Objective: Analyze the circuit shown in Figure 1.35(a). Assume circuit and diode parameters of VP S = 5 V, R = 5 kΩ, Vγ = 0.6 V, and vi = 0.1 sin ωt (V).

Question

Objective: Analyze the circuit shown in Figure 1.35(a). Assume circuit and diode parameters of [latex]V_{PS} = 5 V, R = 5 kΩ, V_{γ} = 0.6 V[/latex], and [latex]v_{i} = 0.1 sin ωt (V).[/latex]

Accepted Answer

Divide the analysis into two parts: the dc analysis and the ac analysis.
For the dc analysis, we set [latex]v_{i}[/latex] = 0 and then determine the dc quiescent current from Figure 1.36(a) as

[latex]I_{DQ} = \frac{V_{PS} - V_{\gamma}}{R } = \frac{5 - 0.6}{5 } = 0.88 mA[/latex]

The dc value of the output voltage is

[latex]V_{o} = I_{DQ} R = (0.88) (5) = 4.4 V[/latex]

For the ac analysis, we consider only the ac signals and parameters in the circuit in Figure 1.36(b). In other words, we effectively set [latex]V_{P S}=0[/latex]. The ac Kirchhoff volt-age law (KVL) equation becomes

[latex]v_{i} = i_{d} r_{d} + i_{d} R = i_{d}(r_{d} + R)[/latex]

where [latex]r_{d}[/latex] is again the small-signal diode diffusion resistance. From Equation (1.32), we have

[latex]r_{d} = \frac{1}{g_{d}} = \frac{V_{T}}{I_{DQ}}[/latex] (1.32)

[latex]r_{d} = \frac{V_{T}}{I_{DQ}} = \frac{0.026}{0.88} = 0.0295 kΩ[/latex]

The ac diode current is

[latex] i_{d} = \frac{v_{i}}{r_{d} + R} = \frac{0.1 sin \omega t}{0.0295 + 5} ⇒ 19.9 sin \omega t (\mu A)[/latex]

The ac component of the output voltage is

[latex]v_{o} = i_{d} R = 0.0995 sin \omega t (V)[/latex]

Comment: Throughout the text, we will divide the circuit analysis into a dc analysis and an ac analysis. To do so, we will use separate equivalent circuit models for each analysis

Question 1.11: Objective: Analyze the circuit shown in Figure 1.35(a). Assu...

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