By assuming that y has a power series expansion of the form $y(t ) = a_{0} +a_{1}t +a_{2}t^{2} +a_{3}t^{3}+· · ·$ , determine the solution to the initial-value problem

y′= y, y(0) = 1

Question

By assuming that y has a power series expansion of the form [latex]y(t ) = a_{0} +a_{1}t +a_{2}t^{2} +a_{3}t^{3}+· · ·[/latex] , determine the solution to the initial-value problem

y′= y, y(0) = 1

Accepted Answer

Writing [latex]y(t ) = a_{0} +a_{1}t +a_{2}t^{2} +a_{3}t^{3}+· · ·[/latex], we know

[latex]y^{\prime}(t ) = a_{1} +2a_{2}t +3a_{3}t^{ 2} +4a_{4}t^{3}+· · ·[/latex]

Equating y and y′, we observe that

[latex]a_{0} +a_{1}t +a_{2}t^{2} +a_{3}t^{3}+· · = a_{1} +2a_{2}t +3a_{3}t^{ 2} +4a_{4}t^{3}+· · ·[/latex] (8.3.1)

Because of the uniqueness of Taylor series expansions (theorem 8.2.2), we may equate like coefficients of powers of t in (8.3.1), from which we deduce that the following recurrence relation among the coefficients ai must hold:

[latex]a_{0} = a_{1}[/latex]
[latex]a_{1} = 2a_{2}[/latex]
[latex]a_{2} = 3a_{3}[/latex]

¦
[latex] a_{n} =(n+1)a_{n+1}[/latex]

Provided that we know [latex]a_{0}[/latex], we can find all of the remaining values of[latex]a_{i}[/latex] . Clearly,[latex]a_{0}[/latex]= y(0), so using the initial condition y(0) = 1,

[latex]a_{0} = 1, a_{1} = 1, a_{2} = \frac {1}{2}, a_{3} = \frac {1}{3}a_{2} = \frac {1}{3 · 2}, . . .[/latex]

From this sequence of coefficients and the general recurrence relation[latex] a_{n+1} =\frac {1}{n+1}a_{n}[/latex], we observe that [latex]a_{n} = \frac {1}{n!}[/latex] , and therefore

[latex]y(t ) = 1+t + \frac {1}{2!} t^{2} + \frac {1}{3!} t^{3}+· · ·+ \frac {1}{n!} t^{n} +· · ·[/latex]

which we recognize as the familiar power series expansion of [latex]y(t ) = e^{t}[/latex] , the solution to the IVP y′= y, y(0) = 1.

Question 8.3.1: By assuming that y has a power series expansion of the form ...

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