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Q13,Q14 please. 25 For the system with transfer function G(S) [13] draw the bode (magnitude and s2+4s+25 phase)...
25 G(s) draw the bode (magnitude and [13] For the system with transfer function s2+4s+25 phase) plot on the semi-log paper 25 G(s) draw the bode (magnitude and [13] For the system with transfer function s2+4s+25 phase) plot on the semi-log paper
[14] The frequency response test on a system yielded the following data: db 900 610 450 00 0.1 -14 0.5 1 5 10 -450 -1360 -1800 7.5 10 50 -19 100 -31 Plot the data on a semi-log graph sheet. And, also determine the system transfer function in a frequency domain. [14] The frequency response test on a system yielded the following data: db 900 610 450 00 0.1 -14 0.5 1 5 10 -450 -1360 -1800 7.5 10 50...
For the transfer function, construct the bode plots for magnitude and phase. Use copies of the semi-log paper on the second page of this assignment. Also, a printable copy of the semi-log paper can be found below. Use one sheet per problem. Indicate the contributions from the factors of the transfer function with light lines in pencil. These are called “guidelines”. Indicate the graphical sum of the guidelines (the final bode plot) with heavier lines in ink. You will find...
A bode plot of the transfer function, GS = - 25 $2+45+25, is shown as below. Bode Diagram System sys Frequency (rad/s): 7 Magnitude (dB): -3.4 Magnitude (dB) Phase (deg) Systemt sys Frequency (rad/s): 7 Phase (deg): - 130 - 135 - 180 10 Frequency (rad/s) Determine the frequency response y(t) when a sinusoidal function, X(t) = 10 sin (7t +30) is applied to the transfer function as an input signal. (20 points)
Sketch the bode plot of a signal conditioner with the transfer function G(s) in the provided graph and calculate the bandwidth of this signal conditioner. GO 10s +1 S2 + 10s + 24 Table 2 Components in G(S) Asymptotes for Magnitude Asymptotes for Phase 20 log,0 1G(jw) Frequency-rad/sec Phase - degrees Frequency - rad/sec
1 Consider the system shown as below. Draw a Bode diagram of the open-loop transfer function G(s). Determine the phase margin, gain-crossover frequency, gain margin and phase-crossover frequency, (Sketch the bode diagram by hand) 2 Consider the system shown as below. Use MATLAB to draw a bode diagram of the open-loop transfer function G(s). Show the gain-crossover frequency and phase-crossover frequency in the Bode diagram and determine the phase margin and gain margin. 3. Consider the system shown as below. Design a...
2. The transfer function of a CT LTI system is given by H(s) (s2 +6s +10) (s2 -4s +8) a) Draw the pole-zero plot of the transfer function. b) Show all possible ROC's associated with this transfer function. c) Obtain the impulse response h(t) associated with each ROC of the transfer function. d) Which one (if any) of the impulse responses of part c) is stable? 2. The transfer function of a CT LTI system is given by H(s) (s2...
3. Draw the Bode plot (magnitude and phase) for the transfer function H(s) of a CT LTI given by H(s) 4000 only the asymptotic plot of the terms that make up the transfer function but also show the composite plot that adds all the terms that make up the transfer function. S+2000s+10 where the ROC includes the ja axis. Show
plot this transfer function using bode diagrems( magnitude and phase) H)+05+200) S2 +101s +100 H)+05+200) S2 +101s +100
The transfer function of the given physical system is 2500 Gp(s)-T-1000 Part 3 1. Frequency response (a) Draw the bode plot of open-loop transfer function when K (b) Use bode plot of open-loop transfer function to determine the type of system (do not use transfer function) (c) For what input the system will have constant steady-state error (d) for the unit input in item (c) calculate the constant steady-state error.(Use bode plot to calculate the error.) (e) Design a lead...