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�LM2595�
�x� t� on�
�[� Load�
�in�
�O�
�in�
�peak�
�2L� 1�
�V�
�O�
�x� 1.0� ,� and� f� osc� +� 52� kHz.�
�f� osc�
�where� t� on� +�
�in�
�O�
�ADDITIONAL� APPLICATIONS�
�Inverting� Regulator�
�An� inverting� buck� ?� boost� regulator� using� the� LM2595� is�
�shown� in� Figure� 23.� This� circuit� converts� a� positive� input�
�voltage� to� a� negative� output� voltage� with� a� common� ground�
�by� bootstrapping� the� regulators� ground� to� the� negative�
�output� voltage.� By� grounding� the� feedback� pin,� the� regulator�
�senses� the� inverted� output� voltage� and� regulates� it.�
�In� this� example� the� LM2595� is� used� to� generate� a� ?� 12� V�
�output.� The� maximum� input� voltage� in� this� case� cannot�
�exceed� +28� V� because� the� maximum� voltage� appearing�
�across� the� regulator� is� the� absolute� sum� of� the� input� and�
�output� voltages� and� this� must� be� limited� to� a� maximum� of�
�40� V.�
�This� circuit� configuration� is� able� to� deliver� approximately�
�0.25� A� to� the� output� when� the� input� voltage� is� 12� V� or� higher.�
�At� lighter� loads� the� minimum� input� voltage� required� drops�
�to� approximately� 4.7� V,� because� the� buck� ?� boost� regulator�
�topology� can� produce� an� output� voltage� that,� in� its� absolute�
�value,� is� either� greater� or� less� than� the� input� voltage.�
�Since� the� switch� currents� in� this� buck� ?� boost� configuration�
�are� higher� than� in� the� standard� buck� converter� topology,� the�
�available� output� current� is� lower.�
�This� type� of� buck� ?� boost� inverting� regulator� can� also�
�require� a� larger� amount� of� startup� input� current,� even� for�
�light� loads.� This� may� overload� an� input� power� source� with�
�a� current� limit� less� than� 1.0� A.�
�Such� an� amount� of� input� startup� current� is� needed� for� at�
�least� 2.0� ms� or� more.� The� actual� time� depends� on� the� output�
�voltage� and� size� of� the� output� capacitor.�
�Because� of� the� relatively� high� startup� currents� required� by�
�this� inverting� regulator� topology,� the� use� of� a� delayed� startup�
�or� an� undervoltage� lockout� circuit� is� recommended.�
�Using� a� delayed� startup� arrangement,� the� input� capacitor�
�can� charge� up� to� a� higher� voltage� before� the� switch� ?� mode�
�regulator� begins� to� operate.�
�The� high� input� current� needed� for� startup� is� now� partially�
�supplied� by� the� input� capacitor� C� in� .�
�It� has� been� already� mentioned� above,� that� in� some�
�situations,� the� delayed� startup� or� the� undervoltage� lockout�
�features� could� be� very� useful.� A� delayed� startup� circuit�
�applied� to� a� buck� ?� boost� converter� is� shown� in� Figure� 28.�
�Figure� 30� in� the� “Undervoltage� Lockout”� section� describes�
�an� undervoltage� lockout� feature� for� the� same� converter�
�topology.�
�Design� Recommendations:�
�The� inverting� regulator� operates� in� a� different� manner�
�than� the� buck� converter� and� so� a� different� design� procedure�
�has� to� be� used� to� select� the� inductor� L1� or� the� output�
�capacitor� C� out� .�
�The� output� capacitor� values� must� be� larger� than� what� is�
�normally� required� for� buck� converter� designs.� Low� input�
�voltages� or� high� output� currents� require� a� large� value� output�
�capacitor� (in� the� range� of� thousands� of� m� F).�
�The� recommended� range� of� inductor� values� for� the�
�inverting� converter� design� is� between� 68� m� H� and� 220� m� H.� To�
�select� an� inductor� with� an� appropriate� current� rating,� the�
�inductor� peak� current� has� to� be� calculated.�
�The� following� formula� is� used� to� obtain� the� peak� inductor�
�current:�
�I� (V� )� |V� |)� V�
�I� )�
�in�
�|V� |�
�V� )� |V� |�
�Under� normal� continuous� inductor� current� operating�
�conditions,� the� worst� case� occurs� when� V� in� is� minimal.�
�12� to� 40� V�
�Feedback�
�R4�
�Unregulated�
�DC� Input�
�+V� in�
�LM2595�
�L1�
�100� m� H�
�C� in�
�100� m� F/50� V�
�C1�
�0.1� m� F�
�ON/OFF�
�R2�
�47k�
�GND�
�D1�
�1N5819�
�R3�
�C� out�
�220� m� F�
�C� FF�
�?� 12� V� @� 0.25� A�
�Regulated�
�Output�
�Figure� 24.� Inverting� Buck� ?� Boost� Develops� with� Delayed� Startup�
�http://onsemi.com�
�18�
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