find solution to ivp xy' + 3y = x(sqrt(y)), y(1) = 0, bernoulli equation
Consider the solution to the IVP y' - xy = x; y(0) = 2 Find y' (0) Consider the solution to the IVP y' - xy = t; y(0) = 2 Find y" (0)
Find the solution of the following initial value problem using the method for a Bernoulli equation: xy' + 3y = xvy,y (1) = 0 (Bernoulli equation)
4.6 (20 pts) Solve the initial value problems for the Bernoulli equation. (a) xy+y=x*y; y(1) = 1/4; (b) xy + 3y = rºy?, y(1) = 1/2.
Find a solution of the IVP dy/dx=xy^3(1+x^2)^-1/2, y(0)=1, and give the interval where the solution is defined.
. Consider the IVP: y + 3y = e 3t, y(0) = 1, y(0) = 0 - Solve the IVP using the guess and test method. .Solve the IVP using the general formula for integrating factors. - Solve the IVP using Laplace Transforms. . Verify that your solution satisfies the differential equation (you should get the same solution using Il three methods, so you only need to test it once).
Solve the IVP (for the Bernoulli equation): dy/dx − (1/x)y = 1/y , y(1) = −3
Consider the IVP y'' + 3y' + 3y = (1 − u(t − 4)) with y'(0) = 0 and y(0) = 0. Solve the differential equation, and if possible, provide a graph
Consider differential equation (x - 1)y" – xy' + y = 0. a). Show that yi = el is a solution of this equation. Use the method of reduction of order to find second linearly independent solution y2 of this equation. (2P.) b). Find solution of the initial value problem (1P.) y(1) = 0, y'(1) = 1. c). Find solution of the initial value problem (1P.) y(1) = 0, y'(1) = 0. d). Does your answer in b) and c)...
Find the solution of the given IVP y" + 3y' + 2y = uz(t); y(0) = 0, y'(0) = 1 a. y = et-e-t + uz(t) [] + e-(6+2) +22(6+2) b. y = ef +e-t+uz(t)ſ - e-(6-2) + şe-26-2)] + uz(t) - e-(1-2) 3e=2(-2)] e + C. y = e-t-e-27 d. None of these
Use the method for solving Bernoulli equations to solve the following differential equation. dy dx +3y = e Xy - 8 Ignoring lost solutions, if any, the general solution is y=0 (Type an expression using x as the variable.)