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Problem 3: For the circuits below a) Find the transfer function H(s)= b) What happens to...
Find the transfer function H(jω) for the
circuit above as a function of jω. (Leave R and L as variables).
Assume V R to be the output and V S to be the input.
С L RVR(t) vs (t) A. Find the transfer function H(jo) for the circuit above as a function of jaw. (Leave R and L as variables). Assume V to be the output and V to be the input. S R B. Find the Magnitude and Phase...
Problem 11.37 A system has a transfer function H(S)= 72 +85 +4 (a) (b) In a magnitude Bode diagram of its frequency response what are the values of all the corner frequencies (in radians/second)? What is the slope (in dB/decade) of the magnitude Bode diagram at very low frequencies (approaching zero)? What is the slope (in dB/decade) of the magnitude Bode diagram at very high frequencies (approaching infinity)? (c)
QUES 2!!!
Problem 1: For the feedback system shown below, compute the transfer functions e/d, x/r. What are the steady-state values for a constant d,r and when do they approach 0 asymptotically as t goes to infinity? C(s) 一心 - P(s) We were unable to transcribe this image
Problem 1: For the feedback system shown below, compute the transfer functions e/d, x/r. What are the steady-state values for a constant d,r and when do they approach 0 asymptotically as t...
QUESTION #2 PLEASE
1. Derive the transfer function for the circuit shown below. Plot H(s) versus frequency in Hertz, on a semilog scale. Ri 11.3 k Ri 22.6 k R R = 68.1 kN R3 C C 0.01 uF R2 Vout(s) Vin(s) C2 10 (s+5) H(s) = (s+100)(s5000) , (a) draw the magnitude Bode plot 2. For the transfer function and find the approximate maximum value of (H(jw) in dB, (b) find the value of w where 1 for w>5...
Problem 2 An RC circuit ( with an active component) has the following transfer function (where R and Care positive) H(s) - Vout(8) _R|| R/10k12 Vin(8) 10KN 1 + $RC Where s = jw Find the value of the resistor and the value of the capacitor so that: for w = 0 rad/s, H(jw)lde = +12dB at f = 1kHz, |H(jw)lab = +9dB Problem 3 The transfer function of a circuit is given by H(S) = Vout(s) Vin(s) Where s...
Problem 5.0 Find the transfer function by using Nodal Analysis for the following circuits: 4 uF 110 kQ (t) 400 kQ 4 HF (a) + w HH 110 k2 600 k2 4 HF 400 k2 4 pF 600 k2 (b)
Problem 5.0 Find the transfer function by using Nodal Analysis for the following circuits: 4 uF 110 kQ (t) 400 kQ 4 HF (a) + w HH
110 k2 600 k2 4 HF 400 k2 4 pF 600 k2 (b)
Problem 5.0 Find the transfer function by using Nodal Analysis for the following circuits: 4F w
Problem 2. Op-amp circuits to ODEs Find the governing equation(s) for the following op-amp circuits. Then find the transfer function, G(s) = Vol. Feel free to either use the impedance method or the time-domain methods. a) a R: R 1. R b) R C HE 1 M
3. Consider an LTI system with transfer function H(s). Pole-zero plot of H(s) is shown below. Im O--- Re (a) How many ROCs can be considered for this system? (b) Assume system is causal. Find ROC of H(S) (c) Assume y(t) is system output with step unit as input. Given lim yết) = 5 , Find H(s). (d) (optional) Find y(2) (y(t) for t = 2).
(3) For the system modeled by with output defined as a) Find the system's transfer function(s) E(t) +3z(t) +2x(t)-Sult) b) Find the system's pole(s) (if any) and zero(s) (if any) c) Find n(t →x) if u(t)-G 120) 0 t<0 e) Find the frequency response function corresponding to output y 1) Find steady-state ya(t) if u(t) 3sin(21)