Difference between revisions of "Reduction of the Order"
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− | '''Reduction of order''' is a technique in | + | '''Reduction of order''' is a technique in mathematics for solving second-order linear ordinary differential equations. It is employed when one solution <math>y_1(x)</math> is known and a second linearly independent solution <math>y_2(x)</math> is desired. The method also applies to ''n''-th order equations. In this case the ansatz will yield an (''n''−1)-th order equation for <math>v</math>. |
== Second-order linear ordinary differential equations== | == Second-order linear ordinary differential equations== | ||
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:<math> a y''(x) + b y'(x) + c y(x) = 0,</math> | :<math> a y''(x) + b y'(x) + c y(x) = 0,</math> | ||
− | where <math>a, b, c</math> are real non-zero coefficients. Two linearly independent solutions for this ODE can be straightforwardly found using | + | where <math>a, b, c</math> are real non-zero coefficients. Two linearly independent solutions for this ODE can be straightforwardly found using characteristic equations except for the case when the discriminant, <math>b^2 - 4 a c</math>, vanishes. In this case, |
:<math> a y''(x) + b y'(x) + \frac{b^2}{4a} y(x) = 0,</math> | :<math> a y''(x) + b y'(x) + \frac{b^2}{4a} y(x) = 0,</math> | ||
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:<math> a y_1 v'' = 0.</math> | :<math> a y_1 v'' = 0.</math> | ||
− | Since <math>a</math> is assumed non-zero and <math>y_1(x)</math> is an | + | Since <math>a</math> is assumed non-zero and <math>y_1(x)</math> is an exponential function (and thus always non-zero), we have |
:<math> v'' = 0.</math> | :<math> v'' = 0.</math> | ||
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:<math> y_2(x) = x y_1(x) = x e^{-\frac{b}{2 a} x}.</math> | :<math> y_2(x) = x y_1(x) = x e^{-\frac{b}{2 a} x}.</math> | ||
− | Finally, we can prove that the second solution <math>y_2(x)</math> found via this method is linearly independent of the first solution by calculating the | + | Finally, we can prove that the second solution <math>y_2(x)</math> found via this method is linearly independent of the first solution by calculating the Wronskian |
:<math>W(y_1,y_2)(x) = \begin{vmatrix} y_1 & x y_1 \\ y_1' & y_1 + x y_1' \end{vmatrix} = y_1 ( y_1 + x y_1' ) - x y_1 y_1' = y_1^{2} + x y_1 y_1' - x y_1 y_1' = y_1^{2} = e^{-\frac{b}{a}x} \neq 0.</math> | :<math>W(y_1,y_2)(x) = \begin{vmatrix} y_1 & x y_1 \\ y_1' & y_1 + x y_1' \end{vmatrix} = y_1 ( y_1 + x y_1' ) - x y_1 y_1' = y_1^{2} + x y_1 y_1' - x y_1 y_1' = y_1^{2} = e^{-\frac{b}{a}x} \neq 0.</math> | ||
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:<math>v''+\left(\frac{2y_1'(t)}{y_1(t)}+p(t)\right)\,v'=\frac{r(t)}{y_1(t)}.</math> | :<math>v''+\left(\frac{2y_1'(t)}{y_1(t)}+p(t)\right)\,v'=\frac{r(t)}{y_1(t)}.</math> | ||
− | The | + | The integrating factor is <math>\mu(t)=e^{\int(\frac{2y_1'(t)}{y_1(t)}+p(t))dt}=y_1^2(t)e^{\int p(t) dt}</math>. |
Multiplying the differential equation by the integrating factor <math>\mu(t)</math>, the equation for <math>v(t)</math> can be reduced to | Multiplying the differential equation by the integrating factor <math>\mu(t)</math>, the equation for <math>v(t)</math> can be reduced to | ||
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==Resources== | ==Resources== | ||
− | |||
* [https://tutorial.math.lamar.edu/Classes/DE/ReductionofOrder.aspx Reduction of the Order Notes]. Produced by Paul Dawkins, Lamar University | * [https://tutorial.math.lamar.edu/Classes/DE/ReductionofOrder.aspx Reduction of the Order Notes]. Produced by Paul Dawkins, Lamar University | ||
+ | |||
+ | == Licensing == | ||
+ | Content obtained and/or adapted from: | ||
+ | * [https://en.wikipedia.org/wiki/Reduction_of_order Reduction of order, Wikipedia] under a CC BY-SA license |
Latest revision as of 22:22, 5 November 2021
Reduction of order is a technique in mathematics for solving second-order linear ordinary differential equations. It is employed when one solution is known and a second linearly independent solution is desired. The method also applies to n-th order equations. In this case the ansatz will yield an (n−1)-th order equation for .
Contents
Second-order linear ordinary differential equations
An example
Consider the general, homogeneous, second-order linear constant coefficient ordinary differential equation. (ODE)
where are real non-zero coefficients. Two linearly independent solutions for this ODE can be straightforwardly found using characteristic equations except for the case when the discriminant, , vanishes. In this case,
from which only one solution,
can be found using its characteristic equation.
The method of reduction of order is used to obtain a second linearly independent solution to this differential equation using our one known solution. To find a second solution we take as a guess
where is an unknown function to be determined. Since must satisfy the original ODE, we substitute it back in to get
Rearranging this equation in terms of the derivatives of we get
Since we know that is a solution to the original problem, the coefficient of the last term is equal to zero. Furthermore, substituting into the second term's coefficient yields (for that coefficient)
Therefore, we are left with
Since is assumed non-zero and is an exponential function (and thus always non-zero), we have
This can be integrated twice to yield
where are constants of integration. We now can write our second solution as
Since the second term in is a scalar multiple of the first solution (and thus linearly dependent) we can drop that term, yielding a final solution of
Finally, we can prove that the second solution found via this method is linearly independent of the first solution by calculating the Wronskian
Thus is the second linearly independent solution we were looking for.
General method
Given the general non-homogeneous linear differential equation
and a single solution of the homogeneous equation [], let us try a solution of the full non-homogeneous equation in the form:
where is an arbitrary function. Thus
and
If these are substituted for , , and in the differential equation, then
Since is a solution of the original homogeneous differential equation, , so we can reduce to
which is a first-order differential equation for (reduction of order). Divide by , obtaining
The integrating factor is .
Multiplying the differential equation by the integrating factor , the equation for can be reduced to
After integrating the last equation, is found, containing one constant of integration. Then, integrate to find the full solution of the original non-homogeneous second-order equation, exhibiting two constants of integration as it should:
Resources
- Reduction of the Order Notes. Produced by Paul Dawkins, Lamar University
Licensing
Content obtained and/or adapted from:
- Reduction of order, Wikipedia under a CC BY-SA license