Let A and B be n-rowed square matrices
STATEMENT - 1 The identity `(x+y)^(2)=x^(2)+2xy+y^(2)` doesn't hold when x and y are substituted by A and B.
and
STATEMENT- 2 : Matrix multiplication is not commutative

If x=1&y=-3 then prove the identity (x+y)^2=x^2+2xy+y^2

STATEMENT -1 : The differential equation (dy)/(dx) = (2xy)/(x^(2) + y^(2)) Can't be solved by the substitution x = vy. and STATEMENT-2 : When the differential equation is homogeneous of first order and first degree, then the substitution that solves the equation is y = vx.

Let f(x,y)=x^(2)+2xy+3y^(2)-6x-2y, where x, y in R, then

Let A and B be two symmetric matrices of order 3. Statement-1 : A(BA) and (AB)A are symmetric matrices. Statement-2 : AB is symmetric matrix if matrix multiplication of A with B is commutative. Statement-1 is true, Statement-2 is true; Statement-2 is a correct explanation for Statement-1. Statement-1 is true, Statement-2 is true; Statement-2 is true; Statement-2 is not a correct explanation for Statement-1. Statement-1 is true, Statement-2 is false. Statement-1 is false, Statement-2 is true.

If square matrices A and B are such that A^(2)=A,B^(2)=B and A,B commut4e for multiplication, then

Statement 1: The product of two diagonal matrices of order 3 is also a diagonal matrix. Statement -2 : In general, matrix multiplication is non-commutative.

STATEMENT-1 : The line y = (b)/(a)x will not meet the hyperbola (x^(2))/(a^(2)) -(y^(2))/(b^(2)) =1, (a gt b gt 0) . and STATEMENT-2 : The line y = (b)/(a)x is an asymptote to the hyperbola.

Let A and B two symmetric matrices of order 3. Statement 1 : A(BA) and (AB)A are symmetric matrices. Statement 2 : AB is symmetric matrix if matrix multiplication of A with B is commutative.

Let A and B are symmetric matrices of order 3. Statement -1 A (BA) and (AB) A are symmetric matrices. Statement-2 AB is symmetric matrix, if matrix multiplication of A with B is commutative.