Find the solution for the initial value problem. (sint)y′ +(cost)y=t, y(π/2)=2

Solve the initial value problem: y′′ − y = t + sint , y(0) = 2...

Solve the initial value problem: y′′ − y = t + sint , y(0) = 2 , y′(0) = 3.

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 < ∞

Let y = y ( t ) be the solution to the initial value problem   ...

Let y = y ( t ) be the solution to the initial value problem    t d y d t + 2 y = sin ⁡ t , y ( π ) = 0 Find the value of

find the value of d2y/dx2 at t =π/4 if x=sint, y=tant

find the value of d2y/dx2 at t =π/4 if x=sint, y=tant

Solve the initial value problem 2(sin(t)dydt+cos(t)y)=cos(t)sin^3(t) for 0<t<π0<t<π and y(π/2)=13.y(π/2)=13. Put the problem in standard form....

Solve the initial value problem 2(sin(t)dydt+cos(t)y)=cos(t)sin^3(t) for 0<t<π0<t<π and y(π/2)=13.y(π/2)=13. Put the problem in standard form. Then find the integrating factor, ρ(t)= and finally find y(t)=

Consider the boundary value problem y''(t) + y(t) = f(t) , y(0) = 0 and  y(π/2) =...

Consider the boundary value problem y''(t) + y(t) = f(t) , y(0) = 0 and  y(π/2) = 0. Find the solution to the boundary value problem

Find the equation of the tangent line to x = sint, y = cost when t...

Find the equation of the tangent line to x = sint, y = cost when t = π/4

find y(t) solution of the initial value problem y'=(2y^2 +bt^2)/(ty), y(1)=1 t>o

find y(t) solution of the initial value problem y'=(2y^2 +bt^2)/(ty), y(1)=1 t>o

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

For 2y' = -tan(t)(y^2-1) find general solution (solve for y(t)) and solve initial value problem y(0)...

For 2y' = -tan(t)(y^2-1) find general solution (solve for y(t)) and solve initial value problem y(0) = -1/3