Consider the differential equation xex (1 + e*)y' = y - y e* + 1 +...
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)...
(1 point) Consider the first order differential equation x' + = 25% = For each of the initial conditions below, determine the largest interval on which the existence and uniqueness theorem for first order linear differential equations guarantees the existence of a unique solution. (Write the interval in the form a < t < b) a. y(-7) = -0.5. help inequalities) b. (-1.5) = -5.5. help (inequalities) C. y(0) = 0. help inequalities) d. y(7.5) = 2.6. help inequalities) e....
e-2 is a 0. Given the fact that y= e' 1. Consider the differential equation y" + 4/" +14y' +20y solution of this differential equation, answer the questions below. [5 ptsl(a) Find a basis for the solution space of this differential equation.
Consider the differential equation 4x2y′′ − 8x2y′ + (4x2 + 1)y = 0 (a) Verify that x0 = 0 is a regular singular point of the differential equation and then find one solution as a Frobenius series centered at x0 = 0. The indicial equation has a single root with multiplicity two. Therefore the differential equation has only one Frobenius series solution. Write your solution in terms of familiar elementary functions. (b) Use Reduction of Order to find a second...
Problem 3 Solve the following differential equation : y = ex-xex) = dy + 2(1-x) x Initial condition is y col=0 ex (1 x) x2 Y (
3. Consider the differential equation ty" - (t+1)y + y = t?e?', t>0. (a) Find a value ofr for which y = et is a solution to the corresponding homogeneous differential equation. (b) Use Reduction of Order to find a second, linearly independent, solution to the correspond- ing homogeneous differential equation. (c) Use Variation of Parameters to find a particular solution to the nonhomogeneous differ- ential equation and then give the general solution to the differential equation.
(Q3) Consider the equation: y′ = y1/3, y(0) = 0 . (a)Does the above IVP have any solution? (b)Is the solution unique? (c)Interpret your results in light of the theorem of existence and uniqueness. (Q3) Consider the equation: y' = y1/3, y(0) = 0 . (a)Does the above IVP have any solution? (b) Is the solution unique? (c)Interpret your results in light of the theorem of existence and uniqueness. (Q4) Solve the following IVP and find the interval of validity:...
4. Consider the differential equation with initial condition r(0) = 0 (a) What does the existence and uniqueness theorem tell you about the solution to this IVP? (10 points) (b) Use separation of variables to find the solution for the IVP r(to) = Io for to +0. (5 points) (c) Are the solutions to b) unique? (5 points) (d) Sketch solutions for Xo = --1,0,1 and to = 1 and show that for all to and to the solution goes...
1. Consider the differential equation y' = y-t. (a) Construct a slope field for this equation. (b) Find the general solution to this differential equation. (c) There is exactly one solution that is given by a straight line. Write the equation for this line and draw it on the slope field.
Consider the differential equation xy" + y + y = 0. Find a series solution for the differential equation about the regular, singular point xo = 0.