(20 pts.) The Laguerre differential equation is ry" + (1 - )y' + Ay = 0....
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....
Do JUST # 2 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....
Question 2 In this question you need to construct a homogeneous linear second order differential equations satisfying particular things . The DE has a regular singular point at 1 and an irregular singular point at 3 X2 Is a solution The DE has a regular singular point at x 0 and y Question 3 Identify the regular singular points and compute their indicial roots of the following DEs Question 3 Find a series solution of ry" - (3x - 2)y...
solve 4 (4) Show that the given differential equation has a regular singular point at r = 0; determine the indicial equation, the recurrence relation, and the roots of the indicial equation; find the series solution (r > 0) corresponding to the larger root: (20 points) y = 0.
3. The second order variable coefficient differential equation Bxy" - ay = 0, (3) has a regular singular point at r = 0, where a > 0 and 8 >0 are given constants. Therefore, equation (3) has at least one solution of the form y(x) = ame" .m+r mao where r is chosen so that do 70. (a) Find the indicial equation and solve it for r. (b) For the larger value of r from part (a), find the corresponding...
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...
7. Consider the differential equation (a) Show that z 0 is a regular singular point of the above differential equation (b) Let y(x) be a solution of the differential equation, where r R and the series converges for any E (-8,s), s > 0 Substitute the series solution y in to the differential equation and simplify the terms to obtain an expression of the form 1-1 where f(r) is a polynomial of degree 2. (c) Determine the values of r....
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...
(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"...
Given that x =0 is a regular singular point of the given differential equation, show that the indicial roots of the singularity do not differ by an integer. Use the method of Frobenius to obtain two linearly independent series solutions about x = 0. Form the general solution on (0, ∞) 2xy''-y'+y=0