2. Find power series solutions y z" Σ anr" of the following equation centered at 0...
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...
15. Consider the instancc of thc Chcbyshev cquation (a) Find two solutions of the equation as power serics about z 0. (b) Determine the interval of convergence for cach solution. 16. The Bossel equation of order zero is (a) Show that 0 is a regular singular point. (b) Show that the indicial equation has repcated roots. (c) Show that onc solution (for z > 0) is given by the Bessel function of order 0 n-1 (d) Find the interval of...
Need some help with SERIES SOLUTION - 2nd ORDER EQUATION For the differential equation, (1) a. Calculate the indicial equation for the power series solution (Answer in a quadratic polynomial in terms of c.) b. Calculate the solutions of the indicial equation found above. c. Calculate the point from the above equation (1) as i. ORDINARY POINT ii. REGULAR SINGULAR POINT iii. IRREGULAR SINGULAR POINT We were unable to transcribe this imagey-Σ@m(z _ 4)nte We were unable to transcribe this...
4. (a) Solve the differential equation (1-12)y"-2cy' + λ(A + 1)y 0 using power series centered at 0 , in which λ is a constant. Write your solution as a linear combination of two independent solutions whose coefficients are expressed in terms of λ . Compute the coefficients of each solution up to and including the 5 term. Without computing them, what is the smallest possible value of the radius of convergence of each solution and why? (b) When λ...
3) Pol the diferential equation: (a) The point o -1 is an ordinary point. Compute the recursion formula for the coefficients of the power series solution centered at zo- -1 and use it to compute the first three nonzero terms of the power series when (-1)--s and y(-1)-0. (25 points) (b) The point 0 is a regular singular point Compute the associated Buler equation and compute the recursion formula for the coefficients of the series solution centered at o 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) =...
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.
4. (a) Solve the differential equation (1 − x 2 )y ′′ − 2xy′ + λ(λ + 1)y = 0 using power series centered at 0 , in which λ is a constant. Write your solution as a linear combination of two independent solutions whose coefficients are expressed in terms of λ . Compute the coefficients of each solution up to and including the x 5 term. Without computing them, what is the smallest possible value of the radius of...
4. (a) Solve the differential equation (1 − x 2 )y ′′ − 2xy′ + λ(λ + 1)y = 0 using power series centered at 0 , in which λ is a constant. Write your solution as a linear combination of two independent solutions whose coefficients are expressed in terms of λ . Compute the coefficients of each solution up to and including the x 5 term. Without computing them, what is the smallest possible value of the radius of...