Find `int_(R)^(∞) (GMm)/(x^(2)) dx` where G, M and m are constants.

Find the value of int_(-l/2)^(+l/2)M/l x^(2) dx where M and l are constants .

The value of int_(-2)^(2)(ax^(2011)+bx^(2001)+c)dx , where a , b , c are constants depends on the value of

If int(dx)/(x+x^(2011))=f(x)+C_(1) and int(x^(2009))/(1+x^(2010))dx=g(x)+C_(2) (where C_(1) and C_(2) are constants of integration). Let h(x)=f(x)+g(x). If h(1)=0 then h(e) is equal to :

int_(m)^(0)f(x)dx is

The value of int((x-4))/(x^2sqrt(x-2)) dx is equal to (where , C is the constant of integration )

Evaluate : (i) int_(-1)^(2){2x}dx (where function {*} denotes fractional part function) (ii) int_(0)^(10x)(|sinx|+|cosx|) dx (iii) (int_(0)^(n)[x]dx)/(int_(0)^(n)[x]dx) where [x] and {x} are integral and fractional parts of the x and n in N (iv) int_(0)^(210)(|sinx|-[|(sinx)/(2)|])dx (where [] denotes the greatest integer function and n in 1 )

If the integral int(x^(4)+x^(2)+1)/(x^(2)-x+1)dx=f(x)+C, (where C is the constant of integration and x in R ), then the minimum value of f'(x) is

If int x^(5)e^(-x^(2))dx = g(x)e^(-x^(2))+C , where C is a constant of integration, then g(-1) is equal to

Prove that y=e^(x)+m is a solution of the differential equation (d^(2)y)/(dx^2)-(dy)/(dx)=0 , where m is a constant.

Let A_(r) be the area of the region bounded between the curves y^(2)=(e^(-kr))x("where "k gt0,r in N)" and the line "y=mx ("where "m ne 0) , k and m are some constants A_(1),A_(2),A_(3),… are in G.P. with common ratio