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 Page 1


1 Quadratic Forms
A quadratic function f : R! R has the form f(x) = a¢x
2
. Generalization
of this notion to two variables is the quadratic form
Q(x
1
;x
2
)=a
11
x
2
1
+a
12
x
1
x
2
+a
21
x
2
x
1
+a
22
x
2
2
:
Here each term has degree 2 (the sum of exponents is 2 for all summands).
A quadratic form of three variables looks as
f(x
1
;x
2
;x
3
)=
a
11
x
2
1
+a
12
x
1
x
2
+a
13
x
1
x
3
+
a
21
x
2
x
1
+a
22
x
2
2
+a
23
x
2
x
3
+
a
31
x
1
x
3
+a
32
x
3
x
2
+a
33
x
2
3
:
Ageneralquadraticformofnvariablesisareal-valuedfunctionQ:R
n
!
R of the form
Q(x
1
;x
2
;:::;x
n
)= a
11
x
2
1
+ a
12
x
1
x
2
+ ::: + a
1n
x
1
x
n
+
a
21
x
2
x
1
+ a
22
x
2
2
+ ::: + a
2n
x
2
x
n
+
::: ::: ::: :::
a
n1
x
n
x
1
+ a
n2
x
n
x
2
+ ::: + a
nn
x
2
n
In short Q(x
1
;x
2
;:::;x
n
)=
P
n
i;j
a
ij
x
i
x
j
.
As we see a quadratic form is determined by the matrix
A=
0
B
@
a
11
::: a
1n
::::::::::::::
a
n1
::: a
nn
1
C
A:
1.1 Matrix Representation of Quadratic Forms
Let Q(x
1
;x
2
;:::;x
n
)=
P
n
i;j
a
ij
x
i
x
j
be a quadratic form with matrix A. Easy
to see that
Q(x
1
;:::;x
n
)=(x
1
;:::;x
n
)¢
0
B
@
a
11
::: a
1n
::::::::::::::
a
n1
::: a
nn
1
C
A¢
0
B
@
x
1
::
x
n
1
C
A:
Page 2


1 Quadratic Forms
A quadratic function f : R! R has the form f(x) = a¢x
2
. Generalization
of this notion to two variables is the quadratic form
Q(x
1
;x
2
)=a
11
x
2
1
+a
12
x
1
x
2
+a
21
x
2
x
1
+a
22
x
2
2
:
Here each term has degree 2 (the sum of exponents is 2 for all summands).
A quadratic form of three variables looks as
f(x
1
;x
2
;x
3
)=
a
11
x
2
1
+a
12
x
1
x
2
+a
13
x
1
x
3
+
a
21
x
2
x
1
+a
22
x
2
2
+a
23
x
2
x
3
+
a
31
x
1
x
3
+a
32
x
3
x
2
+a
33
x
2
3
:
Ageneralquadraticformofnvariablesisareal-valuedfunctionQ:R
n
!
R of the form
Q(x
1
;x
2
;:::;x
n
)= a
11
x
2
1
+ a
12
x
1
x
2
+ ::: + a
1n
x
1
x
n
+
a
21
x
2
x
1
+ a
22
x
2
2
+ ::: + a
2n
x
2
x
n
+
::: ::: ::: :::
a
n1
x
n
x
1
+ a
n2
x
n
x
2
+ ::: + a
nn
x
2
n
In short Q(x
1
;x
2
;:::;x
n
)=
P
n
i;j
a
ij
x
i
x
j
.
As we see a quadratic form is determined by the matrix
A=
0
B
@
a
11
::: a
1n
::::::::::::::
a
n1
::: a
nn
1
C
A:
1.1 Matrix Representation of Quadratic Forms
Let Q(x
1
;x
2
;:::;x
n
)=
P
n
i;j
a
ij
x
i
x
j
be a quadratic form with matrix A. Easy
to see that
Q(x
1
;:::;x
n
)=(x
1
;:::;x
n
)¢
0
B
@
a
11
::: a
1n
::::::::::::::
a
n1
::: a
nn
1
C
A¢
0
B
@
x
1
::
x
n
1
C
A:
Equivalently Q(x)=x
T
¢A¢x.
Example. The quadratic form Q(x
1
;x
2
;x
3
) = 5x
2
1
¡ 10x
1
x
2
+ x
2
2
whose
symmetric matrix is A=
Ã
5 ¡5
¡5 1
!
is the product of three matrices
(x
1
;x
2
;x
3
)¢
Ã
5 ¡5
¡5 1
!
¢
0
B
@
x
1
x
2
x
3
1
C
A:
1.1.1 Symmetrization of matrix
The quadratic form Q(x
1
;x
2
;x
3
)=5x
2
1
¡10x
1
x
2
+x
2
2
can be represented, for
example, by the following 2£2 matrices
Ã
5 ¡2
¡8 1
!
;
Ã
5 ¡3
¡7 1
!
;
Ã
5 ¡5
¡5 1
!
the last one is symmetric: a
ij
=a
ji
.
Theorem 1 Any quadratic form can be represented by symmetric matrix.
Indeed, if a
ij
6= a
ji
we replace them by new a
0
ij
= a
0
ji
=
a
ij
+a
ji
2
, this does
not change the corresponding quadratic form.
Generally, one can ?nd symmetrization A
0
of a matrix A by A
0
=
A+A
T
2
.
1.2 De?niteness of Quadratic Forms
A quadratic form of one variable is just a quadratic function Q(x)=a¢x
2
.
If a> 0 then Q(x)>0 for each nonzero x.
If a< 0 then Q(x)<0 for each nonzero x.
Sothesignofthecoe?cientadeterminesthesignofonevariable quadratic
form.
The notion of de?niteness described bellow generalizes this phenomenon
for multivariable quadratic forms.
1.2.1 Generic Examples
The quadratic form Q(x;y) = x
2
+ y
2
is positive for all nonzero (that is
(x;y)6=(0;0)) arguments (x;y). Such forms are called positive de?nite.
The quadratic form Q(x;y) =¡x
2
¡y
2
is negative for all nonzero argu-
ments (x;y). Such forms are called negative de?nite.
The quadratic form Q(x;y) = (x¡y)
2
is nonnegative. This means that
Q(x;y) = (x¡y)
2
is either positive or zero for nonzero arguments. Such
forms are called positive semide?nite.
Page 3


1 Quadratic Forms
A quadratic function f : R! R has the form f(x) = a¢x
2
. Generalization
of this notion to two variables is the quadratic form
Q(x
1
;x
2
)=a
11
x
2
1
+a
12
x
1
x
2
+a
21
x
2
x
1
+a
22
x
2
2
:
Here each term has degree 2 (the sum of exponents is 2 for all summands).
A quadratic form of three variables looks as
f(x
1
;x
2
;x
3
)=
a
11
x
2
1
+a
12
x
1
x
2
+a
13
x
1
x
3
+
a
21
x
2
x
1
+a
22
x
2
2
+a
23
x
2
x
3
+
a
31
x
1
x
3
+a
32
x
3
x
2
+a
33
x
2
3
:
Ageneralquadraticformofnvariablesisareal-valuedfunctionQ:R
n
!
R of the form
Q(x
1
;x
2
;:::;x
n
)= a
11
x
2
1
+ a
12
x
1
x
2
+ ::: + a
1n
x
1
x
n
+
a
21
x
2
x
1
+ a
22
x
2
2
+ ::: + a
2n
x
2
x
n
+
::: ::: ::: :::
a
n1
x
n
x
1
+ a
n2
x
n
x
2
+ ::: + a
nn
x
2
n
In short Q(x
1
;x
2
;:::;x
n
)=
P
n
i;j
a
ij
x
i
x
j
.
As we see a quadratic form is determined by the matrix
A=
0
B
@
a
11
::: a
1n
::::::::::::::
a
n1
::: a
nn
1
C
A:
1.1 Matrix Representation of Quadratic Forms
Let Q(x
1
;x
2
;:::;x
n
)=
P
n
i;j
a
ij
x
i
x
j
be a quadratic form with matrix A. Easy
to see that
Q(x
1
;:::;x
n
)=(x
1
;:::;x
n
)¢
0
B
@
a
11
::: a
1n
::::::::::::::
a
n1
::: a
nn
1
C
A¢
0
B
@
x
1
::
x
n
1
C
A:
Equivalently Q(x)=x
T
¢A¢x.
Example. The quadratic form Q(x
1
;x
2
;x
3
) = 5x
2
1
¡ 10x
1
x
2
+ x
2
2
whose
symmetric matrix is A=
Ã
5 ¡5
¡5 1
!
is the product of three matrices
(x
1
;x
2
;x
3
)¢
Ã
5 ¡5
¡5 1
!
¢
0
B
@
x
1
x
2
x
3
1
C
A:
1.1.1 Symmetrization of matrix
The quadratic form Q(x
1
;x
2
;x
3
)=5x
2
1
¡10x
1
x
2
+x
2
2
can be represented, for
example, by the following 2£2 matrices
Ã
5 ¡2
¡8 1
!
;
Ã
5 ¡3
¡7 1
!
;
Ã
5 ¡5
¡5 1
!
the last one is symmetric: a
ij
=a
ji
.
Theorem 1 Any quadratic form can be represented by symmetric matrix.
Indeed, if a
ij
6= a
ji
we replace them by new a
0
ij
= a
0
ji
=
a
ij
+a
ji
2
, this does
not change the corresponding quadratic form.
Generally, one can ?nd symmetrization A
0
of a matrix A by A
0
=
A+A
T
2
.
1.2 De?niteness of Quadratic Forms
A quadratic form of one variable is just a quadratic function Q(x)=a¢x
2
.
If a> 0 then Q(x)>0 for each nonzero x.
If a< 0 then Q(x)<0 for each nonzero x.
Sothesignofthecoe?cientadeterminesthesignofonevariable quadratic
form.
The notion of de?niteness described bellow generalizes this phenomenon
for multivariable quadratic forms.
1.2.1 Generic Examples
The quadratic form Q(x;y) = x
2
+ y
2
is positive for all nonzero (that is
(x;y)6=(0;0)) arguments (x;y). Such forms are called positive de?nite.
The quadratic form Q(x;y) =¡x
2
¡y
2
is negative for all nonzero argu-
ments (x;y). Such forms are called negative de?nite.
The quadratic form Q(x;y) = (x¡y)
2
is nonnegative. This means that
Q(x;y) = (x¡y)
2
is either positive or zero for nonzero arguments. Such
forms are called positive semide?nite.
The quadratic form Q(x;y)=¡(x¡y)
2
is nonpositive. This means that
Q(x;y) = (x¡y)
2
is either negative or zero for nonzero arguments. Such
forms are called negative semide?nite.
The quadratic form Q(x;y) = x
2
¡ y
2
is called inde?nite since it can
take both positive and negative values, for example Q(3;1) = 9¡1 = 8 >
0; Q(1;3)=1¡9=¡8<0.
1.2.2 De?niteness
De?nition. A quadratic form Q(x) = x
T
¢A¢x (equivalently a symmetric
matrix A) is
(a) positive de?nite if Q(x)>0 for all x6=02R
n
;
(b) positive semide?nite if Q(x)¸0 for all x6=02R
n
;
(c) negative de?nite if Q(x)<0 for all x6=02R
n
;
(d) negative semide?nite if Q(x)·0 for all x6=02R
n
;
(e) inde?nite if Q(x)>0 for some x and Q(x)<0 for some other x.
1.2.3 De?niteness and Optimality
Determiningthede?nitenessofquadraticformQisequivalenttodetermining
wether x=0 is max, min or neither. Particularly:
If Q is positive de?nite then x=0 is global maximum;
If Q is negative de?nite then x=0 is global minimum.
1.2.4 De?niteness of 2 Variable Quadratic Form
Let Q(x
1
;x
2
) = ax
2
1
+ 2bx
1
x
2
+ cx
2
2
= (x
1
;x
2
)¢
Ã
a b
b c
!
¢
Ã
x
1
x
2
!
be a 2
variable quadratic form.
Here A =
Ã
a b
b c
!
is the symmetric matrix of the quadratic form. The
determinant
¯
¯
¯
¯
¯
a b
b c
¯
¯
¯
¯
¯
=ac¡b
2
is called discriminant of Q.
Easy to see that
ax
2
1
+2bx
1
x
2
+cx
2
2
=a(x
1
+
b
a
x
2
)
2
+
ac¡b
2
a
x
2
2
:
Let us use the notation D
1
= a; D
2
= ac¡ b
2
. Actually D
1
and D
2
are
leading principal minors of A. Note that there exists one more principal
(non leading) minor (of degree 1) D
0
1
=c.
Then
Q(x
1
;x
2
)=D
1
(x
1
+
b
a
x
2
)
2
+
D
2
D
1
x
2
2
:
From this expression we obtain:
Page 4


1 Quadratic Forms
A quadratic function f : R! R has the form f(x) = a¢x
2
. Generalization
of this notion to two variables is the quadratic form
Q(x
1
;x
2
)=a
11
x
2
1
+a
12
x
1
x
2
+a
21
x
2
x
1
+a
22
x
2
2
:
Here each term has degree 2 (the sum of exponents is 2 for all summands).
A quadratic form of three variables looks as
f(x
1
;x
2
;x
3
)=
a
11
x
2
1
+a
12
x
1
x
2
+a
13
x
1
x
3
+
a
21
x
2
x
1
+a
22
x
2
2
+a
23
x
2
x
3
+
a
31
x
1
x
3
+a
32
x
3
x
2
+a
33
x
2
3
:
Ageneralquadraticformofnvariablesisareal-valuedfunctionQ:R
n
!
R of the form
Q(x
1
;x
2
;:::;x
n
)= a
11
x
2
1
+ a
12
x
1
x
2
+ ::: + a
1n
x
1
x
n
+
a
21
x
2
x
1
+ a
22
x
2
2
+ ::: + a
2n
x
2
x
n
+
::: ::: ::: :::
a
n1
x
n
x
1
+ a
n2
x
n
x
2
+ ::: + a
nn
x
2
n
In short Q(x
1
;x
2
;:::;x
n
)=
P
n
i;j
a
ij
x
i
x
j
.
As we see a quadratic form is determined by the matrix
A=
0
B
@
a
11
::: a
1n
::::::::::::::
a
n1
::: a
nn
1
C
A:
1.1 Matrix Representation of Quadratic Forms
Let Q(x
1
;x
2
;:::;x
n
)=
P
n
i;j
a
ij
x
i
x
j
be a quadratic form with matrix A. Easy
to see that
Q(x
1
;:::;x
n
)=(x
1
;:::;x
n
)¢
0
B
@
a
11
::: a
1n
::::::::::::::
a
n1
::: a
nn
1
C
A¢
0
B
@
x
1
::
x
n
1
C
A:
Equivalently Q(x)=x
T
¢A¢x.
Example. The quadratic form Q(x
1
;x
2
;x
3
) = 5x
2
1
¡ 10x
1
x
2
+ x
2
2
whose
symmetric matrix is A=
Ã
5 ¡5
¡5 1
!
is the product of three matrices
(x
1
;x
2
;x
3
)¢
Ã
5 ¡5
¡5 1
!
¢
0
B
@
x
1
x
2
x
3
1
C
A:
1.1.1 Symmetrization of matrix
The quadratic form Q(x
1
;x
2
;x
3
)=5x
2
1
¡10x
1
x
2
+x
2
2
can be represented, for
example, by the following 2£2 matrices
Ã
5 ¡2
¡8 1
!
;
Ã
5 ¡3
¡7 1
!
;
Ã
5 ¡5
¡5 1
!
the last one is symmetric: a
ij
=a
ji
.
Theorem 1 Any quadratic form can be represented by symmetric matrix.
Indeed, if a
ij
6= a
ji
we replace them by new a
0
ij
= a
0
ji
=
a
ij
+a
ji
2
, this does
not change the corresponding quadratic form.
Generally, one can ?nd symmetrization A
0
of a matrix A by A
0
=
A+A
T
2
.
1.2 De?niteness of Quadratic Forms
A quadratic form of one variable is just a quadratic function Q(x)=a¢x
2
.
If a> 0 then Q(x)>0 for each nonzero x.
If a< 0 then Q(x)<0 for each nonzero x.
Sothesignofthecoe?cientadeterminesthesignofonevariable quadratic
form.
The notion of de?niteness described bellow generalizes this phenomenon
for multivariable quadratic forms.
1.2.1 Generic Examples
The quadratic form Q(x;y) = x
2
+ y
2
is positive for all nonzero (that is
(x;y)6=(0;0)) arguments (x;y). Such forms are called positive de?nite.
The quadratic form Q(x;y) =¡x
2
¡y
2
is negative for all nonzero argu-
ments (x;y). Such forms are called negative de?nite.
The quadratic form Q(x;y) = (x¡y)
2
is nonnegative. This means that
Q(x;y) = (x¡y)
2
is either positive or zero for nonzero arguments. Such
forms are called positive semide?nite.
The quadratic form Q(x;y)=¡(x¡y)
2
is nonpositive. This means that
Q(x;y) = (x¡y)
2
is either negative or zero for nonzero arguments. Such
forms are called negative semide?nite.
The quadratic form Q(x;y) = x
2
¡ y
2
is called inde?nite since it can
take both positive and negative values, for example Q(3;1) = 9¡1 = 8 >
0; Q(1;3)=1¡9=¡8<0.
1.2.2 De?niteness
De?nition. A quadratic form Q(x) = x
T
¢A¢x (equivalently a symmetric
matrix A) is
(a) positive de?nite if Q(x)>0 for all x6=02R
n
;
(b) positive semide?nite if Q(x)¸0 for all x6=02R
n
;
(c) negative de?nite if Q(x)<0 for all x6=02R
n
;
(d) negative semide?nite if Q(x)·0 for all x6=02R
n
;
(e) inde?nite if Q(x)>0 for some x and Q(x)<0 for some other x.
1.2.3 De?niteness and Optimality
Determiningthede?nitenessofquadraticformQisequivalenttodetermining
wether x=0 is max, min or neither. Particularly:
If Q is positive de?nite then x=0 is global maximum;
If Q is negative de?nite then x=0 is global minimum.
1.2.4 De?niteness of 2 Variable Quadratic Form
Let Q(x
1
;x
2
) = ax
2
1
+ 2bx
1
x
2
+ cx
2
2
= (x
1
;x
2
)¢
Ã
a b
b c
!
¢
Ã
x
1
x
2
!
be a 2
variable quadratic form.
Here A =
Ã
a b
b c
!
is the symmetric matrix of the quadratic form. The
determinant
¯
¯
¯
¯
¯
a b
b c
¯
¯
¯
¯
¯
=ac¡b
2
is called discriminant of Q.
Easy to see that
ax
2
1
+2bx
1
x
2
+cx
2
2
=a(x
1
+
b
a
x
2
)
2
+
ac¡b
2
a
x
2
2
:
Let us use the notation D
1
= a; D
2
= ac¡ b
2
. Actually D
1
and D
2
are
leading principal minors of A. Note that there exists one more principal
(non leading) minor (of degree 1) D
0
1
=c.
Then
Q(x
1
;x
2
)=D
1
(x
1
+
b
a
x
2
)
2
+
D
2
D
1
x
2
2
:
From this expression we obtain:
1. If D
1
> 0 and D
2
> 0 then the form is of x
2
+y
2
type, so it is positive
de?nite;
2. If D
1
< 0 and D
2
> 0 then the form is of¡x
2
¡y
2
type, so it is negative
de?nite;
3. If D
1
>0 and D
2
<0 then the form is of x
2
¡y
2
type, so it is inde?nite;
If D
1
< 0 and D
2
< 0 then the form is of ¡x
2
+y
2
type, so it is also
inde?nite;
Thus if D
2
<0 then the form is inde?nite.
Semide?niteness depends not only on leading principal minors D
1
; D
2
but also on all principal minors, in this case on D
0
1
=c too.
4. If D
1
¸0; D
0
1
¸0 and D
2
¸0 then the form is positive semide?nite.
NotethatonlyD
1
¸0andD
2
¸0isnotenough,theadditionalcondition
D
0
1
¸0 here is absolutely necessary: consider the form Q(x
1
;x
2
)=¡x
2
2
with
a = 0; b = 0; c =¡1, here D
1
= a¸ 0; D
2
= ac¡b
2
¸ 0, nevertheless the
form is not positive semidie?nite.
5. If D
1
·0; D
0
1
·0 and D
2
¸0 then the form is negative semide?nite.
NotethatonlyD
1
·0andD
2
¸0isnotenough,theadditionalcondition
D
0
1
·0 again is absolutely necessary: consider the form Q(x
1
;x
2
)=x
2
2
with
a = 0; b = 0; c = 1, here D
1
= a· 0; D
2
= ac¡b
2
¸ 0, nevertheless the
form is not negative semidie?nite.
1.2.5 De?niteness of 3 Variable Quadratic Form
Let us start with the following
Example. Q(x
1
;x
2
;x
3
) = x
2
1
+2x
2
2
¡7x
2
3
¡4x
1
x
2
+8x
1
x
3
. The symmetric
matrix of this quadratic form is
0
B
@
1 ¡2 4
¡2 2 0
4 0 ¡7
1
C
A:
The leading principal minors of this matrix are
jD
1
j=
¯
¯
¯ 1
¯
¯
¯=1; jD
2
j=
¯
¯
¯
¯
¯
1 ¡2
¡2 2
¯
¯
¯
¯
¯
=¡2; jD
3
j=
¯
¯
¯
¯
¯
¯
¯
1 ¡2 4
¡2 2 0
4 0 ¡7
¯
¯
¯
¯
¯
¯
¯
=¡18:
Page 5


1 Quadratic Forms
A quadratic function f : R! R has the form f(x) = a¢x
2
. Generalization
of this notion to two variables is the quadratic form
Q(x
1
;x
2
)=a
11
x
2
1
+a
12
x
1
x
2
+a
21
x
2
x
1
+a
22
x
2
2
:
Here each term has degree 2 (the sum of exponents is 2 for all summands).
A quadratic form of three variables looks as
f(x
1
;x
2
;x
3
)=
a
11
x
2
1
+a
12
x
1
x
2
+a
13
x
1
x
3
+
a
21
x
2
x
1
+a
22
x
2
2
+a
23
x
2
x
3
+
a
31
x
1
x
3
+a
32
x
3
x
2
+a
33
x
2
3
:
Ageneralquadraticformofnvariablesisareal-valuedfunctionQ:R
n
!
R of the form
Q(x
1
;x
2
;:::;x
n
)= a
11
x
2
1
+ a
12
x
1
x
2
+ ::: + a
1n
x
1
x
n
+
a
21
x
2
x
1
+ a
22
x
2
2
+ ::: + a
2n
x
2
x
n
+
::: ::: ::: :::
a
n1
x
n
x
1
+ a
n2
x
n
x
2
+ ::: + a
nn
x
2
n
In short Q(x
1
;x
2
;:::;x
n
)=
P
n
i;j
a
ij
x
i
x
j
.
As we see a quadratic form is determined by the matrix
A=
0
B
@
a
11
::: a
1n
::::::::::::::
a
n1
::: a
nn
1
C
A:
1.1 Matrix Representation of Quadratic Forms
Let Q(x
1
;x
2
;:::;x
n
)=
P
n
i;j
a
ij
x
i
x
j
be a quadratic form with matrix A. Easy
to see that
Q(x
1
;:::;x
n
)=(x
1
;:::;x
n
)¢
0
B
@
a
11
::: a
1n
::::::::::::::
a
n1
::: a
nn
1
C
A¢
0
B
@
x
1
::
x
n
1
C
A:
Equivalently Q(x)=x
T
¢A¢x.
Example. The quadratic form Q(x
1
;x
2
;x
3
) = 5x
2
1
¡ 10x
1
x
2
+ x
2
2
whose
symmetric matrix is A=
Ã
5 ¡5
¡5 1
!
is the product of three matrices
(x
1
;x
2
;x
3
)¢
Ã
5 ¡5
¡5 1
!
¢
0
B
@
x
1
x
2
x
3
1
C
A:
1.1.1 Symmetrization of matrix
The quadratic form Q(x
1
;x
2
;x
3
)=5x
2
1
¡10x
1
x
2
+x
2
2
can be represented, for
example, by the following 2£2 matrices
Ã
5 ¡2
¡8 1
!
;
Ã
5 ¡3
¡7 1
!
;
Ã
5 ¡5
¡5 1
!
the last one is symmetric: a
ij
=a
ji
.
Theorem 1 Any quadratic form can be represented by symmetric matrix.
Indeed, if a
ij
6= a
ji
we replace them by new a
0
ij
= a
0
ji
=
a
ij
+a
ji
2
, this does
not change the corresponding quadratic form.
Generally, one can ?nd symmetrization A
0
of a matrix A by A
0
=
A+A
T
2
.
1.2 De?niteness of Quadratic Forms
A quadratic form of one variable is just a quadratic function Q(x)=a¢x
2
.
If a> 0 then Q(x)>0 for each nonzero x.
If a< 0 then Q(x)<0 for each nonzero x.
Sothesignofthecoe?cientadeterminesthesignofonevariable quadratic
form.
The notion of de?niteness described bellow generalizes this phenomenon
for multivariable quadratic forms.
1.2.1 Generic Examples
The quadratic form Q(x;y) = x
2
+ y
2
is positive for all nonzero (that is
(x;y)6=(0;0)) arguments (x;y). Such forms are called positive de?nite.
The quadratic form Q(x;y) =¡x
2
¡y
2
is negative for all nonzero argu-
ments (x;y). Such forms are called negative de?nite.
The quadratic form Q(x;y) = (x¡y)
2
is nonnegative. This means that
Q(x;y) = (x¡y)
2
is either positive or zero for nonzero arguments. Such
forms are called positive semide?nite.
The quadratic form Q(x;y)=¡(x¡y)
2
is nonpositive. This means that
Q(x;y) = (x¡y)
2
is either negative or zero for nonzero arguments. Such
forms are called negative semide?nite.
The quadratic form Q(x;y) = x
2
¡ y
2
is called inde?nite since it can
take both positive and negative values, for example Q(3;1) = 9¡1 = 8 >
0; Q(1;3)=1¡9=¡8<0.
1.2.2 De?niteness
De?nition. A quadratic form Q(x) = x
T
¢A¢x (equivalently a symmetric
matrix A) is
(a) positive de?nite if Q(x)>0 for all x6=02R
n
;
(b) positive semide?nite if Q(x)¸0 for all x6=02R
n
;
(c) negative de?nite if Q(x)<0 for all x6=02R
n
;
(d) negative semide?nite if Q(x)·0 for all x6=02R
n
;
(e) inde?nite if Q(x)>0 for some x and Q(x)<0 for some other x.
1.2.3 De?niteness and Optimality
Determiningthede?nitenessofquadraticformQisequivalenttodetermining
wether x=0 is max, min or neither. Particularly:
If Q is positive de?nite then x=0 is global maximum;
If Q is negative de?nite then x=0 is global minimum.
1.2.4 De?niteness of 2 Variable Quadratic Form
Let Q(x
1
;x
2
) = ax
2
1
+ 2bx
1
x
2
+ cx
2
2
= (x
1
;x
2
)¢
Ã
a b
b c
!
¢
Ã
x
1
x
2
!
be a 2
variable quadratic form.
Here A =
Ã
a b
b c
!
is the symmetric matrix of the quadratic form. The
determinant
¯
¯
¯
¯
¯
a b
b c
¯
¯
¯
¯
¯
=ac¡b
2
is called discriminant of Q.
Easy to see that
ax
2
1
+2bx
1
x
2
+cx
2
2
=a(x
1
+
b
a
x
2
)
2
+
ac¡b
2
a
x
2
2
:
Let us use the notation D
1
= a; D
2
= ac¡ b
2
. Actually D
1
and D
2
are
leading principal minors of A. Note that there exists one more principal
(non leading) minor (of degree 1) D
0
1
=c.
Then
Q(x
1
;x
2
)=D
1
(x
1
+
b
a
x
2
)
2
+
D
2
D
1
x
2
2
:
From this expression we obtain:
1. If D
1
> 0 and D
2
> 0 then the form is of x
2
+y
2
type, so it is positive
de?nite;
2. If D
1
< 0 and D
2
> 0 then the form is of¡x
2
¡y
2
type, so it is negative
de?nite;
3. If D
1
>0 and D
2
<0 then the form is of x
2
¡y
2
type, so it is inde?nite;
If D
1
< 0 and D
2
< 0 then the form is of ¡x
2
+y
2
type, so it is also
inde?nite;
Thus if D
2
<0 then the form is inde?nite.
Semide?niteness depends not only on leading principal minors D
1
; D
2
but also on all principal minors, in this case on D
0
1
=c too.
4. If D
1
¸0; D
0
1
¸0 and D
2
¸0 then the form is positive semide?nite.
NotethatonlyD
1
¸0andD
2
¸0isnotenough,theadditionalcondition
D
0
1
¸0 here is absolutely necessary: consider the form Q(x
1
;x
2
)=¡x
2
2
with
a = 0; b = 0; c =¡1, here D
1
= a¸ 0; D
2
= ac¡b
2
¸ 0, nevertheless the
form is not positive semidie?nite.
5. If D
1
·0; D
0
1
·0 and D
2
¸0 then the form is negative semide?nite.
NotethatonlyD
1
·0andD
2
¸0isnotenough,theadditionalcondition
D
0
1
·0 again is absolutely necessary: consider the form Q(x
1
;x
2
)=x
2
2
with
a = 0; b = 0; c = 1, here D
1
= a· 0; D
2
= ac¡b
2
¸ 0, nevertheless the
form is not negative semidie?nite.
1.2.5 De?niteness of 3 Variable Quadratic Form
Let us start with the following
Example. Q(x
1
;x
2
;x
3
) = x
2
1
+2x
2
2
¡7x
2
3
¡4x
1
x
2
+8x
1
x
3
. The symmetric
matrix of this quadratic form is
0
B
@
1 ¡2 4
¡2 2 0
4 0 ¡7
1
C
A:
The leading principal minors of this matrix are
jD
1
j=
¯
¯
¯ 1
¯
¯
¯=1; jD
2
j=
¯
¯
¯
¯
¯
1 ¡2
¡2 2
¯
¯
¯
¯
¯
=¡2; jD
3
j=
¯
¯
¯
¯
¯
¯
¯
1 ¡2 4
¡2 2 0
4 0 ¡7
¯
¯
¯
¯
¯
¯
¯
=¡18:
Now look:
Q(x
1
;x
2
;x
3
)=x
2
1
+2x
2
2
¡7x
2
3
¡4x
1
x
2
+8x
1
x
3
=
x
2
1
¡4x
1
x
2
+8x
1
x
3
+2x
2
2
¡7x
2
3
=x
2
1
¡4x
1
(x
2
¡2x
3
)+2x
2
2
¡7x
2
3
=
[x
2
1
¡4x
1
(x
2
¡2x
3
)+4(x
2
¡2x
3
)¡4(x
2
¡2x
3
)]+2x
2
2
¡7x
2
3
=
[x
1
¡2x
2
+4x
3
]
2
¡2x
2
2
¡16x
2
x
3
¡23x
2
3
=
[x
1
¡2x
2
+4x
3
]
2
¡2(x
2
2
¡8x
2
x
3
)¡23x
2
3
=
[x
1
¡2x
2
+4x
3
]
2
¡2[x
2
2
¡8x
2
x
3
+16x
2
3
¡16x
2
3
]¡23x
2
3
=
[x
1
¡2x
2
+4x
3
]
2
¡2[x
2
¡4x
3
]
2
¡16x
2
3
)¡23x
2
3
=
[x
1
¡2x
2
+4x
3
]
2
¡2[x
2
¡4x
3
]
2
+32x
2
3
¡23x
2
3
=
[x
1
¡2x
2
+4x
3
]
2
¡2[x
2
¡4x
3
]
2
+9x
2
3
=
jD
1
jl
2
1
+
D
2
D
1
l
2
+
D
3
D
2
l
2
3
;
where
l
1
=x
1
¡2x
2
+4x
3
;
l
2
= x
2
¡4x
3
;
l
3
= x
3
:
That is (l
1
;l
2
;l
3
) are linear combinations of (x
1
;x
2
;x
3
). More precisely
0
B
@
l
1
l
2
l
3
1
C
A=
0
B
@
1 ¡2 4
0 1 ¡4
0 0 1
1
C
A¢
0
B
@
x
1
x
2
x
3
1
C
A
where
P =
0
B
@
1 ¡2 4
0 1 ¡4
0 0 1
1
C
A
is a nonsingular matrix (changing variables).
Now turn to general 3 variable quadratic form
Q(x
1
;x
2
;x
3
)=(x
1
;x
2
;x
3
)¢
0
B
@
a
11
a
12
a
13
a
21
a
22
a
23
a
31
a
32
a
33
1
C
A¢
0
B
@
x
1
x
2
x
3
1
C
A:
The following three determinants
jD
1
j=
¯
¯
¯ a
11
¯
¯
¯; jD
2
j=
¯
¯
¯
¯
¯
a
11
a
12
a
21
a
22
¯
¯
¯
¯
¯
; jD
3
j=
¯
¯
¯
¯
¯
¯
¯
a
11
a
12
a
13
a
21
a
22
a
23
a
31
a
32
a
33
¯
¯
¯
¯
¯
¯
¯
are leading principal minors.
It is possible to show that, as in 2 variable case, if jD
1
j 6= 0; jD
2
j 6= 0,
then
Q(x
1
;x
2
;x
3
)=jD
1
jl
2
1
+
jD
2
j
jD
1
j
l
2
2
+
jD
3
j
jD
2
j
l
2
3
Read More
556 videos|198 docs

FAQs on Quadratic Forms (Reduction and Classification of Quadratic Forms) - CSIR-NET Mathematical Sciences - Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

1. What is a quadratic form?
Ans. A quadratic form is a homogeneous polynomial of degree 2 in several variables. In the context of mathematics, it is often used to represent a symmetric matrix. The quadratic form can be written as Q(x) = x^T Ax, where x is a column vector and A is a symmetric matrix.
2. How can quadratic forms be reduced?
Ans. Quadratic forms can be reduced using the method of completing the square. The aim is to transform the given quadratic form into a diagonal form, where all the cross-product terms are eliminated. This can be achieved by finding an orthogonal transformation matrix that diagonalizes the symmetric matrix A.
3. What is the importance of classifying quadratic forms?
Ans. Classifying quadratic forms is important in various fields of mathematics and physics. It helps in understanding the properties and behavior of quadratic forms, solving systems of linear equations, determining the nature of critical points in optimization problems, and studying conic sections and their geometric properties.
4. How can quadratic forms be classified?
Ans. Quadratic forms can be classified based on their discriminant, which is a numerical value associated with the quadratic form. The discriminant determines the type of conic section represented by the quadratic form. It can be positive, negative, or zero, indicating an ellipse, hyperbola, or parabola, respectively.
5. Can all quadratic forms be reduced to diagonal form?
Ans. Yes, all quadratic forms can be reduced to diagonal form by an appropriate change of variables. This is known as Sylvester's Law of Inertia. The diagonal form of a quadratic form provides a clear representation of its properties, such as the number of positive and negative terms. However, the diagonal form may not always be unique, as different choices of orthogonal transformation matrices can lead to different diagonalizations.
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