`intcos(logx)dx=F(x)+c`, where c is an arbitrary constant. Here F(x)=

If int1/((1+x)sqrt(x))dx=f(x)+A , where A is any arbitrary constant, then the function f(x) is

The general solution of the differential equation (dy)/(dx)=2y tan x+tan^(2)x, AA x in (0, (pi)/(2)) is yf(x)=(x)/(2)-(sin(2x))/(4)+C , (where, C is an arbitrary constant). If ((pi)/(4))=(1)/(2) , then the value of f((pi)/(3)) is equal to

The solution of the differential equation (dy)/(dx)=(x-y)/(x-3y) is (where, c is an arbitrary constant)

The solution of the differential equation (dy)/(dx)=(2x-y)/(x-6y) is (where c is an arbitrary constant)

The value of the integral int((sin x)/(x))^(6)((x cos x - sin x)/(x^2)) dx is (where , c is an arbitrary constant)

Consider the following statements : 1 . The general solution of (dy)/(dx) = f(x) +x is of the form y = g(x) + C , where C is an arbitrary constant . II . The degree of ((dy)/(dx))^2 = f(x) is 2 . Which of the above statements is /are correct ?

The solution of the differential equation x(dy)/(dx)=y ln ((y^(2))/(x^(2))) is (where, c is an arbitrary constant)

The solution of the differential equation (dy)/(dx)+(y)/(x)=(1)/((1+lnx+lny)^(2)) is (where, c is an arbitrary constant)

The solution of differential equation x^(2)(x dy + y dx) = (xy - 1)^(2) dx is (where c is an arbitrary constant)

If the integral I = int x^(sin x)(cos x cdot 1n x + (sin x)/x)dx, = (f(x))^(g(x)) + c (AA x > 0) then the range of y = g(x) is (where, c is an arbitrary constant)