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参数资料
| 型号: | NCV3020BDR2G |
| 厂商: | ON Semiconductor |
| 文件页数: | 18/23页 |
| 文件大小: | 0K |
| 描述: | IC REG CTRLR BUCK PWM VM 8-SOIC |
| 标准包装: | 2,500 |
| PWM 型: | 电压模式 |
| 输出数: | 1 |
| 频率 - 最大: | 670kHz |
| 占空比: | 80% |
| 电源电压: | 4.7 V ~ 28 V |
| 降压: | 是 |
| 升压: | 无 |
| 回扫: | 无 |
| 反相: | 无 |
| 倍增器: | 无 |
| 除法器: | 无 |
| Cuk: | 无 |
| 隔离: | 无 |
| 工作温度: | -40°C ~ 125°C |
| 封装/外壳: | 8-SOIC(0.154",3.90mm 宽) |
| 包装: | 带卷 (TR) |
��
�
�NCP3020A,� NCP3020B,� NCV3020A,� NCV3020B�
�Co� RMS� +� I� O� @�
�I� TRAN� @� L� OUT�
�D� V� OUT� ?� CHG� +�
�V� ESR_C� +� I� O� @� ra� @� ESR� Co� )�
�ESL� @� I� PP� @� F� SW�
�V� ESLON� +�
�ESL� @� I� PP� @� F� SW�
�V� ESLOFF� +�
�Output� Capacitor� Selection�
�The� important� factors� to� consider� when� selecting� an�
�output� capacitor� is� dc� voltage� rating,� ripple� current� rating,�
�output� ripple� voltage� requirements,� and� transient� response�
�requirements.�
�The� output� capacitor� must� be� rated� to� handle� the� ripple�
�current� at� full� load� with� proper� derating.� The� RMS� ratings�
�given� in� datasheets� are� generally� for� lower� switching�
�frequency� than� used� in� switch� mode� power� supplies� but� a�
�multiplier� is� usually� given� for� higher� frequency� operation.�
�The� RMS� current� for� the� output� capacitor� can� be� calculated�
�below:�
�ra�
�(eq.� 17)�
�12�
�The� maximum� allowable� output� voltage� ripple� is� a�
�combination� of� the� ripple� current� selected,� the� output�
�capacitance� selected,� the� equivalent� series� inductance� (ESL)�
�and� ESR.�
�The� main� component� of� the� ripple� voltage� is� usually� due�
�to� the� ESR� of� the� output� capacitor� and� the� capacitance�
�selected.�
�1�
�(eq.� 18)�
�8� @� F� SW� @� Co�
�The� ESL� of� capacitors� depends� on� the� technology� chosen�
�but� tends� to� range� from� 1� nH� to� 20� nH� where� ceramic�
�capacitors� have� the� lowest� inductance� and� electrolytic�
�capacitors� then� to� have� the� highest.� The� calculated�
�contributing� voltage� ripple� from� ESL� is� shown� for� the� switch�
�on� and� switch� off� below:�
�(eq.� 19)�
�D�
�(eq.� 20)�
�(1� *� D� )�
�The� output� capacitor� is� a� basic� component� for� the� fast�
�In� a� typical� converter� design,� the� ESR� of� the� output� capacitor�
�bank� dominates� the� transient� response.� It� should� be� noted�
�that� D� VOUT� ?� DISCHARGE� and� D� VOUT� ?� ESR� are� out� of�
�phase� with� each� other,� and� the� larger� of� these� two� voltages�
�will� determine� the� maximum� deviation� of� the� output� voltage�
�(neglecting� the� effect� of� the� ESL).�
�Conversely� during� a� load� release,� the� output� voltage� can�
�increase� as� the� energy� stored� in� the� inductor� dumps� into� the�
�output� capacitor.� The� ESR� contribution� from� Equation� 18�
�still� applies� in� addition� to� the� output� capacitor� charge� which�
�is� approximated� by� the� following� equation:�
�2�
�(eq.� 23)�
�C� OUT� @� V� OUT�
�Power� MOSFET� Selection�
�Power� dissipation,� package� size,� and� the� thermal�
�environment� drive� MOSFET� selection.� To� adequately� select�
�the� correct� MOSFETs,� the� design� must� first� predict� its� power�
�dissipation.� Once� the� dissipation� is� known,� the� thermal�
�impedance� can� be� calculated� to� prevent� the� specified�
�maximum� junction� temperatures� from� being� exceeded� at� the�
�highest� ambient� temperature.�
�Power� dissipation� has� two� primary� contributors:�
�conduction� losses� and� switching� losses.� The� control� or�
�high� ?� side� MOSFET� will� display� both� switching� and�
�conduction� losses.� The� synchronous� or� low� ?� side� MOSFET�
�will� exhibit� only� conduction� losses� because� it� switches� into�
�nearly� zero� voltage.� However,� the� body� diode� in� the�
�synchronous� MOSFET� will� suffer� diode� losses� during� the�
�non� ?� overlap� time� of� the� gate� drivers.�
�Starting� with� the� high� ?� side� or� control� MOSFET,� the�
�power� dissipation� can� be� approximated� from:�
�P� D_CONTROL� +� P� COND� )� P� SW_TOT� (eq.� 24)�
�The� first� term� is� the� conduction� loss� of� the� high� ?� side�
�MOSFET� while� it� is� on.�
�response� of� the� power� supply.� In� fact,� during� load� transient,�
�for� the� first� few� microseconds� it� supplies� the� current� to� the�
�P� COND� +� I� RMS_CONTROL�
�2�
�@� R� DS(on)_CONTROL� (eq.� 25)�
�I� RMS_CONTROL� +� I� OUT� @�
�D� @� 1� )�
�ra� 2�
�load.� The� controller� immediately� recognizes� the� load�
�transient� and� sets� the� duty� cycle� to� maximum,� but� the� current�
�slope� is� limited� by� the� inductor� value.�
�During� a� load� step� transient� the� output� voltage� initially�
�drops� due� to� the� current� variation� inside� the� capacitor� and� the�
�ESR� (neglecting� the� effect� of� the� effective� series� inductance�
�(ESL)).�
�D� V� OUT� ?� ESR� +� D� I� TRAN� @� ESR� Co� (eq.� 21)�
�A� minimum� capacitor� value� is� required� to� sustain� the�
�current� during� the� load� transient� without� discharging� it.� The�
�voltage� drop� due� to� output� capacitor� discharge� is�
�approximated� by� the� following� equation:�
�Using� the� ra� term� from� Equation� 6,� I� RMS� becomes:�
�(eq.� 26)�
�12�
�The� second� term� from� Equation� 24� is� the� total� switching�
�loss� and� can� be� approximated� from� the� following� equations.�
�P� SW_TOT� +� P� SW� )� P� DS� )� P� RR� (eq.� 27)�
�The� first� term� for� total� switching� losses� from� Equation� 27�
�includes� the� losses� associated� with� turning� the� control�
�MOSFET� on� and� off� and� the� corresponding� overlap� in� drain�
�voltage� and� current.�
�D� V� OUT� ?� DISCHG� +�
�2�
�I� TRAN� @� L� OUT�
�C� OUT� @� V� IN� *� V� OUT�
�(eq.� 22)�
�P� SW� +� P� TON� )� P� TOFF�
�2�
�+� 1� @� I� OUT� @� V� IN� @� f� SW� @� t� ON� )� t� OFF�
�(eq.� 28)�
�http://onsemi.com�
�18�
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