Consider a system of linear equation in ...

Consider a system of linear equation in three variables x,y,z
`a_1x+b_1y+ c_1z = d_1 , a_2x+ b_2y+c_2z=d_2 , a_3x + b_3y + c_3z=d_3`
The systems can be expressed by matrix equation `[(a_1,b_1,c_1),(a_2,b_2,c_2),(c_1,c_2,c_3)][(x),(y),(z)]=[(d_1),(d_2),(d_3)]`
if A is non-singular matrix then the solution of above system can be found by X =`A^(-1)B`, the solution in this case is unique.
if A is a singular matrix i.e. then the system will have
no unique solution if no solution (i.e. it is inconsistent) if
Where Adj A is the adjoint of the matrix A, which is obtained by taking transpose of the matrix obtained by replacing each element of matrix A with corresponding cofactors.
Now consider the following matrix.
`A=[(a,1,0),(1,b,d),(1,b,c)], B=[(a,1,1),(0,d,c),(f,g,h)], U=[(f),(g),(h)], V=[(a^2),(0),(0)], X=[(x),(y),(z)]`
If AX=U has infinitely many solutions then the equation BX=U is consistent if

`(3n + 4)2^(n-1) - 2`

`(2n - 4)2^(n-1) - 2`

`(3n -4)2^(n-1) - 2`

`(3n- 4)2^(n-1) + 2`

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