Solution:
For solving this Op-Amp network, we will take help of Laplace Analysis and virtual ground concept.
For obtaining time domain equation of output, we will perform stepwise partial fraction expansion of output equation then take inverse Laplace Transform.
solve for part a & b only 13.46 PSPICE MULTISIM The op amp in the circuit...
63 k12 The Op Amp in the circuit shown in Fig. 1 is ideal, 30 k02 12 V 12 k 12 - 12 V + a. Calculate vo when Vg equals 4 V. b. Specify the range of values of vg so that the Op Amp operates in a linear mode. c. Assume that Vg equals 2 V and that the 63 K12 resistor is replaced with a variable resistor. What value of the variable resistor will cause the Op...
Assuming an ideal op-amp find the 3dB frequency of the circuit, if R1=2.3 K12, R2=13.1 KS2, R3=20 KS2, and C=5 nF. HA с R2 R1 Viljw) Vo R3 IH = Consider the above circuit with the component values: R1=2.3 KS2, R2=13.1 K12, R3=20 KS2 and C=5 nF. Find the DC gain of the circuit. Consider the above circuit with the component values: R1=13.1 K12, R2= 795.77 12, R3=20 K2, and C=100 nF. Find the angle of the transfer function in...
5.20 The op amp in the circuit shown in Fig, P5.20 is ideal, Calculate v, when v, equals 3 V b) Specify the range of values of vg so that the op amp operates in a linear mode. c) Assume that a's equals 5 V and that the 48n resistor is replaced with a variable resistor. What value of the variable resistor will cause the op amp to saturate? Figure P5.20 48 kΩ 15 kΩ 10 V 30 kΩ 10...
Assuming an ideal op-amp find the 3dB frequency of the circuit, if R1=2.4 KS2, R2=13.4 K2, R3=20 KS2, and C=5 nF. HH C R2 R1 + Vi(jw) Vo R3 IH Answer: rad/s Consider the above circuit with the component values: R1=2.4 K12, R2=13.4 KS, R3=20 KN and C=5 nF. Find the DC gain of the circuit. Answer: Consider the above circuit with the component values: R1=13.4 KS, R2= 795.77 12, R3=20 K12, and C=100 nF. Find the angle of the...
Solve by using basic node-voltage or superposition! The op amp in the circuit of Fig. P5.23 is ideal. a) What op amp circuit configuration is this? b) Find vo in terms of vs c) Find the range of values for such that does not saturate and the op amp remains in its linear region of operation. Figure P5.23 96 kΩ 24 kΩ 10 V 16 kΩ 10V 24 kΩ
Can you solve this exercise?
I) 20pts Given the following circuit oscillator. Assume an ideal Op Amp. R1 Vo Cl Vf R2 C2 R' I) a-What is the nature of this oscillator b- Identify on the circuit the amplifier circuit and the feedback circuit. 2) a- Express the gain of the amplifier A -Vo/Vf b- Express the feedback fraction B Vf/Vo -e-Find and draw the modulus and phase angle of B in terms of ω 3) a- Write the oscillation...
The op amp in the circuit in (Figure 1) is ideal. Suppose R-16 kΩ Part A What op amp circuit configuration is this? O This circuit is an example of the inverting amplifier o This circuit is an example of the non-inverting amplifier Submit Request Answer ▼ Part B Find vo in terms of vs Express your answer in terms of vs 07 Figure 1 of 1 > Submit Request Answer Part C 56 kΩ Find the minimum value of...
Problem 5.36 PSpice|Multisim
The signal voltage vg in the circuit shown in
(Figure 1) is described by the following equations:
vg=0, t≤0,
vg=4cos(π4t)V,
0≤t≤∞.
Problem 5.36 PSpicelMultisim The signal voltage vg in the circuit shown in (Figure 1) is described by the following equations: v 0, t S0, va 4 cos T t V, 0 S t S oo. Figure 1 of 1 20 kn 60 kn 10V 1.8 km 100 V vo 5 kn 5.4 km Part A Choose...
Part A only please
Part A - Analysis of an op-amp circuit using a realistic circuit model Learning Goal For an ideal op-amp, we assume that the current flowing into the More realistically, calculatei in the circuit given when R1 9.6 k, R2 -4.2 kQ R3-95 ko. V,-2920 μν , and Voe-15 V . Assume that the op-amp can be modeled with an input resistance of Ri-6.00 M, an output resistance of Ro- 9.5 kS2, and an open-loop gain of...
5.4 The op amp in the circuit of Fig. P5.19 is ideal. a) What op amp circuit configuration is this? b) Find in terms of us . c) Find the range of values for e, such that e, does nol saturate and thc op amp remains in its lincar region of operation. Figure P5.19 40 kΩ 10 V 12 kΩ 10 V 1 S1DE