SLUAAN0 Application note

SLUAAN0 December 2022 TPS62933F

2.2 Equations for Maximum Output Current

In practice, the transformer has more or less leakage inductance, which determines the ramp rate of the current in the secondary winding to charge the output capacitor. The simplified current waveforms in Figure 2-3 shows its relationship with leakage inductance. With lower leakage inductance, the current ramps up quickly to a high value, charging the output capacitor quickly. With the leakage inductance increasing, the current rises slowly, which can result in less energy being supplied to the output capacitance and less output voltage. The higher leakage inductance is the higher peak charging current obtained in secondary winding under the same output power rate. A high negative current is reflected in the primary winding at the same time. Leakage inductance along with duty cycle impacts not only the output voltage regulation, but also limits the output power resulting from the minimum low-side sink current limit. Therefore, the leakage inductance must be minimized and the maximum duty cycle must be chosen carefully to mitigate their impacts.

Figure 2-3 Current Waveforms Affected by Leakage Inductance

The winding and output currents have a relationship as shown in Equation 3 and Equation 4 on one cycle average basis.

Equation 3.

I_{p r i} = I_{O U T 1}

Equation 4.

I_{s e c} = I_{O U T 2}

The magnetizing current in the transformer that combines the two windings current is identical to a buck converter. Therefore, the magnetizing current ripple can be derived as in Equation 5.

Equation 5.

∆ i_{m} = \frac{(V_{I N} - V_{O U T 1})}{L_{p r i} \times f_{S W}} \frac{V_{O U T 1}}{V_{I N}} = \frac{(V_{I N} - V_{O U T 1})}{L_{p r i}} \frac{D}{f_{S W}}

The positive primary winding and switching peak current during T_ON is given by Equation 6.

Equation 6.

i_{S W_p o s p k} = i_{p r i_p o s p k} = I_{O U T 1} + \frac{N_{2}}{N_{1}} I_{O U T 2} + \frac{∆ i_{m}}{2}

Implementing the principle of charge balance to the secondary output capacitor, the secondary winding peak current can be approximately derived as Equation 7 for a higher leakage case.

Considering the worst case, the following equation is derived based on having higher leakage.

Equation 7.

i_{s e c_p k} = \frac{2}{1 - D} I_{O U T 2}

Then the negative primary winding peak current can be derived as Equation 8.

Equation 8.

i_{p r i_n e g p k} = - \frac{N_{2}}{N_{1}} I_{s e c_p k} + i_{p r i_p o s p k} - ∆ i_{m} = - \frac{N_{2}}{N_{1}} I_{O U T 2} (\frac{1 + D}{1 - D}) - \frac{∆ i_{m}}{2} + I_{O U T 1}

In fact, we must ensure that during T_ON the positive primary winding peak current does not exceed the minimum high-side source current limit, ILIM_HS(min), and that during T_OFF, the negative primary winding peak current does not exceed the minimum low-side sink current limit, ILIM_LSSOC(min). Therefore the positive and negative primary winding peak current should meet that of Equation 9.

Equation 9.

\{\begin{matrix} i_{p r i_p o s p k} \leq I_{H S_L I M I T (m i n)} \\ |i_{p r i_n e g p k}| \leq I_{L S_N O C (m i n)} \end{matrix}