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Question 1 Find Vo in the circuit in the figure below using superposition. /a 2 mA 9 ks2 7 k2 5 k2 0 Vo with only Va turned on H with only Vb turned on Vo with only Ia on
Problem 2: Consider the circuit shown in Figure 2. VCC-15V, R1-100 K2, R2-47 K2, RE-3.9K, Draw the small signal model Compute rel and re2. Rin1 and Rin2 as (shown in the circuit) . Find the overall gain. Using OCTC approach compute the high frequency time constants, given Cr-Cμ-1 pF. Stage 2 Load Source Stage 1 Re Ri RI 0 R, Ri Ri Figure 2 Problem 2: Consider the circuit shown in Figure 2. VCC-15V, R1-100 K2, R2-47 K2, RE-3.9K, Draw...
Smar On M (2) Find the o ut put voltage vo for the following circuit: Excha 100 kΩ 20 k2 10V ( 0 Smar On M (2) Find the o ut put voltage vo for the following circuit: Excha 100 kΩ 20 k2 10V ( 0
1. Find the ratio of the output voltage to the input voltage, Vo/Vin, in the circuit shown. State your assumptions in using the ideal op-amp model. 15 k2 Vin 2. Find the output voltage Vo in the circuit shown assuming an ideal op-amp. State your assumptions in using the ideal op-amp model 15 k12 Vo . Find the voltage Vx and the output voltage Vo in the circuit shown assuming ideal op-amp 3 k2 1 V 6 kn 12 k2
Problem 2: Find vo and io in the circuit of figure below 3Ω 1Ω 1o Problem 2: Find vo and io in the circuit of figure below 3Ω 1Ω 1o
For the circuit below, voltage vo is: 20 k2 ww 2 k2 + 3 kS2 1 V Da-1.5 b.0.1 OC-10 Od.10 For the circuit in Fig. 5.40, current iy is: 20 k2 wW 2 k2 1 V 3 kQ a. 1 mA b.500 HA C. 200 HA Od.0.1 HA OIO+O
2. H(s)Vo/v, for the circuit shown in Figure P9-12. 1 ΜΩ Figure P9-12 2. H(s)Vo/v, for the circuit shown in Figure P9-12. 1 ΜΩ Figure P9-12
(20 pts) Use Thevenin's theorem to find Vo in the circuit. 6 V 2 k2 2 I Ik() 1 k12 0 (20 pts) Use Thevenin's theorem to find Vo in the circuit. 6 V 2 k2 2 I Ik() 1 k12 0
2) For the circuit shown in Figure 2, find Vo using the node voltage method. kn kn Ma 0
3) For the circuit shown in figure 03, the initial condition is zero. (a) Find Vo(s) using Thevenin's theorem (b) Apply initial and final value theorem to find Vo(t-0) and Volt-M) from Vo(s) (c) Obtain Volt) and from that find the values of Volt = 0) and vdt→ again Figure 03