Proceed as in Example 3 of Section 4.8 to find a solution of the given initial-value...

Find the Laplace transform Y(s)=L{y} of the solution of the given initial value problem. A. y′′+16y...

Find the Laplace transform Y(s)=L{y} of the solution of the given initial value problem. A. y′′+16y = {1, 0 ≤ t < π = {0, π ≤ t < ∞, y(0)=3, y′(0)=5 B. y′′ + 4y = { t, 0 ≤ t < 1 = {1, 1 ≤ t < ∞, y(0)=3, y′(0)=3

Find the solution of the initial value problem 16y′′−y=0, y(−4)=1 and y′(−4)=−1

Find the solution of the initial value problem 16y′′−y=0, y(−4)=1 and y′(−4)=−1

Solve the given initial-value problem by finding, as in Example 4 of Section 2.4, an appropriate...

Solve the given initial-value problem by finding, as in Example 4 of Section 2.4, an appropriate integrating factor. (x2 + y2 − 7) dx = (y + xy) dy, y(0) = 1

Find the solution of the initial value problem y′′+16y′+63y=0, y(0)=7 and y′(0)=−59. y(t)=

Find the solution of the initial value problem y′′+16y′+63y=0, y(0)=7 and y′(0)=−59. y(t)=

Proceed as in Example 4 in Section 11.3 to find a particular solution xp(t) of equation...

Proceed as in Example 4 in Section 11.3 to find a particular solution xp(t) of equation (11) in Section 11.3 m d2x dt2 + kx = f(t)    (11) when m = 1 2 , k = 16, and the driving force f(t) is as given. Assume that when f(t) is extended to the negative t-axis in a periodic manner, the resulting function is even. f(t) = 2πt − t2, 0 < t < 2π;

9.       Determine the solution to the initial value problem using the Laplace transform and the convolution integral....

9.       Determine the solution to the initial value problem using the Laplace transform and the convolution integral.                                                  y'’ + y = cos(2t);          y(0) = 1, y’(0) = 0. Evaluate the convolution integral and simplify your solution

Find the solution of the initial-value problem. y'' + y = 4 + 3 sin(x), y(0)...

Find the solution of the initial-value problem. y'' + y = 4 + 3 sin(x), y(0) = 7, y'(0) = 1

B. a non-homogeneous differential equation, a complementary solution, and a particular solution are given. Find a...

B. a non-homogeneous differential equation, a complementary solution, and a particular solution are given. Find a solution satisfying the given initial conditions. y''-2y'-3y=6 y(0)=3 y'(0) = 11 yc= C1e-x+C2e3x yp = -2 C. a third-order homogeneous linear equation and three linearly independent solutions are given. Find a particular solution satisfying the given initial conditions y'''+2y''-y'-2y=0, y(0) =1, y'(0) = 2, y''(0) = 0 y1=ex, y2=e-x,, y3= e-2x

Find the solution of the given initial value problem: y " + y = f(t); y(0)...

Find the solution of the given initial value problem: y " + y = f(t); y(0) = 6, y' (0) = 3 where f(t) = 1, 0 ≤ t < π 2 0, π 2 ≤ t < ∞

Find the Laplace transform Y(s)=L{y} of the solution of the given initial value problem. y′′+9y={t, 0≤t<1...

Find the Laplace transform Y(s)=L{y} of the solution of the given initial value problem. y′′+9y={t, 0≤t<1 1, 1≤t<∞, y(0)=3, y′(0)=4 Enclose numerators and denominators in parentheses. For example, (a−b)/(1+n). Y(s)=