Q)Design a Discrete Time Low Pass Filter for a signal. Butterworth Filter. Chebeyshev Filter The specifications are:(Voice Signal) 1) Passband Fp = 4 kHz, with 0.2 dB ripple; Stopband FS 4.5 kHz, with 45 dB ripple. Sampling Frequency Fs = 22 kHz. (Use For Both Filters). 2) passband ripple - 0.2 stopband ripple-45 passband frequency- 1300 stopband frequency = 1500 sampling frequency - 10000. (Chebeyshev Filter) 3) Passband ripple=0.5 stopband ripple = 50 passband frequency = 1200 stopband frequency = 2400 Sampling Frequency= 10000. (Butterworth filter)."

Q)Design a Discrete Time Low Pass Filter for a signal. Butterworth Filter. Chebeyshev Filter The specifications are:(Voice Signal) 1) Passband Fp = 4 kHz, with 0.2 dB ripple; Stopband FS 4.5 kHz, with 45 dB ripple. Sampling Frequency Fs = 22 kHz. (Use For Both Filters). 2) passband ripple - 0.2 stopband ripple-45 passband frequency- 1300 stopband frequency = 1500 sampling frequency - 10000. (Chebeyshev Filter) 3) Passband ripple=0.5 stopband ripple = 50 passband frequency = 1200 stopband frequency = 2400 Sampling Frequency= 10000. (Butterworth filter)."

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...

See similar textbooks

Similar questions

select an answer1. In a digital PLL system, the blocks that compose it are...A. Phase detector, integrator and oscillator.B. Integrator, Mixer and a Loop.C. Phase detector, loop filter and VCO.D. Phase detector, loop filter and NCO.
In Bilinear Transformation Method, determine the bandwith for a second-order digital band-pass Butterworth filter with the following specifications: upper cutoff frequency of 3100 Hz, lower cutoff frequency of 2700 Hz and sampling frequency is 11000 Hz.
A geophone is able to pick up signals in the frequency range of 20 Hz to 340Hz. Design anactive filter and a passive filter the earth vibration signal which ranges from 50 Hz to 250 Hz.What is the filter gain when the signal is at 450 Hz for both filters? Please state which type offilter performs better in this scenario and why
1. Derive the lower cut-off frequency for the basic RC high-pass circuit in Figure 1. R, Figure 1.
He (e tw) -27 27 The frequency-omplitude graph of discrete time low pass filter is given above. Based on this graph, find the time domain equivalent of a high-pass fiter in the time doman by inverse fourter transformartion.
A two-stage active band pass filter (BPF) is shown in Figure Q2. A table of components values is shown in Table Q2. For this BPF: a) Calculate the passband voltage gain in dB and the quality factor Q of each stage. b) Calculate the critical frequencies and bandwidth of the filter. c) Sketch the frequency response of the filter. R RA RA Rc Св Rp RB Figure Q2. RB=1kQ Rc=4700 RD=3300 CB=27NF Table of Component values of the BPF CA=56nF RA=2kQ Table Q2 HHI•
-3dB point in frequency response of an active filter corresponds to A. absolute value negative 3dB of gain B. decrement of 3dB from maximum gain C. minimum gain attained D. minus 3dB of average gain value
(a) Explain the function of a high pass filter. Draw a diagram of a simple high–pass filter using a capacitor and a resistor.
5 a) Consider the sample sequence (5000, 5000, 5000, 5000, -5000, -5000, -5000, -5000}. These are samples of a square wave with a period of eight samples or 1ms at 16 KHz sampling frequency. What are the sinusoidal frequencies in the output waveform?
For band pass filter, should the lower and upper edge frequency values be chosen close to each other? What should be considered when choosing?
If the signal to be analyzed is an analog signal, then we pass the signal to an antialiasing filter where B is the bandwidth of the filtered signal. What sampling frequency (Fs) should be used to make this signal discrete/digital?
A discrete-spectrum baseband modulating signal has com- ponents at the following frequencies: 500 Hz, 1.5 kHz, 6-3