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参数资料
| 型号: | LTC1922IG-1#TR |
| 厂商: | Linear Technology |
| 文件页数: | 9/24页 |
| 文件大小: | 0K |
| 描述: | IC REG CTRLR ISO PWM 20-SSOP |
| 标准包装: | 1,800 |
| PWM 型: | 电流/电压模式 |
| 输出数: | 1 |
| 频率 - 最大: | 1MHz |
| 占空比: | 99% |
| 电源电压: | 3.8 V ~ 10.3 V |
| 降压: | 无 |
| 升压: | 无 |
| 回扫: | 无 |
| 反相: | 无 |
| 倍增器: | 无 |
| 除法器: | 无 |
| Cuk: | 无 |
| 隔离: | 是 |
| 工作温度: | -40°C ~ 85°C |
| 封装/外壳: | 20-SSOP(0.209",5.30mm 宽) |
| 包装: | 带卷 (TR) |
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�
�LTC1922-1�
�OPERATIO�
�Each� full� cycle� of� the� transformer� has� two� distinct� periods�
�in� which� power� is� delivered� to� the� output,� and� two� “free-�
�wheeling”� periods.� The� two� sides� of� the� external� bridge�
�have� fundamentally� different� operating� characteristics� that�
�become� important� when� designing� for� ZVS� over� a� wide�
�load� current� range.� The� left� bridge� leg� is� referred� to� as� the�
�“passive”� leg,� while� the� right� leg� is� referred� to� as� the�
�“active”� leg.� The� following� descriptions� provide� insight� as�
�to� why� these� differences� exist.�
�State� 1� (Power� Pulse� 1)�
�Referring� to� Figure� 1,� State� 1� begins� with� MA,� MD� and� MF�
�“ON”� and� MB,� MC� and� ME� “OFF.”� During� the� simultaneous�
�conduction� of� MA� and� MD,� the� full� input� voltage� is� applied�
�across� the� transformer� primary� winding� and� following� the�
�dot� convention,� V� IN� /N� is� applied� to� the� left� side� of� LO1�
�allowing� current� to� increase� in� LO1.� The� primary� current�
�during� this� period� is� approximately� equal� to� the� output�
�inductor� current� (LO1)� divided� by� the� transformer� turns�
�ratio� plus� the� transformer� magnetizing� current� (V� IN� ?� t� ON� /�
�L� MAG� ).� MD� turns� off� and� ME� turns� on� at� the� end� of� State� 1.�
�State� 2� (Active� Transition� and� Freewheel� Interval)�
�MD� turns� off� when� the� phase� modulator� comparator�
�transitions.� At� this� instant,� the� voltage� on� the� MD/MC�
�junction� begins� to� rise� towards� the� applied� input� voltage�
�(V� IN� ).� The� transformer’s� magnetizing� current� and� the�
�reflected� output� inductor� current� propels� this� action.� The�
�slew� rate� is� limited� by� MOSFET� MC� and� MD’s� output�
�capacitance� (C� OSS� ),� snubbing� capacitance� and� the� trans-�
�former� interwinding� capacitance.� The� voltage� transition�
�on� the� active� leg� from� the� ground� reference� point� to� V� IN� will�
�always� occur,� independent� of� load� current� as� long� as�
�energy� in� the� transformer’s� magnetizing� and� leakage� in-�
�ductance� is� greater� than� the� capacitive� energy.� That� is,�
�1/2� ?� (L� M� +� L� I� )� ?� I� M2� >� 1/2� ?� 2� ?� C� OSS� ?� V� IN2� —� the� worst� case�
�occurs� when� the� load� current� is� zero.� This� condition� is�
�usually� easy� to� meet.� The� magnetizing� current� is� virtually�
�constant� during� this� transition� because� the� magnetizing�
�inductance� has� positive� voltage� applied� across� it� through-�
�out� the� low� to� high� transition.� Since� the� leg� is� actively�
�driven� by� this� “current� source,”� it� is� called� the� active� or�
�risen� to� V� IN� ,� MOSFET� MC� is� switched� on� by� the� LTC1922-�
�1� DirectSense� circuitry.� The� primary� current� now� flows�
�through� the� two� high� side� MOSFETs� (MA� and� MC).� The�
�transformer’s� secondary� windings� are� electrically� shorted�
�at� this� time� since� both� ME� and� MF� are� “ON”.� As� long� as�
�positive� current� flows� in� LO1� and� LO2,� the� transformer�
�primary� (magnetizing)� inductance� is� also� shorted� through�
�normal� transformer� action.� MA� and� MF� turn� off� at� the� end�
�of� State� 2.�
�State� 3� (Passive� Transition)�
�MA� turns� off� when� the� oscillator� timing� period� ends,� i.e.,�
�the� clock� pulse� toggles� the� internal� flip-flop.� At� the� instant�
�MA� turns� off,� the� voltage� on� the� MA/MB� junction� begins� to�
�decay� towards� the� lower� supply� (GND).� The� energy� avail-�
�able� to� drive� this� transition� is� limited� to� the� primary� leakage�
�inductance� and� added� commutating� inductance� which�
�have� (I� MAG� +� I� OUT� /2N)� flowing� through� them� initially.� The�
�magnetizing� and� output� inductors� don’t� contribute� any�
�energy� because� they� are� effectively� shorted� as� mentioned�
�previously,� significantly� reducing� the� available� energy.�
�This� is� the� major� difference� between� the� active� and� passive�
�transitions.� If� the� energy� stored� in� the� leakage� and� com-�
�mutating� inductance� is� greater� than� the� capacitive� energy,�
�the� transition� will� be� completed� successfully.� During� the�
�transition,� an� increasing� reverse� voltage� is� applied� to� the�
�leakage� and� commutating� inductances,� helping� the� overall�
�primary� current� to� decay.� The� inductive� energy� is� thus�
�resonantly� transferred� to� the� capacitive� elements,� hence,�
�the� term� passive� or� resonant� transition.� Assuming� there� is�
�sufficient� inductive� energy� to� propel� the� bridge� leg� to�
�GND,� the� time� required� will� be� approximately� equal� to�
�π� ?� √� LC/2.� When� the� voltage� on� the� passive� leg� nears� GND,�
�MOSFET� MB� is� commanded� “ON”� by� the� LTC1922-1�
�DirectSense� circuitry.� Current� continues� to� increase� in� the�
�leakage� and� external� series� inductance� which� is� opposite�
�in� polarity� to� the� reflected� output� inductor� current.� When�
�this� current� is� equal� in� magnitude� to� the� reflected� output�
�current,� the� primary� current� reverses� direction,� the� oppo-�
�site� secondary� winding� becomes� forward� biased� and� a�
�new� power� pulse� is� initiated.� The� time� required� for� the�
�current� reversal� reduces� the� effective� maximum� duty� cycle�
�linear� transition.� When� the� voltage� on� the� active� leg� has�
�9�
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