Find an appropriate integrating factor that will convert the given not exact differential equation cos ⁡...

Determine whether the given differential equation is exact. If it is exact, solve it. (If it...

Determine whether the given differential equation is exact. If it is exact, solve it. (If it is not exact, enter NOT.) (tan(x) − sin(x) sin(y)) dx + cos(x) cos(y) dy = 0

Find an integrating factor for the equation that depends on one variable only. Verify that the...

Find an integrating factor for the equation that depends on one variable only. Verify that the equation that results from multiplying the equation below by your integrating factor is indeed exact. You do not need to solve the equation. 1 + (1 + t + y)dy/dt = 0

Use the Integrating Factor Technique to find the solution to the first-order linear differential equation (1...

Use the Integrating Factor Technique to find the solution to the first-order linear differential equation (1 − ? ∙ ?in(?)) ∙ ?? − cos(?) ∙ ?? = 0 with ?(?) = 1

consider the equation y*dx+(x^2y-x)dy=0. show that the equation is not exact. find an integrating factor o...

consider the equation y*dx+(x^2y-x)dy=0. show that the equation is not exact. find an integrating factor o the equation in the form u=u(x). find the general solution of the equation.

Solve the given differential equation by undetermined coefficients. y'' + 2y' + y = 2 cos...

Solve the given differential equation by undetermined coefficients. y'' + 2y' + y = 2 cos x − 2x sin x

Solve the given differential equation by finding, as in Example 4 of Section 2.4, an appropriate...

Solve the given differential equation by finding, as in Example 4 of Section 2.4, an appropriate integrating factor. (14 − 10y + e−5x) dx − 2 dy = 0

Find an integrating factor and solve the O.D.E. 1 + (x/y − sin(y) *dy/dx = 0.

Find an integrating factor and solve the O.D.E. 1 + (x/y − sin(y) *dy/dx = 0.

Find the solution to the following equation using an appropriate integrating factor. Include largest interval solution...

Find the solution to the following equation using an appropriate integrating factor. Include largest interval solution is valid for x(dy/dx)-2y√(x) =3√(x) y(1)= -1

A) In this problem we consider an equation in differential form ???+???=0Mdx+Ndy=0. The equation (5?^4?+4cos(2?)?^−4)??+(5?^5−3?^−4)??=0 in...

A) In this problem we consider an equation in differential form ???+???=0Mdx+Ndy=0. The equation (5?^4?+4cos(2?)?^−4)??+(5?^5−3?^−4)??=0 in differential form ?˜??+?˜??=0 is not exact. Indeed, we have My-Mx= ________ 5x^4-4(4)cos(2x)*y^(-5)-25x^4 (My-Mn)/M=_____ -4/y in function y alone. ?(?)= _____y^4 Multiplying the original equation by the integrating factor we obtain a new equation ???+???=0 where M=____ N=_____ which is exact since My=_____ Nx=______ This problem is exact. Therefore an implicit general solution can be written in the form  ?(?,?)=? where ?(?,?)=_________ Finally find the value...

5. In the following exercises solve the given equation using the integrating factor method. Assumet>0: (a)...

5. In the following exercises solve the given equation using the integrating factor method. Assumet>0: (a) e^t y′+y=1, (b) y′+y=2−et.