Consider the following Initial Value Problem (IVP) y' = 2xy, y(0) = 1. Does the IVP...

solve the following initial value problem x' = 2xy y' = y -2t +1 x(0) =...

solve the following initial value problem x' = 2xy y' = y -2t +1 x(0) = x0 y(0) = y0

consider ivp given by x^2y" + 2xy' - 6y = 0 w/ y(1) = 1, y'(1)...

consider ivp given by x^2y" + 2xy' - 6y = 0 w/ y(1) = 1, y'(1) = 2 verify y(x) = x^2 and y(x) = x^-3 are solutions use wronskian to show both y(x) above are linearly independent find unique solution to ivp

Consider the initial value problem y' + 5 4 y = 1 − t 5 ,    y(0)...

Consider the initial value problem y' + 5 4 y = 1 − t 5 ,    y(0) = y0. Find the value of y0 for which the solution touches, but does not cross, the t-axis. (A computer algebra system is recommended. Round your answer to three decimal places.) y0 =

1)Consider the following initial-value problem. (x + y)2 dx + (2xy + x2 − 2) dy...

1)Consider the following initial-value problem. (x + y)2 dx + (2xy + x2 − 2) dy = 0,   y(1) = 1. Let af/ax = (x + y)2 = x2 + 2xy + y2. Integrate each term of this partial derivative with respect to x, letting h(y) be an unknown function in y. f(x, y) =   + h(y) Solve the given initial-value problem. 2) Solve the given initial-value problem. (6y + 2t − 3) dt + (8y + 6t − 1) dy...

1)  Consider the following initial-value problem. (x + y)2 dx + (2xy + x2 − 2) dy...

1)  Consider the following initial-value problem. (x + y)2 dx + (2xy + x2 − 2) dy = 0,   y(1) = 1 Let af/ax = (x + y)2 = x2 + 2xy + y2. Integrate each term of this partial derivative with respect to x, letting h(y) be an unknown function in y. f(x, y) =    + h(y) Find the derivative of h(y). h′(y) = Solve the given initial-value problem. 2) Solve the given initial-value problem. (6y + 2t − 3) dt...

Does the initial value problem y' = ( ((cos 4x) / (1 + 2 log x)1/2)...

Does the initial value problem y' = ( ((cos 4x) / (1 + 2 log x)1/2) + esin2x ), y(0) = 1.7 have a solution in an open interval? Specify the interval if it exists. If the solution exists, is the solution unique?

Let be the problem with initial value f(t,y) = yt3   , y(0)=1 Write the general formula...

Let be the problem with initial value f(t,y) = yt3   , y(0)=1 Write the general formula for Picard iterations. Then start with the function y0 (t) = y (0) = 1 and calculate the iterations y1 (t) and y2 (t).

Consider the initial value problem: y' - (7/2)y = 7t + 2e^t Initial condition: y(0) =...

Consider the initial value problem: y' - (7/2)y = 7t + 2e^t Initial condition: y(0) = y0 a) Find the value of y0 that separates solutions that grow positively as t → ∞ from those that grow negatively. (A computer algebra system is recommended. Round your answer to three decimal places.) b) How does the solution that corresponds to this critical value of y0 behave as t → ∞? Will the corresponding solution increase without bound, decrease without bound, converge...

determine if the given initial value problem has a unique solution or not. why? y' =...

determine if the given initial value problem has a unique solution or not. why? y' = 2xy^(3/4) , y(1) = 0

y^4 - y = 0 IVP (Initial Value Problem) y(0) = 0 y'(0) = 1 y''(0)...

y^4 - y = 0 IVP (Initial Value Problem) y(0) = 0 y'(0) = 1 y''(0) = 0 y'''(0) = 0 The answer is y(t) = [sinh(t) + sin(t)] / 2 but I cannot figure out how to reach this.