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14: Appendix A- Linear Algebra Overview

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    • 14.1: Basic Linear Algebra
      This page provides a tutorial on key linear algebra concepts, focusing on linear independence, span, and basis, particularly concerning eigenvectors and eigenfunctions in signal processing. It defines linear independence, illustrates span through vector combinations, and explains that a basis is a linearly independent set spanning a space.
    • 14.2: Eigenvectors and Eigenvalues
      This page explores linear systems with n×n complex matrices, focusing on eigenvectors and eigenvalues. It defines eigenvectors as vectors that, when multiplied by a matrix, yield a scalar multiple (the eigenvalue). The text explains how to find eigenvalues through the characteristic polynomial, followed by determining eigenvectors from a system of equations.
    • 14.3: Matrix Diagonalization
      This page discusses the relationship between operator matrix \(A\), eigenvalues, and eigenvectors, noting that \(n\) distinct eigenvalues lead to eigenvectors that span \(\mathbb{C}^n\). It describes expressing vectors using a matrix \(V\) of eigenvectors, allowing for a diagonalized form of \(A\).
    • 14.4: Eigen-Stuff in a Nutshell
      This page discusses the importance of eigenvectors in linear algebra, focusing on their relationship with matrices. It explains that when a matrix \(A\) operates on an eigenvector \(\boldsymbol{v}\), it scales the vector easily. Although not all vectors are eigenvectors, some matrices have eigenvectors that can span \(\mathbb{C}^n\), allowing any vector \(\boldsymbol{x}\) to be expressed as a combination of these eigenvectors.
    • 14.5: Eigenfunctions of LTI Systems
      This page discusses eigenvectors and eigenfunctions in linear time-invariant (LTI) systems, comparing their operation on continuous signals to that of matrices on vectors. It defines eigenfunctions as signals that scale when processed by LTI systems, highlighting complex exponentials \(e^{st}\) as common eigenfunctions with system-dependent eigenvalues. The text underscores the importance of expressing signals as combinations of these exponentials.

    This page titled 14: Appendix A- Linear Algebra Overview is shared under a CC BY 3.0 license and was authored, remixed, and/or curated by Richard Baraniuk et al. via source content that was edited to the style and standards of the LibreTexts platform.