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Title: Lecture 14 - Eigen-analysis


1
Lecture 14 - Eigen-analysis
  • CVEN 302
  • July 10, 2002

2
Lectures Goals
  • QR Factorization
  • Householder
  • Hessenberg Method

3
QR Factorization
The technique can be used to find the eigenvalue
using a successive iteration using Householder
transformation to find an equivalent matrix to
A having an eigenvalues on the diagonal
4
QR Factorization
Another form of factorization
A QR
Produces an orthogonal matrix (Q) and a right
upper triangular matrix (R) Orthogonal matrix
- inverse is transpose
5
QR Factorization
Why do we care? We can use Q and R to find
eigenvalues 1. Get Q and R (A QR) 2. Let A
RQ 3. Diagonal elements of A are eigenvalue
approximations 4. Iterate until converged
Note QR eigenvalue method gives all eigenvalues
simultaneously, not just the
dominant ?
6
QR Eigenvalue Method
In practice, QR factorization on any given matrix
requires a number of steps First transform A into
Hessenberg form
Hessenberg matrix - upper triangular plus first
sub-diagonal
Special properties of Hessenberg matrix make it
easier to find Q, R, and eigenvalues
7
QR Factorization
  • Construction of QR Factorization

8
QR Factorization
  • Use Householder reflections and given rotations
    to reduce certain elements of a vector to zero.
  • Use QR factorization that preserve the
    eigenvalues.
  • The eigenvalues of the transformed matrix are
    much easier to obtain.

9
Jordan Canonical Form
  • Any square matrix is orthogonally similar to a
    triangular matrix with the eigenvalues on the
    diagonal

10
Similarity Transformation
  • Transformation of the matrix A of the form H-1AH
    is known as similarity transformation.
  • A real matrix Q is orthogonal if QTQ I.
  • If Q is orthogonal, then A and Q -1AQ are said to
    be orthogonally similar
  • The eigenvalues are preserved under the
    similarity transformation.

11
Upper Triangular Matrix
  • The diagonal elements Rii of the upper triangular
    matrix R are the eigenvalues

12
Householder Reflector
  • Householder reflector is a matrix of the form
  • It is straightforward to verify that Q is
    symmetric and orthogonal

13
Householder Matrix
  • Householder matrix reduces zk1 ,,zn to zero
  • To achieve the above operation, v must be a
    linear combination of x and ek

14
Householder Transformation
15
Householder Matrix
  • Corollary (kth Householder matrix) Let A be an
    nxn matrix and x any vector. If k is an integer
    with 1lt kltn-1 we can construct a vector w(k)
    and matrix H(k) I - 2w(k)w(k) so that

16
Householder matrix
  • Define the value ? so that
  • The vector w is found by
  • Choose ? sign(xk)g to reduce round-off error

17
Householder Matrices
18
Example Householder Matrix
19
Example Householder Matrix
20
Basic QR Factorization
  • A Q R
  • Q is orthogonal, QTQ I
  • R is upper triangular
  • QR factorization using Householder matrices
  • Q H(1)H(2).H(n-1)

21
Example QR Factorization
22
QR Factorization
QR A
  • Similarity transformation B QTAQ preserve the
    eigenvalues

23
Finding Eigenvalues Using QR Factorization
  • Generate a sequence A(m) that are orthogonally
    similar to A
  • Use Householder transformation H-1AH
  • the iterates converge to an upper triangular
    matrix with the eigenvalues on the diagonal

Find all eigenvalues simultaneously!
24
QR Eigenvalue Method
  • QR factorization A QR
  • Similarity transformation A(new) RQ

25
Example QR Eigenvalue
26
Example QR Eigenvalue
27
MATLAB Example
A 2.4634 1.8104 -1.3865 -0.0310
3.0527 1.7694 0.0616 -0.1047 -0.5161 A
2.4056 1.8691 1.3930 0.0056
2.9892 -1.9203 0.0099 -0.0191 -0.3948 A
2.4157 1.8579 -1.3937 -0.0010
3.0021 1.8930 0.0017 -0.0038 -0.4178 A
2.4140 1.8600 1.3933 0.0002
2.9996 -1.8982 0.0003 -0.0007 -0.4136 A
2.4143 1.8596 -1.3934 0.0000
3.0001 1.8972 0.0001 -0.0001
-0.4143 e 2.4143 3.0001 -0.4143
A1 2 -1 2 2 -1 2 -1 2 A 1 2
-1 2 2 -1 2 -1 2
Q,RQR_factor(A) Q -0.3333 -0.5788
-0.7442 -0.6667 -0.4134 0.6202 -0.6667
0.7029 -0.2481 R -3.0000 -1.3333
-0.3333 0.0000 -2.6874 2.3980 0.0000
0.0000 -0.3721 eQR_eig(A,6) A
2.1111 2.0535 1.4884 0.1929 2.7966
-2.2615 0.2481 -0.2615 0.0923
QR factorization
eigenvalue
28
Improved QR Method
  • Using similarity transformation to form an upper
    Hessenberg Matrix (upper triangular matrix one
    nonzero band below diagonal) .
  • More efficient to form Hessenberg matrix without
    explicitly forming the Householder matrices (not
    given in textbook).

function A Hessenberg(A) n,nn size(A) for
k 1n-2 H Householder(A(,k),k1)
A HAH end
29
Improved QR Method
A 2.4056 -2.1327 0.9410 -0.0114
-0.4056 -1.9012 0.0000 0.0000
3.0000 A 2.4157 2.1194 -0.9500
-0.0020 -0.4157 -1.8967 0.0000 0.0000
3.0000 A 2.4140 -2.1217 0.9485
-0.0003 -0.4140 -1.8975 0.0000 0.0000
3.0000 A 2.4143 2.1213 -0.9487
-0.0001 -0.4143 -1.8973 0.0000 0.0000
3.0000 e 2.4143 -0.4143 3.0000
eig(A) ans 2.4142 -0.4142 3.0000
A1 2 -1 2 2 -1 2 -1 2 A 1 2
-1 2 2 -1 2 -1 2
Q,RQR_factor_g(A) Q 0.4472 0.5963
-0.6667 0.8944 -0.2981 0.3333 0
-0.7454 -0.6667 R 2.2361 2.6833
-1.3416 -1.4907 1.3416 -1.7889 -1.3333
0 -1.0000 eQR_eig_g(A,6) A
2.1111 -2.4356 0.7071 -0.3143 -0.1111
-2.0000 0 0.0000 3.0000 A
2.4634 2.0523 -0.9939 -0.0690 -0.4634
-1.8741 0.0000 0.0000 3.0000
Hessenberg matrix
eigenvalue
MATLAB function
30
Summary
  • QR Factorization
  • Householder matrix
  • Hessenberg matrix

31
Interpolation
32
Lectures Goals
  • Interpolation methods
  • Lagranges Interpolation
  • Newtons Interpolation
  • Hermites Interpolation
  • Rational Function Interpolation
  • Spline (Linear,Quadratic, Cubic)
  • Interpolation of 2-D data

33
Interpolation Methods
Why would we be interested in interpolation
methods?
  • Interpolation method are the basis for other
    procedures that we will deal with
  • Numerical differentiation
  • Numerical integration
  • Solution of ODE (ordinary differential equations)
    and PDE (partial differential equations)

34
Interpolation Methods
Why would we be interested in interpolation
methods?
  • These methods demonstrate some important theory
    about polynomials and the accuracy of numerical
    methods.
  • The interpolation of polynomials serve as an
    excellent introduction to some techniques for
    drawing smooth curves.

35
Interpolation Methods
Interpolation uses the data to approximate a
function, which will fit all of the data points.
All of the data is used to approximate the values
of the function inside the bounds of the data.
We will look at polynomial and rational function
interpolation of the data and piece-wise
interpolation of the data.
36
Polynomial Interpolation Methods
  • Lagrange Interpolation Polynomial - a
    straightforward, but computational awkward way to
    construct an interpolating polynomial.
  • Newton Interpolation Polynomial - there is no
    difference between the Newton and Lagrange
    results. The difference between the two is the
    approach to obtaining the coefficients.

37
Lagrange Interpolation
This method is generally the easiest to work.
The data does not have to be equally spaced and
is useful for finding the points between
quadratic and cubic methods. However, it does
not provide an accurate model for large sets of
terms.
38
Lagrange Interpolation
The function can be defined as
where,
39
Lagrange Interpolation
The function can be defined as
where, the coefficients are defined as
40
Lagrange Interpolation
The method works for quadratic and cubic
polynomials. As you add additional points in the
degree of the polynomial increases. So if you
have n points it will fit a (n-1)th degree
polynomial.
41
Example of Lagrange Interpolation
What are the coefficients of the polynomial and
what is the value of P2(2.3)?
42
Example of Lagrange Interpolation
  • The values are evaluated
  • P(x) 9.2983(x-1.7)(x-3.0)
  • - 19.4872(x-1.1)(x-3.0)
  • 8.2186(x-1.1)(x-1.7)
  • P(2.3) 9.2983(2.3-1.7)(2.3-3.0)
  • - 19.4872(2.3-1.1)(2.3-3.0)
  • 8.2186(2.3-1.1)(2.3-1.7)
  • 18.3813

43
Lagrange Interpolation Program
The Lagrange interpolation is broken up into two
programs to evaluate the new polynomial.
  • C Lagrange_coef(x,y), which evaluates the
    coefficients of the Lagrange technique
  • P(x) Lagrange_eval(t,x,c), which uses the
    coefficients and x values to evaluate the
    polynomial
  • Plottest(x,y),which will plot the Lagrange
    polynomial

44
Example of Lagrange Interpolation
What happens if we increase the number of data
points?
Coefficient for 2 is
45
Example of Lagrange Interpolation
Note that the coefficient creates a P4(x)
polynomial and comparison between the two curves.
The original value P2(x) is given. The problem
with adding additional points will create
bulges in the graph.
46
Newton Interpolation
The Newton interpolation uses a divided
difference method. The technique allows one to
add additional points easily.
47
Newton Interpolation
For given set of data points (x1,y1), (x2,y2),
(x3,y3)
48
Newton Interpolation
The function can be defined as
49
Newton Interpolation
The method works for quadratic and cubic
polynomials. As you add additional points in the
degree of the polynomial increases. So if you
have n points it will fit a (n-1)th degree
polynomial. The method is setup to show the a
pattern for combining a table computation and
provide additional points.
50
Example of Newton Interpolation
What are the coefficients of the polynomial and
what is the value of P2(2.3)?
The true function of the points is f(x) 2x
51
Example of Newton Interpolation
52
Example of Newton Interpolation
The coefficients are the top row of the chart
53
Example of Newton Interpolation
  • The values are evaluated
  • P(x) 1 (x-0)
  • 0.5(x-0)(x-1)
  • 0.1667(x-0)(x-1)(x-2)
  • 0.04167(x)(x-1)(x-2)(x-3)
  • P(2.3) 1 (2.3)
  • 0.5(2.3)(1.3)
  • 0.1667(2.3)(1.3)(0.3)
  • 0.04167(2.3)(1.3)(0.3)(-0.7)
  • 4.9183 (4.9246)

54
Newton Interpolation Program
The Newton interpolation is broken up into two
programs to evaluate the new polynomial.
  • C Newton_coef(x,y), which evaluates the
    coefficients of the Newton technique
  • P(x) Newton_eval(t,x,c), which uses the
    coefficients and x values to evaluate the
    polynomial
  • Plottest_new(x,y),which will plot the Newton
    polynomial

55
Summary
  • The Lagrange and Newton Interpolation are
    basically the same methods, but use different
    coefficients. The polynomials depend on the
    entire set of data points.

56
Homework
  • Check the Homework webpage
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