2. Obtain the transfer function Vo(s)/V (S) for the op-amp shown below. Hint use complex impedances...
Determine the complex transfer function T(s) = V/V; for the circuit shown below. Specify it as a function of the complex frequency, s, and the symbols for the resistors and capacitor. On the attached graph, plot the magnitude of the complex transfer function T(jw) in decibels as a function of the frequency f of the source as f varies from 1 Hz to 1 MHz. Assume that the op amp is ideal. Use as the numerical values for the resistors...
(i) Find the transfer function G(s) = Vo(s)/Vi(s) of this system using electrical impedances. Express the transfer function as a ratio of two s polynomials. (ii) Plot the output voltage v, as a function of time by means of the transfer function determined at (i) for an input voltage vi= 120e0.18 Volt, R2 = 110 9, R2 = 900, R3 = 100 0, L = 3H and C= 80-106 F. Use MATLAB's step command to plot volt). Also use Simulink...
Q4 For the ideal Op-Amp in the figure below, use nodal analysis to express V, in terms of Vi and Vi2. What is the function of the circuit? (6 marks) R R V 2R Vyo 2R V120W C
VO Problem 1 (25 Pts) Consider the OP amp circuit shown below with R = 100k12 and C = 1(10)-5 F: Part a) 10 pts Find the complex transfer function for the circuit in terms of frequency f (Hz). Vi Part b) 5 pts Compute the gain of ko at as a function of frequency f (Hz). Part c) 10 pts Compute the corresponding gains at 100, 1000, 10000 Hz. Vi R BR 5R с Vi - Ve
Problem 2: In the circuit shown assume the Op-Amp is ideal. A) Find vo as a function of vi and vs. B) Next assume the Op-Amp is ideal, except its low frequency gain is Ao= 100 V/V. Now find vo as a function of vi and v2. C) The Op-Amp has a terminal frequency of fi 10° Hz, find the -3 dB (corner) frequency of the output signal w2 10K
For the circuit shown below, determine the output voltage vo. Assume ideal op amp behavior. S V to
Problem 1 (25 Pts) Consider the OP amp circuit shown below with R = 100kN and C = 1(10)-5 F: for the circuit in terms of frequency f(Hz). VO Part b) 5 pts Compute the gain of at as a function of frequency f(Hz). Vi Part c) 10 pts Compute the corresponding gains at 100, 1000, 10000 Hz. Part a) 10 pts Find the complex transfer function in R 3R 5R Via V.
Problem 1 (25 Pts) Consider the OP amp circuit shown below with R = 100kN and C = 1(10)-5 F: Part a) 10 pts Find the complex transfer function for the circuit in terms of frequency f (Hz). Vi Part b) 5 pts Compute the gain of at as a function of frequency f(Hz). Part c) 10 pts Compute the corresponding gains at 100, 1000, 10000 Hz. Vo R 3R 5R с Vů V.
The transfer function of the Op-Amp in the figure shown is: * (2 Points) L S0002 R HH Vin(t) + + Vout(t) = 5
Ch 5 Analysis of Ideal Op Amp Circuits 1 of 11> Part B Ideal op amp circuits with a voltage source: part 2 Learning Goal: For the circuit shown (Figure 1), determine the range (i.e., maximum and minimum values) of V so that the op amp operates in the linear region. Assume that R1-5 ? . R2-1 kN. R3-60 ? , and V,-15 V To analyze circuits that contain op amps using the ideal op amp assumptions. Express your answer...