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Consider the circuit below with a feedback resistance of RF = 82 KΩ and a drain resistance of RD = 5 KΩ. The small-signal model of the nMOS transistor is gm = 3 mS and ro = 10 KΩ. a. Find the input impedance RIN using the Miller approximation. b. Find the input impedance without using the Miller approximation. c. Find the output impedance Rout using the Miller approximation. d. Find the output impedance without using the Miller approximation.

Consider the circuit below with a feedback resistance of RF = 82 KΩ and a drain resistance of RD = 5 KΩ. The small-signal model of the nMOS transistor is gm = 3 mS and ro = 10 KΩ. a. Find the input impedance RIN using the Miller approximation. b. Find the input impedance without using the Miller approximation. c. Find the output impedance Rout using the Miller approximation. d. Find the output impedance without using the Miller approximation.

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Consider the circuit below with a feedback resistance of R F = 82 K Ω and a drain resistance of R D = 5 K Ω . The small-signal model of the nMOS transistor is g m = 3 mS and r o = 10 K Ω . a. Find the input impedance R I N using the Miller approximation. b. Find the input impedance without using the Miller approximation. c. Find the output impedance Rout using the Miller approximation. d. Find the output impedance without using the Miller approximation.

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