Matrices

(i) Number of rows = 3

(ii) Number of columns = 4

(iii) Order of matrix = Number of rows x Number of columns = (3 x 4)

(iv) Number of entries = (Number of rows) x (Number of columns)

= 3 x 4

= 12

(V)

i.

Order of matrix = Number of rows x Number of columns

= (2 x 4)

ii.

Order of matrix = Number of rows x Number of columns

= (4 x 2)

iii.

Order of matrix = Number of rows x Number of columns

= (1 x 4)

iv. D = [8 -3]

Order of matrix = Number of rows x Number of columns

= (1 x 2)

v.

Order of matrix = Number of rows x Number of columns

= (3 x 1)

vi, F = [6]

Order of matrix = Number of rows x Number of columns

= (1 x 1)

Number of entries = (Number of rows) x (Number of columns) = 18

If order is (a x b) then, Number of entries = a x b

So now a x b = 18 (in this case)

Possible cases are (1 x 18), (2 x 9), (3 x 6), (6 x 3), (9 x 2), (18 x 1)

Conclusion: If a matrix has 18 elements, then possible orders are (1 x 18), (2 x 9), (3 x 6), (6 x 3), (9 x 2), (18 x 1)

Number of entries = (Number of rows) x (Number of columns) = 7

If order is (a x b) then, Number of entries = a x b

So now a x b = 7 (in this case)

Possible cases are (1 x 7), (7 x 1)

Conclusion: If a matrix has 18 elements, then possible orders are (1 x 7), (7 x 1)

Given: a_ij = (2i – j)

Now, a₁₁ = (2 × 1 – 1) = 2 – 1 = 1

a₁₂ = 2 × 1 – 2 = 2 – 2 = 0

a₂₁ = 2 × 2 – 1 = 4 – 1 = 3

a₂₂ = 2 × 2 – 2 = 4 – 2 = 2

a₃₁ = 2 × 3 – 1 = 6 – 1 = 5

a₃₂ = 2 × 3 – 2 = 6 – 2 = 4

Therefore,

It is (4 x 3) matrix. So it has 4 rows and 3 columns

Given

So, , , ,

, , ,

, , ,

, ,

So, the matrix

Conclusion: Therefore, Matrix is

It is a (2 x 2) matrix. So, it has 2 rows and 2 columns.

Given

So, , ,

,

So, the matrix

Conclusion: Therefore, Matrix is

It is a (2 x 3) matrix. So, it has 2 rows and 3 columns.

Given

So, , , ,

, ,

So, the matrix

Conclusion: Therefore, Matrix is

It is a (3 x 4) matrix. So, it has 3 rows and 4 columns.

Given

So, , , , ,

, , , ,

, , ,

So, the matrix

Conclusion: Therefore, Matrix is

A + B

B + A

= B + A

Therefore, A + B = B + A

This is true for any matrix

Conclusion: A + B = B + A

(A+B)+C

A+(B+C)

Therefore, (A+B)+C = A+(B+C)

It is true for any matrix

Conclusion: (A+B)+C = A+(B+C)

2A

(2A-B)

Conclusion: (2A-B)

A + 2B

Conclusion: (A+2B) =

ii. B – 4c

B-4C

Conclusion: B-4C

iii. A – 2B + 3C

A-2B+3C

Conclusion: A_2B+3C

5A-3B+4C

Conclusion: 5A-3B+4C

5A

A

A

Conclusion: A

Add (A+B) and (A-B)

We get (A+B)+(A-B)

2A

A

Now Subtract (A-B) from (A+B)

(A+B)-(A-B)

(2B)

B

Conclusion: A , B

Add 2(2A-B) and (2B+A)

2(2A-B)+(2B+A)

5A

5A

A

B

B

Conclusion: A , B

(GIVEN ANSWER IS WRONG for question 8)

Given

Conclusion : x

Given A + B – C = 0

Conclusion:

Given 2A – B + X = 0

Conclusion:

Given A+B+C is zero matrix i.e A+B+C = 0

Conclusion:

If Z = diag[a,b,c], then we can write it as

So, A+2B

=diag[4,9,37]

Conclusion: A + 2B = diag[4,9,37]

(Given answer is wrong)

ii. B + C – A

If Z = diag[a,b,c], then we can write it as

B+C-A

= diag[-1,6,8]

Conclusion: B+C-A = diag[-1,6,8]

iii. 2A + B – 5C

If Z = diag[a,b,c], then we can write it as

2A+B-5C

= diag[-19,27,17]

Conclusion: 2A + B – 5C = diag[-19,27,17]

(Given answer is wrong)

If ,

Then a=e, b=f, c=g, d=h

Given

So, x + y = 8 and x - y = 4

Adding these two gives 2x = 12

y =2

Conclusion : x = 6 and y =2

ii.

Given,

So, 2x+5 = x-3 and 3y-7 = -5

Conclusion : x = -8 and y =

iii.

2x+3 = 7

2y-4 = 14

Conclusion : x = 2 and y = 9

(Given answer is wrong)

Given

So, 2+y = 5 and 2x+2 = 8

i.e y = 3 and x = 3

Therefore, x+y=6

Conclusion: Therefore x+y = 6

If ,

Then a=e, b=f, c=g, d=h

Given, ,

So, x-y = 1, x+y =5, 2y = 4 and 2y+z = 9

Therefore, x+y = 5

Conclusion: x+y = 5

(Given answer is wrong)

Given : and

Matrix A is of order 3 2, and Matrix B is of order 2 2

To find : matrix AB and BA

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

If A is a matrix of order a b and B is a matrix of order c d ,then matrix BA exists and is of order c b ,if and only if d = a

For matrix AB, a = 3,b = c = 2,d = 2 ,thus matrix AB is of order 3 2

Matrix AB =

Matrix AB =

Matrix AB =

Matrix AB =

For matrix BA, a = 3,b = c = 2,d = 2 ,thus matrix BA exists, if and only if d=a

But 3 2

Thus matrix BA does not exist

Given : and

Matrix A is of order 3 2, and Matrice B is of order 3 3

To find : matrix AB and BA

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrice of order c d ,then matrice AB exists and is of order a d ,if and only if b = c

If A is a matrix of order a b and B is a matrice of order c d ,then matrice BA exists and is of order c b ,if and only if d = a

For matrix AB, a = 3,b = 2,c = 3,d = 3 ,thus matrix AB does not exist, as d a

But 2 3

Thus matrix AB does not exist

For matrix BA, a = 3,b = 2,c = 3,d = 3 ,thus matrix BA is of order 3 2

as d = a = 3

Matrix BA =

Matrix BA =

Matrix

Matrix BA =

Given : and

Matrix A is of order 2 3 and Matrix B is of order 3 2

To find : matrices AB and BA

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

If A is a matrix of order a b and B is a matrix of order c d ,then matrix BA exists and is of order c b ,if and only if d = a

For matrix AB, a = 2,b = 3,c = 3,d = 2 ,matrix AB exists and is of order 2 2,as

b = c = 3

Matrix AB =

Matrix AB = =

Matrix AB =

Matrix AB =

For matrix BA, a = 2,b = 3,c = 3,d = 2 ,matrix BA exists and is of order 3 3,as

d = a = 2

Matrix BA =

Matrix BA =

Matrix BA =

Matrix BA =

Given : A = [1 2 3 4] and

Matrix A is of order 1 4 and Matrix B is of order 4 1

To find : matrices AB and BA

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

If A is a matrix of order a b and B is a matrix of order c d ,then matrix BA exists and is of order c b ,if and only if d = a

For matrix AB, a = 1,b = 4,c = 4,d = 1 ,matrix AB exists and is of order 1 1,as

b = c = 4

Matrix AB =

Matrix AB = =

Matrix AB =

Matrix AB =

For matrix BA, a = 1,b = 4,c = 4,d = 1 ,matrix BA exists and is of order 4 4,as

d = a = 1

Matrix BA =

Matrix BA =

Matrix BA =

Given : and

Matrix A is of order 3 2 and Matrix B is of order 2 3

To find : matrices AB and BA

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

If A is a matrix of order a b and B is a matrix of order c d ,then matrix BA exists and is of order c b ,if and only if d = a

For matrix AB, a = 3,b = 2,c = 2,d = 3 ,matrix AB exists and is of order 3 3,as

b = c = 2

Matrix AB =

Matrix AB = =

Matrix AB =

Matrix AB =

For matrix BA, a = 3,b = 2,c = 2,d = 3 ,matrix BA exists and is of order 2 2,as

d = a = 3

Matrix BA =

Matrix BA = =

Matrix BA =

Matrix BA =

Given : and

Matrix A is of order 2 2 and Matrix B is of order 2 2

To show : matrix AB BA

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

If A is a matrix of order a b and B is a matrix of order c d ,then matrix BA exists and is of order c b ,if and only if d = a

For matrix AB, a = 2,b = c = 2,d = 2 ,thus matrix AB is of order 2 2

Matrix AB =

Matrix AB = =

Matrix AB =

For matrix BA, a = 2,b = c = 2,d = 2 ,thus matrix BA is of order 2 2

Matrix BA=

Matrix BA = =

Matrix BA =

Matrix BA = and Matrix AB =

Matrix AB BA

Given : and

Matrix A is of order 3 3, and Matrix B is of order 3 3

To show : matrix AB BA

The formula used :

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

If A is a matrix of order a b and B is a matrix of order c d ,then matrix BA exists and is of order c b ,if and only if d = a

For matrix AB, a = 3,b = c = 3,d = 3 ,thus matrix AB is of order 3 3

Matrix AB =

Matrix AB = =

Matrix AB =

For matrix BA, a = 3,b = c = 3,d = 3 ,thus matrix AB is of order 3 3

Matrix BA=

=

Matrix BA = =

Matrix BA =

Matrix BA = and Matrix AB =

Matrix AB BA

Given : and

Matrix A is of order 2 2 and Matrix B is of order 2 2

To show : matrix AB = BA

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

If A is a matrix of order a b and B is a matrix of order c d ,then matrix BA exists and is of order c b ,if and only if d = a

For matrix AB, a = 2,b = c = 2,d = 2 ,thus matrix AB is of order 2 2

Matrix AB =

Matrix AB =

Matrix AB =

For matrix BA, a = 2,b = c = 2,d = 2 ,thus matrix BA is of order 2 2

Matrix BA=

Matrix BA =

Matrix BA = Matrix AB =

Thus Matrix AB = BA

Given : and

Matrix A is of order 3 3 and Matrix B is of order 3 3

To show : matrix AB BA

Formula used :

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

If A is a matrix of order a b and B is a matrix of order c d ,then matrix BA exists and is of order c b ,if and only if d = a

For matrix AB, a = 3,b = c = 3,d = 3 ,thus matrix AB is of order 3 3

Matrix AB = =

Matrix AB = =

Matrix AB =

For matrix BA, a = 3,b = c = 3,d = 3 ,thus matrix AB is of order 3 3

Matrix BA=

=

Matrix BA = =

Matrix AB BA

Given : and

Matrix A is of order 3 3 and Matrix B is of order 3 3

To show : matrix AB = BA

Formula used :

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

If A is a matrix of order a b and B is a matrix of order c d ,then matrix BA exists and is of order c b ,if and only if d = a

For matrix AB, a = 3,b = c = 3,d = 3 ,thus matrix AB is of order 3 3

Matrix AB = =

Matrix AB = =

Matrix AB =

For matrix BA, a = 3,b = c = 3,d = 3 ,thus matrix AB is of order 3 3

Matrix BA =

Matrix BA =

Matrix BA =

Matrix BA =

Matrix AB = Matrix BA =

Given : and

Matrix A is of order 3 3 and Matrix B is of order 3 3

To show : matrix AB = A, BA = B

Formula used :

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

If A is a matrix of order a b and B is a matrix of order c d ,then matrix BA exists and is of order c b ,if and only if d = a

For matrix AB, a = 3,b = c = 3,d = 3 ,thus matrix AB is of order 3 3

Matrix AB = =

Matrix AB = =

Matrix AB = = Matrix A

Matrix AB = Matrix A

For matrix BA, a = 3,b = c = 3,d = 3 ,thus matrix AB is of order 3 3

Matrix BA =

Matrix BA =

Matrix BA = =

Matrix BA = = Matrix B

Matrix BA = = Matrix B

MATRIX AB = A and MATRIX BA = B

Given : and

Matrix A is of order 3 3 , matrix B is of order 3 3 and matrix C is of order 3 3

To show : AB is a zero matrix

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

If A is a matrix of order a b and B is a matrix of order c d ,then matrix BA exists and is of order c b ,if and only if d = a

= 0 matrix

Hence, Proved

Given : and C = [1 -2]

Matrix A is of order 2 3 , matrix B is of order 3 1 and matrix C is of order 1 2

To show : matrix A(BC) = (AB)C

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

If A is a matrix of order a b and B is a matrix of order c d ,then matrix BA exists and is of order c b ,if and only if d = a

For matrix BC, a = 3,b = c = 1,d = 2 ,thus matrix BC is of order 3 2

Matrix BC = = =

Matrix BC =

For matrix A(BC),a = 2 ,b = c = 3 ,d = 2 ,thus matrix A(BC) is of order 2 x 2

Matrix A(BC) = =

Matrix A(BC) = =

Matrix A(BC) =

Matrix A(BC) =

For matrix AB, a = 2,b = c = 3,d = 1 ,thus matrix BC is of order 2 1

Matrix AB = =

Matrix AB = =

Matrix AB =

For matrix (AB)C, a = 2,b = c = 1,d = 2 ,thus matrix (AB)C is of order 2 2

Matrix (AB)C = = =

Matrix (AB)C =

Matrix A(BC) = (AB)C =

Given : and

Matrix A is of order 2 2 , matrix B is of order 2 2 and matrix C is of order 2 2

To verify : A(B + C) = (AB + AC)

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

If A is a matrix of order a b and B is a matrix of order c d ,then matrix BA exists and is of order c b ,if and only if d = a

B + C = + = =

B + C =

Matrix A(B + C) is of order 2 x 2

A(B + C) = =

A(B + C) = =

A(B + C) =

For matrix AB, a = b = c = d = 2 ,matrix AB is of order 2 x 2

Matrix AB = =

Matrix AB = =

Matrix AB =

For matrix AC, a = b = c = d = 2 ,matrix AC is of order 2 x 2

Matrix AC = =

Matrix AC = =

Matrix AC =

Matrix AB + AC = + = =

Matrix AB + AC = A(B + C) =

A(B + C) = (AB + AC)

Given : and

Matrix A is of order 3 2 , matrix B is of order 2 2 and matrix C is of order 2 2

To verify : A(B + C) = (AB + AC)

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

If A is a matrix of order a b and B is a matrix of order c d ,then matrix BA exists and is of order c b ,if and only if d = a

B + C = + = =

B + C =

For Matrix A(B + C), a = 3,b = c = d = 2,thus matrix A(B + C) is of order 3 x 2

A(B + C) = =

A(B + C) = =

A(B + C) =

For matrix AB, a = 3, b = c = d = 2 ,matrix AB is of order 3 x 2

Matrix AB = =

Matrix AB = =

Matrix AB =

For matrix AC, a = 3, b = c = d = 2 ,matrix AC is of order 3 x 2

Matrix AC = =

Matrix AC = =

Matrix AC =

Matrix AB + AC = + = =

Matrix AB + AC = A(B + C) =

A(B + C) = (AB + AC)

Given : and

Matrix A is of order 3 3; matrix B is of order 3 3 and matrix C is of order 3 3

To verify : A(B – C) = (AB – AC).

The formula used :

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

If A is a matrix of order a b and B is a matrix of order c d ,then matrix BA exists and is of order c b ,if and only if d = a

B - C = =

B - C =

For Matrix A(B - C), a = 3,b = c = d = 3,thus matrix A(B + C) is of order 3 x 3

A(B - C) =

A(B - C) =

A(B - C) = =

A(B - C) =

For matrix AB, a = 3, b = c = d = 3 ,matrix AB is of order 3 x 3

Matrix AB =

Matrix AB =

Matrix AB = =

Matrix AB =

For matrix AC, a = 3, b = c = d = 3 ,matrix AC is of order 3 x 3

Matrix AC =

Matrix AC =

Matrix AC = =

Matrix AC =

Matrix AB - AC = =

Matrix AB - AC =

A(B – C) = (AB – AC) =

Given :

Matrix A is of order 2 2

To show : A² = O

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

A² = =

A² = =

A² =

A² = O

Given :

Matrix A is of order 3 3

To show : A² = A

Formula used :

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

A² =

A² =

A² = =

A² = A =

Given :

Matrix A is of order 3 3

To show : A² = I

Formula used :

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

A² =

A² =

A² = =

A² = I =

Given : and

Matrix A is of order 2 2, Matrix B is of order 2 2

To find : 3A² – 2B + I

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

A² = = =

A² =

3A² = 3 × =

3A² =

2B = 2 × =

2B =

I =

3A² – 2B + I = + =

3A² – 2B + I =

3A² – 2B + I =

Given :

Matrix A is of order 2 2.

To find : -A² + 6A

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

A² = = =

A² =

-A² = =

6A = 6 × =

6A =

-A² + 6A = + = =

-A² + 6A =

Given :

Matrix A is of order 2 2.

To show : A² - 5A +7I = 0

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

A² = = =

A² =

5A = 5 × =

5A =

I =

7I = =

7I =

A² - 5A + 7I = + = =

A² - 5A + 7I = 0

Given :

Matrix A is of order 2 2.

To show : A³ - 4A² + A = 0

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

A² and A³ are matrices of order 2 x 2.

A² = = =

A² =

A³ = = =

A³ =

4A² = 4 × =

4A² =

A³ - 4A² + A = + = =

A³ - 4A² + A = 0

Given : A² = kA – 2I.

Matrix A is of order 2 2.

To find : k

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

A² is a matrix of order 2 x 2.

A² = = =

A² =

kA = k × =

kA – 2I = =

It is the given that A² = kA – 2I

=

Equating like terms,

3k – 2 = 1

3k = 1 + 2 = 3

3k = 3

k = = 1

k = 1

Given : and

Matrix A is of order 2 3 , matrix B is of order 3 3 and matrix C is of order 3 1

To show : matrix A(BC) = (AB)C

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

If A is a matrix of order a b and B is a matrix of order c d ,then matrix BA exists and is of order c b ,if and only if d = a

For matrix BC, a = 3,b = c = 3,d = 1 ,thus matrix BC is of order 3 1

Matrix BC = = =

Matrix BC =

For matrix A(BC),a = 2 ,b = c = 3 ,d = 1 ,thus matrix A(BC) is of order 2 x 1

Matrix A(BC) = = =

Matrix A(BC) =

Matrix A(BC) =

For matrix AB, a = 2,b = c = 3,d = 3 ,thus matrix BC is of order 2 3

Matrix AB =

Matrix AB =

Matrix AB = =

Matrix AB =

For matrix (AB)C, a = 2,b = c = 3,d = 1 ,thus matrix (AB)C is of order 2 1

Matrix (AB)C = =

Matrix (AB)C = =

Matrix (AB)C =

Matrix A(BC) = (AB)C =

Given : and f(x) = x² – 2x + 3.

Matrix A is of order 2 2.

To find : f(A)

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

A² is a matrix of order 2 x 2.

f(x) = x² – 2x + 3

f(A) = A² – 2A + 3I

A² = =

A² = =

A² =

2A = 2 × =

2A =

3I = 3 × =

3I =

f(A) = A² – 2A + 3I = + =

f(A) = A² – 2A + 3I =

f(A) = A² – 2A + 3I =

Given : and f(x) = 2x³ + 4x + 5

Matrix A is of order 2 2.

To find : f(A)

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

A³ is a matrix of order 2 x 2.

f(x) = 2x³ + 4x + 5

f(A) = 2A³ + 4A + 5I

A² = = =

A² =

A³ = × =

A³ = =

A³ =

2A³ = 2 × =

2A³ =

4A = 4 × =

4A =

5I = 5 × =

5I =

2A³ + 4A + 5I = + + =

f(A) = 2A³ + 4A + 5I =

f(A) = 2A³ + 4A + 5I =

Given :

To find : x and y

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

The resulting matrix obtained on multiplying and is of order 2 × 1

× = =

=

Equating similar terms,

2x – 3y = 1 equation 1

x + y = 3 equation 2

equation 1 + 3(equation 2) and solving the above equations,

x = = 2

x = 2 , substituting x = 2 in equation 2,

2 + y = 3

y = 3 – 2 = 1

x = 2 and y = 1

Given :

To find : x and y

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

The resulting matrix obtained on multiplying and is of order 2 × 1

× = =

=

Equating similar terms,

3x – 4y = 3 equation 1

x + 2y = 11 equation 2

equation 1 + 2(equation 2) and solving the above equations,

5x = 25

x = = 5

x = 5 , substituting x = 2 in equation 2,

5 + 2y = 11

2y =11 – 5 = 6

2y = 6

y = = 3

x = 5 and y = 3

Given : A² + xI = yA.

A is a matrix of order 2 x 2

To find : x and y

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

A² is a matrix of order 2 x 2

A² = = =

A² = =

A² =

xI = =

xI =

A² + xI = + = =

A² + xI =

yA = y =

yA =

It is given that A² + xI = yA,

=

Equating similar terms in the given matrices,

16 + x = 3y and 8 = y,

hence y = 8

Substituting y = 8 in equation 16 + x = 3y

16 + x = 3 × 8 = 24

16 + x = 24

x = 24 – 16 = 8

x = 8

x = 8, y = 8

Given : A² + aA + bI = O

A is a matrix of order 2 x 2

To find : a and b

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

A² is a matrix of order 2 x 2

A² = = =

A² =

aA = a =

bI = b =

bI =

A² + aA + bI = + + =

A² + aA + bI =

It is given that A² + aA + bI = 0

=

Equating similar terms in the matrices,we get

4 + a = 0 and 3 + a + b = 0

a = 0 – 4 = -4

a = -4

substituting a = -4 in 3 + a + b = 0

3 – 4 + b = 0

-1 + b = 0

b = 0 + 1 = 1

b = 1

a = -4 and b = 1

Given :

To find : matrix A

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

IF XA = B, then A = X^-1B

. A =

A =

To find

Determinant of given matrix = = 5(3) – (-7)(-2) = 15 – 14 = 1

Adjoint of matrix =

= × =

=

A = =

A = = =

A =

A =

Given : A.

To find : matrix A

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

IF AX = B, then A = BX^-1

A. =

A =

To find

Determinant of given matrix = = 5(2) – (4)(3) = 10 – 12 = -2

Adjoint of matrix =

= × =

=

A = =

A = =

A = = =

A =

A =

Given :

(A + B)² = (A² + B²)

To find : a and b

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

A + B = + = =

A + B =

(A + B)² = × =

(A + B)² = =

(A + B)² =

A² = × = =

A² =

B² = × = =

B² =

(A² + B²) = + =

(A² + B²) =

It is given that (A + B)² = (A² + B²)

=

Equating similar terms in the given matrices we get,

2 – 2a = -a + 1 and -2b = -b + 1

2 – 1 = -a + 2a and -2b + b = 1

1 = a and -b = 1

a = 1 and b = -1

Given :

To show : F(x) . F(y) = F(x + y).

Formula used :

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

F(x) =

F(y) =

F(x + y) =

F(x) . F(y) = .

=

F(x) . F(y) =

We know that,

cosx(cosy) – sinx (siny) = cos(x+y) and -cosx(siny) - sinx(cosy) = -sin(x+y)

F(x) . F(y) =

F(x + y) = F(x) . F(y) =

F(x + y) = F(x) . F(y)

Given :

To show :

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

A =

A² = ×

A² =

A² =

We know that cos2α = and sin2α =

A² =

A² =

Given :

To find : x

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

= 0

=

=

=

= ×

× =

× = =

= = 0

12x + 20 = 0

12x = -20

x = =

x =

Given :

To find : x

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

= 0

=

=

=

= = = 0

2x² + 6x + 4 = 0

x² + 3x + 2 = 0

(x + 1)(x + 2) = 0

x + 1 = 0 or x + 2 = 0

x = -1 or x = -2

x = -1 or x = -2

Given :

To find : a and b

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

If A is a matrix of order a b and B is a matrix of order c d ,then matrix AB exists and is of order a d ,if and only if b = c

=

= = =

=

Equating similar terms,

2a – b = 5

-2a – 2b = 4

Adding the above two equations,we get

-3b = 9

b = = -3

b = -3

substituting b = -3 in 2a – b = 5,we get

2a + 3 = 5

2a = 5 – 3 = 2

a = 1

a = 1 and b = -3

Given : and f(x) = x² – 5x + 7.

Matrix A is of order 2 2.

To find : f(A)

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

A² is a matrix of order 2 x 2.

f(x) = x² – 5x + 7

f(A) = A² – 5A + 7I

A² = = =

A² =

5A = 5 × =

5A =

7I = 7 × =

7I =

f(A) = A² – 5A + 7I = + =

f(A) = A² – 5A + 7I =

f(A) = A² – 5A + 7I =

Given :

Matrix A is of order 2 2.

To prove :

Proof :

A =

Let us assume that the result holds for A^{n – 1}

A^{n – 1} =

We need to prove that the result holds for Aⁿ by mathematical induction .

Aⁿ = A^{n – 1} × A = =

Aⁿ = =

Aⁿ =

Given : A ≠ 0,B ≠ 0 ,AB = 0, BA ≠ 0

To Find : matrix A and B

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

Let A = and B =

A ≠ 0,B ≠ 0

AB = = =

AB = = 0

BA = = =

BA =

A = and B =

Given : AB = AC and B ≠ C.

To Find : matrix A and B

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

Let A = , B = and C =

B ≠ C

AB = =

AB = = 0

AC = =

AC = = 0

AB = AC = 0

A = , B = and C =

Given : and

Matrices A and B are of order 2 2.

To find : (3A² – 2B + I).

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

A² is a matrix of order 2 x 2.

A =

A² = =

A² = =

3A² = 3 × =

3A² =

2B = 2 × =

2B =

I =

3A² – 2B + I = + =

3A² – 2B + I =

Given :

To find : x

Formula used :

Where c_ij = a_i1b_1j + a_i2b_2j + a_i3b_3j + ……………… + a_inb_nj

=

= = =

= =

=

Equating similar terms in the two matrices, we get

x = 13

x = 13

Transpose of a matrix is obtained by interchanging the rows and the columns of matrix A. It is denoted by A’.

e.g. A₁₂ = A₂₁

Hence transpose of matrix A is,

Given

To Prove: (2A)’ = 2A’

Proof: Let us consider, B = 2A

Now,

LHS

Again to find RHS, we will find the transpose of matrix A

RHS = 2A’

LHS = RHS

Hence proved.

Given and

To Prove: (A + B)’ = A’ + B’

Proof: Let us consider C = A + B

Now LHS = C’

To find RHS, we will find transpose of matrix A and B

And

RHS = A’ + B’

LHS = RHS

Hence proved.

Given and

To Prove: (P + Q)’ = P’ + Q’

Proof: Let us consider R = P + Q,

LHS = R (P + Q)’

To find RHS, we will first find the transpose of matrix P and Q

And

RHS = P’ + Q’

LHS = RHS

Hence proved.

Given

To Prove: A + A’ is symmetric.(Note:A matrix P is symmetric if P’ = P)

Proof: We will find A’,

Now let us take P = A + A’

Now

Hence A + A’ is a symmetric matrix.

Given

To prove: A-A’ is a skew-symmetric matrix.(Note: A matrix P is skew-symmetric if P’ = -P)

Proof: First we will find the transpose of matrix A

Let us take P = A-A’

P’ = P

Hence A-A’ is a skew symmetric matrix.

Given

To Prove: A is a skew symmetric matrix.

Proof: As for a matrix to be skew symmetric A’ = -A

We will find A’.

= -

A’ = -A

So A is A skew symmetric matrix.

Given , As for a symmetric matrix A’ = A hence

A + A’ = 2A

A (Symmetric Matrix)

Similarly for a skew symmetric matrix since A’ = -A hence

A-A’ = 2A

A(Skew Symmetric Matrix)

So a matrix can be represented as a sum of a symmetric matrix P and skew symmetric matrix Q.

First, we will find the transpose of matrix A,

Now using the above formulas,

Hence A = P + Q

+ [Matrix A as the sum of P and Q]

Given ,to express as sthe um of symmetric matrix P and skew symmetric matrix Q.

A = P + Q

Where and ,we will find transpose of matrix A

Now using the above formulas

Hence A = P + Q

[Matrix A as the sum of P and Q]

Given, to express as sum of symmetric matrix P and skew symmetric matrix Q.

A = P + Q

Where and,

First, we find A’

Now using the above mentioned formulas

Now A = P + Q

[Matrix A as sum of P and Q]

Given, to express as sum of symmetric matrix P and skew symmetric matrix Q

A = P + Q

Where and,

First we will find A’,

A’

Now using above mentioned formulas,

Now A = P + Q

[Matrix A as sum of P and Q]

Given, to express as sum of symmetric matrix P and skew symmetric matrix Q.

A = P + Q

Where and,

First we will find A’

Now using above mentioned formulas

Now A = P + Q

Let us take C = AB

To find RHS we will find transpose of matrix A and B,

And

RHS = B’A’

LHS = RHS

Hence proved.

Let us take C = AB

To find RHS we will find transpose of matrix A and B,

And

RHS = B’A’

LHS = RHS

Hence proved.

Let us take C = AB

LHS = C’

To find RHS we will find transpose of matrix A and B,

And

RHS = B’A’

LHS = RHS

Hence proved.

Let us take C = AB

LHS = C’

To find RHS we will find transpose of matrix A and B,

And

RHS = B’A’

LHS = RHS

Hence proved.

Given , We will find A’

LHS = A’A

[Using and commutative law a.b = b.a i.e. ]

RHS = I

LHS = RHS

Hence proved.

Given [1 2 3]

We will find A’ to calculate AA’,

Now

[1 + 4 + 9]

[14]

Let, A =

Now we are going to write the Augmented Matrix followed by matrix A and the Identity matrix I, i.e.,

, where I =

Now our job is to convert the matrix A into Identity Matrix. Therefore, the matrix we will get converting the matrix I will be our A^-1.

Here, the matrix A is converted into Identity matrix. Therefore, we get the A^-1 as,

A^-1 = [Answer]

The value of A^-1 is correct or not can be verified by the formula: AA^-1 = I

Let, A =

Now we are going to write the Augmented Matrix followed by matrix A and the Identity matrix I, i.e.,

, where I =

Now our job is to convert the matrix A into Identity Matrix. Therefore, the matrix we will get converting the matrix I will be our A^-1.

Here, the matrix A is converted into the Identity matrix. Therefore, we get the A^-1 as,

A^-1 = [Answer]

The value of A^-1 is correct or not can be verified by the formula: AA^-1 = I

Let, A =

Now we are going to write the Augmented Matrix followed by matrix A and the Identity matrix I, i.e.,

, where I =

Now our job is to convert the matrix A into Identity Matrix. Therefore, the matrix we will get converting the matrix I will be our A^-1.

Here, the matrix A is converted into Identity matrix. Therefore, we get the A^-1 as,

A^-1 = [Answer]

The value of A^-1 is correct or not can be verified by the formula: AA^-1 = I

Let, A =

Now we are going to write the Augmented Matrix followed by matrix A and the Identity matrix I, i.e.,

, where I =

Now our job is to convert the matrix A into Identity Matrix. Therefore, the matrix we will get converting the matrix I will be our A^-1.

Here, the matrix A is converted into Identity matrix. Therefore, we get the A^-1 as,

A^-1 = [Answer]

The value of A^-1 is correct or not can be verified by the formula: AA^-1 = I

Let, A =

Now we are going to write the Augmented Matrix followed by matrix A and the Identity matrix I, i.e.,

, where I =

Now our job is to convert the matrix A into Identity Matrix. Therefore, the matrix we will get converting the matrix I will be our A^-1.

Here, the matrix A is converted into Identity matrix. Therefore, we get the A^-1 as,

A^-1 = [Answer]

The value of A^-1 is correct or not can be verified by the formula: AA^-1 = I

Let, A =

Now we are going to write the Augmented Matrix followed by matrix A and the Identity matrix I, i.e.,

, where I =

Now our job is to convert the matrix A into Identity Matrix. Therefore, the matrix we will get converting the matrix I will be our A^-1.

Here, the matrix A is converted into Identity matrix. Therefore, we get the A^-1 as,

A^-1 = [Answer]

The value of A^-1 is correct or not can be verified by the formula: AA^-1 = I

Let, A =

Now we are going to write the Augmented Matrix followed by matrix A and the Identity matrix I, i.e.,

, where I =

Now our job is to convert the matrix A into Identity Matrix. Therefore, the matrix we will get converting the matrix I will be our A^-1.

Here, the matrix A is converted into Identity matrix. Therefore, we get the A^-1 as,

A^-1 = [Answer]

The value of A^-1 is correct or not can be verified by the formula: AA^-1 = I

Let, A =

Now we are going to write the Augmented Matrix followed by matrix A and the Identity matrix I, i.e.,

, where I =

Now our job is to convert the matrix A into Identity Matrix. Therefore, the matrix we will get converting the matrix I will be our A^-1.

Here, the matrix A is converted into Identity matrix. Therefore, we get the A^-1 as,

A^-1 = [Answer]

The value of A^-1 is correct or not can be verified by the formula: AA^-1 = I

Let, A =

Now we are going to write the Augmented Matrix followed by matrix A and the Identity matrix I, i.e.,

, where I =

Now our job is to convert the matrix A into Identity Matrix. Therefore, the matrix we will get converting the matrix I will be our A^-1.

Here, the matrix A is converted into Identity matrix. Therefore, we get the A^-1 as,

A^-1 = [Answer]

The value of A^-1 is correct or not can be verified by the formula: AA^-1 = I

Let, A =

Now we are going to write the Augmented Matrix followed by matrix A and the Identity matrix I, i.e.,

, where I =

Now our job is to convert the matrix A into Identity Matrix. Therefore, the matrix we will get converting the matrix I will be our A^-1.

Here, the matrix A is converted into Identity matrix. Therefore, we get the A^-1 as,

A^-1 = [Answer]

The value of A^-1 is correct or not can be verified by the formula: AA^-1 = I

Let, A =

Now we are going to write the Augmented Matrix followed by matrix A and the Identity matrix I, i.e.,

, where I =

Now our job is to convert the matrix A into Identity Matrix. Therefore, the matrix we will get converting the matrix I will be our A^-1.

Here, the matrix A is converted into Identity matrix. Therefore, we get the A^-1 as,

A^-1 = [Answer]

The value of A^-1 is correct or not can be verified by the formula: AA^-1 = I

Let, A =

Now we are going to write the Augmented Matrix followed by matrix A and the Identity matrix I, i.e.,

, where I =

Now our job is to convert the matrix A into Identity Matrix. Therefore, the matrix we will get converting the matrix I will be our A^-1.

Here, the matrix A is converted into Identity matrix. Therefore, we get the A^-1 as,

A^-1 = [Answer]

The value of A^-1 is correct or not can be verified by the formula: AA^-1 = I

Let, A =

Now we are going to write the Augmented Matrix followed by matrix A and the Identity matrix I, i.e.,

, where I =

Now our job is to convert the matrix A into Identity Matrix. Therefore, the matrix we will get converting the matrix I will be our A^-1.

Here, the matrix A is converted into Identity matrix. Therefore, we get the A^-1 as,

A^-1 = [Answer]

The value of A^-1 is correct or not can be verified by the formula: AA^-1 = I

Let, A =

Now we are going to write the Augmented Matrix followed by matrix A and the Identity matrix I, i.e.,

, where I =

Now our job is to convert the matrix A into Identity Matrix. Therefore, the matrix we will get converting the matrix I will be our A^-1.

Here, the matrix A is converted into Identity matrix. Therefore, we get the A^-1 as,

A^-1 = [Answer]

The value of A^-1 is correct or not can be verified by the formula: AA^-1 = I

Let, A =

Now we are going to write the Augmented Matrix followed by matrix A and the Identity matrix I, i.e.,

, where I =

Now our job is to convert the matrix A into Identity Matrix. Therefore, the matrix we will get converting the matrix I will be our A^-1.

Here, the matrix A is converted into Identity matrix. Therefore, we get the A^-1 as,

A^-1 = [Answer]

The value of A^-1 is correct or not can be verified by the formula: AA^-1 = I

Here, i is the subscript for a row, and j is the subscript for column

And the given matrix is 3×2, so 1≤ i ≤ 3 and 1≤j ≤2

Hence for i=1, j=1, =

For i=1, j=2, =

For i=2, j=1 = 0

For i=2, j=2 = 2

For i=3, j=1 =

For i=3, j=2 =

Hence the required matrix is :-

The elements of the matrix are given by,

Matrix is 2 hence,

Here, i is the subscript for a row, and j is the subscript for column

For i=1, j=1,

For i=1, j=2,

For i=1, j=3,

For i=2, j=1,

For i=2, j=2,

For i=2, j=3,

Hence the required matrix is :-

On comparing L.H.S. and R. H.S we get,

On comparing each term we get,

….(i)

…(ii)

…..(iii)

From (i), (ii) and (iii), we get,

Given,

Using the property of matrix multiplication such that h is scalar,

Using the matrix property of matrix addition, when two matrices are of the same order then, each element gets added to the corresponding element,

Comparing each element we get,

2+y=5, ⇒ y=3

2x+2=8, ⇒x=3

Given,

And we have,

Solving the linear equations, we get,

Given,

On comparing each element of the two matrices we get,

x=3,

3x-y=2

y=7

2x+z=4,

z=-2,

3y-w=7,

w=14

Given,

First applying matrix addition then, comparing each element of the matrix with the corresponding element we get,

We now have, …..(i)

x=2

…….(ii)

6+x+y=3y, substituting x from (i) we get,

y = 4,

And -1+z+w=3z, substituting w from (ii), we get,

z=1

We are given two diagonal matrices A and B,

On adding the two diagonal matrices of order (3) we get an diagonal matrix of order (33)

Each of the elements get added to the corresponding element hence, we get after adding,

Hence, we get A+B = diag(4 1 1)

We have to show that

Multiplying the scalars with we get,

And we know that

Hence, proved.

Given, A+B+C = zero matrix

We know that zero matrix is a matrix whose all elements are zero, so we have,

WE have A+B+C=0,

So C = -A+B,

Given,

Here, A’ i.e. A transpose is

We are given that A+A’=I

So,

After doing addition of matrices, we get,

On comparing the elements we get,

This implies,

For belongs 0 to , =

Given,

Applying matrix multiplication we get,

On comparing the elements we get, 2x-3y = 1,

x+y = 3,

On solving the equations we get, x=2, y=1

Given,

Applying matrix multiplication we have,

On comparing the elements with each other we get,

The linear equations, x+2y=3, 3y+2x=5

On solving these equations we get x = 1, y = 1

Given,

Then, (A +A’) will be,

The matrix is a symmetrical matrix.

Given,

, and

(A - A’) =

The matrix is skew-symmetric.

Given,

We need to a matrix X such that, A +2B + X = 0

We have, X = -(A + 2B),

Given,

We have 3A – 2B + X = 0

So X = -(3A – 2B)

Thus,

Given,

Then ,

Applying matrix multiplication we get,

Hence,

As we know that

We are given that A and B are symmetric matrices of the same order then, we need to show that (AB – BA) is a skew symmetric matrix.

Let us consider P is a matrix of the same order as A and B

And let P = (AB – BA),

we have A = A’ and B = B’

then, P’ = (AB – BA)’

P’ = ((AB)’ – (BA)’) …….using reversal law we have (CD)’=D’C’

P’ = (B’A’ – A’B’)

P’ = (BA – AB)

P’ = -P

Hence, P is a skew symmetric matrix.

Given,

f(x) = x² – 4x + 1,

f(A) = A² – 4A + I,

f(A) =

f(A) =

f(A) =

Given that matrix A is both symmetric and skew symmetric, then,

We have A = A’ ……(i)

And A = -A’ ……(ii)

From (i) and (ii) we get,

A’ = -A’,

2A’ = 0

A’ = 0

Then, A = 0

Hence proved.