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Sec 3.4 Eigen values and Eigen vectors.pptx
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- 2. Section 3.4 Eigen Valuesand Eigenvectors
- 3. Eigen vectors A = X= FindAX. Now take X= and find AX 2 1 4 5 1 2 1 4
- 4. Few things toknow about Eigen values and Eigen vectors Eigenvalues are often introduced in the context of linear algebra or matrix theory. Historically, however, they arose in the study of quadratic forms and differential equations.
- 5. In the 18thcentury Euler studied the rotational motion of a rigid body and discovered the importance of the principal axes. Lagrange realized that the principal axes are the eigenvectors of the inertia matrix.
- 6. Now it findsapplications in Statistics -Principal component analysis. Physics- Vibration analysis Image processing/ Image compression Population growth models Stability analysis in control theory Structural mechanics Google search engine
- 7. Definition If A isan nxn matrix. A real number λ is an eigen value of A iff there is a non zero n- vector X such that AX= λX. This non zero vector X is called an eigen vector corresponding to the eigen value λ.
- 8. Problem If verify that -1is an eigen value of A and X= is the associated Eigen vector. 1 2 2 1 2 1 3 2 2 A 1 0 1
- 9. Method of findingEigen Pairs let X be an eigenvector of A corresponding to the eigen value λ, then we have AX= λX This homogeneous system has a nontrivial solution if …………….(1) (1) is called the characteristic equation of A. 0 A I X 0 A I
- 10. This is apolynomial equation that has n roots say These roots are called the eigen values of A . Now, for each λ solve A X= λ X to get the corresponding eigen vector. 1 2 , ,... n
- 11. Problem Find the characteristicpolynomial of 3 1 1 2 A
- 12. Problem Find the eigenvalues and the associated eigen vectors of 1 2 2 1 2 1 3 2 2 A
- 13. Properties of Eigenpairs If X is an eigenvector of A associated with an eigenvalue and k is any nonzero scalar, kX is also an eigenvector of A associated with the same eigenvalue.
- 14. Properties continued Aneigenvector X of A X= λ X cannot correspond to more than one eigenvalue of A. If A is an upper ( lower) or diagonal, then the eigenvalues of A are the elements of the main diagonal of A. A and AT have the same eigenvalues.
- 15. Properties continued If λis an eigenvalue of A with associated eigenvector X. Then λk is an eigenvalue of Ak associated with the same eigenvector X. If λ is an eigen value of A with associated eigenvector X. Then 1/ λ is an eigenvalue of A-1 with associated vector X. The sum of the eigenvalues of A = Trace(A).
- 16. If λ =0is an eigenvalue of A, then A is not invertible. The determinant of A is the product of the eigenvalues of A.
- 17. Problem If A isidempotent, Show that the only possible eigenvalues of A are 0 and 1.
- 18. Problems contd.. IfA is a matrix all of whose columns add up to 1, then 1 is an eigenvalue of A. If A= , find the eigenvalues of 2 0 0 2 3 0 3 2 1 I A A A 2 6 5 3 2 3
- 19. Find the eigenpairsfor the following matrices 1 2 1 1 0 1 3 4 3 A 0 1 1 1 0 1 1 1 0 A
- 20. Cayley Hamilton Theorem EverySquare matrix satisfies its characteristic equation.
- 21. Problem Verify Cayley Hamiltontheorem for And hence find A3 and A-1 6 8 4 6 A
- 22. Applications of Eigenvectors Google ◦To rank web pages for a given query, Google calculates an eigenvector of a matrix A (n n) ◦ = 1 if page i links to page j; 0 otherwise ◦ is the number of links to page j ◦ p is the fraction of pages searched that have outgoing links (usually taken as 0.85) 1 ij ij j n a g p p c ij g j c
- 23. Applications of Eigenvectors (continued) Google ◦Let x be an eigenvector corresponding to λ = 1 ◦ Normalize x so that the sum of its components equals 1 ◦ This vector gives Google’s PageRank ◦ The determinant method can be used to find eigenvectors of small matrices, but it is not practical for large matrices such as A (2.7 billion 2.7 billion in 2002) – Google’s method is unknown