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14: Linear Algebra Equations

  • Page ID
    122654
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    • 14.1: Matrix Methods for Linear Equations
      This page discusses the importance of systems of linear equations in various fields, explaining their representation in matrix form and classification into consistent, inconsistent, or those with unique/infinitely many solutions.
    • 14.2: Well-Determined Fully Specified System
      This page covers solving well-determined N-th order linear systems using Python's NumPy library, emphasizing the use of the numpy.linalg.solve() function for both non-singular and singular systems. It explains well-determined systems (with equal equations and variables) and how to handle situations with singular matrices (determinant of zero) that result in no unique solutions.
    • 14.3: Underdetermined Systems
      This page discusses solving underdetermined systems of linear equations, characterized by more variables than equations. It highlights methods like the pseudoinverse and least-squares to find particular and general solutions, with examples using Python libraries. The particular solution is illustrated and verified, alongside the identification of the null space to explore various solution forms.
    • 14.4: Overdetermined Systems
      This page explains overdetermined systems of linear equations, emphasizing the lack of exact solutions due to inconsistencies. It introduces the least squares method for finding approximate solutions by minimizing squared residuals, noting its uniqueness under full column rank conditions and representation by normal equations.
    • 14.5: A General Solution
      This page discusses the Moore-Penrose pseudo-inverse, which generalizes the matrix inverse for various types of matrices, including singular ones. It provides a method for finding best-fit solutions in overdetermined and underdetermined systems. The application of the pseudo-inverse is illustrated through examples, including solving a system with a singular matrix, demonstrating its capability to achieve minimum-norm solutions.
    • 14.6: Summary
      This page discusses methods for solving systems of linear equations, categorizing them as well-determined, underdetermined, or overdetermined. Well-determined systems have unique solutions via matrix inversion or numerical solvers; underdetermined systems have infinitely many solutions defined by a particular solution and the null space; overdetermined systems typically lack exact solutions, requiring the least squares method for approximations.


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