Q5) Sketch the Bode Plot (magnitude response) of the following systems. NOTE: Try to sketch yourself...
Please plot on semi-log scale for both magnitude and phase
separately
B. Sketch the Bode plots for the magnitude and the phase for the transfer function: 10(S + 1) H(S) = S(S + 10)(8 + 100)
6. Sketch Bode log magnitude plot for the following transfer functions manually. Then use Matlab's "bode" command to plot the same and compare it with your manually obtained sketches. (s + 10) (s + 200) a) X(s) = TS + 20)-(s +1000) b) X(S) = TS + 1)(52 + 4s + 16)
i) Draw the Bode plots (hand sketch, magnitude and phase!) for the following transfer function. Plot over the range 0.1 to 1000 rad/s HS 10,000 (s) = s* + 20s 10,000 ii) what are the Q and Bw for this circuit? iii) Design and draw a circuit (including values) that would yield this transfer function. It should use a 100mH inductor , , Qano
Problem 6 (5 marks) Draw the Bode plots for the system G(s) = 10 Bode Plot .... 1- - .... ... . 20 log M - - - 1111-... - - TH .. 101 100 102 --- - Phase (degrees) .... 101 10 10° Frequency (rad/s)
Bode Plots Sketch the Bode plot magnitude and phase for each of the three open-loop transfer functions listed below. Verify your results using the bode m function in MATLAB.(a) \(G(s)=\frac{100}{s(0.1 s+1)(0.01 s+1)}\)(b) \(G(s)=\frac{1}{(s+1)^{2}\left(s^{2}+s+9\right)}\)(c) \(G(s)=\frac{16000 s}{(s+1)(s+100)\left(s^{2}+5 s+1600\right)}\)
QUESTION 4 This question will reinforce how the Bode plot provides the steady-state response for a linear system in response to a sinusoidal input. Consider this forced mass-spring-damper system: Let M 6, B-48, K-72 Part a) As you did for HW 1, determine steady-state solution "x,()" when FC) 3120 cos(4b) Part b) Determine the transfer function Part c) The Bode plots for the transfer function of Part b are provided in this handout. with the parameter values of Part a....
Problem 3 (20 points) A Bode plot is a graph of the frequency response of a system. It is a combination of a magnitude plot, expressing the magnitude in dB of the frequency response, and a phase plot expressing the phase shift. Both quantities are plotted on a horizontal axis proportional to the logarithm of the frequency. Below is an example of a Bode plot created in Matlab. Bode Diagram 0 -20 3-40 E-60 -80 180 90 10 10 10...
Steps would be much appreciated
A.) Sketch each terms magnitude and phase.
B.) Plot the bode plot for the function.
14.13 Construct the Bode plots for Gs) 0.1s + D s(s +10) ja
Problem #4) Sketch the square wave response of a circuit, given its bode plot shown here. Bode Diagram 20 60 pautr 45 135 180 101 101 Frequency (rad/s) Bonus (2 points): Draw a circuit that will match both of the behaviors shown above.
Problem 3. Sketch the Bode plot (magnitude only) for the following transfer function. Label all slopes (dB/dec): (s 1000)(s 10,000) (s/100+1) (s/1000+1)(s/10,000+1) 7(s) T(s)- 0 dB 20 dB 0 40 dB 3 60 dB -80 dB -100 dB 10 10 103 104 105 106