1.78 For the circuit shown in Fig. P1.78, first evaluate Ti (s) = Vi(s)/Vs(s) and the corresponding cutoff (corner) frequency. Second, evaluate To(s) = Vo(s)/Vi(s) and the corresponding cutoff frequency. Put each of the transfer functions in the standard form (see Table 1.2), and combine them to form the overall transfer function, T(s) = Ti(s) × To (s). Provide a Bode magnitude plot for |T(jω)|. What is the bandwidth between 3-dB cutoff points?

78 8 - 1.78 For the circuit shown in Fig. P1.78, first evaluate Ti (s) = Vi(s)/Vs(s) and the corresponding cutoff (corner) frequency. Second, evaluate To(s) = Vo(s)/Vi(s) and the corresponding cutoff frequency. Put each of the transfer functions in the standard form (see Table 1.2), and combine them to form the overall transfer function, T(s) = Ti(s) × To (s). Provide a Bode magnitude plot for |T(jω)|. What is the bandwidth between 3-dB cutoff points?

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images - 1.78 For the circuit shown in Fig. P1.78, first evaluate Ti (s) = Vi(s)/Vs(s) and the corresponding cutoff (corner) frequency. Second, evaluate To(s) = Vo(s)/Vi(s) and the corresponding cutoff frequency. Put each of the transfer functions in the standard form (see Table 1.2), and combine them to form the overall transfer function, T(s) = Ti(s) × To (s). Provide a Bode magnitude plot for |T(jω)|. What is the bandwidth between 3-dB cutoff points?

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