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An NMOS transistor's iv curves are shown below with VT = 3 V and k = 10 mA/V2. In the active region, its drain current is ID = k(VGS − VT)2. a. If VGS = 6 V, then find ID. b. Now, assume ID = 50 mA. If VDD = 10 V and VDS = 5 V, find the drain resistor value, RD. c. Now, let VGS = 5 V, VT = 3 V, VDD = 10 V and RD = 125 ohms, draw a loadline on the iv curve above and indicate the operating point with a dot. Specify the operating point: ID = mA VDS = V

An NMOS transistor's iv curves are shown below with VT = 3 V and k = 10 mA/V2. In the active region, its drain current is ID = k(VGS − VT)2. a. If VGS = 6 V, then find ID. b. Now, assume ID = 50 mA. If VDD = 10 V and VDS = 5 V, find the drain resistor value, RD. c. Now, let VGS = 5 V, VT = 3 V, VDD = 10 V and RD = 125 ohms, draw a loadline on the iv curve above and indicate the operating point with a dot. Specify the operating point: ID = mA VDS = V

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An NMOS transistor's i v curves are shown below with V T = 3 V and k = 10 m A / V 2 . In the active region, its drain current is I D = k ( V G S V T ) 2 . a. If V G S = 6 V , then find I D . b. Now, assume I D = 50 m A . If V D D = 10 V and V D S = 5 V , find the drain resistor value, R D . c. Now, let V G S = 5 V , V T = 3 V , V D D = 10 V and R D = 125 ohms, draw a loadline on the iv curve above and indicate the operating point with a dot. Specify the operating point:
I D =
mA V D S = V

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