HP 15c User Manual

Section 4: Using Matrix Operations

119

)

rows

1

(

),

row

1

(

rows)

(

ˆ



























p

n

p

q

0

0

0

g

U

V

and Û is an upper-triangular matrix. If this factorization results from including n rows

r

m

=

(x

m1

, x

m2

, …, x

mp

, y

m

)

for m = 1, 2, ... , n in [X y], consider how to advance to n + 1 rows

by appending row

r

n+1

to[X y]:











































1

1

1

0

0

n

T

n

r

V

Q

r

y

X

.

The zero rows of V are discarded.

Multiply the (p + 2) × (p + 1) matrix

)

1

(

)

1

(

)

(

ˆ

1

row

row

rows

p

q

n

























r

0

g

U

A

by a product of elementary orthogonal matrices, each differing from the identity matrix

I

p+2

In only two rows and two columns. For k = 1, 2, ... , p + 1 in turn, the k th orthogonal matrix
acts on the k th and last rows to delete the k th element of the last row to alter subsequent
elements in the last row. The k th orthogonal matrix has the form







































































C

s

s

c

1

0

1

1

0

1











where c = cos(θ), s = sin(θ), and θ = tan

-1

(a

p+2,k

/ a

kk

). After p + 1 such factors have been

applied to matrix A, it will look like