Consider the following differential equation Note: For each part below you must give your answers in terms of fractions...
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...
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 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...
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 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...
Consider the following differential equation, xy''-7y'+9xy=0 Solve two questions below. (d) You must now calculate the solution for the largest of the two indicial roots. First, enter the corresponding recurrence relation below, as an equation. Note 1: You must include an equals sign. Note 2: You must use the symbol m as your index. Note 3: am is entered as a(m), am+1 as a(m+1), etc. (e) Hence enter the first three non-zero terms of the solution corresponding to the largest...
(1 point) In this problem you will solve the differential equation or @() (1) Since P(a) 0 are not analytic at and 2() is a singular point of the differential equation. Using Frobenius' Theorem, we must check that are both analytic a # 0. Since #P 2 and #2e(z) are analytic a # 0-0 is a regular singular point for the differential equation 28x2y® + 22,23, + 4y 0 From the result ol Frobenius Theorem, we may assume that 2822y"...
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...
Do JUST # 3 Please In each of Problems 1 through 6: a. Show that the given differential equation has a regular singular point at x0. b. Determine the indicial equation, the recurrence relation, and the roots of the indicial equation. c. Find the series solution (x >0) corresponding to the larger root. d. If the roots are unequal and do not differ by an integer, find the series solution corresponding to the smaller root also. 2. xy" +xy+ 3....