- 您现在的位置:买卖IC网 > PDF目录20553 > HIP6602BCRZ-T (Intersil)IC DRVR MOSF 2CH SYC BUCK 16-QFN PDF资料下载
参数资料
| 型号: | HIP6602BCRZ-T |
| 厂商: | Intersil |
| 文件页数: | 7/12页 |
| 文件大小: | 0K |
| 描述: | IC DRVR MOSF 2CH SYC BUCK 16-QFN |
| 标准包装: | 6,000 |
| 配置: | 高端和低端,同步 |
| 输入类型: | PWM |
| 电流 - 峰: | 400mA |
| 配置数: | 2 |
| 输出数: | 4 |
| 高端电压 - 最大(自引导启动): | 15V |
| 电源电压: | 10.8 V ~ 13.2 V |
| 工作温度: | 0°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 16-VQFN 裸露焊盘 |
| 供应商设备封装: | 16-QFN-EP(5x5) |
| 包装: | 带卷 (TR) |
��
�
�HIP6602B�
�C� BOOT� ≥� ------------------------�
�A� falling� transition� on� PWM� indicates� the� turn-off� of� the�
�upper� MOSFET� and� the� turn-on� of� the� lower� MOSFET.� A�
�short� propagation� delay� [TPDL� UGATE� ]� is� encountered�
�before� the� upper� gate� begins� to� fall� [TF� UGATE� ].� Again,� the�
�adaptive� shoot-through� circuitry� determines� the� lower� gate�
�delay� time,� TPDH� LGATE� .� The� PHASE� voltage� is� monitored�
�and� the� lower� gate� is� allowed� to� rise� after� PHASE� drops�
�below� 0.5V.� The� lower� gate� then� rises� [TR� LGATE� ],� turning�
�on� the� lower� MOSFET.�
�Three-State� PWM� Input�
�A� unique� feature� of� the� HIP6602B� drivers� is� the� addition� of� a�
�shutdown� window� to� the� PWM� input.� If� the� PWM� signal�
�enters� and� remains� within� the� shutdown� window� for� a� set�
�holdoff� time,� the� output� drivers� are� disabled� and� both�
�MOSFET� gates� are� pulled� and� held� low.� The� shutdown� state�
�is� removed� when� the� PWM� signal� moves� outside� the�
�shutdown� window.� Otherwise,� the� PWM� rising� and� falling�
�thresholds� outlined� in� the� Electrical� Specifications� determine�
�when� the� lower� and� upper� gates� are� enabled.�
�Adaptive� Shoot-Through� Protection�
�The� drivers� incorporate� adaptive� shoot-through� protection� to�
�prevent� upper� and� lower� MOSFETs� from� conducting�
�simultaneously� and� shorting� the� input� supply.� This� is�
�accomplished� by� ensuring� the� falling� gate� has� turned� off� one�
�MOSFET� before� the� other� is� allowed� to� rise.�
�During� turn-off� of� the� lower� MOSFET,� the� LGATE� voltage� is�
�monitored� until� it� reaches� a� 2.2V� threshold,� at� which� time� the�
�UGATE� is� released� to� rise.� Adaptive� shoot-through� circuitry�
�monitors� the� PHASE� voltage� during� UGATE� turn-off.� Once�
�PHASE� has� dropped� below� a� threshold� of� 0.5V,� the� LGATE�
�is� allowed� to� rise.� If� the� PHASE� does� not� drop� below� 0.5V�
�within� 250ns,� LGATE� is� allowed� to� rise.� This� is� done� to�
�generate� the� bootstrap� refresh� signal.� PHASE� continues� to�
�be� monitored� during� the� lower� gate� rise� time.� If� the� PHASE�
�voltage� exceeds� the� 0.5V� threshold� during� this� period� and�
�remains� high� for� longer� than� 2μs,� the� LGATE� transitions� low.�
�This� is� done� to� make� the� lower� MOSFET� emulate� a� diode.�
�Both� upper� and� lower� gates� are� then� held� low� until� the� next�
�rising� edge� of� the� PWM� signal.�
�Power-On� Reset� (POR)� Function�
�During� initial� start-up,� the� VCC� voltage� rise� is� monitored� and�
�gate� drives� are� held� low� until� a� typical� VCC� rising� threshold�
�of� 9.95V� is� reached.� Once� the� rising� VCC� threshold� is�
�exceeded,� the� PWM� input� signal� takes� control� of� the� gate�
�drives.� If� VCC� drops� below� a� typical� VCC� falling� threshold� of�
�7.6V� during� operation,� then� both� gate� drives� are� again� held�
�low.� This� condition� persists� until� the� VCC� voltage� exceeds�
�the� VCC� rising� threshold.�
�Internal� Bootstrap� Device�
�The� HIP6602B� features� an� internal� bootstrap� device.� Simply�
�adding� an� external� capacitor� across� the� BOOT� and� PHASE�
�pins� completes� the� bootstrap� circuit.�
�7�
�The� bootstrap� capacitor� must� have� a� maximum� voltage�
�rating� above� PVCC� +� 5V.� The� bootstrap� capacitor� can� be�
�chosen� from� the� following� equation:�
�Q� GATE�
�?� V� BOOT�
�Where� Q� GATE� is� the� amount� of� gate� charge� required� to� fully�
�charge� the� gate� of� the� upper� MOSFET.� The� ?� V� BOOT� term� is�
�defined� as� the� allowable� droop� in� the� rail� of� the� upper� drive.�
�As� an� example,� suppose� a� HUF76139� is� chosen� as� the�
�upper� MOSFET.� The� gate� charge,� Q� GATE� ,� from� the� data�
�sheet� is� 65nC� for� a� 10V� upper� gate� drive.� We� will� assume� a�
�200mV� droop� in� drive� voltage� over� the� PWM� cycle.� We� find�
�that� a� bootstrap� capacitance� of� at� least� 0.325μF� is� required.�
�The� next� larger� standard� value� capacitance� is� 0.33μF.�
�In� applications� which� require� down� conversion� from� +12V� or�
�higher� and� PVCC� is� connected� to� a� +12V� source,� a� boot�
�resistor� in� series� with� the� boot� capacitor� is� required.� The�
�increased� power� density� of� these� designs� tend� to� lead� to�
�increased� ringing� on� the� BOOT� and� PHASE� nodes,� due� to�
�faster� switching� of� larger� currents� across� given� circuit�
�parasitic� elements.� The� addition� of� the� boot� resistor� allows�
�for� tuning� of� the� circuit� until� the� peak� ringing� on� BOOT� is�
�below� 29V� from� BOOT� to� GND� and� 17V� from� BOOT� to� VCC.�
�A� boot� resistor� value� of� 5� ?� typically� meets� this� criteria.�
�In� some� applications,� a� well� tuned� boot� resistor� reduces� the�
�ringing� on� the� BOOT� pin,� but� the� PHASE� to� GND� peak�
�ringing� exceeds� 17V.� A� gate� resistor� placed� in� the� UGATE�
�trace� between� the� controller� and� upper� MOSFET� gate� is�
�recommended� to� reduce� the� ringing� on� the� PHASE� node� by�
�slowing� down� the� upper� MOSFET� turn-on.� A� gate� resistor�
�value� between� 2� ?� to� 10� ?� typically� reduces� the� PHASE� to�
�GND� peak� ringing� below� 17V.�
�Gate� Drive� Voltage� Versatility�
�The� HIP6602B� provides� the� user� flexibility� in� choosing� the�
�gate� drive� voltage.� Simply� applying� a� voltage� from� 5V� up� to�
�12V� on� PVCC� will� set� both� driver� rail� voltages.�
�Power� Dissipation�
�Package� power� dissipation� is� mainly� a� function� of� the� switching�
�frequency� and� total� gate� charge� of� the� selected� MOSFETs.�
�Calculating� the� power� dissipation� in� the� driver� for� a� desired�
�application� is� critical� to� ensuring� safe� operation.� Exceeding� the�
�maximum� allowable� power� dissipation� level� will� push� the� IC�
�beyond� the� maximum� recommended� operating� junction�
�temperature� of� 125°C.� The� maximum� allowable� IC� power�
�dissipation� for� the� 14� lead� SOIC� package� is� approximately�
�1000mW.� Improvements� in� thermal� transfer� may� be� gained� by�
�increasing� the� PC� board� copper� area� around� the� HIP6602B.�
�Adding� a� ground� pad� under� the� IC� to� help� transfer� heat� to� the�
�outer� peripheral� of� the� board� will� help.� Also� keeping� the� leads� to�
�the� IC� as� wide� as� possible� and� widening� this� these� leads� as�
�soon� as� possible� to� further� enhance� heat� transfer� will� also� help.�
�When� designing� the� driver� into� an� application,� it� is�
�recommended� that� the� following� calculation� be� performed� to�
�FN9076.5�
�July� 22,� 2005�
�相关PDF资料 |
PDF描述 |
|---|---|
| LXC150-1050SW | POWER SUPPLY LED 150W 1050MA |
| REC3-2405SRWZ/H6/A | CONV DC/DC 3W 9-36VIN 05VOUT |
| R1D12-1212/HP | CONV DC/DC 1W 12VIN +/-12VOUT |
| R1D12-1209/HP | CONV DC/DC 1W 12VIN +/-09VOUT |
| T95C106K025EZAS | CAP TANT 10UF 25V 10% 2812 |
相关代理商/技术参数 |
参数描述 |
|---|---|
| HIP6602CB | 制造商:Rochester Electronics LLC 功能描述:- Bulk |
| HIP6602CB-T | 制造商:Rochester Electronics LLC 功能描述:- Tape and Reel |
| HIP6603 | 制造商:INTERSIL 制造商全称:Intersil Corporation 功能描述:Synchronous-Rectified Buck MOSFET Drivers |
| HIP6603A | 制造商:INTERSIL 制造商全称:Intersil Corporation 功能描述:Synchronous Rectified Buck MOSFET Drivers |
| HIP6603ACB | 制造商:Rochester Electronics LLC 功能描述:- Bulk |
发布紧急采购,3分钟左右您将得到回复。