| The
determinant of a matrix |
| Determinants
are defined only for square matrices. |
| The
determinant D
of an n
´
n
matrix A,
also denoted det(A)
or | A |
is an ordered square array of elements |
 |
| the
value of which is given by an alternating sum of products of the
elements of A,
that can be obtained by
using the method of expanding the determinant to
cofactors. |
|
|
Expanding a determinant
by cofactors
|
| That
is, the value of a determinant equals the sum of the products of
the entries in anyone row or column and their
respective cofactors. |
| A cofactor
of an entry aik
is
a signed minor or (a sub-determinant) derived from a given matrix or
determinant
by the deletion of the row and column containing the specified
entry. |
| Therefore, the
cofactor
of the entry aik
of a matrix A |
| Aik =
(-1)i
+ k · Dik
, |
| where
Dik
is the minor (or sub-determinant) of the matrix A
obtained by deleting its ith
row and kth
column. |
| A
determinant can be expanded along any row or column without
affecting the determinant's value. |
| Thus,
the value of a determinant of order n
expanded along the kth
column |
 |
| where
k
can be any column between 1 and n. |
|
|
| Calculating the value
of a determinant |
| The
determinant of a 2
´
2
matrix |
| Let
apply the above formula to calculate the value of the
determinant of a 2
´
2
matrix A, |
 |
| then,
the expansion of the above determinant by the first column |
 |
| thus,
obtained is |
 |
|
| The
determinant of a 3
´
3
matrix |
| Using
the above determinant expansion by cofactors formula we calculate the value of the
determinant of a |
| 3
´
3
matrix A, |
 |
| The
diagram below shows the method of determining cofactors of the 2nd
column's entries, as we chose to expand
the above determinant along that column |
 |
| thus,
obtained is |
 |
|
| Example:
For the given 3
´
3 matrix
A, find the
value of the determinant D
= det(A),
|
 |
| By
expanding the determinant by the first column obtained is |
 |
|
| Properties of determinants |
| Use of the following properties simplify calculation of the value of
higher order determinants. |
| 1.
Interchanging (switching) two rows or columns changes the sign
of the determinant. |
| 2.
A determinant with a row or column of zeros has value 0. |
| 3.
A determinant with two rows or columns equal (or proportional) has value 0. |
| 4.
A common factor of all elements of a row or a column can be factored out. |
| 5.
The multiplication of a determinant by a scalar can be done by multiplying each element of any row or column by the scalar. |
| 6.
The determinant of a triangular matrix is equal to the product
of the diagonal elements. |
| 7.
The value of a determinant will not change by adding multiples of
any column or row to any other column or row. |
| 8.
A
determinant can be expanded along any row or column (without
affecting the determinant's value). |
|
| Therefore,
we use the above properties to set as many zeros in a row or column as possible to to simplify calculation of the value of
a determinant. |
|
| Example:
Let find the
value of the determinant of the matrix A
from the previous example applying the method of expanding the determinant to
cofactors and using properties of determinants.
|
 |
| First,
added is the second row to the first writing the sum to the
first row. Then we add third row to second, writing
the sum to the second row. Finally, the first column multiplied
by -1
we added to the second column to
obtain the triangular matrix. |
| By
expanding the above triangular matrix by the first column
obtained is |
 |
| This
way proved is the 6th
property stating that the determinant of a triangular matrix is
equal to the product of
its diagonal elements. |
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| Pre-calculus contents
K |
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