Figure 3 (b) is the Miller equivalent circuit of Figure 3 (a). Derive a relationshipbetween the capacitances C, C: and C and state the main hypothesis for thevalıdity of the theorem.Figure 3 (a)Figure 3 (b)(b)The open loop gain A,, for a circuit is given by:AOL-8* JAR (C, +G1-erLR CC,)Calculate the resonant frequency fi and the gain Aot at Explain wha.you use and show the details of the calculation.(e)If C=Cy= IpF, g2.2 mS and R,5 k2, can you conclude that the circuitwould oscillate if the feedback loop were closed Justify your conclusion, 1Figure 4 (a) and Figure 4 (b) show two current mirrors based on MOSFETSMaMsFigure 4 (a)Figure 4 (b)(a)Derive a formula relating the input current I, to the output current I for thecurrent mirror of Figure 4 (a) stating any assumptions.(b)Draw the small-signal equivalent circuit for the current mirror of Figure 4 (a)and determine the output resistance RDerive a formula relating I and L for the circuit of Figure 4 (b) assuming that(c)Mi and Ma are identical, and that the length and width of the channel for thetransistor Ma are double respect to those of M3. State any assumption.

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Figure 3 (b) is the Miller equivalent circuit of Figure 3 (a). Derive a relationship between the capacitances Ci, C2 and C and state the main hypothesis for the valıdity of the theorem. (a) Figure 3 (a) Figure 3 (b)

Figure 3 (b) is the Miller equivalent circuit of Figure 3 (a). Derive a relationship between the capacitances Ci, C2 and C and state the main hypothesis for the valıdity of the theorem. (a) Figure 3 (a) Figure 3 (b)

Introductory Circuit Analysis (13th Edition)

13th Edition

ISBN:9780133923605

Author:Robert L. Boylestad

Publisher:Robert L. Boylestad

Chapter1: Introduction

Section: Chapter Questions

Problem 1P: Visit your local library (at school or home) and describe the extent to which it provides literature...

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