integrar x[(sen(x2+1)cos(x2-1)]dx

find dy/dx : F(x) =(2x7-x2)(x-1/x+1)

find dy/dx : F(x) =(2x7-x2)(x-1/x+1)

Evaluate ∮C(x^3+xy)dx+(cos(y)+x2)dy∮C(x^3+xy)dx+(cos(y)+x^2)dy where C is the positively oriented boundary of the region bounded by  C:0≤x^2+y^2≤16, x≥0,y≥0C:0≤x^2+y^2≤16,x≥0,y≥0

Evaluate ∮C(x^3+xy)dx+(cos(y)+x2)dy∮C(x^3+xy)dx+(cos(y)+x^2)dy where C is the positively oriented boundary of the region bounded by  C:0≤x^2+y^2≤16, x≥0,y≥0C:0≤x^2+y^2≤16,x≥0,y≥0

Intergrate: (a) 12sin^6(x)cos^2(x) dx (b) (x-7)/(x+9)(x-2) dx

Intergrate: (a) 12sin^6(x)cos^2(x) dx (b) (x-7)/(x+9)(x-2) dx

. Explain why integral of (g(x) sin(x) dx) is equal to (- g(x) cos(x) + integral...

. Explain why integral of (g(x) sin(x) dx) is equal to (- g(x) cos(x) + integral of (g'(x) cos(x) dx))

Solve the following Differential equations a) x sin y dx + (x^2 + 1) cos y...

Solve the following Differential equations a) x sin y dx + (x^2 + 1) cos y dy = 0

y = (6 +cos(x))^x Use Logarithmic Differentiation to find dy/dx dy/dx = Type sin(x) for sin(x)sin(x)...

y = (6 +cos(x))^x Use Logarithmic Differentiation to find dy/dx dy/dx = Type sin(x) for sin(x)sin(x) , cos(x) for cos(x)cos(x), and so on. Use x^2 to square x, x^3 to cube x, and so on. Use ( sin(x) )^2 to square sin(x). Use ln( ) for the natural logarithm.

List these six partial derivatives for z = 3 x2 y + cos (x y) –...

List these six partial derivatives for z = 3 x2 y + cos (x y) – ex+y dz/dx dz/dy d2z/dx2 d2z/ dy2 d2z/dxdy d2z/dydx                   Evaluate the partial derivative            dz        at the point (2, 3, 30) for the function z = 3 x4 – x y2 dx

Solve the special type second order differential equation:                             x2*d2y/dx^2+x(dy/dx)=1

Solve the special type second order differential equation:                             x2*d2y/dx^2+x(dy/dx)=1

Prove that the family of trigonometric functions { 1, cos x, sin x, ..., cos nx,...

Prove that the family of trigonometric functions { 1, cos x, sin x, ..., cos nx, sin nx, ...} form an orthogonal system on [-pi,pi] prove that the following orthogonality relations hold integral from -pi to pi of sin nx dx = 0 and integral from -pi to pi of cos nx dx = 0

Evaluate double integral Z 2 0 Z 1 y/2 cos(x^2 )dx dy (integral from 0 to...

Evaluate double integral Z 2 0 Z 1 y/2 cos(x^2 )dx dy (integral from 0 to 2)(integral from y/2 to 1) for cos(x^2) dx dy