An isolated buck converter is a synchronous buck converter with the inductor replaced by a coupled inductor or flyback-type transformer. The primary output is still regulated as in a sync buck. The secondary output is generated by a diode rectifying the secondary winding. Figure 2-1 shows an isolated buck converter with two outputs.

Figure 2-2 shows typical isolated buck operating waveforms, where V_IN is the input voltage of the converter, V_OUT1 is the primary output voltage and V_OUT2 is the secondary output voltage. During T_ON, the high-side MOSFET Q₁ is on and the voltage stress of the low side FET Q₂ is the input voltage, V_IN. The rectifier diode D₁ is turned off, because the reflected voltage across the secondary winding is negative and its voltage stress is N×(V_IN-V_OUT1)+V_OUT2. The isolated output capacitor C_OUT2 is discharged, supplying the load current, and the primary side behaves identical to a buck regulator. During T_OFF, the low-side MOSFET is on, and the reflected voltage on the secondary winding turns positive, forcing the diode forward conducting. The current in the primary winding splits into two parts: one part continues to supply the primary output (the magnetizing current, i_m, similar to a buck converter inductor current), the other part starts to flow to the secondary output. The secondary current waveform is determined by the load, leakage inductance, and output capacitance.

The primary output voltage is the same as a buck converter and is given by Equation 1:

The secondary output voltage is given by Equation 2:

where

• N₁ and N₂ are the turns of the primary winding and secondary winding
• V_F is the forward voltage drop of the secondary rectifier diode