Buck Regulator Peak to Peak Ripple Current of Inductor Expression Derivation

In this topic, you study How to derive an expression for Peak to Peak ripple current and Condition of inductor maximum ripple current for Buck Regulator.


The buck regulator produces a lower average output voltage than the dc source input voltage. Let us assume large filter capacitance connected across the load so that output voltage remains almost constant. The Resistive load is considered.

Circuit diagram

The working of a buck regulator is explained using the circuit diagram as shown in Figure 1. The switch ${S_1}$ shown in the circuit diagram can be a conventional thyristor i.e., SCR, a GTO thyristor, a power transistor, or a MOSFET.

Circuit diagram of buck Regulator

Waveforms

The typical waveforms in the converter are shown in Figure 2.

Waveforms of buck Regulator.

Mode of Operation Interval 1: –

The time interval is 0  ≤  t  ≤  ${T_{ON}}$. The switch ${S_1}$ is turned on. The circuit diagram for Mode of Operation Interval 1 is shown in Figure 3 and the corresponding waveforms are shown in Figure 2.

Circuit diagram of buck Regulator when switch S1 ON

From the waveform of voltage across the inductor, as shown in Figure 2, the equation for the inductor voltage write as

\[{v_L}\hspace{0.1cm} =\hspace{0.1cm}{V_S}\hspace{0.1cm}-\hspace{0.1cm}{V_O}\hspace{1cm}….(1)\]

The general equation relates voltage across inductor and current passes through it as

\[{v_L} = L\frac{{d{i_L}}}{{dt}}\hspace{1cm}….(2)\]

Put Equation 2 in Equation 1 gives

\[L\frac{{d{i_L}}}{{dt}} = {V_S}\hspace{0.1cm} -\hspace{0.1cm} {V_O}\hspace{1cm}….(3)\]

The waveform for current passes through inductor L as shown in Figure 2, Integrate Equation 3 using maximum and minimum value of inductor current gives

\[\int\limits_{{I_{\min }}}^{{I_{\max }}} d {i_L} = \frac{{{V_S}\hspace{0.1cm} \hspace{0.1cm}- \hspace{0.1cm}{V_O}}}{L}\int\limits_0^{{T_{ON}}} d t\]

or

\[{I_{\max }}\hspace{0.1cm} -\hspace{0.1cm} {I_{\min }} = \frac{{{V_S}\hspace{0.1cm} – \hspace{0.1cm}{V_O}}}{L}.{T_{ON}}….(4)\]

Here $\Delta {I_L} = {\text{ }}{I_{\max }} – {I_{\min }}$ is the peak to peak ripple current of inductor L and hence Equation 4 can be write as

\[\Delta {I_L} = \frac{{{V_S}\hspace{0.1cm} – \hspace{0.1cm}{V_O}}}{L}.{T_{ON}}….(5)\]

The average output voltage for buck converter is given as

\[{V_O} = \alpha {V_S}….(6)\]

Also

\[{T_{ON}} = \alpha T = \frac{\alpha }{f}….(7)\]

Using Equation 5, Equation 6 and Equation 7 gives

\[\Delta {I_L} = \frac{{{V_S}\hspace{0.1cm}(1 – \alpha )}}{L}.\frac{\alpha }{f}….(8)\]

Equation 8 describes the peak to peak ripple current of inductor L in buck converter.

Condition for inductor maximum ripple current $\Delta {I_{L\max }}$

To get inductor maximum ripple current, differentiate Equation 8 with respect to duty cycle $\alpha$ and equate to zero,

\[\frac{{d\Delta {I_L}}}{{d\alpha }} = \frac{d}{{d\alpha }}\left[ {\frac{{{V_S}\hspace{0.1cm}(1 – \alpha )}}{L}.\frac{\alpha }{f}} \right] = 0…(9)\]

After solving Equation 9 gives $\alpha$ = 0.5 and put in Equation 8, so the inductor maximum ripple current is

\[\Delta {I_{L\max }} = \frac{{{V_S}\hspace{0.1cm}(1 – 0.5)}}{L}.\frac{{0.5}}{f}\]

or

\[\Delta {I_{L\max }} = \frac{{{V_S}}}{{4fL}}….(10)\]

Equation 10 describes the maximum ripple current of inductor L in buck converter.

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