Statement 1 `lim_(mtooo)lim_(n tooo){sin^(2m)n!pin}=0m, n epsilonN`,when x is rational.
Statement 2 When `n to oo` and x is rational`n!x` is integer.

Evaluate lim_(ntooo)(pin)^(2//n)

Let f(x)=lim_(m->oo){lim_(n->oo)cos^(2m)(n !pix)}, where x in Rdot Then the range of f(x)

lim_(ntooo)(sin^(n)1+cos^(n)1)^(n) is equal to

If x is a rational number then x^(n)xx x^(b)=x^(axxb)

Solve The equation Statement -1 x^(2)+(2m+1)x+(2n+1)=0 where m and n are integers, cannot have any rational roots. Statement - 2 The quantity (2m+1)^2 −4(2n+1) , where m,n∈I, can never be a perfect square.

lim_(x->0) (sin(nx)((a-n)nx – tanx))/x^2= 0 , when n is a non-zero positive integer, then a is equal to

Evaluate lim_(nto oo)((n+2)!+(n+1)!)/((n+2)!-(n+1)!)

If I(mn)=int_(0)^(1)x^(m)(1-x)^(n)dx,(m, n epsilon I, m,n ge 0 ) , then

evaluate lim_(n->oo)((e^n)/pi)^(1/ n)

Statement-1 The number of terms in the expansion of (x + (1)/(x) + 1)^(n) " is " (2n +1) Statement-2 The number of terms in the expansion of (x_(1) + x_(2) + x_(3) + …+ x_(m))^(n) "is " ^(n + m -1)C_(m-1) .