Question 8 (10 marks) Solve the following initial value problem by means of a power series...
In this exercise we consider finding the first five coefficients in the series solution of the first order linear initial value problem (+3)y' 2y 0 subject to the initial condition y(0) 1. Since the equation has an ordinary point at z 0 it has a power series solution in the form We learned how to easily solve problems like this separation of variables but here we want to consider the power series method (1) Insert the formal power series into...
Question 3:(7 points) Consider the following initial value problem, Note: For each part below you must give your answers in terms of fractions (as appropriate), not decimals (a) This differential equation has singular points at Note: You must use a semicolon here to separate your answers. (b) Since there is no singular point at z 0 you can find a normal power series solution for y(a) about z 0 ie TTt s part of the solution process you must determine...
Consider the following initial value problem, (1 - z2)y"+zy' - 12y-0, (0)3, y' (0)-0. Note: For each part below you must give your answers in terms of fractions (as appropriate), not decimals (a) This differential equation has singular points at Note: You must use a semicolon here to separate your answers. (b) Since there is no singular point at z 0, you can find a normal power series solution for y(x about z0,i.e. m-0 As part of the solution process...
Consider the following initial value problem, (1 - 2)" + 3xy' - 8y = 0, 3(0) = 3, 7(0) = 0. Note: For each part below you must give your answers in terms of fractions (as appropriate), not decimals. (a) This differential equation has singular points at Note: You must use a semicolon here to separate your answers (b) Since there is no singular point at x = 0, you can find a normal power series solution for y() about...
Consider the tollowing initial value problem, Note: For each part below you must give your answers in terms of fractions (as appropriate), not decimals (a) This diferential equation has singular points at Note: You must use a semicolon here to separate your answers (b) Since there is no singular point at -0, you can find a normal power series solution for y() about -0,ie y(z) = Σ amzm n-0 As part of the solution process you must determine the recurrence...
(10) Find the first six non-zero terms of the power series solution of the following problem about the ordinary point zo = 0 (That is, find the first three non-zero terms for yı and find the first three non-zero terms for y2, where the general solution is y = Ciyi + c2y2): + 20 + 2y = 0
Given the DE: y"-(x+1)y'-y=0 use it to answer the following: a) Find the singular point(s), if any, and if lower bound for the radius of convergence for a power series solution about the ordinary points x=0 b)The recurrence relation Hint: It will be a 3-term recurrence relation c)Give the first four non-zero terms of each of the two linearly independent power series solutions near the ordinary point x=0
2. Solve each of these ODEs using power series method expanded around Xo = 0. Find the recurrence relation and use it to find the first FOUR terms in each of the two linearly independent solution. Express your answer in general form where possible (well, it is not always possible). (a) (25 marks) (x2 + 2)y” - xy + 4y = 2x - 1-47 Note: expressa in terms of power series. (b) 2x2y" + 3xy' + (2x - 1) =...
Consider the ODE:3xy"+y' - 2xy = 0. Find the general solution in power series form about the regular singular point x = 0, following parts (a) – (c), below. (a) Obtain the recurrence relation. (b) Find the exponents of the singularity. (e) Obtain only one of the two linearly independent solutions, call it y(x), that corresponds to the smaller exponent of the singularity; but, only explicitly include the first four non-zero terms of the power series solution. Write down the...
Chapter 5, Section 5.2, Question 2 In the Problem: • a. Seek power series solutions of the given differential equation about the given point xo; find the recurrence relation that the coefficients must satisfy. . b. Find the first four nonzero terms in each of two solutions yn and y2 (unless the series terminates sooner). • c. By evaluating the Wronskian W[y1, y2](xo), show that y, and y2 form a fundamental set of solutions. • d. If possible, find the...