Signals And Systems Problems And Solutions Pdf Page
\subsection*Problem 2: Even and Odd Decomposition Find the even and odd parts of \(x(t) = e^-atu(t)\), where \(u(t)\) is the unit step.
\sectionLaplace Transform
\subsection*Solution First term: \(e^-2tu(t) \leftrightarrow \frac1s+2\), \(\textRe(s) > -2\). \\ Second term: \(e^3tu(-t) \leftrightarrow -\frac1s-3\), \(\textRe(s) < 3\). \\ Thus \(X(s) = \frac1s+2 - \frac1s-3 = \frac-5(s+2)(s-3)\), ROC: \(-2 < \textRe(s) < 3\). signals and systems problems and solutions pdf
\noindent\textbf15. Check: Input \(x(t-\tau)\) gives \(x(t-\tau)\cos t\), but for time-invariance we need \(x(t-\tau)\cos(t-\tau)\).
\subsection*Problem 5: Fourier Transform of a Rectangular Pulse Compute the Fourier transform of \(x(t) = \textrect(t/T) = 1\) for \(|t| < T/2\), 0 otherwise. \subsection*Problem 2: Even and Odd Decomposition Find the
\noindent\textbf12. Find Laplace transform of \(t e^-2tu(t)\). \textitAns: \(1/(s+2)^2\), ROC \(\textRe(s)>-2\).
\noindent\textbf14. Z-transform of \(x[n]=n(1/3)^n u[n]\). \textitAns: \(\frac(1/3)z^-1(1-(1/3)z^-1)^2\), \(|z|>1/3\). ROC: \(-2 <
\noindent\textbf12. Using \(t^n e^-atu(t) \leftrightarrow \fracn!(s+a)^n+1\).