- 您现在的位置:买卖IC网 > Datasheet目录328 > ICL7667CBAZA-T (Intersil)IC MOSFET DRIVER DUAL 8-SOIC Datasheet资料下载
参数资料
| 型号: | ICL7667CBAZA-T |
| 厂商: | Intersil |
| 文件页数: | 5/10页 |
| 文件大小: | 0K |
| 描述: | IC MOSFET DRIVER DUAL 8-SOIC |
| 标准包装: | 1 |
| 配置: | 低端 |
| 输入类型: | 反相 |
| 延迟时间: | 20ns |
| 电流 - 峰: | 1A |
| 配置数: | 2 |
| 输出数: | 2 |
| 电源电压: | 4.5 V ~ 15 V |
| 工作温度: | 0°C ~ 70°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 8-SOIC(0.154",3.90mm 宽) |
| 供应商设备封装: | 8-SOIC |
| 包装: | 标准包装 |
| 产品目录页面: | 1240 (CN2011-ZH PDF) |
| 其它名称: | ICL7667CBAZA-TDKR |
��
�
�ICL7667�
�current� capability� of� the� ICL7667� enables� it� to� drive� a�
�1000pF� load� with� a� rise� time� of� only� 40ns.� Because� the�
�output� stage� impedance� is� very� low,� up� to� 300mA� will� flow�
�through� the� series� N-Channel� and� P-Channel� output� devices�
�(from� V+� to� V-)� during� output� transitions.� This� crossover� current�
�is� responsible� for� a� significant� portion� of� the� internal� power�
�dissipation� of� the� ICL7667� at� high� frequencies.� It� can� be�
�minimized� by� keeping� the� rise� and� fall� times� of� the� input� to� the�
�ICL7667� below� 1μs.�
�Application� Notes�
�Although� the� ICL7667� is� simply� a� dual� level-shifting� inverter,�
�there� are� several� areas� to� which� careful� attention� must� be�
�paid.�
�Grounding�
�Since� the� input� and� the� high� current� output� current� paths�
�both� include� the� V-� pin,� it� is� very� important� to� minimize� and�
�common� impedance� in� the� ground� return.� Since� the� ICL7667�
�is� an� inverter,� any� common� impedance� will� generate�
�negative� feedback,� and� will� degrade� the� delay,� rise� and� fall�
�times.� Use� a� ground� plane� if� possible,� or� use� separate�
�ground� returns� for� the� input� and� output� circuits.� To� minimize�
�any� common� inductance� in� the� ground� return,� separate� the�
�input� and� output� circuit� ground� returns� as� close� to� the�
�ICL7667� as� is� possible.�
�Bypassing�
�The� rapid� charging� and� discharging� of� the� load� capacitance�
�requires� very� high� current� spikes� from� the� power� supplies.� A�
�2.� Output� stage� crossover� current� loss�
�3.� Output� stage� I� 2� R� power� loss�
�The� sum� of� the� above� must� stay� within� the� specified� limits� for�
�reliable� operation.�
�As� noted� above,� the� input� inverter� current� is� input� voltage�
�dependent,� with� an� I� V+� of� 0.1mA� maximum� with� a� logic� 0�
�input� and� 6mA� maximum� with� a� logic� 1� input.�
�The� output� stage� crowbar� current� is� the� current� that� flows�
�through� the� series� N-Channel� and� P-Channel� devices� that�
�form� the� output.� This� current,� about� 300mA,� occurs� only�
�during� output� transitions.� Caution:� The� inputs� should� never�
�be� allowed� to� remain� between� V� IL� and� V� IH� since� this� could�
�leave� the� output� stage� in� a� high� current� mode,� rapidly�
�leading� to� destruction� of� the� device.� If� only� one� of� the� drivers�
�is� being� used,� be� sure� to� tie� the� unused� input� to� V-� or�
�ground.� NEVER� leave� an� input� floating.� The� average� supply�
�current� drawn� by� the� output� stage� is� frequency� dependent,�
�as� can� be� seen� in� Figure� 5� (I� V+� vs� Frequency� graph� in� the�
�Typical� Characteristics� Graphs).�
�The� output� stage� I� 2� R� power� dissipation� is� nothing� more� than�
�the� product� of� the� output� current� times� the� voltage� drop�
�across� the� output� device.� In� addition� to� the� current� drawn� by�
�any� resistive� load,� there� will� be� an� output� current� due� to� the�
�charging� and� discharging� of� the� load� capacitance.� In� most�
�high� frequency� circuits� the� current� used� to� charge� and�
�discharge� capacitance� dominates,� and� the� power� dissipation�
�is� approximately:�
�parallel� combination� of� capacitors� that� has� a� low� impedance�
�over� a� wide� frequency� range� should� be� used.� A� 4.7μF�
�P� AC� =� CV� V� 2� f�
�(EQ.� 1)�
�tantalum� capacitor� in� parallel� with� a� low� inductance� 0.1μF�
�capacitor� is� usually� sufficient� bypassing.�
�Output� Damping�
�Ringing� is� a� common� problem� in� any� circuit� with� very� fast�
�where� C� =� Load� Capacitance,� f� =� Frequency�
�In� cases� where� the� load� is� a� power� MOSFET� and� the� gate�
�drive� requirement� are� described� in� terms� of� gate� charge,� the�
�ICL7667� power� dissipation� will� be:�
�rise� or� fall� times.� Such� ringing� will� be� aggravated� by� long�
�inductive� lines� with� capacitive� loads.� Techniques� to� reduce�
�ringing� include:�
�P� AC� =� QGV� V� f�
�where� Q� G� =� Charge� required� to� switch� the� gate,� in�
�Coulombs,� f� =� Frequency.�
�(EQ.� 2)�
�?� Reduce� inductance� by� making� printed� circuit� board� traces�
�as� short� as� possible.�
�?� Reduce� inductance� by� using� a� ground� plane� or� by� closely�
�coupling� the� output� lines� to� their� return� paths.�
�?� Use� a� 10� Ω� to� 30� Ω� resistor� in� series� with� the� output� of� the�
�ICL7667.� Although� this� reduces� ringing,� it� will� also� slightly�
�increase� the� rise� and� fall� times.�
�?� Use� good� by-passing� techniques� to� prevent� supply�
�voltage� ringing.�
�Power� Dissipation�
�The� power� dissipation� of� the� ICL7667� has� three� main�
�components:�
�1.� Input� inverter� current� loss�
�5�
�Power� MOS� Driver� Circuits�
�Power� MOS� Driver� Requirements�
�Because� it� has� a� very� high� peak� current� output,� the� ICL7667�
�the� at� driving� the� gate� of� power� MOS� devices.� The� high�
�current� output� is� important� since� it� minimizes� the� time� the�
�power� MOS� device� is� in� the� linear� region.� Figure� 9� is� a�
�typical� curve� of� Charge� vs� Gate� voltage� for� a� power�
�MOSFET.� The� flat� region� is� caused� by� the� Miller�
�capacitance,� where� the� drain-to-gate� capacitance� is�
�multiplied� by� the� voltage� gain� of� the� FET.� This� increase� in�
�capacitance� occurs� while� the� power� MOSFET� is� in� the� linear�
�region� and� is� dissipating� significant� amounts� of� power.� The�
�very� high� current� output� of� the� ICL7667� is� able� to� rapidly�
�FN2853.6�
�April� 29,� 2010�
�相关PDF资料 |
PDF描述 |
|---|---|
| ICL7667CPA+ | IC DRIVER MOSFET DUAL PWR 8-DIP |
| ICM7243BIPLZ | IC LED DRIVR WHITE BCKLGT 40-DIP |
| IDC5N | INPUT MODULE DC 34MA 5VDC |
| IDS7 | SHELF FIXED 14.1X20.3" BEIGE |
| IDT6116SA25TPGI | IC SRAM 16KBIT 25NS 24DIP |
相关代理商/技术参数 |
参数描述 |
|---|---|
| ICL7667CJA | 功能描述:功率驱动器IC 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 |
| ICL7667CPA | 功能描述:功率驱动器IC DL PWR MOS DRVR COM 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 |
| ICL7667CPA+ | 功能描述:功率驱动器IC Dual Power Inverting MOSFET Driver 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 |
| ICL7667CPAZ | 功能描述:功率驱动器IC W/ANNEAL DL PWR MOS DRVR COM 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 |
| ICL7667CTV | 制造商:Rochester Electronics LLC 功能描述:- Bulk 制造商:Harris Corporation 功能描述: |
发布紧急采购,3分钟左右您将得到回复。