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|G(w) 3 dB 1/√√2 u(t) y(t) 20 dB/decade 1+ jan 1 + jωτ 1/τ W Figure 3: Bode plot of a low-pass filter Figure 4: Block diagram of a cascaded low-pass filter 3. Consider a low-pass filter with frequency response function G₁(w) 1 1+ jwT (3) where is a time constant, from which a cutoff frequency 1/7 is defined. Moreover, magnitude |G1(w) is plotted in Fig. 3. When w<1/7, the magnitude |G₁(w) is roughly 1. When w>1/7, the magnitude |G₁(w)| rolls off with 20 dB/decade. The bandwidth is defined when G₁(w) is dropped from 1 to 1/√2. Engineer X wants to have a filter with a faster 2 rolloff. Therefore, Engineer X designs a new filter by cascading two low-pass filters as shown in Fig. 4. Therefore, the new filter has a frequency response function 1 G₂(w)= (1+jwT)² Answer the following questions. (4) (a) Derive the magnitude and phase of G2(w) as functions of w. (b) Let us focus on |G2(w), the magnitude of G₂(w). Plot |G2(w)| by conducting the fol- lowing asymptotic analysis. When w<1/7, what does the magnitude |G2(w)| approach to? When w>1/7, how fast does the magnitude |G2(w)| rolls off? (c) What is the bandwidth of the new filter G2(w)? [Hint: Recall the definition of band- width above.] What is the phase angle LG2(w), when the driving frequency reaches the bandwidth of G2(w)? (d) Does Engineer X achieve his goal, i.e., a faster rolloff when w>1/7? Does Engineer X sacrifice any performance of the new filter? Please justify your answer instead of simply stating yes or no.