Author Topic: Thanksgiving bonus 1  (Read 9261 times)

Victor Ivrii

  • Administrator
  • Elder Member
  • *****
  • Posts: 2607
  • Karma: 0
    • View Profile
    • Personal website of Victor Ivrii
Thanksgiving bonus 1
« on: October 05, 2018, 05:31:47 PM »
If we want to find a second order equations with the fundamental system of solutions $\{y_1(x),y_2(x)\}$ s.t. $W(y_1,y_2):=\left|\begin{matrix} y_1 & y_2\\ y_1' &y_2'\end{matrix}\right|\ne 0$, we write
$$
W(y,y_1,y_2):=\left|\begin{matrix}y & y_1 & y_2\\ y' &y_1' &y_2'\\ y'' &y_1''&y_2'' \end{matrix}\right|= 0.$$

Problem.
Find a second order equation with the fundamental system of solutions $\{y_1(x),y_2(x)\}=\displaystyle{\{\frac{1}{x+1},\frac{1}{x-1}\}}$.

The error corrected
« Last Edit: October 05, 2018, 10:03:50 PM by Victor Ivrii »

Pengyun Li

  • Full Member
  • ***
  • Posts: 20
  • Karma: 14
    • View Profile
Re: Thanksgiving bonus 1
« Reply #1 on: October 05, 2018, 08:52:24 PM »
We want to find a second order equation with the fundamental system of solutions $\{y_1(x),y_2(x)\} = \{\frac{1}{x+1}, \frac{1}{x-1}\}$.

Then $y_1=\frac{1}{x+1}, y_2=\frac{1}{x-1}$.

$\implies$ $W(y,y_1,y_2) = W(y, \frac{1}{x+1},\frac{1}{x-1})$ = $\left|\begin{matrix}y & \frac{1}{x+1} & \frac{1}{x-1}\\ y' &-\frac{1}{(x+1)^2} &-\frac{1}{(x-1)^2}\\ y'' &\frac{2x}{(x+1)^4}& \frac{2x}{(x-1)^4} \end{matrix}\right|= 0.$

$\implies$ Solve the determinant : $y\  \left|\begin{matrix} -\frac{1}{(x+1)^2} & -\frac{1}{(x-1)^2}\\ \frac{2x}{(x+1)^4} &\frac{2x}{(x-1)^4}\end{matrix}\right| - y^{'}\ \left|\begin{matrix} \frac{1}{x+1} & \frac{1}{x-1}\\ \frac{2x}{(x+1)^4} &\frac{2x}{(x-1)^4}\end{matrix}\right| + y^{''}\ \left|\begin{matrix} \frac{1}{x+1} & \frac{1}{x-1}\\ -\frac{1}{(x+1)^2} &-\frac{1}{(x-1)^2}\end{matrix}\right|$

                                         = $y\ (-\frac{8x^2}{(x+1)^4(x-1)^4}) - y^{'}\frac{12x^3+4x}{(x+1)^4(x-1)^4} + y^{''}\frac{-2}{(x+1)^2(x-1)^2} = 0$

Wrong second derivatives!

 Then we multiply both sides with $(x-1)^4(x+1)^4$ to get:


$y(-8x^2) - y^{'}(12x^3+4x) + y^{''}(-2x^4+4x^2-2) = 0$


our final equation is: $(-x^4+2x^2-1)y^{''}-(6x^3+2x)y^{'}+(-4x^2)y = 0$.
« Last Edit: October 05, 2018, 09:59:28 PM by Victor Ivrii »

Yiwei Han

  • Newbie
  • *
  • Posts: 3
  • Karma: 5
    • View Profile
Re: Thanksgiving bonus 1
« Reply #2 on: October 05, 2018, 09:12:44 PM »
but this question for w in the 2nd row is y2''...

Jiacheng Ge

  • Full Member
  • ***
  • Posts: 19
  • Karma: 8
    • View Profile
Re: Thanksgiving bonus 1
« Reply #3 on: October 05, 2018, 09:18:48 PM »
Happy Thanksgiving.

Jiacheng Ge

  • Full Member
  • ***
  • Posts: 19
  • Karma: 8
    • View Profile
Re: Thanksgiving bonus 1
« Reply #4 on: October 05, 2018, 10:17:40 PM »
new answer
« Last Edit: October 05, 2018, 10:31:27 PM by Jiacheng Ge »

Jiacheng Ge

  • Full Member
  • ***
  • Posts: 19
  • Karma: 8
    • View Profile
Re: Thanksgiving bonus 1
« Reply #5 on: October 05, 2018, 10:27:37 PM »
By the way, I think my answer to the original question is correct.
« Last Edit: October 05, 2018, 10:33:55 PM by Jiacheng Ge »

Pengyun Li

  • Full Member
  • ***
  • Posts: 20
  • Karma: 14
    • View Profile
Re: Thanksgiving bonus 1
« Reply #6 on: October 05, 2018, 10:37:55 PM »
Hi Sir, I figured out the problem and corrected the answer below! Thank you!
« Last Edit: October 05, 2018, 11:21:40 PM by Pengyun Li »

Monika Dydynski

  • Full Member
  • ***
  • Posts: 26
  • Karma: 30
    • View Profile
Re: Thanksgiving bonus 1
« Reply #7 on: October 05, 2018, 10:55:40 PM »
Pengyun,

$\left({1 \over {(x+1)}}\right)''=\left(-{1 \over {(x+1)^2}}\right)'\ne{2x\over(x+1)^4}$. Instead, $y_1''(x)={2\over(x+1)^3}$

Similarly,

$y_2''(x)={2\over(x-1)^3}$, not ${2x\over(x-1)^4}$

Pengyun Li

  • Full Member
  • ***
  • Posts: 20
  • Karma: 14
    • View Profile
Re: Thanksgiving bonus 1
« Reply #8 on: October 05, 2018, 11:15:44 PM »
Corrected: :)

We want to find a second order equation with the fundamental system of solutions $\{y_1(x),y_2(x)\} = \{\frac{1}{x+1}, \frac{1}{x-1}\}$.

Then $y_1=\frac{1}{x+1}, y_2=\frac{1}{x-1}$.

$\implies$ $W(y,y_1,y_2) = W(y, \frac{1}{x+1},\frac{1}{x-1})$ = $\left|\begin{matrix}y & \frac{1}{x+1} & \frac{1}{x-1}\\ y' &-\frac{1}{(x+1)^2} &-\frac{1}{(x-1)^2}\\ y'' &\frac{2}{(x+1)^3}& \frac{2}{(x-1)^3} \end{matrix}\right|= 0.$

$\implies$ Solve the determinant : $y\  \left|\begin{matrix} -\frac{1}{(x+1)^2} & -\frac{1}{(x-1)^2}\\ \frac{2}{(x+1)^3} &\frac{2}{(x-1)^3}\end{matrix}\right| - y^{'}\ \left|\begin{matrix} \frac{1}{x+1} & \frac{1}{x-1}\\ \frac{2}{(x+1)^3} &\frac{2}{(x-1)^3}\end{matrix}\right| + y^{''}\ \left|\begin{matrix} \frac{1}{x+1} & \frac{1}{x-1}\\ -\frac{1}{(x+1)^2} &-\frac{1}{(x-1)^2}\end{matrix}\right|$

                                         = $y\ (-\frac{4}{(x+1)^3(x-1)^3}) - y^{'}\frac{8x}{(x+1)^3(x-1)^3} + y^{''}\frac{-2}{(x+1)^2(x-1)^2} = 0$


 Then we multiply both sides with $(x-1)^3(x+1)^3$ to get:


$y(-4) - y^{'}(8x) + y^{''}(2-2x^2) = 0$


Our final equation is: $2y+4xy'+(x^2-1)y'' = 0$.