Exercise: second-order linear differential equation












0












$begingroup$


I have the system



$$begin{cases} y'_{1} = dfrac{1}{2};y_{1} - dfrac{3}{2};y_{2} \ y'_{2} = - dfrac{3}{2};y_{1} + dfrac{1}{2};y_{2}end{cases}$$



Retrieving $y_{2}$ from the first one



$$y_{2} = - dfrac{2}{3};y'_{1} + dfrac{1}{3};y_{1}$$



Now, the result I should get by replacing $y_{2}$ in the second one is



$$y''_{1} - y'_{1} + 2y_{1} = 0$$



Yes I know how to resolv a second-order differential equation. What I would like to know, is how to get this equation by replacing in the second one



Thank you in advances










share|cite|improve this question











$endgroup$












  • $begingroup$
    Make the ansatz $$y_1=e^{lambda t}$$
    $endgroup$
    – Dr. Sonnhard Graubner
    Jan 22 at 14:58










  • $begingroup$
    Yes I know how to resolv a second-order differential equation. What I would like to know, is how to get this equation
    $endgroup$
    – user3204810
    Jan 22 at 15:03






  • 1




    $begingroup$
    Just plug it in?
    $endgroup$
    – Klaus
    Jan 22 at 15:06






  • 1




    $begingroup$
    Take the derivative of your expression for $y_2$ and plug it in the second equation.
    $endgroup$
    – WarreG
    Jan 22 at 15:24










  • $begingroup$
    @WarreG this is the solution! Thanks!
    $endgroup$
    – user3204810
    Jan 22 at 15:39
















0












$begingroup$


I have the system



$$begin{cases} y'_{1} = dfrac{1}{2};y_{1} - dfrac{3}{2};y_{2} \ y'_{2} = - dfrac{3}{2};y_{1} + dfrac{1}{2};y_{2}end{cases}$$



Retrieving $y_{2}$ from the first one



$$y_{2} = - dfrac{2}{3};y'_{1} + dfrac{1}{3};y_{1}$$



Now, the result I should get by replacing $y_{2}$ in the second one is



$$y''_{1} - y'_{1} + 2y_{1} = 0$$



Yes I know how to resolv a second-order differential equation. What I would like to know, is how to get this equation by replacing in the second one



Thank you in advances










share|cite|improve this question











$endgroup$












  • $begingroup$
    Make the ansatz $$y_1=e^{lambda t}$$
    $endgroup$
    – Dr. Sonnhard Graubner
    Jan 22 at 14:58










  • $begingroup$
    Yes I know how to resolv a second-order differential equation. What I would like to know, is how to get this equation
    $endgroup$
    – user3204810
    Jan 22 at 15:03






  • 1




    $begingroup$
    Just plug it in?
    $endgroup$
    – Klaus
    Jan 22 at 15:06






  • 1




    $begingroup$
    Take the derivative of your expression for $y_2$ and plug it in the second equation.
    $endgroup$
    – WarreG
    Jan 22 at 15:24










  • $begingroup$
    @WarreG this is the solution! Thanks!
    $endgroup$
    – user3204810
    Jan 22 at 15:39














0












0








0





$begingroup$


I have the system



$$begin{cases} y'_{1} = dfrac{1}{2};y_{1} - dfrac{3}{2};y_{2} \ y'_{2} = - dfrac{3}{2};y_{1} + dfrac{1}{2};y_{2}end{cases}$$



Retrieving $y_{2}$ from the first one



$$y_{2} = - dfrac{2}{3};y'_{1} + dfrac{1}{3};y_{1}$$



Now, the result I should get by replacing $y_{2}$ in the second one is



$$y''_{1} - y'_{1} + 2y_{1} = 0$$



Yes I know how to resolv a second-order differential equation. What I would like to know, is how to get this equation by replacing in the second one



Thank you in advances










share|cite|improve this question











$endgroup$




I have the system



$$begin{cases} y'_{1} = dfrac{1}{2};y_{1} - dfrac{3}{2};y_{2} \ y'_{2} = - dfrac{3}{2};y_{1} + dfrac{1}{2};y_{2}end{cases}$$



Retrieving $y_{2}$ from the first one



$$y_{2} = - dfrac{2}{3};y'_{1} + dfrac{1}{3};y_{1}$$



Now, the result I should get by replacing $y_{2}$ in the second one is



$$y''_{1} - y'_{1} + 2y_{1} = 0$$



Yes I know how to resolv a second-order differential equation. What I would like to know, is how to get this equation by replacing in the second one



Thank you in advances







ordinary-differential-equations






share|cite|improve this question















share|cite|improve this question













share|cite|improve this question




share|cite|improve this question








edited Jan 22 at 15:22







user3204810

















asked Jan 22 at 14:56









user3204810user3204810

1947




1947












  • $begingroup$
    Make the ansatz $$y_1=e^{lambda t}$$
    $endgroup$
    – Dr. Sonnhard Graubner
    Jan 22 at 14:58










  • $begingroup$
    Yes I know how to resolv a second-order differential equation. What I would like to know, is how to get this equation
    $endgroup$
    – user3204810
    Jan 22 at 15:03






  • 1




    $begingroup$
    Just plug it in?
    $endgroup$
    – Klaus
    Jan 22 at 15:06






  • 1




    $begingroup$
    Take the derivative of your expression for $y_2$ and plug it in the second equation.
    $endgroup$
    – WarreG
    Jan 22 at 15:24










  • $begingroup$
    @WarreG this is the solution! Thanks!
    $endgroup$
    – user3204810
    Jan 22 at 15:39


















  • $begingroup$
    Make the ansatz $$y_1=e^{lambda t}$$
    $endgroup$
    – Dr. Sonnhard Graubner
    Jan 22 at 14:58










  • $begingroup$
    Yes I know how to resolv a second-order differential equation. What I would like to know, is how to get this equation
    $endgroup$
    – user3204810
    Jan 22 at 15:03






  • 1




    $begingroup$
    Just plug it in?
    $endgroup$
    – Klaus
    Jan 22 at 15:06






  • 1




    $begingroup$
    Take the derivative of your expression for $y_2$ and plug it in the second equation.
    $endgroup$
    – WarreG
    Jan 22 at 15:24










  • $begingroup$
    @WarreG this is the solution! Thanks!
    $endgroup$
    – user3204810
    Jan 22 at 15:39
















$begingroup$
Make the ansatz $$y_1=e^{lambda t}$$
$endgroup$
– Dr. Sonnhard Graubner
Jan 22 at 14:58




$begingroup$
Make the ansatz $$y_1=e^{lambda t}$$
$endgroup$
– Dr. Sonnhard Graubner
Jan 22 at 14:58












$begingroup$
Yes I know how to resolv a second-order differential equation. What I would like to know, is how to get this equation
$endgroup$
– user3204810
Jan 22 at 15:03




$begingroup$
Yes I know how to resolv a second-order differential equation. What I would like to know, is how to get this equation
$endgroup$
– user3204810
Jan 22 at 15:03




1




1




$begingroup$
Just plug it in?
$endgroup$
– Klaus
Jan 22 at 15:06




$begingroup$
Just plug it in?
$endgroup$
– Klaus
Jan 22 at 15:06




1




1




$begingroup$
Take the derivative of your expression for $y_2$ and plug it in the second equation.
$endgroup$
– WarreG
Jan 22 at 15:24




$begingroup$
Take the derivative of your expression for $y_2$ and plug it in the second equation.
$endgroup$
– WarreG
Jan 22 at 15:24












$begingroup$
@WarreG this is the solution! Thanks!
$endgroup$
– user3204810
Jan 22 at 15:39




$begingroup$
@WarreG this is the solution! Thanks!
$endgroup$
– user3204810
Jan 22 at 15:39










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