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| 型号: | TC110303ECTTR |
| 厂商: | Microchip Technology |
| 文件页数: | 6/16页 |
| 文件大小: | 0K |
| 描述: | IC REG CTRLR BST PWM SOT23A-5 |
| 标准包装: | 3,000 |
| PWM 型: | 控制器 |
| 输出数: | 1 |
| 频率 - 最大: | 345kHz |
| 占空比: | 92% |
| 电源电压: | 2 V ~ 10 V |
| 降压: | 无 |
| 升压: | 是 |
| 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 ~ 85°C |
| 封装/外壳: | SC-74A,SOT-753 |
| 包装: | 带卷 (TR) |
��
�
�TC110�
�3.5�
�Output� Capacitor�
�Care� must� be� taken� to� ensure� the� inductor� can� handle�
�The� effective� series� resistance� of� the� output� capacitor�
�directly� affects� the� amplitude� of� the� output� voltage�
�ripple.� (The� product� of� the� peak� inductor� current� and�
�the� ESR� determines� output� ripple� amplitude.)� There-�
�fore,� a� capacitor� with� the� lowest� possible� ESR� should�
�be� selected.� Smaller� capacitors� are� acceptable� for� light�
�loads� or� in� applications� where� ripple� is� not� a� concern.�
�The� Sprague� 595D� series� of� tantalum� capacitors� are�
�among� the� smallest� of� all� low� ESR� surface� mount�
�capacitors� available.� Table� 4-1� lists� suggested�
�components� and� suppliers.�
�peak� switching� currents,� which� can� be� several� times�
�load� currents.� Exceeding� rated� peak� current� will� result�
�in� core� saturation� and� loss� of� inductance.� The� inductor�
�should� be� selected� to� withstand� currents� greater� than�
�I� PK� (Equation� 3-10)� without� saturating.�
�Calculating� the� peak� inductor� current� is� straightforward.�
�Inductor� current� consists� of� an� AC� (sawtooth)� current�
�centered� on� an� average� DC� current� (i.e.,� input� current).�
�Equation� 3-6� calculates� the� average� DC� current.� Note�
�that� minimum� input� voltage� and� maximum� load� current�
�values� should� be� used:�
�3.6� Inductor� Selection�
�Selecting� the� proper� inductor� value� is� a� trade-off�
�between� physical� size� and� power� conversion� require-�
�EQUATION� 3-4:�
�Input� Power� =�
�Output Power�
�Efficiency�
�ments.� Lower� value� inductors� cost� less,� but� result� in�
�higher� ripple� current� and� core� losses.� They� are� also�
�more� prone� to� saturate� since� the� coil� current� ramps�
�faster� and� could� overshoot� the� desired� peak� value.� This�
�Re-writing� in� terms� of� input� and� output� currents� and�
�voltages:�
�EQUATION� 3-5:�
�not� only� reduces� efficiency,� but� could� also� cause� the�
�current� rating� of� the� external� components� to� be�
�exceeded.� Larger� inductor� values� reduce� both� ripple�
�current� and� core� losses,� but� are� larger� in� physical� size�
�and� tend� to� increase� the� start-up� time� slightly.�
�(V� IN� MIN� )� (I� IN� MAX� )� =�
�Solving� for� input� curent:�
�EQUATION� 3-6:�
�(V� OUT� MAX� ) (I� OUT� MAX� )�
�Efficiency�
�A� 22� μ� H� inductor� is� recommended� for� the� 300kHz�
�versions� and� a� 47� μ� H� inductor� is� recommended� for� the�
�100kHz� versions.� Inductors� with� a� ferrite� core� (or�
�I� IN� MAX� =�
�(V� OUT� MAX� )(I� OUT� MAX� )�
�(Efficiency)(V� IN� MAX� )�
�equivalent)� are� also� recommended.� For� highest�
�efficiency,� use� inductors� with� a� low� DC� resistance� (less�
�than� 20� m� ?� ).�
�The� inductor� value� directly� affects� the� output� ripple�
�voltage.� Equation� 3-3� is� derived� as� shown� below,� and�
�can� be� used� to� calculate� an� inductor� value,� given� the�
�The� sawtooth� current� is� centered� on� the� DC� current�
�level;� swinging� equally� above� and� below� the� DC� current�
�calculated� in� Equation� 3-6.� The� peak� inductor� current� is�
�the� sum� of� the� DC� current� plus� half� the� AC� current.�
�Note� that� minimum� input� voltage� should� be� used� when�
�calculating� the� AC� inductor� current� (Equation� 3-9).�
�required� output� ripple� voltage� and� output� capacitor�
�series� resistance:�
�EQUATION� 3-1:�
�EQUATION� 3-7:�
�V� =�
�L(di)�
�dt�
�V� RIPPLE� ≈� ESR(di)�
�EQUATION� 3-8:�
�where� ESR� is� the� equivalent� series� resistance� of� the�
�output� filter� capacitor,� and� V� RIPPLE� is� in� volts.�
�Expressing� di� in� terms� of� switch� ON� resistance� and�
�time:�
�EQUATION� 3-9:�
�di� =�
�V(dt)�
�dt�
�[(V� IN� MIN� –� V� SW� )t� ON� ]�
�EQUATION� 3-2:�
�V� RIPPLE� ≈�
�Solving� for� L:�
�EQUATION� 3-3:�
�ESR [(V� IN� – V� SW� )t� ON� ]�
�L�
�di� =�
�L�
�where:� V� SW� =� V� CESAT� of� the� switch� (note� if� a� CMOS�
�switch� is� used� substitute� V� CESAT� for� r� DS� ON� x� I� IN� )�
�Combining� the� DC� current� calculated� in� Equation� 3-6,�
�with� half� the� peak� AC� current� calculated� in� Equation� 3-�
�L�
�≈�
�ESR [(V� IN� – V� SW� )t� ON� ]�
�V� RIPPLE�
�9,� the� peak� inductor� current� is� given� by:�
�EQUATION� 3-10:�
�I� PK� =� I� IN� MAX� +� 0.5(di)�
�DS21355B-page� 6�
�2002� Microchip� Technology� Inc.�
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