� with� logic�
�level� FETs� in� high� side� applications� with� a� supply� voltage� of� 3�
�to� 4V.� (If� higher� supply� voltages� [>4V]� are� used� with� logic� level�
�FETs,� an� external� zener� clamp� must� be� supplied� to� ensure�
�that� the� maximum� V� GS� rating� of� the� logic� FET� [10V]� is� not�
�exceeded.)� In� addition,� a� standard� IGBT� can� be� driven� using�
�these� devices.�
�Choice� of� one� topology� over� another� is� usually� based� on�
�speed� vs.� safety.� The� fastest� topology� is� the� low� side� driver,�
�however,� it� is� not� usually� considered� as� safe� as� high� side�
�driving� as� it� is� easier� to� accidentally� short� a� load� to� ground� than�
�to� V� CC.� The� slowest,� but� safest� topology� is� the� high� side�
�driver;� with� speed� being� inversely� proportional� to� supply�
�voltage.� It� is� the� preferred� topology� for� most� military� and�
�automotive� applications.� Speed� can� be� improved� consider-�
�ably� by� bootstrapping� from� the� supply.�
�All� topologies� implemented� using� these� devices� are� well�
�suited� to� driving� inductive� loads,� as� either� the� gate� or� the�
�source� pin� can� be� pulled� 20V� below� ground� with� no� effect.�
�External� clamp� diodes� are� unnecessary,� except� for� the� case�
�in� which� a� transient� may� exceed� the� overvoltage� trip� point.�
�High� Side� Driver� (Figure� 1)� The� high� side� topology� shown�
�here� is� an� implementation� of� a� “sleep-mode”� switch� for� a�
�laptop� or� notebook� computer� which� uses� a� logic� level� FET.� A�
�standard� power� FET� can� easily� be� substituted� when� supply�
�voltages� above� 4V� are� required.�
�+3V� to� +30V�
�uncommon� to� find� bench� power� supplies� in� the� 1kW� class� that�
�overshoot� or� undershoot� by� as� much� as� 50%� when� pulse�
�10μF�
�MIC5014�
�loaded.� Not� only� will� the� load� current� and� voltage� measure-�
�1�
�V+�
�NC�
�8�
�ments� be� affected,� but� it� is� possible� to� overstress� various�
�components,� especially� electrolytic� capacitors,� with� possibly�
�Control� Input�
�ON�
�OFF�
�2�
�3�
�Input�
�Source�
�NC�
�NC�
�7�
�6�
�catastrophic� results.� A� 10� μ� F� supply� bypass� capacitor� at� the�
�chip� is� recommended.� Residual� resistances� :� Resistances�
�in� circuit� connections� may� also� cause� confusing� results.� For�
�example,� a� circuit� may� employ� a� 50m� ?� power� MOSFET� for�
�low� voltage� drop,� but� unless� careful� construction� techniques�
�4� Gnd�
�Gate� 5�
�are� used,� one� could� easily� add� 50� to� 100m� ?� resistance.� Do�
�Figure� 2.� Low� Side� Driver�
�June� 2005�
�5�
�MIC5014/5015�
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相关代理商/技术参数 |
参数描述 |
|---|---|
| MIC5015 | 制造商:MICREL 制造商全称:Micrel Semiconductor 功能描述:Low-Cost High- or Low-Side MOSFET Driver |
| MIC5015BM | 功能描述:IC DRIVER MOSF HI/LOW SIDE 8SOIC RoHS:否 类别:集成电路 (IC) >> PMIC - MOSFET,电桥驱动器 - 外部开关 系列:- 标准包装:50 系列:- 配置:高端 输入类型:非反相 延迟时间:200ns 电流 - 峰:250mA 配置数:1 输出数:1 高端电压 - 最大(自引导启动):600V 电源电压:12 V ~ 20 V 工作温度:-40°C ~ 125°C 安装类型:通孔 封装/外壳:8-DIP(0.300",7.62mm) 供应商设备封装:8-DIP 包装:管件 其它名称:*IR2127 |
| MIC5015BM TR | 功能描述:IC DRIVER MOSF HI/LOW SIDE 8SOIC RoHS:否 类别:集成电路 (IC) >> PMIC - MOSFET,电桥驱动器 - 外部开关 系列:- 标准包装:50 系列:- 配置:高端 输入类型:非反相 延迟时间:200ns 电流 - 峰:250mA 配置数:1 输出数:1 高端电压 - 最大(自引导启动):600V 电源电压:12 V ~ 20 V 工作温度:-40°C ~ 125°C 安装类型:通孔 封装/外壳:8-DIP(0.300",7.62mm) 供应商设备封装:8-DIP 包装:管件 其它名称:*IR2127 |
| MIC5015BMTR | 制造商:Rochester Electronics LLC 功能描述:- Tape and Reel |
| MIC5015BN | 制造商:MICREL 制造商全称:Micrel Semiconductor 功能描述:Low-Cost High- or Low-Side MOSFET Driver |
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