, answer the next six questions.

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Frequency Response Problems Conceptual Questions 1) T/F Given f(t) = A cos (ωt + θ): The amplitude of the output in sinusoidal steady-state increases as K increases and decreases as ω increases. 2) T/F Given f(t) = A cos (ωt + θ): The magnitude of the phase shift (sinusoidal steady-state) between x(t) and f(t) increases as either τ or ω increases. The phase shift does not depend upon K or A. 3) What order is the above system? Explain your answer. 4) Give the transfer function for the above system. 5) What is the the magnitude of the static gain? Explain your answer. Given the transfer function, o TF(s) = = V(s) 1000, answer the next six questions. V(s) s + 20 6) T/F The low frequency magnitude in db will be 20log 10 1000. 7) T/F The high frequency slope for TF db will be -20dB/decade. in 8) Give the differential equation describing the relationship between v in (t) and v o (t). Identify the order, the time constant, and the static gain coefficient. 9) T/F If v in-1 = 5 cos(10t) V and v in-2 = 50 cos(100t) V, the amplitude of v out-1 will be greater than v out-2. Why or why not? 10) T/F If v in-1 = 1000 cos(10 4 t) V and v in-2 = 10 cos(500t) V, the amplitude of v out-2 is greater than v out-1. Why or why not? 11) T/F The high frequency phase of TF will be -90.

12) What order system is described by the above Bode magnitude plot. 13) Give a transfer function which would have the above Bode magnitude plot. Note: The answer is not unique. There s more than one answers possible. 14) Give the differential equation describing the relationship between the output [assume x(t) as the output] and the input [assume f(t) as the input]. 15) Identify the static gain coefficient, the damping ratio, and the natural frequency. Is the system overdamped or underdamped? 16) T/F Increasing C in the high-pass filter will lower its break frequency. 17) T/F Increasing R in in the bandpass filter has no effect on its lower break frequency. 18) T/F Increasing C in the high-pass filter has no effect on its high-frequency gain. 19) T/F Increasing C in in the bandpass filter has no effect on its passband gain.

20) T/F Time-domain response. Increasing C will lower the magnitude of the static gain coefficient. 21) T/F Time-domain response. Increasing R f will increase the time constant. 22) T/F Frequency-domain response. Lowering R in will lower the break frequency. 23) T/F Frequency-domain response. Increasing R f will increase magnitude of the DC gain. 24) T/F If V in = 20 cos (2000t) mv, the amplitude of V o will be approximately 2 V. 25) T/F If R in = 2 kω, C in will be approximately 50 nf. Why or why not? 26) T/F If V o = 50 cos (30t) mv, the amplitude of V in will be approximately ½ V. 27) T/F If a signal V in-signal = 100 cos (3000t) mv were corrupted with low frequency noise V in-noise = 50 cos (30t) mv, the signal-to-noise ratio at the output will be approximately 200. 28) T/F Circuit on left: R f = 100kΩ, R in = 10 KΩ, C = 0.01µF. The circuit is a low-pass filter with a DC gain of 10 and a break frequency of 10 4 r/s. 29) T/F Circuit in middle: R f = 20kΩ, R in = 4KΩ, C = 0.025µF. For V in = 20 cos(10t) mv, V o is approximately 0.02 mv. 30) T/F Circuit on right:. R f = 10kΩ, R in = 5KΩ, C in = 0.1µF, C f = 100 pf. The circuit is a bandpass filter with a passband gain of 2, a lower corner frequency of 2000 r/s and an upper corner frequency of 10 6 r/s.

Workout Problems 1. Using nodal analysis, find H(s) = V o (s)/v in (s). 2. Using nodal analysis and superposition to express V o (s) in terms of V 1 (s) and V 2 (s).

3. The band-pass filter shown below has an upper corner frequency of 250 krad/sec and a lower corner frequency of 10 krad/sec. The band-pass gain of this filter should be 40 db. The largest resistor is to be 1 MO. Design this filter by determining: i) R in, C in, R f, and C f. ii) Filter transfer function in the s-domain. iii) Using semilog paper, sketch the Bode magnitude plot by hand. iv) Using Matlab, find the Bode magnitude and phase plot. 4. Given the step response, i) find V o (s). ii) find H(s). iii) Using semilog paper, sketch the Bode magnitude plot by hand.

5. Given the Bode magnitude plot below for H db, i) Find the transfer function, H(s), which will have this magnitude plot. ii) Design a circuit which will have this H(s). iii) Find the output for this circuit, v o (t), when the input, v in (t) = u(t). s 6. Given the transfer function H(s) = 240, i) Determine the filter type 2 s + 120s + 90000 ii) Using semilog paper, sketch the Bode magnitude plot by hand iii) Using Matlab, give the Bode magnitude and phase plot iv) The sinusoidal steady-state response for v (t) if v (t) = [2 + 1.414 cos ( 360t + 30 ) + 2 cos ( 10000t + 50 )] V. in o 7. A measurement system has been found, through experiment, to have the following equation of motion. v + 2000v = 20 x 10 measured measured 3 v actual i) Determine the Static Gain and Time Constant. ii) Write the transfer function, in the s domain, for v measured as output and v(t) actual as input. iii) Find v(t) actual, in steady-state, given v(t) measured = 6 + 14 cos(1500t 16.9 ) V.

8. For the circuit shown below, i) Find the general expression for the transfer function V o / V s. ii) For R L = R s = 100 Ω and C = 1µF, give the transfer function in Bode form iii) Using semilog paper, sketch the Bode magnitude and phase plots by hand iv) What are the circuit's filtering properties? v) Find v o (t) for v s (t) = 10 + 5 cos (200000t + 30 ) V 9. For the circuit shown below, i) Find the general expression for the transfer function V o / V s. ii) For R in = 2 KΩ, R f = 10 KΩ and C = 0.01 µf, give the transfer function in Bode form iii) Using semilog paper, sketch the Bode magnitude and phase plots by hand iv) What are the circuit's filtering properties? v) Find v o (t) for v s (t) = 10 + 5 cos (200000t + 30 ) V

10. Given the circuit below with R s = R L = 100 Ω and C = 1 µf, i) Find the transfer function V o (s)/v in (s). ii) Given a pulse train input for v s (t), find the first four non-zero terms in the Fourier series for v s (t). Perform the necessary integrals by hand. iii) Using Maple or some other mathematical tool, plot the output waveform for v o (t). 11. Given the circuit below with R s = R L = 100 Ω and C = 1 µf, i) Find the transfer function V o (s)/v in (s). ii) Given a pulse train input for v s (t), find the first four non-zero terms in the Fourier series for v s (t). Perform the necessary integrals by hand. iii) Using Maple or some other mathematical tool, plot the output waveform for v o (t).

12. Given the circuit below, i) Find the transfer function V o (s)/v i (s). ii) Using semilog paper, sketch the Bode magnitude plot. 13. For the transfer function below, i) Using semilog paper, sketch the Bode magnitude plot. ii) Using computer tools, give the Bode magnitude and phase plots. iii) What type of filtering does this system display? H(s) = 5000s 2 s + 105s + 500 14. For the transfer function below, i) Using semilog paper, sketch the Bode magnitude plot. ii) Using computer tools, give the Bode magnitude and phase plots. iii) What type of filtering does this system display? 5000 H(s) = - s + 1000 15. Given the straight-line approximation for a Bode magnitude plot shown below, write a corresponding transfer function. (Note: There is more than one correct solution.)

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