Consider the following initial value problem, (1 - z2)y"+zy' - 12y-0, (0)3, y' (0)-0. Note: For each part b...
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...
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 - 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 following differential equation Note: For each part below you must give your answers in terms of fractions (as appropriate), not decimals (a) The above difterential equation has a singular point at-0. If the singular point at -0 is a regular singular point, then a power series for the solution y) can be found using the Frobenius method. Show that z-0 is a regular singular point by caliculating p/a)- 2(2) Since both of these functions are analytic at -0...
Consider the following difterential equation Note: For each part below you must give your answers in terms of fractions (as appropriate), not decimals (a) The above differential equation has a singular point at z-0.I the singular point at z-0 is a regular singular point, then a power series for the solution y)can be found using the Frobenius method. Show that z-0is a regular singular point by calculating: zr(z) = 2g() Since both of these functions are analytic at z-0 the...
Consider the following differential equation Note: For each part below you must give your answers in terms of fractions (as appropriate), not decimas. (a) The above differential equation has a singular point at z-0.I the singular point at z -0 is a regular singular point, then a power series for the solution ()can be found using the Frobenius method. Show that z-O is a regular singular point by calculating plz)-3 Since both of these functions are analytic at r -0...
Conslder the following differentlal equatlon, Note: For each part below you must give your answers in terms ot fractions (as appropriate), not decimals. (a) The above ditferential equation has a singular point at0. If the singular point at-0 is a regular singular point, then a power series for the solution y) can be found using the Frobenius method. Show that -0 is a regular singular point by calculating pa)2 Since both of these functlons are analytlic at regular the singular...
Consider the following differential equation Note: For each part below you must give your answers in terms of fractions (as appropriate), not decimals (a) The above differential equation has a snaar point at x 0 . It the singular point at x-0 is a regular singular point, then a power series for the solution y(x) can be lound using the Frobenius method. Show that x = 0 is a regular sigar point by calculating: xp(x) = y(x) = Since both...
cnrn Consider the following differential equation. (1 + 3x?) y" – 2xy' – 12y = 0 (a) If you were to look for a power series solution about xo = 0, i.e., of the form Σ n=0 00 then the recurrence formula for the coefficients would be given by Ck+2 g(k) Ck, k > 2. Enter the function g(k) into the answer box below. (b) Find the solution to the above differential equation with initial conditions y(0) = 0 and...
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...