4-1) Distortionless transmissionA bandpass signal g(t) of bandwidth B = 2000 Hz centered at f= 5.0x104 Hz is passed through the RC filter belowwith RC = 4.0x105 radians/s. If over the passband, a variation of less than 2% in both amplitude response andtime delay is considered to be distortionless transmission, would g(t) be transmitted without distortion? Find theapproximate magnitude response and the approximate time delay for the signal.Rwg(1)y(t)

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Answered: 4-1) Distortionless transmission A…

Introductory Circuit Analysis (13th Edition)

13th Edition

ISBN:9780133923605

Author:Robert L. Boylestad

Publisher:Robert L. Boylestad

Chapter1: Introduction

Section: Chapter Questions

Problem 1P: Visit your local library (at school or home) and describe the extent to which it provides literature...

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Answer the following wuth illustration and solutions. 1.) A second-order band pass filter is to be constructed using RC components that will only allow a range of frequencies to pass above 500Hz and below 1.5kHz. Assuming that both the resistor have values of 1kohms, calculate the values of the two capacitors required. Find also the center frequency of the two frequencies. This is the example/guide that might help.
2a A signal x (t ) =e that has a spectrum X (f ) = a² +(2xf ) ` a) Find the magnitude spectrum and the phase spectrum. Then sketch them. b) Is this signal band-limited? If not, find the 3-dB bandwidth of this signal.
1. A) B) Write the transfer function for the RC high-pass filter of Figure 2. First write it in terms of jw (or s) and then write it as its magnitude and phase angle. Determine and record below the cutoff frequencies of the circuit. wwwwww Sketch the straight line approximations of the frequency responses for the RC high-pass filter on Graph Av0.1 0 -10 -20 90° 60* 30° 0⁰ -30° -60° -90° e-2 sin (et) 0.1 0.2 (a) Voltage gain response 0,5 0.2 (b) Phase shift response 0.5 1 C = 0.47 uF R-330 ohms 2 ww 5 10 10 Vout 20 20 50 50 100 f (kHz) 100 (kHz)
n The figure below shows the amplitude component of a receptance Bode plot (on a linear scale in both axes) for a mode with natural frequency @ = 14rad/s and damping ratio = 0.049. The maximum amplitude and half power amplitudes are shown, along with the half power bandwidth, denoted Aw. What is the value of the half power bandwidth (Aw)? Express your answer in rad/s and to two decimal places. max max Δω
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These 5 parts are for one question
Please do part D and E
(c) Design a series RLC bandpass filter with cutoff frequencies fc₁ = 1 KHz, fcz = 20 KHz, using a 100 resistor. Draw the circuit and label all the components, including circuit values, including input and output. Also draw the magnitude and phase plots for the filter. Amplitude [dB] 50 40 30- Phase [°] 10 of- -10... -20... -30- -40- -50 0.1 180 135 90 C 45 of -45- -90 -135- -180 0.1 1 1 10 10 100 100 1000 1000 10,000 Freq. (Hz) 10,000 Freq. (Hz)
As part of a radio receiver, you are asked to design a simple bandpass filter using a series inductor, capacitor and resistor. The filter needs to pass a centre frequency of f0 = 1089 kHz with a bandwidth of 9 kHz. Do this by finding the capacitor and resistor values together with a 240 uH inductor that will give you the correct centre frequency and bandwidth. Also, calculate the quality factor Q for your filter. Sketch the filter circuit and show all your calculations.
Design an active Low-Pass Filter with a specified break frequency of 10100 rad/sec and a Passband gain equal to 22. use a capacitor Vahe of loont. For these design, Showi ⑦A circuit diagram of final filter design, Label all Components and Indicate the Input and Output Locations. Do not Include De Power to the op-amp ⑥The Jw transfer Function for the filter, The Passband gain in de use the tf and bode command In MATLAB to generate a bode Plot for the Filter Confirming that the Passband gam break Frequency. and the CLabel both m cle Correct
The spectrum of the trumpet signal for note G(784 Hz) is negligible above the ninth harmonic. What is the Nyquist sampling rate required for reconstructing the trumpet signal from the samples?

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