Question 7.SP.13: For the JFET drain characteristics of Fig. 4-2(a), take vDS ......

Schaum’s Outline of Electronic Devices and Circuits [1089587]

For the JFET drain characteristics of Fig. 4-2(a), take $v_{DS}$ as the dependent variable [so that $v_{DS} = f (v_{GS}, i_D)$ ] and derive the voltage-source small-signal model.

4.2

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For small variations about a Q point, the chain rule gives
$v_{d s} = \Delta v_{D S} \approx d v_{D S} = {\frac{\partial v_{D S}}{\partial v_{G S}}}\bigg|_{Q} v_{g s} + {\frac{\partial v_{D S}}{\partial i_{D}}}\bigg|_{Q}\bigg. i_d$ (1)

Now we may define
$\left.{\frac{\partial v_{D S}}{\partial v_{G S}}}\right|_{Q} = \mu \qquad {\mathrm{and}} \qquad \left.{\frac{\partial v_{D S}}{\partial i_{D}}}\right|_{Q} = r_{ds}$

If the JFET operates in the pinchoff region, then gate current is negligible and (1) is satisfied by the equivalent circuit of Fig. 7-1(b).

7.1

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