The nonhomogeneous equation t2 y′′−2 y=29 t2−1, t>0, has homogeneous solutions y1(t)=t2, y2(t)=t−1. Find the particular...

The nonhomogeneous equation t2 y′′−2 y=19 t2−1, t>0, has homogeneous solutions y1(t)=t2, y2(t)=t−1. Find the particular...

The nonhomogeneous equation t2 y′′−2 y=19 t2−1, t>0, has homogeneous solutions y1(t)=t2, y2(t)=t−1. Find the particular solution to the nonhomogeneous equation that does not involve any terms from the homogeneous solution. Enter an exact answer. Enclose arguments of functions in parentheses. For example, sin(2x). y(t)=

Given that y1 = t, y2 = t 2 are solutions to the homogeneous version of...

Given that y1 = t, y2 = t 2 are solutions to the homogeneous version of the nonhomogeneous DE below, verify that they form a fundamental set of solutions. Then, use variation of parameters to find the general solution y(t). (t^2)y'' - 2ty' + 2y = 4t^2 t > 0

The function y1(t) = t is a solution to the equation. t2 y'' + 2ty' -...

The function y1(t) = t is a solution to the equation. t2 y'' + 2ty' - 2y = 0, t > 0 Find another particular solution y2 so that y1 and y2 form a fundamental set of solutions. This means that, after finding a solution y2, you also need to verify that {y1, y2} is really a fundamental set of solutions.

Let y1 and y2 be solutions of Bessel's equation t2y" + ty' + (t2 - n2)y...

Let y1 and y2 be solutions of Bessel's equation t2y" + ty' + (t2 - n2)y =0 on the interval 0 < t < oo, with y1(l)= l, y!(l)=O, yil)=O, and y2(l)= I. Compute W[y1,y2](t).

In this problem verify that the given functions y1 and y2 satisfy the corresponding homogeneous equation....

In this problem verify that the given functions y1 and y2 satisfy the corresponding homogeneous equation. Then find a particular solution of the nonhomogeneous equation. x^2y′′−3xy′+4y=31x^2lnx, x>0, y1(x)=x^2, y2(x)=x^2lnx. Enter an exact answer.

Choose the correct answers If y1 and y2 are two solutions of a nonhomogeneous equation ayjj+...

Choose the correct answers If y1 and y2 are two solutions of a nonhomogeneous equation ayjj+ byj+ cy =f (x), then their difference is a solution of the equation ayjj+ byj+ cy = 0. If f (x) is continuous everywhere, then there exists a unique solution to the following initial value problem.                                   f (x)yj= y,   y(0) = 0 The differential equation yjj + t2yj − y = 3 is linear. There is a solution to the ODE yjj+3yj+y...

Given y1(t)=t^2 and y2(t)=t^-1 satisfy the corresponding homogeneous equation of t^2y''−2y=2−t3,  t>0 Then the general solution to...

Given y1(t)=t^2 and y2(t)=t^-1 satisfy the corresponding homogeneous equation of t^2y''−2y=2−t3,  t>0 Then the general solution to the non-homogeneous equation can be written as y(t)=c1y1(t)+c2y2(t)+yp(t) yp(t) =

The indicated functions are known linearly independent solutions of the associated homogeneous differential equation on (0,...

The indicated functions are known linearly independent solutions of the associated homogeneous differential equation on (0, ∞). Find the general solution of the given nonhomogeneous equation. x2y'' + xy' + y = sec(ln(x)) y1 = cos(ln(x)), y2 = sin(ln(x))

Consider the differential equation t 2 y" + 3ty' + y = 0, t > 0....

Consider the differential equation t 2 y" + 3ty' + y = 0, t > 0. (a) Check that y1(t) = t −1 is a solution to this equation. (b) Find another solution y2(t) such that y1(t) and y2(t) are linearly independent (that is, y1(t) and y2(t) form a fundamental set of solutions for the differential equation)

Find the function y1(t) which is the solution of 4y″+32y′+64y=0 with initial conditions y1(0)=1,y′1(0)=0. y1(t)=? Find...

Find the function y1(t) which is the solution of 4y″+32y′+64y=0 with initial conditions y1(0)=1,y′1(0)=0. y1(t)=? Find the function y2(t) which is the solution of 4y″+32y′+64y=0 with initial conditions y2(0)=0, y′2(0)=1. y2(t)= ? Find the Wronskian of these two solutions you have found: W(t)=W(y1,y2). W(t)=?