How to resolve the algorithm QR decomposition step by step in the MATLAB / Octave programming language
How to resolve the algorithm QR decomposition step by step in the MATLAB / Octave programming language
Table of Contents
Problem Statement
Any rectangular
m × n
{\displaystyle m\times n}
matrix
A
{\displaystyle {\mathit {A}}}
can be decomposed to a product of an orthogonal matrix
Q
{\displaystyle {\mathit {Q}}}
and an upper (right) triangular matrix
R
{\displaystyle {\mathit {R}}}
, as described in QR decomposition. Task Demonstrate the QR decomposition on the example matrix from the Wikipedia article: and the usage for linear least squares problems on the example from Polynomial regression. The method of Householder reflections should be used: Method Multiplying a given vector
a
{\displaystyle {\mathit {a}}}
, for example the first column of matrix
A
{\displaystyle {\mathit {A}}}
, with the Householder matrix
H
{\displaystyle {\mathit {H}}}
, which is given as reflects
a
{\displaystyle {\mathit {a}}}
about a plane given by its normal vector
u
{\displaystyle {\mathit {u}}}
. When the normal vector of the plane
u
{\displaystyle {\mathit {u}}}
is given as then the transformation reflects
a
{\displaystyle {\mathit {a}}}
onto the first standard basis vector which means that all entries but the first become zero. To avoid numerical cancellation errors, we should take the opposite sign of
a
1
{\displaystyle a_{1}}
: and normalize with respect to the first element: The equation for
H
{\displaystyle H}
thus becomes: or, in another form with Applying
H
{\displaystyle {\mathit {H}}}
on
a
{\displaystyle {\mathit {a}}}
then gives and applying
H
{\displaystyle {\mathit {H}}}
on the matrix
A
{\displaystyle {\mathit {A}}}
zeroes all subdiagonal elements of the first column: In the second step, the second column of
A
{\displaystyle {\mathit {A}}}
, we want to zero all elements but the first two, which means that we have to calculate
H
{\displaystyle {\mathit {H}}}
with the first column of the submatrix (denoted *), not on the whole second column of
A
{\displaystyle {\mathit {A}}}
. To get
H
2
{\displaystyle H_{2}}
, we then embed the new
H
{\displaystyle {\mathit {H}}}
into an
m × n
{\displaystyle m\times n}
identity: This is how we can, column by column, remove all subdiagonal elements of
A
{\displaystyle {\mathit {A}}}
and thus transform it into
R
{\displaystyle {\mathit {R}}}
. The product of all the Householder matrices
H
{\displaystyle {\mathit {H}}}
, for every column, in reverse order, will then yield the orthogonal matrix
Q
{\displaystyle {\mathit {Q}}}
. The QR decomposition should then be used to solve linear least squares (Multiple regression) problems
A
x
b
{\displaystyle {\mathit {A}}x=b}
by solving When
R
{\displaystyle {\mathit {R}}}
is not square, i.e.
m
n
{\displaystyle m>n}
we have to cut off the
m
− n
{\displaystyle {\mathit {m}}-n}
zero padded bottom rows. and the same for the RHS: Finally, solve the square upper triangular system by back substitution:
Let's start with the solution:
Step by Step solution about How to resolve the algorithm QR decomposition step by step in the MATLAB / Octave programming language
Source code in the matlab programming language
A = [12 -51 4
6 167 -68
-4 24 -41];
[Q,R]=qr(A)
You may also check:How to resolve the algorithm Parallel calculations step by step in the Delphi programming language
You may also check:How to resolve the algorithm Non-decimal radices/Convert step by step in the Fortran programming language
You may also check:How to resolve the algorithm Hough transform step by step in the zkl programming language
You may also check:How to resolve the algorithm Character codes step by step in the Elena programming language
You may also check:How to resolve the algorithm Happy numbers step by step in the PARI/GP programming language