The calculation of the Output Capacitor Value in all the Primary converters is based on : Select one:a.Capacitor Charge Balance Equationb.Power Balance equationsc.Inductor Voltage Balance Equationd.Energy Balance Equations

The calculation of the Output Capacitor Value in all the Primary converters is based on

The calculation of the Input-Output relationship in all the Primary converters is based on : Select one:a.Inductor Volt-sec balance equationb.Capacitor Volt-sec balance equationc.Energy Balance Equationsd.Power Balance equations

A boost converter has the following specifications: Vin = 36 V, Vo= constant = 108 V, Fs = 51 kHz, and the output power may vary with a range of Po(range) = 107 W to 200 W. Assuming that the converter is ideal, calculate: a) the smallest value of the inductor, L, in order to have continuous current b) the value of the output filter capacitor, C, so that the output voltage ripple to be lower than 0.5 V. Use the inductance you calculated in part (a)

A Buck converter is charging a battery, with the following specifications:  (Consider ideal switch and ideal diode) a)  Vin = 25 V, Vb = 8 V, RL=20 Ω,  b)  fs= 100kHz (switching frequency), d=0.4 (duty ratio) c) Peak to peak inductor current ripple is 10% of the output current. d) Output voltage ripple across capacitor is 5% of the output voltage.

A Buck converter is charging a battery, with the following specifications:  (Consider ideal switch and ideal diode) a)  Vin = 25 V, Vb = 8 V, RL=20 Ω,  b)  fs= 100kHz (switching frequency), d=0.4 (duty ratio) c) Peak to peak inductor current ripple is 10% of the output current. d) Output voltage ripple across capacitor is 5% of the output voltage. What is the Capacitor C from the below Circuit in