Calculate the ripple factor for the half-wave rectifier of Example 2.10 (a) without a filter and (b) with a shunt capacitor filter as in Fig. 2-15(a).

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Accepted Answer

(a) For the circuit of Example 2.10,
[latex]F_r = \frac{Δv_L}{V_{L0}} = \frac{V_{Lm}}{V_{Lm/π}} = π ≈ 3.14[/latex]

(b) The capacitor in Fig. 2-15(a) stores energy while the diode allows current to flow, and delivers energy to the load when current flow is blocked. The actual load voltage [latex]v_L[/latex] that results with the filter inserted is sketched in Fig. 2-15(b), for which we assume that [latex]v_S = V_{Sm} \sin ωt[/latex] and [latex]D[/latex] is an ideal diode. For [latex]0 < t ≤ t_1, D[/latex] is forward-biased and capacitor [latex]C[/latex] charges to the value [latex]V_{Sm}[/latex]. For [latex]t_1 < t ≤ t_2, v_S[/latex] is less than [latex]v_L[/latex], reverse-biasing [latex]D[/latex] and causing it to act as an open circuit. During this interval the capacitor is discharging through the load [latex]R_L[/latex], giving
[latex]v_L = V_{Sm} e^{-(t - t_1)/R_LC} \quad (t_1 < t ≤ t_2)[/latex] (2.9)

Over the interval [latex]t_2 < t ≤ t_2 + δ, v_S[/latex] forward-biases diode [latex]D[/latex] and again charges the capacitor to [latex]V_{Sm}[/latex]. Then [latex]v_S[/latex] falls below the value of [latex]v_L[/latex] and another discharge cycle identical to the first occurs.
Obviously, if the time constant [latex]R_{L}C[/latex] is large enough compared to [latex]T[/latex] to result in a decay like that indicated in Fig. 2-15(b), a major reduction in [latex]Δv_L[/latex] and a major increase in [latex]V_{L0}[/latex] will have been achieved, relative to the unfiltered rectifier. The introduction of two quite reasonable approximations leads to simple formulas for [latex]Δ{v_L}[/latex] and [latex]V_{L0}[/latex], and hence for [latex]F_r[/latex], that are sufficiently accurate for design and analysis work:
1. If [latex]Δ{v_L}[/latex] is to be small, then [latex]δ → 0[/latex] in Fig. 2-15(b) and [latex]t_2 - t_1 ≈ T[/latex].
2. If [latex]Δ{v_L}[/latex] is small enough, then (2.9) can be represented over the interval [latex]t_1 < t ≤ t_2[/latex] by a straight line with a slope of magnitude [latex]V_{Sm}/R_LC[/latex].
The dashed line labeled ‘‘Approximate [latex]v_L[/latex]’’ in Fig. 2-15(b) implements these two approximations. From right triangle abc,
[latex]\frac{Δ{v_L}}{T} = \frac{V_{Sm}}{R_LC} \quad ext{or} \quad Δ{v_L} = \frac{V_{Sm}}{fR_LC}[/latex]

where [latex]f[/latex] is the frequency of [latex]v_S[/latex]. Since, under this approximation,
[latex]V_{L0} = V_{Sm} - \frac{1}{2} Δ{v_L}[/latex]

and [latex]R_LC/T = fR_LC[/latex] is presumed large,
[latex]F_r = \frac{Δv_L}{V_{L0}} = \frac{2}{2fR_L C - 1} ≈ \frac{1}{fR_L C}[/latex] (2.10)

Question 2.13: Calculate the ripple factor for the half-wave rectifier of E......

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