y'' + 2y' + y = x + e^(-x) , y(0)=0 , y'(0)=0
Solve the following 2nd ODE and find y(x)
y'' + 2y' + y = x + e^(-x) , y(0)=0 , y'(0)=0 Solve the following...
Solve the following ODE for y(x) y''+y'-2y=sin(2x) y(0)=2 y'(0)=0
1. a) Solve the following linear ODE. dy * dx + 2y = 4x2, x > 0 b) Solve the following ODE using the substitution, u = dy (x - y) dx = y c) Solve the Bernoulli's ODE dy 1 + -y = dx = xy2 ; x > 0
1) Solve the following ODE with IVP 2y" + 6y' - 8y = 0 y(0) = 4 y'(0) = -1
5. Solve the linear, constant coefficient ODE y" – 3y' + 2y = 0; y(0) = 0, y'(0) = 1. 6. Solve the IVP with Cauchy-Euler ODE x2y" - 4xy' + 6y = 0; y(1) = 2, y'(1) = 0. 7. Given that y = Ge3x + cze-5x is a solution of the homogeneous equation, use the Method of Undetermined Coefficients to find the general solution of the non-homogeneous ODE " + 2y' - 15y = 3x 8. A 2...
Solve the equation y" + 2y" - V - 2y = 0 using the method of converting to a linear system of first-order ODE's. Show that the coefficient matrix is the 3 x 3 matrix from problem 1. Then find the system's solution using the eigenvectors and eigenvalues. At the very end, note that the vector solution has components for y, y'.,y". Thus the solution to the original ODE is just the first coordinate of your vector solution.
Solve the equation y" + 2y" - 5'- 2y = 0 using the method of converting to a linear system of first-order ODE's. Show that the coefficient matrix is the 3 x 3 matrix from problem 1. Then find the system's solution using the eigenvectors and eigenvalues. At the very end, note that the vector solution has components for y, y',y". Thus the solution to the original ODE is just the first coordinate of your vector solution.
2. (20 pts) Solve the following ODE: 3. (30 pts) Solve the following (ODE. y"2y'2y = 2x
Solve the ODE/IVP: 4x^2y'' + 8xy' +y=0, y(1)=2, y'(1)=0 Please help me solve this using series. Thanks
solve the following differential equations
(e* + 2y)dx + (2x – sin y)dy = 0 xy' + y = y? (6xy + cos2x)dx +(9x?y? +e")dy = 0 +2ye * )dx = (w*e * -2rcos x) di
(1) Use the Laplace transform method to solve the initial value problem x + 2y. V=x+', (0) = 0 (0) -0. (Note that once you find either (t) or y(t), the other can be computed from the syste of ODE.) ISA - X-xo) = x +2Y ST-y(0) = X te 15.- 2 1 X(5-)-2Y=0 lo -2ts(s)