Problem 563

Substituting the values of

A, B, C

from (3) in the above and simplifying gives

Equation (7) is now solved. After ﬁnding

z (x)

then

y

is found using the inverse transformation

The ﬁrst step is to determine the case of Kovacic algorithm this ode belongs to. There are 3 cases depending on the order of poles of

r

and the order of

r

\infty

. The following table summarizes these cases.


Case	Allowed pole order for $r$	Allowed value for $O (\infty)$

1	${0, 1, 2, 4, 6, 8, \dots}$	${\dots, - 6, - 4, - 2, 0, 2, 3, 4, 5, 6, \dots}$

2	Need to have at least one pole that is either order $2$ or odd order greater than $2$ . Any other pole order is allowed as long as the above condition is satisﬁed. Hence the following set of pole orders are all allowed. ${1, 2}$ , ${1, 3}$ , ${2}$ , ${3}$ , ${3, 4}$ , ${1, 2, 5}$ .	no condition

3	${1, 2}$	${2, 3, 4, 5, 6, 7, \dots}$

Table 2.547: Necessary conditions for each Kovacic case

The order of

r

\infty

is the degree of

t

minus the degree of

s

. Therefore

The poles of

r

in eq. (7) and the order of each pole are determined by solving for the roots of

t = 36 x^{2}

. There is a pole at

x = 0

of order

2

. Since there is no odd order pole larger than

2

and the order at

\infty

- 2

then the necessary conditions for case one are met. Since there is a pole of order

2

then necessary conditions for case two are met. Therefore

For the pole at

x = 0

let

b

be the coeﬃcient of

\frac{1}{x^{2}}

in the partial fractions decomposition of

r

given above. Therefore

b = - \frac{1}{4}

. Hence

[\sqrt{r}]_{\infty}

is the sum of terms involving

x^{i}

for

0 \leq i \leq v

in the Laurent series for

\sqrt{r}

\infty

. Therefore

Let

a

be the coeﬃcient of

x^{v} = x^{1}

in the above sum. The Laurent series of

\sqrt{r}

\infty

\begin{matrix} (9) & \sqrt{r} \approx \frac{x}{3} - \frac{1}{2} + \frac{1}{x} + \frac{3}{4 x^{2}} - \frac{3}{4 x^{3}} - \frac{27}{8 x^{4}} - \frac{117}{32 x^{5}} + \frac{405}{64 x^{6}} + \dots \end{matrix}

Now we need to ﬁnd

b

, where

b

be the coeﬃcient of

x^{v - 1} = x^{0} = 1

r

minus the coeﬃcient of same term but in

{([\sqrt{r}]_{\infty})}^{2}

where

[\sqrt{r}]_{\infty}

was found above in Eq (10). Hence

{([\sqrt{r}]_{\infty})}^{2} = \frac{1}{9} x^{2} - \frac{1}{3} x + \frac{1}{4}

This shows that the coeﬃcient of

1

in the above is

\frac{1}{4}

. Now we need to ﬁnd the coeﬃcient of

1

r

. How this is done depends on if

v = 0

or not. Since

v = 1

which is not zero, then starting

r = \frac{s}{t}

, we do long division and write this in the form

r = Q + \frac{R}{t}

Where

Q

is the quotient and

R

is the remainder. Then the coeﬃcient of

1

r

will be the coeﬃcient this term in the quotient. Doing long division gives

We see that the coeﬃcient of the term

x

in the quotient is

\frac{11}{12}

. Now

b

can be found.

The following table summarizes the ﬁndings so far for poles and for the order of

r

\infty

where

r

r = \frac{4 x^{4} - 12 x^{3} + 33 x^{2} - 18 x - 9}{36 x^{2}}

Now that the all

[\sqrt{r}]_{c}

and its associated

α_{c}^{\pm}

have been determined for all the poles in the set

Γ

and

[\sqrt{r}]_{\infty}

and its associated

α_{\infty}^{\pm}

have also been found, the next step is to determine possible non negative integer

d

from these using

Where

s (c)

is either

+

-

and

s (\infty)

is the sign of

α_{\infty}^{\pm}

. This is done by trial over all set of families

s = (s (c))_{c \in Γ \cup \infty}

until such

d

is found to work in ﬁnding candidate

ω

. Trying

α_{\infty}^{+} = \frac{1}{2}

then

Now that

ω

is determined, the next step is ﬁnd a corresponding minimal polynomial

p (x)

of degree

d = 0

to solve the ode. The polynomial

p (x)

needs to satisfy the equation

The equation is satisﬁed since both sides are zero. Therefore the ﬁrst solution to the ode

z^{″} = r z

The second solution

y_{2}

to the original ode is found using reduction of order

y_{2} = y_{1} \int \frac{e^{\int - \frac{B}{A} d x}}{y_{1}^{2}} d x

✓ Maple. Time used: 0.093 (sec). Leaf size: 32

\begin{array}{lll} Let’s solve \\ 9 x^{2} (\frac{d}{d x} \frac{d}{d x} y (x)) + 3 x (- 2 x^{2} + 3 x + 5) (\frac{d}{d x} y (x)) + (- 14 x^{2} + 12 x + 1) y (x) = 0 \\ ∙ & Highest derivative means the order of the ODE is 2 \\ \frac{d}{d x} \frac{d}{d x} y (x) \\ ∙ & Isolate 2nd derivative \\ \frac{d}{d x} \frac{d}{d x} y (x) = \frac{(14 x^{2} - 12 x - 1) y (x)}{9 x^{2}} + \frac{(2 x^{2} - 3 x - 5) (\frac{d}{d x} y (x))}{3 x} \\ ∙ & Group terms with y (x) on the lhs of the ODE and the rest on the rhs of the ODE; ODE is linear \\ \frac{d}{d x} \frac{d}{d x} y (x) - \frac{(2 x^{2} - 3 x - 5) (\frac{d}{d x} y (x))}{3 x} - \frac{(14 x^{2} - 12 x - 1) y (x)}{9 x^{2}} = 0 \\ ◻ & Check to see if x_{0} = 0 is a regular singular point \\ \circ & Define functions \\ [P_{2} (x) = - \frac{2 x^{2} - 3 x - 5}{3 x}, P_{3} (x) = - \frac{14 x^{2} - 12 x - 1}{9 x^{2}}] \\ \circ & x \cdot P_{2} (x) is analytic at x = 0 \\ (x \cdot P_{2} (x)) |_{x = 0} = \frac{5}{3} \\ \circ & x^{2} \cdot P_{3} (x) is analytic at x = 0 \\ (x^{2} \cdot P_{3} (x)) |_{x = 0} = \frac{1}{9} \\ \circ & x = 0 is a regular singular point \\ Check to see if x_{0} = 0 is a regular singular point \\ x_{0} = 0 \\ ∙ & Multiply by denominators \\ 9 x^{2} (\frac{d}{d x} \frac{d}{d x} y (x)) - 3 x (2 x^{2} - 3 x - 5) (\frac{d}{d x} y (x)) + (- 14 x^{2} + 12 x + 1) y (x) = 0 \\ ∙ & Assume series solution for y (x) \\ y (x) = \overset{\infty}{\sum_{k = 0}} a_{k} x^{k + r} \\ ◻ & Rewrite ODE with series expansions \\ \circ & Convert x^{m} \cdot y (x) to series expansion for m = 0. .2 \\ x^{m} \cdot y (x) = \overset{\infty}{\sum_{k = 0}} a_{k} x^{k + r + m} \\ \circ & Shift index using k - > k - m \\ x^{m} \cdot y (x) = \overset{\infty}{\sum_{k = m}} a_{k - m} x^{k + r} \\ \circ & Convert x^{m} \cdot (\frac{d}{d x} y (x)) to series expansion for m = 1. .3 \\ x^{m} \cdot (\frac{d}{d x} y (x)) = \overset{\infty}{\sum_{k = 0}} a_{k} (k + r) x^{k + r - 1 + m} \\ \circ & Shift index using k - > k + 1 - m \\ x^{m} \cdot (\frac{d}{d x} y (x)) = \overset{\infty}{\sum_{k = - 1 + m}} a_{k + 1 - m} (k + 1 - m + r) x^{k + r} \\ \circ & Convert x^{2} \cdot (\frac{d}{d x} \frac{d}{d x} y (x)) to series expansion \\ x^{2} \cdot (\frac{d}{d x} \frac{d}{d x} y (x)) = \overset{\infty}{\sum_{k = 0}} a_{k} (k + r) (k + r - 1) x^{k + r} \\ Rewrite ODE with series expansions \\ a_{0} {(1 + 3 r)}^{2} x^{r} + (a_{1} {(4 + 3 r)}^{2} + 3 a_{0} (4 + 3 r)) x^{1 + r} + (\overset{\infty}{\sum_{k = 2}} (a_{k} {(3 k + 3 r + 1)}^{2} + 3 a_{k - 1} (3 k + 3 r + 1) - 2 a_{k - 2} (3 k + 3 r + 1)) x^{k + r}) = 0 \\ ∙ & a_{0} cannot be 0 by assumption, giving the indicial equation \\ {(1 + 3 r)}^{2} = 0 \\ ∙ & Values of r that satisfy the indicial equation \\ r = - \frac{1}{3} \\ ∙ & Each term must be 0 \\ a_{1} {(4 + 3 r)}^{2} + 3 a_{0} (4 + 3 r) = 0 \\ ∙ & Solve for the dependent coefficient(s) \\ a_{1} = - \frac{3 a_{0}}{4 + 3 r} \\ ∙ & Each term in the series must be 0, giving the recursion relation \\ a_{k} {(3 k + 3 r + 1)}^{2} + (3 k + 3 r + 1) (- 2 a_{k - 2} + 3 a_{k - 1}) = 0 \\ ∙ & Shift index using k - > k + 2 \\ a_{k + 2} {(3 k + 3 r + 7)}^{2} + (3 k + 3 r + 7) (- 2 a_{k} + 3 a_{k + 1}) = 0 \\ ∙ & Recursion relation that defines series solution to ODE \\ a_{k + 2} = \frac{2 a_{k} - 3 a_{k + 1}}{3 k + 3 r + 7} \\ ∙ & Recursion relation for r = - \frac{1}{3} \\ a_{k + 2} = \frac{2 a_{k} - 3 a_{k + 1}}{3 k + 6} \\ ∙ & Solution for r = - \frac{1}{3} \\ [y (x) = \overset{\infty}{\sum_{k = 0}} a_{k} x^{k - \frac{1}{3}}, a_{k + 2} = \frac{2 a_{k} - 3 a_{k + 1}}{3 k + 6}, a_{1} = - a_{0}] \end{array}


pole $c$ location	pole order	$[\sqrt{r}]_{c}$	$α_{c}^{+}$	$α_{c}^{-}$

$0$	$2$	$0$	$\frac{1}{2}$	$\frac{1}{2}$


Order of $r$ at $\infty$	$[\sqrt{r}]_{\infty}$	$α_{\infty}^{+}$	$α_{\infty}^{-}$

$- 2$	$\frac{x}{3} - \frac{1}{2}$	$\frac{1}{2}$	$- \frac{3}{2}$

2.1.547 Problem 563

Solved as second order ode using Kovacic algorithm

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