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

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

Find an appropriate integrating factor that will convert the given not exact differential equation cos ⁡ x d x + ( 1 + 2 y ) sin ⁡ x d y = 0 into an exact one. Then solve the new exact differential equation.

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 following equation using integrating factor. y dx + (2x − ye^y) dy = 0

Solve the following equation using integrating factor. y dx + (2x − ye^y) 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.

Solve the Initial Value Problem: a) dydx+2y=9, y(0)=0 y(x)=_______________ b) dydx+ycosx=5cosx,        y(0)=7d y(x)=______________ c) Find the...

Solve the Initial Value Problem: a) dydx+2y=9, y(0)=0 y(x)=_______________ b) dydx+ycosx=5cosx,        y(0)=7d y(x)=______________ c) Find the general solution, y(t), which solves the problem below, by the method of integrating factors. 8t dy/dt +y=t^3, t>0 Put the problem in standard form. Then find the integrating factor, μ(t)= ,__________ and finally find y(t)= __________ . (use C as the unkown constant.) d) Solve the following initial value problem: t dy/dt+6y=7t with y(1)=2 Put the problem in standard form. Then find the integrating...

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

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.

test if the equation ((x^4)(y^2) - y)dx + ((x^2)(y^4) - x)dy = 0 is exact. If...

test if the equation ((x^4)(y^2) - y)dx + ((x^2)(y^4) - x)dy = 0 is exact. If it is not exact, try to find an integrating factor. after the equation is made exact, solve by looking for integrable combinations

Consider the differential equation y′′+ 9y′= 0.( a) Let u=y′=dy/dt. Rewrite the differential equation as a...

Consider the differential equation y′′+ 9y′= 0.( a) Let u=y′=dy/dt. Rewrite the differential equation as a first-order differential equation in terms of the variables u. Solve the first-order differential equation for u (using either separation of variables or an integrating factor) and integrate u to find y. (b) Write out the auxiliary equation for the differential equation and use the methods of Section 4.2/4.3 to find the general solution. (c) Find the solution to the initial value problem y′′+ 9y′=...

In this problem we consider an equation in differential form ???+???=0 The equation (6?^(1/?)+4?^3?^−3)??+(6?^2?^−2+4)??=0 in differential...

In this problem we consider an equation in differential form ???+???=0 The equation (6?^(1/?)+4?^3?^−3)??+(6?^2?^−2+4)??=0 in differential form ?˜??+?˜??=0 is not exact. Indeed, we have ?˜?−?˜?/M=______ is a function of ? alone. Namely we have μ(y)= Multiplying the original equation by the integrating factor we obtain a new equation ???+???=0 ?=____ ?=_____ Which is exact since ??=______ ??=_______ are equal. This problem is exact. Therefore an implicit general solution can be written in the form  ?(?,?)=?F where ?(?,?)=__________