(E) Recalling that fs = 1.5fs,min, which of the following reconstruction filters can be expected to provide ideal reconstruction of x(t) (up to scale) from its samples? (1) p(t) = sinc(5t)sinc(t), (2) p(t) = sinc(6t)sinc(t), (3) p(t) = sinc(8t) sinc(3t). Give reasons for your answers. (F) For numerical experiments, consider a truncated version of p(t): p₁(t) = p(t)I[-T。/2,To/2](t). Again, set To = 8. What percentage of the energy of p is captured in this truncation interval? You will need to compute the energy of p₁ numerically and compare it with analytical computa- tion of the energy of p using Parseval's identity. (G) Using a "fast" sampling rate ffast = 16fs (or faster if needed) to emulate continuous time reconstruction, write a Matlab program that produces: (1) the upsampled sequence x₁ [k] and a stem plot of it. (2) samples of p(t), truncated as in (f), at rate ffast, and a stem plot of the samples. Let us call these samples p[n]. (H) Implement (4), convolving xμ with p to obtain x, [m]. Recognizing that each increment in m corresponds to an increment in t of Tfast = 1/ffast, plot x,(t) versus t. Plot x(t) versus t in the same way. Comment on how the two waveforms are related. (I) Replot x,(t) and x(t) after delaying and scaling x,(t) to best align it with x(t) (accounting for the delay and scaling due to filtering). Eyeball the plots to comment on how good the recon- struction is. (A) Consider the bandlimited signal x(t) = sinc(4t) sinc(t). What is fs,min, the minimum sam- pling rate for ideal reconstruction? What is the energy of x? (use Parseval's identity) (B) Let x[n] denote samples of x(t) obtained by sampling at rate fs = ½-½ = 1.5fs,min (i.e., 50% faster than the minimum sampling rate). Compute analytically and sketch the DTFT Ŷ(f) of the samples over 3 periods, centered around f = 0. Hint: Use the relationship between the DTFT and the Fourier transform of the impulse trained sampled waveform Σ x(nT)(t – nT). (C) For our numerical experiments, we consider a truncated version of x(t): x₁(t) = x(t)I–T。/2,T。/2](t). Set To = 8. What percentage of the energy of x is captured in this truncation interval? You will need to compute the energy of x₁ numerically and compare it with the energy of x computed analytically in (A). (D) Do a stem plot of samples x[n] at rate fs (of the truncated waveform in (C)).

Database System Concepts
7th Edition
ISBN:9780078022159
Author:Abraham Silberschatz Professor, Henry F. Korth, S. Sudarshan
Publisher:Abraham Silberschatz Professor, Henry F. Korth, S. Sudarshan
Chapter1: Introduction
Section: Chapter Questions
Problem 1PE
Question

part f, part g, part h, part i. use python

(E) Recalling that fs = 1.5fs,min, which of the following reconstruction filters can be expected
to provide ideal reconstruction of x(t) (up to scale) from its samples?
(1) p(t) = sinc(5t)sinc(t), (2) p(t) = sinc(6t)sinc(t), (3) p(t) = sinc(8t) sinc(3t). Give reasons for
your answers.
(F) For numerical experiments, consider a truncated version of p(t): p₁(t) = p(t)I[-T。/2,To/2](t).
Again, set To = 8. What percentage of the energy of p is captured in this truncation interval?
You will need to compute the energy of p₁ numerically and compare it with analytical computa-
tion of the energy of p using Parseval's identity.
(G) Using a "fast" sampling rate ffast = 16fs (or faster if needed) to emulate continuous time
reconstruction, write a Matlab program that produces:
(1) the upsampled sequence x₁ [k] and a stem plot of it.
(2) samples of p(t), truncated as in (f), at rate ffast, and a stem plot of the samples. Let us call
these samples p[n].
(H) Implement (4), convolving xμ with p to obtain x, [m]. Recognizing that each increment in m
corresponds to an increment in t of Tfast = 1/ffast, plot x,(t) versus t. Plot x(t) versus t in the
same way. Comment on how the two waveforms are related.
(I) Replot x,(t) and x(t) after delaying and scaling x,(t) to best align it with x(t) (accounting
for the delay and scaling due to filtering). Eyeball the plots to comment on how good the recon-
struction is.
Transcribed Image Text:(E) Recalling that fs = 1.5fs,min, which of the following reconstruction filters can be expected to provide ideal reconstruction of x(t) (up to scale) from its samples? (1) p(t) = sinc(5t)sinc(t), (2) p(t) = sinc(6t)sinc(t), (3) p(t) = sinc(8t) sinc(3t). Give reasons for your answers. (F) For numerical experiments, consider a truncated version of p(t): p₁(t) = p(t)I[-T。/2,To/2](t). Again, set To = 8. What percentage of the energy of p is captured in this truncation interval? You will need to compute the energy of p₁ numerically and compare it with analytical computa- tion of the energy of p using Parseval's identity. (G) Using a "fast" sampling rate ffast = 16fs (or faster if needed) to emulate continuous time reconstruction, write a Matlab program that produces: (1) the upsampled sequence x₁ [k] and a stem plot of it. (2) samples of p(t), truncated as in (f), at rate ffast, and a stem plot of the samples. Let us call these samples p[n]. (H) Implement (4), convolving xμ with p to obtain x, [m]. Recognizing that each increment in m corresponds to an increment in t of Tfast = 1/ffast, plot x,(t) versus t. Plot x(t) versus t in the same way. Comment on how the two waveforms are related. (I) Replot x,(t) and x(t) after delaying and scaling x,(t) to best align it with x(t) (accounting for the delay and scaling due to filtering). Eyeball the plots to comment on how good the recon- struction is.
(A) Consider the bandlimited signal x(t) = sinc(4t) sinc(t). What is fs,min, the minimum sam-
pling rate for ideal reconstruction? What is the energy of x? (use Parseval's identity)
(B) Let x[n] denote samples of x(t) obtained by sampling at rate fs = ½-½ = 1.5fs,min (i.e., 50%
faster than the minimum sampling rate). Compute analytically and sketch the DTFT Ŷ(f) of
the samples over 3 periods, centered around f = 0.
Hint: Use the relationship between the DTFT and the Fourier transform of the impulse trained
sampled waveform Σ x(nT)(t – nT).
(C) For our numerical experiments, we consider a truncated version of x(t): x₁(t) = x(t)I–T。/2,T。/2](t).
Set To
= 8. What percentage of the energy of x is captured in this truncation interval? You will
need to compute the energy of x₁ numerically and compare it with the energy of x computed
analytically in (A).
(D) Do a stem plot of samples x[n] at rate fs (of the truncated waveform in (C)).
Transcribed Image Text:(A) Consider the bandlimited signal x(t) = sinc(4t) sinc(t). What is fs,min, the minimum sam- pling rate for ideal reconstruction? What is the energy of x? (use Parseval's identity) (B) Let x[n] denote samples of x(t) obtained by sampling at rate fs = ½-½ = 1.5fs,min (i.e., 50% faster than the minimum sampling rate). Compute analytically and sketch the DTFT Ŷ(f) of the samples over 3 periods, centered around f = 0. Hint: Use the relationship between the DTFT and the Fourier transform of the impulse trained sampled waveform Σ x(nT)(t – nT). (C) For our numerical experiments, we consider a truncated version of x(t): x₁(t) = x(t)I–T。/2,T。/2](t). Set To = 8. What percentage of the energy of x is captured in this truncation interval? You will need to compute the energy of x₁ numerically and compare it with the energy of x computed analytically in (A). (D) Do a stem plot of samples x[n] at rate fs (of the truncated waveform in (C)).
Expert Solution
steps

Step by step

Solved in 2 steps

Blurred answer
Recommended textbooks for you
Database System Concepts
Database System Concepts
Computer Science
ISBN:
9780078022159
Author:
Abraham Silberschatz Professor, Henry F. Korth, S. Sudarshan
Publisher:
McGraw-Hill Education
Starting Out with Python (4th Edition)
Starting Out with Python (4th Edition)
Computer Science
ISBN:
9780134444321
Author:
Tony Gaddis
Publisher:
PEARSON
Digital Fundamentals (11th Edition)
Digital Fundamentals (11th Edition)
Computer Science
ISBN:
9780132737968
Author:
Thomas L. Floyd
Publisher:
PEARSON
C How to Program (8th Edition)
C How to Program (8th Edition)
Computer Science
ISBN:
9780133976892
Author:
Paul J. Deitel, Harvey Deitel
Publisher:
PEARSON
Database Systems: Design, Implementation, & Manag…
Database Systems: Design, Implementation, & Manag…
Computer Science
ISBN:
9781337627900
Author:
Carlos Coronel, Steven Morris
Publisher:
Cengage Learning
Programmable Logic Controllers
Programmable Logic Controllers
Computer Science
ISBN:
9780073373843
Author:
Frank D. Petruzella
Publisher:
McGraw-Hill Education