Lectures related to Linear Transformations and Change of Bases

Explores characteristic polynomials, similarity of matrices, and eigenvalues in linear transformations.

Covers linear applications, matrices, transformations, and the principle of superposition.

Covers the theory and examples of diagonalizing matrices, focusing on eigenvalues, eigenvectors, and linear independence.

Covers linear transformations using matrices, focusing on linearity, image, and kernel.

Covers the concept of basis, linear transformations, matrices, inverses, determinants, and bijective transformations.

Explores eigenvalues and eigenvectors in 3D linear algebra, covering characteristic polynomials, stability under transformations, and real roots.

Explores the relationship between matrices under different bases in linear algebra.

Explores change of basis matrices in linear algebra, emphasizing the importance of understanding matrix transformations between different bases.

Covers diagonalization of matrices, eigenvectors, linear maps, and least squares method.

Covers the reduction of a linear application and finding corresponding reduced forms and bases.

Introduces eigenspaces in linear algebra through definitions and practical examples of determining eigenspaces for matrices.

Explores linear applications in R² and matrix representation, including basis, operations, and geometric interpretation of transformations.

Explains the diagonalization of matrices, criteria, and significance of distinct eigenvalues.

Explores diagonalization in 3D linear algebra, covering conditions for diagonalizability and eigenvectors.

Explores matrix similarity, diagonalization, characteristic polynomials, eigenvalues, and eigenvectors in linear algebra.

Covers the diagonalization of linear transformations in R^3, exploring properties and examples.

Explains the construction of U, verification of results, and interpretation of SVD in matrix decomposition.

Covers the concept of expressing vectors in proper bases and the importance of diagonalization of matrices.

Explores eigenvalues and eigenvectors, demonstrating their importance in linear algebra and their application in solving systems of equations.

Explains the diagonalization of linear transformations using eigenvectors and eigenvalues to form a diagonal matrix.