(a). Find VH, VL, and the power dissipation (for Vo-VL) for each circuit. +2.5 V +2.5 V 300 kΩ 200 ㏀ 4/1V (a). Find VH, VL, and the power dissipation (for Vo-VL) for each circuit. +2.5 V +2.5 V...
Find VL and VH for the inverter circuit below. Circle your final answer. 5) +2.5 V o VDD 1.81 Kn-100 HA/V2 To0.6 V VTo-0.85v Uo UI 2.22 2ф,-0.6 V Neglect short channel effects (Based on the symbol of the transistor, you should be able to find the VTO of ML and MS. Go to the MOSFET symbol lookup table. You should very clearly provide reasons for the state of the transistor (cutoff, triode, saturation) to get credit. Find VL and...
For the amplifier shown in the circuit below, find Vo/Vsig. Here Vt=1V and kn= 0.2 mA/V2. Approximate your answer to two decimal points +15 V 10 M2 7.5 kΩ 7る 10 k2 7) s1g in
3. Find V, from following circuit using Thevenin's theorem. 3 kΩ 6 kΩ 3 kΩ ' 4 mA 12V 12V 4. Find Vo from following circuit using Norton's theorem only. 12V 2 ΚΩ 3 mA ( 4 ΚΩ 4 ΚΩ 12 ΚΩ
(1 point) Problem 5 In the circuit below, Vl = 4 V. V2 = 0.9 V. and RL = 1 .2kS2. Find vo Vi- RL 0
Find V. in the circuit in the figure below using superposition. =3 mA 7 kΩ Ο 4 kg 7 kΩ Ta = 2V I h = 8V 4 ΚΩ 6 kΩ Ι ο Vo with only V, turned on Vo with only V6 turned on 75.6 V with only I, on = V =
Find the power dissipated in the 4 kΩ resistor 2. 6 V 24 V power
Use the note voltage method to find Vo in the circuit shown below: 300 1002 200 + 201, Vo 402 + 10V
3. Find V, from following circuit using Thevenin's theorem. 3 kΩ 6 kΩ: 3 kΩ 4 mA 12V ) 12V
Consider the circuit shown in (Figure 1). Suppose that R = 6 kΩ. Find the current io in the circuit by making a succession of appropriate source transformations. Express your answer to three significant figures and include the appropriate units. Work back through the circuit to find the magnitude of the power developed by the 120 V source. Express your answer to three significant figures and include the appropriate units. 40 kΩ Αν 4 kΩ 2.5 kΩ Αν +) 120...
4. In the circuit below, Vo = 120 V, w = 200 rad/s, L = 0.500 H, C = 6.00 pF, and R-3252 R V = V, sin(at) HE с (a) (3 pts) Calculate the rms current in the resistor. (b) (2 pts) Calculate the average power dissipated in the resistor. (e) (2 pts) You are able to vary the angular frequency w of the AC emf source in this circuit while keeping Vo = 120 V. For what value...