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Given the mosfet parameters in the common source amplifier shown: For NMOS: For PMOS: VTH = 0.4V VTH = -0.4V unCox = 200uA/V2 upCox = 100uA/V2 = 0.1V-1 = 0.2V-1 a) Compute VSG2 and ID. Don't ignore the effect of Ans. 0.5V and 9.6uA b) Compute V1. Don't ignore the effect of Ans. 0.45V c) Compute Rout (look up the equation) Ans. 347kohms d) Compute Av, (look up the equation) Ans. -133V/V

Given the mosfet parameters in the common source amplifier shown: For NMOS: For PMOS: VTH = 0.4V VTH = -0.4V unCox = 200uA/V2 upCox = 100uA/V2 = 0.1V-1 = 0.2V-1 a) Compute VSG2 and ID. Don't ignore the effect of Ans. 0.5V and 9.6uA b) Compute V1. Don't ignore the effect of Ans. 0.45V c) Compute Rout (look up the equation) Ans. 347kohms d) Compute Av, (look up the equation) Ans. -133V/V

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Given the mosfet parameters in the common source amplifier shown: For NMOS: For PMOS: VTH = 0.4V VTH = -0.4V unCox = 200uA/V2 upCox = 100uA/V2 = 0.1V-1 = 0.2V-1 a) Compute VSG2 and ID. Don't ignore the effect of Ans. 0.5V and 9.6uA b) Compute V1. Don't ignore the effect of Ans. 0.45V c) Compute Rout (look up the equation) Ans. 347kohms d) Compute Av, (look up the equation) Ans. -133V/V

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