For given V = 10 V, i = 2 A, v 2 = 3 V, v 3 = 3 V, Io = 4 A, and α = 0.5 in the figure shown, determine the power (p) in watts (W) that is given by the independent voltage source:
Question # 3 R1 10 1A R2 10Ω V2 10V For the circuit shown in the above figure: 1) Calculate the voltage across the current source. 2) Calculate the current in the voltage source. 3) Determine which source is discharging (delivering power) and which is charging (receiving power). Prove that the power is balanced in the above circuit. Calculate the energy dissipated by the resistor R2 (10 Ω) in 20 seconds. 4)
In the following circuit: Vg=24V,ix=2A,β=1.5,V1=12V,V3=3V,V4=4V Find V: Find Vx: Find the power consumed in element 1: Find the power consumed in element 2: Find the power consumed in element 3: Find the power consumed in element 4: Find the power consumed in the independent voltage source: Find the power consumed in the not independent current source: 1 + 1 V4 + . + I + L V1 1
1. Design the common source amplifier shown in Figure 1 with Ip- 1 mA and Vo 5 V Determine V2 and Ri. The MOSFET characteristics are V-50 V, k-0.093 A/V, gate-to- drain capacitance, Cd 40 pF, and Vi 1.1 V. (For PSpice simulations, use parameters: VTO. 1.1 LAMBDA-002 KP-0.093 CGDO-4E-7 w=100u L-I00u for the 2N7000 MOSFET.) a. Determine the gain and gm of the circuit b. Determine the low-frequency (high-pass response) poles of the common-source amplifier due to the coupling...
V.+w Operation in the triode reglon Condition v. e Wov 20 Vos uov os os-V (2) p V, so onl+Pala Characteristics Same relationships as for NMOS trasistos tCharacteristics: a CuGs- V,) ®os- } ip.C Replace .and NA with p,,and Nprespectively. V.V V, and yare negative. 2 wov ps For vos 2( -V) e Conditions for operation in the triode region ip lvi Q1. (10 points) For the following configuration of the given figure below, with the following parameters: VDD= +10...
Problem 03.020 Nodal analysis: Independent voltage source and current dependent voltage source In the circuit given below, R-25 ?. Find v1, v2, and v3 using nodal analysis. 240 V 20i 20 ? 3 li 40? ": 10? The value of vy in the circuit is The value of v2 in the circuit is| |V The value of vy in the circuit isv V.
In Figure 3 shown, V1 = 100 millivolts. Further, R1 = 1Kohm, R2 = 10 Kohm, R3 = 5 Kohm, R4= 5 Kohm, R5 = 10 Kohm and RL = 1Kohm. (i) Determine the amplified output voltage V2 of the op-amp (of open-loop gain A) in circuit shown in Figure 3. (ii) Suppose this amplified voltage V2 becomes the source voltage to a passive circuit as illustrated in Figure.3. Find Thevenin’s equivalent circuit looking at the terminal XY. Hence, determine...
The voltage v(t) shown in the accompanying Figure (a) is given by the graph shown in the accompanying Figure (b). If iL(0) =0, answer the following questions: (a) How much energy is stored in the inductor at t = 2 s? (b) How much power is supplied by the source at t = 3 s? (c) What is i(t = 7 s)? and (d) How much power is absorbed by the inductor at t = 2 s? Please show all...
I need to know how to answer the first one, thanks in advance! 1. Consider the circuit shown in Fig. 1. p(t) = - 2 + 2t watts <t<sec., (a) Determine the equations for the voltage v(t), and the current i(t). (6) Sketch y(t), and p(t). (c) Determine the total energy absorbed by the circuit eleme 2. Determine the value of the current IA and the voltage V, in the circuit shown in Fig. 2. Vo= 12V. 3. Consider the...
Why did my working not work? Where is my logic wrong The actual solution, Ad=(1/2)(gm)(ro) Question 3 Determine the differential gain a MOSFET differential amplifier shown in Figure 3 biased by 0.2mA/V, Cx 0.1mA/V2, A = 0.1, VDD 10V and Vss -10V mA, (W/L)1,2=100, (W/L)3,4=2, HnCox a current source of I = VDD M3 Vo M2 V2 M1 V1 Vss Elee3403, Ture 3 fo, o Vour to,sm -m ( Vzs2 m, Jmy Vifa) 2 1ms .-[ 3m, Vinfals Vout Question...
egg Study I : 2. Three Resist X ion Consider the circuit as shown below. tion R-60 Use Kirchoff's rules to calculate (a) the current through each resistor: L.e (b) the power suppied by each DC source ie v1: (P1] watts V2: (P2] Watts v3: [P3] Watts and (c) the power dissipated in each resistor: lie Ri: IPR1] Watts R2: [PR2) Watts R3: PR3] watts R4: [PR4] watts