All Calculus 3 Resources
Example Questions
Example Question #35 : Matrices
Find the matrix product of , where and
In order to multiply two matrices, , the respective dimensions of each must be of the form and to create an (notation is rows x columns) matrix. Unlike the multiplication of individual values, the order of the matrices does matter.
For a multiplication of the form
The resulting matrix is
The notation may be daunting but numerical examples may elucidate.
We're told that and
The resulting matrix product is then:
Example Question #36 : Matrices
Find the matrix product of , where and
In order to multiply two matrices, , the respective dimensions of each must be of the form and to create an (notation is rows x columns) matrix. Unlike the multiplication of individual values, the order of the matrices does matter.
For a multiplication of the form
The resulting matrix is
The notation may be daunting but numerical examples may elucidate.
We're told that and
The resulting matrix product is then:
Example Question #33 : Matrices
Find the matrix product of , where and
In order to multiply two matrices, , the respective dimensions of each must be of the form and to create an (notation is rows x columns) matrix. Unlike the multiplication of individual values, the order of the matrices does matter.
For a multiplication of the form
The resulting matrix is
The notation may be daunting but numerical examples may elucidate.
We're told that and
The resulting matrix product is then:
Example Question #34 : Matrices
Find the matrix product of , where and
In order to multiply two matrices, , the respective dimensions of each must be of the form and to create an (notation is rows x columns) matrix. Unlike the multiplication of individual values, the order of the matrices does matter.
For a multiplication of the form
The resulting matrix is
The notation may be daunting but numerical examples may elucidate.
We're told that and
The resulting matrix product is then:
Example Question #39 : Matrices
Find the matrix product of , where and
In order to multiply two matrices, , the respective dimensions of each must be of the form and to create an (notation is rows x columns) matrix. Unlike the multiplication of individual values, the order of the matrices does matter.
For a multiplication of the form
The resulting matrix is
The notation may be daunting but numerical examples may elucidate.
We're told that and
The resulting matrix product is then:
Example Question #631 : Vectors And Vector Operations
Find the determinant of the matrix
The determinant of a 3x3 matrix can be found via a means of reduction into three 2x2 matrices as follows:
These can then be further reduced via the method of finding the determinant of a 2x2 matrix:
For the matrix
The determinant is thus:
(It is of note that if a matrix has a zero determinant, then its columns are linearly dependent. In other words, one column could be created by some via some combination of the other two.
Note how if you multiply the second column by two and then subtract the first column, the third column results.)
Example Question #632 : Vectors And Vector Operations
Find the determinant of the matrix
The determinant of a 3x3 matrix can be found via a means of reduction into three 2x2 matrices as follows:
These can then be further reduced via the method of finding the determinant of a 2x2 matrix:
For the matrix
The determinant is thus:
Example Question #633 : Vectors And Vector Operations
Find the determinant of the matrix
The determinant of a 3x3 matrix can be found via a means of reduction into three 2x2 matrices as follows:
These can then be further reduced via the method of finding the determinant of a 2x2 matrix:
For the matrix
The determinant is thus:
Example Question #634 : Vectors And Vector Operations
Find the determinant of the matrix
The determinant of a 3x3 matrix can be found via a means of reduction into three 2x2 matrices as follows:
These can then be further reduced via the method of finding the determinant of a 2x2 matrix:
For the matrix
The determinant is thus:
Example Question #635 : Vectors And Vector Operations
Find the determinant of the matrix
The determinant of a 3x3 matrix can be found via a means of reduction into three 2x2 matrices as follows:
These can then be further reduced via the method of finding the determinant of a 2x2 matrix:
For the matrix
The determinant is thus: