Buy BOOKS at Discounted Price

Adjoint And Inverse Of A Matrix

Class 12th Mathematics RS Aggarwal Solution
Exercise 7
  1. [ {ll} {2}&{3} {5}&{9} ] Find the adjoint of the given matrix and verify in each…
  2. [ {cc} {3}&{-5} {-1}&{2} ] Find the adjoint of the given matrix and verify in…
  3. [ {cc} {cosalpha }&{sinalpha} {sinalpha}&{cosalpha} ] Find the adjoint of the…
  4. [ {ccc} {1}&{-1}&{2} {3}&{1}&{-2} {1}&{0}&{3} ] Find the adjoint of the given…
  5. [ {ccc} {3}&{-1}&{1} {-15}&{6}&{-5} {5}&{-2}&{2} ] Find the adjoint of the given…
  6. [ {lll} {0}&{1}&{2} {1}&{2}&{3} {3}&{1}&{1} ] Find the adjoint of the given…
  7. [ {ccc} {9}&{7}&{3} {5}&{-1}&{4} {6}&{8}&{2} ] Find the adjoint of the given…
  8. [ {lll} {4}&{5}&{3} {1}&{0}&{6} {2}&{7}&{9} ] Find the adjoint of the given…
  9. [ {ccc} {cosalpha }&{-sinalpha}&{0} {sinalpha}&{cosalpha}&{0} {0}&{0}&{1} ] Find…
  10. If A = [ {ccc} {-4}&{-3}&{-3} {1}&{0}&{1} {4}&{4}&{3} ] , show that adj A = A.…
  11. If A = [ {ccc} {-1}&{-2}&{-2} {2}&{1}&{-2} {2}&{-2}&{1} ] , show that adj A =…
  12. [ {cc} {3}&{-5} {-1}&{2} ]
  13. [ {ll} {4}&{1} {2}&{3} ] Find the inverse of each of the matrices given below.…
  14. [ {cc} {2}&{-3} {4}&{6} ] Find the inverse of each of the matrices given below.…
  15. [ {ll} {a}&{b} {c}&{d} ] , when (ab – bc) y^{2} 0 Find the inverse of each…
  16. [ {ccc} {1}&{2}&{5} {1}&{-1}&{-1} {2}&{3}&{-1} ] Find the inverse of each of…
  17. [ {ccc} {2}&{-1}&{1} {3}&{0}&{-1} {2}&{6}&{0} ] Find the inverse of each of the…
  18. [ {ccc} {2}&{-3}&{3} {2}&{2}&{3} {3}&{-2}&{2} ] Find the inverse of each of the…
  19. [ {ccc} {0}&{0}&{-1} {3}&{4}&{5} {-2}&{-4}&{-7} ] Find the inverse of each of…
  20. [ {ccc} {2}&{-1}&{4} {-3}&{0}&{1} {-1}&{1}&{2} ] Find the inverse of each of…
  21. [ {ccc} {8}&{-4}&{1} {10}&{0}&{6} {8}&{1}&{6} ] Find the inverse of each of the…
  22. If A = [ {cc} {2}&{3} {5}&{-2} ] , show that A-1 = {1}/{19} A.…
  23. If A = [ {ccc} {1}&{-1}&{1} {2}&{-1}&{0} {1}&{0}&{0} ] , show that A-1 = A2.…
  24. If A = [ {ccc} {3}&{-3}&{4} {2}&{-3}&{4} {0}&{-1}&{1} ] , prove that A-1 = A3.…
  25. If A = {1}/{9} [ {ccc} {-8}&{1}&{4} {4}&{4}&{7} {1}&{-8}&{4} ] show that…
  26. Let D = diag [d1, d2, d3], where none of d1, d2, d3 is 0; prove that D-1 = diag…
  27. If A = [ {ll} {3}&{2} {7}&{5} ] and B = [ {ll} {6}&{7} {8}&{9} ] , verify…
  28. If A = [ {ll} {9}&{-1} {6}&{-2} ] and B = [ {cc} {-4}&{3} {5}&{-4} ] , verify…
  29. Compute (AB)-1 when A = [ {ccc} {1}&{1}&{2} {0}&{2}&{-3} {3}&{-2}&{4} ] and…
  30. Obtain the inverses of the matrices [ {lll} {1}&{p}&{0} {0}&{1}&{p}…
  31. If A = [ {ll} {3}&{2} {2}&{1} ] , verify that A2 – 4A – I = O, and hence find…
  32. Show that the matrix A = [ {cc} {-8}&{5} {2}&{4} ] satisfies the equation 𝒳2…
  33. If A = [ {cc} {-1}&{-1} {2}&{-2} ] , show that A2 + 3A + 4I2 = O and hence…
  34. If A = [ {ll} {3}&{1} {7}&{5} ] , find 𝒳 and 𝒴 such that A2 + 𝒳I = 𝒴A.…
  35. If A = [ {cc} {3}&{-2} {4}&{-2} ] . Find the value of λ so that A2 = λA – 2I.…
  36. Show that the A = [ {ccc} {1}&{0}&{-2} {-2}&{-1}&{2} {3}&{4}&{1} ] satisfies…
  37. Prove that: (i) adj I = I (ii) adj O = O (iii) I-1 = I.

Exercise 7
Question 1.

Find the adjoint of the given matrix and verify in each case that A. (adj A) = (adj A) =m |A|.I.




Answer:

Here,

Now, we have to find adj A and for that we have to find co-factors:


a11 (co – factor of 2) = (-1)1+1(9) = (-1)2(9) = 9


a12 (co – factor of 3) = (-1)1+2(5) = (-1)3(5) = -5


a21 (co – factor of 5) = (-1)2+1(3) = (-1)3(3) = -3


a22 (co – factor of 9) = (-1)2+2(2) = (-1)4(2) = 2



Now, adj A = Transpose of co-factor Matrix



Calculating A (adj A)







= 3I


Calculating (adj A)A







= 3I


Calculating |A|.I





= (2 × 9 – 3 × 5)I


= (18 – 15)I


= 3I


Thus, A(adj A) = (adj A)A = |A|I = 3I


⇒ A(adj A) = (adj A)A = |A|I


Hence Proved


Ans.



Question 2.

Find the adjoint of the given matrix and verify in each case that A. (adj A) = (adj A) =m |A|.I.


Answer:

Here,

Now, we have to find adj A and for that we have to find co-factors:


a11 (co – factor of 3) = (-1)1+1(2) = (-1)2(2) = 2


a12 (co – factor of -5) = (-1)1+2(-1) = (-1)3(-1) = 1


a21 (co – factor of -1) = (-1)2+1(-5) = (-1)3(-5) = 5


a22 (co – factor of 2) = (-1)2+2(3) = (-1)4(3) = 3



Now, adj A = Transpose of co-factor Matrix



Calculating A (adj A)






= I


Calculating (adj A)A






= I


Calculating |A|.I





= [3 × 2 – (-1) × (-5)]I


= [6 – (5)] I


= (1)I


= I


Thus, A(adj A) = (adj A)A = |A|I = I


⇒ A(adj A) = (adj A)A = |A|I


Hence Proved


Ans.



Question 3.

Find the adjoint of the given matrix and verify in each case that A. (adj A) = (adj A) =m |A|.I.


Answer:

Here,

Now, we have to find adj A and for that we have to find co-factors:


a11 (co – factor of cos α) = (-1)1+1(cos α)= (-1)2(cos α) = cos α


a12 (co – factor of sin α) = (-1)1+2(sin α) = (-1)3(sin α) = -sin α


a21 (co – factor of sin α) = (-1)2+1(sin α) = (-1)3(sin α) = -sin α


a22 (co – factor of cos α) = (-1)2+2(cos α)= (-1)4(cos α) = cos α



Now, adj A = Transpose of co-factor Matrix



Calculating A (adj A)





= (cos2 α – sin2 α) I


Calculating (adj A)A






= (cos2 α – sin2 α) I


Calculating |A|.I





= [cos α × cos α – (sin α) × (sin α)]I


= [cos2 α – sin2 α] I


Thus, A(adj A) = (adj A)A = |A|I = I


⇒ A(adj A) = (adj A)A = |A|I


Hence Proved


Ans.



Question 4.

Find the adjoint of the given matrix and verify in each case that A. (adj A) = (adj A) =m |A|.I.


Answer:

Here,


Now, we have to find adj A, and for that, we have to find co-factors:












Calculating A (adj A)






= 12I


Calculating (adj A)A






= 12I


Calculating |A|.I


Expanding along C1, we get




= [1(3 – 0) – (-1){9 – (-2)} + 2(0 – 1)]I


= [3 + 1(11) + 2(-1)] I


= (3 + 11 – 2 )I


= 12I


Thus, A(adj A) = (adj A)A = |A|I = 12I


⇒ A(adj A) = (adj A)A = |A|I


Hence Proved


Ans.



Question 5.

Find the adjoint of the given matrix and verify in each case that A. (adj A) = (adj A) =m |A|.I.


Answer:

Here,


Now, we have to find adj A, and for that, we have to find co-factors:












Calculating A (adj A)





= I


Calculating (adj A)A





= I


Calculating |A|.I


Expanding along C1, we get




= [3(12 – 10) – (-15){-2 – (-2)} + 5(5 – 6)]I


= [3(2) + 15(0) + 5(-1)] I


= (6 – 5)I


= I


Thus, A(adj A) = (adj A)A = |A|I = I


⇒ A(adj A) = (adj A)A = |A|I


Hence Proved


Ans.



Question 6.

Find the adjoint of the given matrix and verify in each case that A. (adj A) = (adj A) =m |A|.I.


Answer:

Here,


Now, we have to find adj A, and for that, we have to find co-factors:












Calculating A (adj A)






= -2I


Calculating (adj A)A






= -2I


Calculating |A|.I


Expanding along C1, we get




= [0(2 – 3) – (1){1 – 2} + 3(3 – 4)]I


= [0 – 1(-1) + 3(-1)] I


= (1 – 3)I


= -2I


Thus, A(adj A) = (adj A)A = |A|I = -2I


⇒ A(adj A) = (adj A)A = |A|I


Hence Proved


Ans.



Question 7.

Find the adjoint of the given matrix and verify in each case that A. (adj A) = (adj A) =m |A|.I.


Answer:

Here,


Now, we have to find adj A and for that we have to find co-factors:












Calculating A (adj A)






=-70 I


Calculating (adj A)A






= -70 I


Calculating |A|.I


Expanding along C1, we get




= [9(-2 – 32) – (5){14 – 24} + 6(28 – (-3))]I


= [9(-34) – 5(-10) + 6(31)] I


= (-306 + 50 + 186)I


=-70 I


Thus, A(adj A) = (adj A)A = |A|I = -70 I


⇒ A(adj A) = (adj A)A = |A|I


Hence Proved


Ans.



Question 8.

Find the adjoint of the given matrix and verify in each case that A. (adj A) = (adj A) =m |A|.I.




Answer:

Here,


Now, we have to find adj A and for that we have to find co-factors:












Calculating A (adj A)






= -132I


Calculating (adj A)A






= -132I


Calculating |A|.I


Expanding along C1, we get




= [4(0 – 42) – (1){45 – 21} + 2(30 – 0 )]I


= [4(-42) – 1(24) + 2(30)] I


= (-168 – 24 + 60)I


= -132I


Thus, A(adj A) = (adj A)A = |A|I = -132I


⇒ A(adj A) = (adj A)A = |A|I


Hence Proved


Ans.



Question 9.

Find the adjoint of the given matrix and verify in each case that A. (adj A) = (adj A) =m |A|.I.




Answer:

Here,


Now, we have to find adj A, and for that, we have to find co-factors:











[∵cos2 α + sin2 α = 1]



Calculating A (adj A)






[∵cos2 α + sin2 α = 1]



= I


Calculating (adj A)A






[∵cos2 α + sin2 α = 1]



= I


Calculating |A|.I


Expanding along C1, we get




= [0 – 0 + 1(cos2 α – (-sin2 α))]I


= [cos2 α + sin2 α] I


= (1)I [∵cos2 α + sin2 α = 1]


= I


Thus, A(adj A) = (adj A)A = |A|I = I


⇒ A(adj A) = (adj A)A = |A|I


Hence Proved


Ans.



Question 10.

If A = , show that adj A = A.


Answer:

Here,


Now, we have to find adj A, and for that, we have to find co-factors:












Thus, adj A = A


Hence Proved



Question 11.

If A = , show that adj A = 3A’.


Answer:

We have,

To show: adj A = 3A’


Firstly, we find the Transpose of A i.e. A’



So,


…(i)


Now, we have to find adj A, and for that, we have to find co-factors:












Now, taking Adj A i.e.




= 3A’ [from eq. (i)]


Hence Proved



Question 12.




Answer:

Here,

We have to find A-1 and


Firstly, we find the adj A and for that we have to find co-factors:


a11 (co – factor of 3) = (-1)1+1(2) = (-1)2(2) = 2


a12 (co – factor of -5) = (-1)1+2(-1) = (-1)3(-1) = 1


a21 (co – factor of -1) = (-1)2+1(-5) = (-1)3(-5) = 5


a22 (co – factor of 2) = (-1)2+2(3) = (-1)4(3) = 3



Now, adj A = Transpose of co-factor Matrix



Calculating |A|





= [3 × 2 – (-1) × (-5)]


= (6 – 5)


= 1



Ans.



Question 13.

Find the inverse of each of the matrices given below.




Answer:

Here,

We have to find A-1 and


Firstly, we find the adj A and for that we have to find co-factors:


a11 (co – factor of 4) = (-1)1+1(3) = (-1)2(3) = 3


a12 (co – factor of 1) = (-1)1+2(2) = (-1)3(2) = -2


a21 (co – factor of 2) = (-1)2+1(1) = (-1)3(1) = -1


a22 (co – factor of 3) = (-1)2+2(4) = (-1)4(4) = 4



Now, adj A = Transpose of co-factor Matrix



Calculating |A|





= [4 × 3 – 1 × 2]


= (12 – 2)


= 10



Ans.



Question 14.

Find the inverse of each of the matrices given below.




Answer:

Here,

We have to find A-1 and


Firstly, we find the adj A and for that we have to find co-factors:


a11 (co – factor of 2) = (-1)1+1(6) = (-1)2(6) = 6


a12 (co – factor of -3) = (-1)1+2(4) = (-1)3(4) = -4


a21 (co – factor of 4) = (-1)2+1(-3) = (-1)3(-3) = 3


a22 (co – factor of 6) = (-1)2+2(2) = (-1)4(2) = 2



Now, adj A = Transpose of co-factor Matrix



Calculating |A|





= [2 × 6 – (-3) × 4]


= (12 + 12)


= 24



Ans.



Question 15.

Find the inverse of each of the matrices given below.

, when (ab – bc) 0


Answer:

Here,

We have to find A-1 and


Firstly, we find the adj A and for that we have to find co-factors:


a11 (co – factor of a) = (-1)1+1(d) = (-1)2(d) = d


a12 (co – factor of b) = (-1)1+2(c) = (-1)3(c) = -c


a21 (co – factor of c) = (-1)2+1(b) = (-1)3(b) = -b


a22 (co – factor of d) = (-1)2+2(a) = (-1)4(a) = a



Now, adj A = Transpose of co-factor Matrix



Calculating |A|





= [a × d – c × b]


= ad – bc



Ans.



Question 16.

Find the inverse of each of the matrices given below.




Answer:

We have,


We have to find A-1 and


Firstly, we find |A|


Expanding |A| along C1, we get




= 1(1 – (-3)) – 1(-2 – 15) + 2(-2 – (-5))


= (1 + 3) – 1(-17) + 2(-2 + 5)


= 4 + 17 + 2(3)


= 21 + 6


= 27


Now, we have to find adj A, and for that, we have to find co-factors:













Ans.



Question 17.

Find the inverse of each of the matrices given below.




Answer:

We have,


We have to find A-1 and


Firstly, we find |A|


Expanding |A| along C1, we get




= 2(0 – (-6)) – 3(0 – 6) + 2(1 – 0)


= 2(6) – 3(-6) + 2(1)


= 12 + 18 + 2


= 32


Now, we have to find adj A, and for that, we have to find co-factors:













Ans.



Question 18.

Find the inverse of each of the matrices given below.




Answer:

We have,


We have to find A-1 and


Firstly, we find |A|


Expanding |A| along C1, we get




= 2(4 – (-6)) – 2(-6 – (-6)) + 3(-9 – 6)


= 2(4 + 6) – 2(-6 + 6) + 3(-15)


= 2(10) – 2(0) – 45


= 20 – 45


= -25


Now, we have to find adj A and for that we have to find co-factors:
















Ans.



Question 19.

Find the inverse of each of the matrices given below.




Answer:

We have,


We have to find A-1 and


Firstly, we find |A|


Expanding |A| along C1, we get




= 0 – 3(0 – 4) – 2(0 – (-4))


= 12 – 2(4)


= 12 – 8


= 4


Now, we have to find adj A and for that we have to find co-factors:













Ans.



Question 20.

Find the inverse of each of the matrices given below.




Answer:

We have,


We have to find A-1 and


Firstly, we find |A|


Expanding |A| along C1, we get




= 2(0 – 1) + 3(-2 – 4) – 1(-1 – 0)


= 2(-1) + 3(-6) – 1(-1)


= -2 – 18 + 1


= -19



Now, we have to find adj A and for that we have to find co-factors:













Ans.



Question 21.

Find the inverse of each of the matrices given below.




Answer:

We have,


We have to find A-1 and


Firstly, we find |A|


Expanding |A| along C1, we get




= 8(0 – 6) – 10(-24 – 1) + 8(-24 – 0)


= 8(-6) – 10(-25) + 8(-24)


= -48 + 250 – 192


= 250 – 240


= 10


Now, we have to find adj A and for that we have to find co-factors:













Ans.



Question 22.

If A = , show that A-1 = A.


Answer:

Here,

To show:


We have to find A-1 and


Firstly, we find the adj A and for that we have to find co-factors:


a11 (co – factor of 2) = (-1)1+1(-2) = (-1)2(-2) = -2


a12 (co – factor of 3) = (-1)1+2(5) = (-1)3(5) = -5


a21 (co – factor of 5) = (-1)2+1(3) = (-1)3(3) = -3


a22 (co – factor of -2) = (-1)2+2(2) = (-1)4(2) = 2



Now, adj A = Transpose of co-factor Matrix



Calculating |A|





= [2 × (-2) – 3 × 5]


= (-4 – 15)


= -19




[Taking (-1) common from the matrix]



Hence Proved



Question 23.

If A = , show that A-1 = A2.


Answer:

We have,

To show: A-1 = A2


Firstly, we have to find A-1 and


Calculating |A|


Expanding |A| along C1, we get




= 1(0) – 2(0) + 1(0 – (-1))


= 1(1)


= 1


Now, we have to find adj A and for that we have to find co-factors:












…(i)


Calculating A2





= A-1 [from eq. (i)]


Thus, A2 = A-1


Hence Proved



Question 24.

If A = , prove that A-1 = A3.


Answer:

We have,

To show: A-1 = A3


Firstly, we have to find A-1 and


Calculating |A|


Expanding |A| along C1, we get




= 3(-3 – (-4)) – 2(-3 – (-4)) + 0


= 3(- 3 + 4) – 2(-3 + 4)


= 3(1) – 2(1)


= 3 – 2


= 1


Now, we have to find adj A and for that we have to find co-factors:












…(i)


Calculating A3








= A-1 [from eq. (i)]


Thus, A3 = A-1


Hence Proved



Question 25.

If A = show that A-1= A’.


Answer:

We have,

To show: A-1 = A’


Firstly, we find the Transpose of A, i.e. A.’



Here,


So, …(i)


Now, we have to find A-1 and


Calculating |A|


Expanding |A| along C1, we get










= -1


Now, we have to find adj A, and for that, we have to find co-factors:














= A’ [from eq. (i)]


Thus, A-1 = A’


Hence Proved



Question 26.

Let D = diag [d1, d2, d3], where none of d1, d2, d3 is 0; prove that D-1 = diag [d1-1, d2-1, d3-1].


Answer:

Given: D = diag [d1, d2, d3]

It is also given that d1 ≠ 0, d2 ≠ 0, d3 ≠ 0



A diagonal matrix D = diag(d1, d2, …dn) is invertible iff all diagonal entries are non – zero, i.e. di ≠ 0 for 1 ≤ i ≤ n


If D is invertible then D-1 = diag(d1-1, …dn-1)


By the Inverting Diagonal Matrices Theorem, which states that


Here, it is given that d1 ≠ 0, d2 ≠ 0, d3 ≠ 0


∴ D is invertible


⇒ D-1 = diag [d1-1, d2-1, d3-1]


Hence Proved.



Question 27.

If A = and B = , verify that (AB)-1 = B-1 A-1.


Answer:

Given:


To Verify: (AB)-1= B-1A-1


Firstly, we find the (AB)-1


Calculating AB





We have to find (AB)-1 and


Firstly, we find the adj AB and for that we have to find co-factors:


a11 (co – factor of 34) = (-1)1+1(94) = (-1)2(94) = 94


a12 (co – factor of 39) = (-1)1+2(82) = (-1)3(82) = -82


a21 (co – factor of 82) = (-1)2+1(39) = (-1)3(39) = -39


a22 (co – factor of 94) = (-1)2+2(34) = (-1)4(34) = 34



Now, adj AB = Transpose of co-factor Matrix



Calculating |AB|





= [34 × 94 – (82) × (39)]


= (3196 – 3198)


= -2



Now, we have to find B-1A-1


Calculating B-1


Here,


We have to find A-1 and


Firstly, we find the adj B and for that we have to find co-factors:


a11 (co – factor of 6) = (-1)1+1(9) = (-1)2(9) = 9


a12 (co – factor of 7) = (-1)1+2(8) = (-1)3(8) = -8


a21 (co – factor of 8) = (-1)2+1(7) = (-1)3(7) = -7


a22 (co – factor of 9) = (-1)2+2(6) = (-1)4(6) = 6



Now, adj B = Transpose of co-factor Matrix



Calculating |B|





= [6 × 9 – 7 × 8]


= (54 – 56)


= -2



Calculating A-1


Here,


We have to find A-1 and


Firstly, we find the adj A and for that we have to find co-factors:


a11 (co – factor of 3) = (-1)1+1(5) = (-1)2(5) = 5


a12 (co – factor of 2) = (-1)1+2(7) = (-1)3(7) = -7


a21 (co – factor of 7) = (-1)2+1(2) = (-1)3(2) = -2


a22 (co – factor of 5) = (-1)2+2(3) = (-1)4(3) = 3



Now, adj A = Transpose of co-factor Matrix



Calculating |A|





= [3 × 5 – 2 × 7]


= (15 – 14)


= 1



Calculating B-1A-1


Here,


So,





So, we get


and


∴ (AB)-1 = B-1A-1


Hence verified



Question 28.

If A = and B = , verify that (AB)-1 = B-1 A-1.


Answer:

Given:


To Verify: (AB)-1= B-1A-1


Firstly, we find the (AB)-1


Calculating AB





We have to find (AB)-1 and


Firstly, we find the adj AB and for that we have to find co-factors:


a11 (co – factor of -41) = (-1)1+1(26) = (-1)2(26) = 26


a12 (co – factor of 31) = (-1)1+2(-34) = (-1)3(-34) = 34


a21 (co – factor of -34) = (-1)2+1(31) = (-1)3(31) = -31


a22 (co – factor of 26) = (-1)2+2(-41) = (-1)4(-41) = -41



Now, adj AB = Transpose of co-factor Matrix



Calculating |AB|





= [-41 × 26 – (-34) × (31)]


= (-1066 + 1054)


= -12



Now, we have to find B-1A-1


Calculating B-1


Here,


We have to find A-1 and


Firstly, we find the adj B and for that we have to find co-factors:


a11 (co – factor of -4) = (-1)1+1(-4) = (-1)2(-4) = -4


a12 (co – factor of 3) = (-1)1+2(5) = (-1)3(5) = -5


a21 (co – factor of 5) = (-1)2+1(3) = (-1)3(3) = -3


a22 (co – factor of -4) = (-1)2+2(-4) = (-1)4(-4) = -4



Now, adj B = Transpose of co-factor Matrix



Calculating |B|





= [(-4) × (-4) – 3 × 5]


= (16 – 15)


= 1



Calculating A-1


Here,


We have to find A-1 and


Firstly, we find the adj A and for that we have to find co-factors:


a11 (co – factor of 9) = (-1)1+1(-2) = (-1)2(-2) = -2


a12 (co – factor of -1) = (-1)1+2(6) = (-1)3(6) = -6


a21 (co – factor of 6) = (-1)2+1(-1) = (-1)3(-1) = 1


a22 (co – factor of -2) = (-1)2+2(9) = (-1)4(9) = 9



Now, adj A = Transpose of co-factor Matrix



Calculating |A|





= [9 × (-2) – (-1) × 6]


= (-18 + 6)


= -12



Calculating B-1A-1


Here,


So,





So, we get


and


∴ (AB)-1 = B-1A-1


Hence verified



Question 29.

Compute (AB)-1 when A = and B-1 -= .


Answer:

We have,

To find: (AB)-1


We know that,


(AB)-1 = B-1A-1


and here, B-1 is given but we have to find A-1 and


Firstly, we find |A|


Expanding |A| along C1, we get




= 1(8 – 6) – 0 + 3(-3 – 4)


= 1(2) + 3(-7)


= 2 – 21


= -19


Now, we have to find adj A and for that we have to find co-factors:













Now, we have



So,





Ans.



Question 30.

Obtain the inverses of the matrices and . And, hence find the inverse of the matrix .


Answer:

Let


To find: A-1, B-1 and C-1


Calculating A-1


We have,


We have to find A-1 and


Firstly, we find |A|


Expanding |A| along C1, we get




= 1(1 – 0)


= 1


Now, we have to find adj A and for that we have to find co-factors:












…(i)


Calculating B-1


We have,


We have to find B-1 and


Firstly, we find |A|


Expanding |B| along C1, we get




= 1(1 – 0) – q(0)


= 1


Now, we have to find adj B and for that we have to find co-factors:













…(ii)


Calculating C-1


Here,



⇒ C = AB


⇒ C-1 = (AB)-1


We know that,


(AB)-1 = B-1A-1


Substitute the values, we get




Ans. , and .



Question 31.

If A = , verify that A2 – 4A – I = O, and hence find A-1.


Answer:

Given:

To verify: A2 – 4A – I = 0


Firstly, we find the A2





Taking LHS of the given equation .i.e.


A2 – 4A – I







= 0


= RHS


∴ LHS = RHS


Hence verified


Now, we have to find A-1


Finding A-1 using given equation


A2 – 4A – I = O


Post multiplying by A-1 both sides, we get


(A2 – 4A – I)A-1 = OA-1


⇒ A2.A-1 – 4A.A-1 – I.A-1 = O [OA-1 = O]


⇒ A.(AA-1) – 4I – A-1 = O [AA-1 = I]


⇒ A(I) – 4I – A-1 = O


⇒ A – 4I – A-1 = O


⇒ A – 4I – O = A-1


⇒ A – 4I = A-1






Ans.



Question 32.

Show that the matrix A = satisfies the equation 𝒳2 + 4𝒳 – 42 = 0 and hence find A-1.


Answer:

Given:

To show: Matrix A satisfies the equation x2 + 4x – 42 = 0


If Matrix A satisfies the given equation then


A2 + 4A – 42 = 0


Firstly, we find the A2





Taking LHS of the given equation .i.e.


A2 + 4A – 42







= O


= RHS


∴ LHS = RHS


Hence matrix A satisfies the given equation x2 + 4x – 42 = 0


Now, we have to find A-1


Finding A-1 using given equation


A2 + 4A – 42 = O


Post multiplying by A-1 both sides, we get


(A2 + 4A – 42)A-1 = OA-1


⇒ A2.A-1 + 4A.A-1 – 42.A-1 = O [OA-1 = O]


⇒ A.(AA-1) + 4I – 42A-1 = O [AA-1 = I]


⇒ A(I) + 4I – 42A-1 = O


⇒ A + 4I – 42A-1 = O


⇒ A + 4I – O = 42A-1







Ans. .



Question 33.

If A = , show that A2 + 3A + 4I2 = O and hence find A-1.


Answer:

Given:

To verify: A2 + 3A + 4I = 0


Firstly, we find the A2





Taking LHS of the given equation .i.e.


A2 + 3A + 4I







= O


= RHS


∴ LHS = RHS


Hence verified


Now, we have to find A-1


Finding A-1 using given equation


A2 + 3A + 4I = O


Post multiplying by A-1 both sides, we get


(A2 + 3A + 4I)A-1 = OA-1


⇒ A2.A-1 + 3A.A-1 + 4I.A-1 = O [OA-1 = O]


⇒ A.(AA-1) + 3I + 4A-1 = O [AA-1 = I]


⇒ A(I) + 3I + 4A-1 = O


⇒ A + 3I + 4A-1 = O


⇒ 4A-1 = – A – 3I + O









Ans.



Question 34.

If A = , find 𝒳 and 𝒴 such that A2 + 𝒳I = 𝒴A. Hence, find A-1. [CBSE 2005]


Answer:

Given:

To find: value of x and y


Given equation: A2 + xI = yA


Firstly, we find the A2





Putting the values in given equation


A2 + xI = yA






On Comparing, we get


16 + x = 3y …(i)


y = 8 …(ii)


56 = 7y …(iii)


32 + x = 5y …(iv)


Putting the value of y = 8 in eq. (i), we get


16 + x = 3(8)


⇒ 16 + x = 24


⇒ x = 8


Hence, the value of x = 8 and y = 8


So, the given equation become A2 + 8I = 8A


Now, we have to find A-1


Finding A-1 using given equation


A2 + 8I = 8A


Post multiplying by A-1 both sides, we get


(A2 + 8I)A-1 = 8AA-1


⇒ A2.A-1 + 8I.A-1 = 8AA-1


⇒ A.(AA-1) + 8A-1 = 8I [AA-1 = I]


⇒ A(I) + 8A-1 = 8I


⇒ A + 8A-1 = 8I


⇒ 8A-1 = – A + 8I







Ans. 𝒳 = 8, 𝒴 =8 and A-1 = . .



Question 35.

If A = . Find the value of λ so that A2 = λA – 2I. Hence, find A-1.

[CBSE 2007]


Answer:

Given:

To find: value of λ


Given equation: A2 = λA – 2I


Firstly, we find the A2





Putting the values in given equation


A2 = λA – 2I






On Comparing, we get


3λ – 2 = 1 …(i)


-2λ = -2 …(ii)


4λ = 4 …(iii)


-2λ – 2 = -4 …(iv)


Solving eq. (iii), we get


4λ = 4


⇒ λ = 1


Hence, the value of λ = 1


So, the given equation become A2 = A – 2I


Now, we have to find A-1


Finding A-1 using given equation


A2 = A – 2I


Post multiplying by A-1 both sides, we get


(A2)A-1 = (A – 2I) A-1


⇒ A2.A-1 = AA-1 – 2IA-1


⇒ A.(AA-1) = I – 2A-1 [AA-1 = I]


⇒ A(I) = I – 2A-1


⇒ A + 2A-1 = I


⇒ 2A-1 = – A + I







Ans. λ= 1, A-1 = .



Question 36.

Show that the A = satisfies the equation A3 – A2 – 3A – I = O, and hence find A-1.


Answer:

Given:

We have to show that matrix A satisfies the equation A3 – A2 – 3A – I = O


Firstly, we find the A2





Now, we have to calculate A3





Taking LHS of the given equation .i.e.


A3 – A2 – 3A – I


Putting the values, we get








= O


= RHS


∴ LHS = RHS


Hence, the given matrix A satisfies the equation A3 – A2 – 3A – I


Now, we have to find A-1


Finding A-1 using given equation


A3 – A2 – 3A – I


Post multiplying by A-1 both sides, we get


(A3 – A2 – 3A – I)A-1 = OA-1


⇒ A3.A-1 – A2.A-1 – 3A.A-1 – I.A-1 = O [OA-1 = O]


⇒ A2.(AA-1) – A.(AA-1) – 3I – A-1 = O


⇒ A2(I) – A(I) – 3I – A-1 = O [AA-1 = I]


⇒ A2 – A – 3I – A-1 = O


⇒ O + A-1 = A2 – A – 3I


⇒ A-1 = A2 – A – 3I








Ans. .



Question 37.

Prove that: (i) adj I = I (ii) adj O = O (iii) I-1 = I.


Answer:

(i) To Prove: adj I = I

We know that, I means the Identity matrix


Let I is a 2 × 2 matrix



Now, we have to find adj I and for that we have to find co-factors:


a11 (co – factor of 1) = (-1)1+1(1) = (-1)2(1) = 1


a12 (co – factor of 0) = (-1)1+2(0) = (-1)3(0) = 0


a21 (co – factor of 0) = (-1)2+1(0) = (-1)3(0) = 0


a22 (co – factor of 1) = (-1)2+2(1) = (-1)4(1) = 1



Now, adj I = Transpose of co-factor Matrix



Thus, adj I = I


Hence Proved


(ii) To Prove: adj O = O


We know that, O means Zero matrix where all the elements of matrix are 0


Let O is a 2 × 2 matrix



Calculating adj O


Now, we have to find adj O and for that we have to find co-factors:


a11 (co – factor of 0) = (-1)1+1(0) = 0


a12 (co – factor of 0) = (-1)1+2(0) = 0


a21 (co – factor of 0) = (-1)2+1(0) = 0


a22 (co – factor of 0) = (-1)2+2(0) = 0



Now, adj O = Transpose of co-factor Matrix



Thus, adj O = O


Hence Proved


(iii) To Prove: I-1 = I


We know that,



From the part(i), we get adj I


So, we have to find |I|


Calculating |I|




= [1 × 1 – 0]


= 1



Thus, I-1 = I


Hence Proved