NOTE: You would have to clearly mark out the cut-off frequencies and the slopes of the magnitude lines (e.g., ±20 dB/decade), and the phase angle values in your asymptotic Bode plots. For your convenience, it is okay to approximate phase angle and magnitude values in your Bode plots. Let us draw the asymptotic Bode plot of the following transfer function: 10 (s+1) S (s + 10) but we will do so by constructing the Bode plots for each of the first order terms separately, H(s) = H3(s) · H4(s) H5(s) . 10 H3(s) = s+10' Problem 2 where, H(s) 1 HA(S) = S' and H5(s) = s +1 and then putting those plots together (i.e., by stacking them on top of each other). a) Draw the asymptotic Bode plot of H₁(s) = 1 b) Draw the asymptotic Bode plot of H5(s) = s +1 c) Finally, use the above results to draw the asymptotic Bode plot of: H(s) = H3(s) H4(s). H5(s). Note: You should reuse the asymptotic Bode plot of H3(s) = 10 from the previous problem. s+10

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NOTE: You would have to clearly mark out the cut-off frequencies and the slopes of the magnitude lines (e.g., ±20 dB/decade), and the phase angle values in your asymptotic Bode plots. For your convenience, it is okay to approximate phase angle and magnitude values in your Bode plots. Let us draw the asymptotic Bode plot of the following transfer function: 10 (s+1) S (s + 10) but we will do so by constructing the Bode plots for each of the first order terms separately, . H(s) = H3(s) · H4(s) H5(s) 10 H3(s) = s+10' Problem 2 where, H(s) 1 H4(s) == S and H5(s) = s +1 and then putting those plots together (i.e., by stacking them on top of each other). a) Draw the asymptotic Bode plot of H₁(s) = 1 b) Draw the asymptotic Bode plot of H5(s) = s +1 c) Finally, use the above results to draw the asymptotic Bode plot of: H(s) = H3(s) H4(s). H5(s). Note: You should reuse the asymptotic Bode plot of H3(s) = 10 from the previous problem. s+10