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...

Let y1 and y2 be two solutions of the equation y'' + a(t)y' + b(t)y =...

Let y1 and y2 be two solutions of the equation y'' + a(t)y' + b(t)y = 0 and let W(t) = W(y1, y2)(t) be the Wronskian. Determine an expression for the derivative of the Wronskian with respect to t as a function of the Wronskian itself.

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.

Two solutions to the differential equation y00 + 2y0 + y = 0 are y1(t) =...

Two solutions to the differential equation y00 + 2y0 + y = 0 are y1(t) = e−t and y2(t) = te−t. Verify that y1(t) is a solution and show that y1,y2 form a fundamental set of solutions by computing the Wronskian

y1 = 2 cos(x) − 1 is a particular solution for y'' + 4y = 6...

y1 = 2 cos(x) − 1 is a particular solution for y'' + 4y = 6 cos(x) − 4. y2 = sin(x) is a particular solution for y''+4y = 3 sin(x). Using the two particular solutions, find a particular solution for y''+4y = 2 cos(x)+sin(x)− 4/3 . Verify if the particular solution satisfies the given DE. [Hint: Rewrite the right hand of this equation in terms of the given particular solutions to get the particular solution] Verify if the particular...

if y1 and y2 are linearly independent solutions of t^2y'' + 3y' + (2 + t)y...

if y1 and y2 are linearly independent solutions of t^2y'' + 3y' + (2 + t)y = 0 and if W(y1,y2)(1)=3, find W(y1,y2)(3). ROund your answer to the nearest decimal.

The indicated function y1(x) is a solution of the given differential equation. Use reduction of order...

The indicated function y1(x) is a solution of the given differential equation. Use reduction of order or formula (5) in Section 4.2, y2 = y1(x) e−∫P(x) dx y 2 1 (x) dx        (5) as instructed, to find a second solution y2(x). y'' + 64y = 0;    y1 = cos(8x) y2 =

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=29 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.

Find the solution of the initial value problem y′′+4y=t^2+4^(et), y(0)=0, y′(0)=3.

Find the solution of the initial value problem y′′+4y=t^2+4^(et), y(0)=0, y′(0)=3.

Consider the differential equation: 66t^2y''+12t(t-11)y'-12(t-11)y=5t^3, . You can verify that y1 = 5t and y2 =...

Consider the differential equation: 66t^2y''+12t(t-11)y'-12(t-11)y=5t^3, . You can verify that y1 = 5t and y2 = 4te^(-2t/11)satisfy the corresponding homogeneous equation. The Wronskian W between y1 and y2 is W(t) = (-40/11)t^2e^((-2t)/11) Apply variation of parameters to find a particular solution. yp = ?????

Consider the equation y'' + 4y = 0. a) Justify why the functions y1 = cos(4t)...

Consider the equation y'' + 4y = 0. a) Justify why the functions y1 = cos(4t) and y2 = sin(4t) do not constitute a fundamental set of solutions of the above equation. b) Find y1, y2 that constitute a fundamental set of solutions, justifying your answer.