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Prof. Uddhar Negi gave this assignment for Advanced Unified Engineering course at Allahabad University. It includes: Karnaugh, Maps, Truth, Tables, Simplify, Expression, Boolean, Diagram, Convert, Rules, Engine
Typology: Exercises
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The problems in this problem set cover lecture C
a. Using truth tables, show that A 〈 B =( A + B )
b. Using K-Maps, simplify the following expression:
c. Using K-Maps, simplify the following expression: A 〈 B 〈 D + B 〈 C 〈 D + A 〈 B 〈 C 〈 D + C 〈 D
d. Simplify the same expression using the rules of simplification (Boolean Algebra Theorems).
Note : When using truth tables, list the complete table. When using K-Maps, show the simplifications on the diagram. When using rules of simplification, state the rule being used on the same line in square brackets.
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Unified Engineering II Spring 2004
Problem S15 (Signals and Systems)
Find the Fourier transforms of the following signals:
g(t) = δ(t − T ) Note: The system with impulse response g(t) produces an output that is the input delayed by T. Since delays occur frequently in signal processing, G(jω) is an important transfer function.
g(t) =
1 , |t| ≤ T 0 , |t| > T
Note: Because g(t) is symmetric, G(jω) should be real. Please express your answer so that it is apparent that the answer is real.
g(t) =
t^2 + T 2 Hint: If you find the integral hard to do, you might be able to find the answer using duality.
g(t) =
sin πt/T πt/T Hint: You almost certainly won’t be able to do the FT integral directly. Use duality and the results of (2) above to find the answer. The g(t) in this problem has important connections to, among other things, CD players!
G(jω) =
sin ωT ωT
using the results of part (2), and FT properties.