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Answer should be Q=4.22 10.28 Find the quality factor for the circuit given in Fig. P10.21...
For the following resonant series circuit shown in fig. 1, find : - Quality factor, Q. - Bandwidth, B. - The voltage across the capacitor. - The voltage across the inductor. - The voltage across the resistor. L = 4.7 mH C = 0.001uF S R = 470 VIN-1 V Fig. 1 Resonant series circuit
The center frequency is not given. I believe that it must be
find based on the body plot.
Problem 6:The Bode plot for a passive series RLC bandpass filter is shown in Fig. 2. This filter was built from a 10 μ F capacitor. What is the filter's center frequency, wo, and its quality factor,昱? If you wanted to double the filter's center frequency without changing its quality factor, using the same 10 pu F capacitor, then how would you...
Design an RLC Notch filter (circuit on slide 9) that will have a quality factor Q-20 (very selective filter), and will reject the 60 Hz frequency. Select C= 100 uF. b) Calculate fci, fcz, and BW
1) Consider the circuit in Fig. 1 (a). Assume that the transistor is operating in the linear region and has β 100 R-90 KD R-10 -17V 10 ka R,-10 KD (a) Problem (b) After Thevenin Equivalent Fig I. Circuits for Problem1) a) (8 points) Find the Thevenin equivalent across a - b. Indicate the values of Vih and Res in Fig. 1(b). b) (6 points) Determine io, fe and ie e) (I point) Determine Vor and verify that the assumption...
Q-1, 15 Marks] In the circuit of Fig.1 the switch (Sw) is closed to ground for a long time and opened at t = 0 s. 1. Find the voltage on the capacitor at a time of 1 s 2. Is the voltage on the capacitor at 1 s greater than or less than the voltage on the capacitor at time too s Data: V-10 V (DC and polarity as in Fig. 1), R= 1 Ω , L-1 H, C=...
2. (Textbook: 18.15) For the circuit in Fig. 1 (textbook: Fig. P18.15), find L(s), L(jw), the frequency for zero loop phase, and R2/R; for oscillation. Assume the op amp to be ideal. RI R2 w + R R = = Fig. 1
Answer a, b, c, d
A circuit consists of a resistor R connected in series with a capacitor C, as shown in Fig.1 EL Eo Fig 1. The capacitor C is connected in series with the resistor R The equation which describes this circuit when subject to a step function is given below di 0.3.21-9 dt a) What is the time constant r of this system? b) Assume zero initial condition (0 when r0), find the solution i() of the...
Find the charge q(t) on the capacitor and the current i(t) in the given LRC-series circuit. 5 h, R 2 1 f, E(t) 20 = 0 A 10 , C 200 V, q(0) 0 C, i(0) q(t) C i(t) A Find the maximum charge on the capacitor. (Round your answer to three decimal places.) C C II
Find the charge q(t) on the capacitor and the current i(t) in the given LRC-series circuit. 5 h, R 2 1 f, E(t)...
Q.11. Calculate the base, collector and emitter currents for the circuit given in Fig. 01. Also, determine the value of the voltage drop between collecter and emitter (Ve). Assume that the transistor is in active region and the value current amplification factor is 200. Given that the base-emitter voltage V is 0.7 V. Vcc - 10V 21 Ves = 4V W 220 KS2 Fig. Q11
0.55 +0.5 102 S Problem 4.4 In Fig. 4.4, R=0.2 M2, C=25 pF and L=0.04 H. Show that the transfer function H(s) is: 1 (5) H(S)= (5) + +1 L102 107 (a) Plot the pole-zero diagram of H(s). (b) What filter is given by H(s)? Why? (e) Determine the resonant frequency 0o, the quality factor Q, the cut-off frequencies 01 and 02 and the bandwidth B. i (0) it) R Fig. 4.4