Characteristic equation (calculus)

In mathematics, the characteristic equation (or auxiliary equation^[1]) is an algebraic equation of degree $n\,$ on which depends the solutions of a given $n\,$ ^th-order differential equation.^[2] The characteristic equation can only be formed when the differential equation is linear, homogeneous, and has constant coefficients.^[1] Such a differential equation, with $y\,$ as the dependent variable and $a_{n},a_{n-1},\ldots ,a_{1},a_{0}$ as constants,

a_{n}y^{(n)}+a_{1}y^{(n-1)}+\cdots +a_{1}y'+a_{0}y=0

will have a characteristic equation of the form

a_{n}r^{n}+a_{1}r^{n-1}+\cdots +a_{1}r+a_{0}=0

where $r^{n},r^{n-1},\ldots ,r$ are the roots from which the general solution can be formed.^[1]^[3]^[4] This method of integrating linear ordinary differential equations with constant coefficients was discovered by Leonhard Euler, who found that the solutions depended on an algebraic 'characteristic' equation.^[2] The qualities of the Euler's characteristic equation were later considered in greater detail by French mathematicians Augustin-Louis Cauchy and Gaspard Monge.^[2]^[4]

Derivation

Starting with a linear homogeneous differential equation with constant coefficients $a_{n},a_{n-1},\ldots ,a_{1},a_{0}$ ,

a_{n}y^{(n)}+a_{n-1}y^{(n-1)}+\cdots +a_{1}y^{'}+a_{0}y=0

it can be see that if $y(x)=e^{rx}\,$ , each term would be a constant multiple of $e^{rx}\,$ . This results from the fact that the derivative of the exponential function $e^{rx}\,$ is a multiple of itself. Therefore, $y'=re^{rx}\,$ , $y''=r^{2}e^{rx}\,$ , and $y^{(n)}=r^{n}e^{rx}\,$ are all multiples. This suggests that certain values of $r\,$ will allow multiples of $e^{rx}\,$ to sum to zero, thus solving the homogeneous differential equation.^[3] In order to solve for $r\,$ , one can substitute $y=e^{rx}\,$ and its derivatives into the differential equation to get

a_{n}r^{n}e^{rx}+a_{n-1}r^{n-1}e^{rx}+\cdots +a_{1}re^{rx}+a_{0}e^{rx}=0

Since $e^{rx}\,$ can never equate to zero, it can be divided out, giving the characteristic equation

a_{n}r^{n}+a_{n-1}r^{n-1}+\cdots +a_{1}r+a_{0}=0

By solving for the roots, $r\,$ , in this characteristic equation, one can find the general solution to the differential equation.^[1]^[4] For example, if $r\,$ is found to equal to 3, then the general solution will be $y(x)=ce^{3x}\,$ , where $c\,$ is a constant.

Formation of the general solution

Example

The linear homogeneous differential equation with constant coefficients

y^{(5)}+y^{(4)}-4y^{(3)}-16y''-20y'-12y=0\,

has the characteristic equation

r^{5}+r^{4}-4r^{3}-16r^{2}-20r-12=0\,

By factoring the characteristic equation into

(r-3)(r^{2}+2r+2)^{2}=0\,

one can see that the solutions for $r\,$ are the distinct single root $r_{1}=3\,$ and the double complex root $r_{2,3,4,5}=-1\pm i$ . This corresponds to the real-valued general solution with constants $c_{1},\ldots ,c_{5}$ of

y(x)=c_{1}e^{3x}+e^{-x}(c_{2}\cos x+c_{3}\sin x)+xe^{-x}(c_{4}\cos x+c_{5}\sin x)\,

Solving the characteristic equation for its roots, $r_{1},\ldots ,r_{n}$ , allows one to find the general solution of the differential equation. The roots may be real and/or complex, as well as distinct and/or repeated. If a characteristic equation has parts with distinct real roots, $h\,$ repeated roots, and/or $k\,$ complex roots corresponding to general solutions of $y_{D}(x)\,$ , $y_{R_{1}}(x),\ldots ,y_{R_{h}}(x)$ , and $y_{C_{1}}(x),\ldots ,y_{C_{k}}(x)$ , respectively, then the general solution to the differential equation is

y(x)=y_{D}(x)+y_{R_{1}}(x)+\cdots +y_{R_{h}}(x)+y_{C_{1}}(x)+\cdots +y_{C_{k}}(x)

Distinct real roots

The superposition principle for linear homogeneous differential equations with constant coefficients says that if $u_{1},\ldots ,u_{n}$ are $n\,$ linearly independent solutions to a particular differential equation, then $c_{1}u_{1}+\cdots +c_{n}u_{n}$ is also a solution for all values $c_{1},\ldots ,c_{n}$ .^[1]^[5] Therefore, if the characteristic equation has distinct real roots $r_{1},\ldots ,r_{n}$ , then a general solution will be of the form

y_{D}(x)=c_{1}e^{r_{1}x}+c_{2}e^{r_{2}x}+\cdots +c_{n}e^{r_{n}x}

Repeated real roots

If the characteristic equation has a root $r_{1}$ that is repeated $k\,$ times, then it is clear that $y_{p}(x)=c_{1}e^{r_{1}x}$ is at least one solution.^[1] However, this solution lacks linearly independent solutions from the other $k-1/,$ roots. Since r_{1} has multiplicity $k\,$ , the differential equation can be factored into^[1]

\left({\frac {d}{dx}}-r_{1}\right)^{k}y=0

The fact that $y_{p}(x)=c_{1}e^{r_{1}x}$ is one solution allows one to presume that the general solution may be of the form $y(x)=u(x)e^{r_{1}x}\,$ , where $u(x)\,$ is a function to be determined. Substituting $ue^{r_{1}x}\,$ gives

\left({\frac {d}{dx}}-r_{1}\right)ue^{r_{1}x}={\frac {d}{dx}}(ue^{r_{1}x})-r_{1}ue^{r_{1}x}={\frac {d}{dx}}(u)e^{r_{1}x}+r_{1}ue^{r_{1}x}-r_{1}ue^{r_{1}x}={\frac {d}{dx}}(u)e^{r_{1}x}

when $k=1\,$ . By applying this fact $k\,$ times, it follows that

\left({\frac {d}{dx}}-r_{1}\right)^{k}ue^{r_{1}x}={\frac {d^{k}}{dx^{k}}}(u)e^{r_{1}x}=0

By dividing out $e^{r_{1}x}\,$ , it can be seen that

{\frac {d^{k}}{dx^{k}}}(u)=u^{(k)}=0

However, this is the case if and only if $u(x)\,$ is a polynomial of degree $k\,$ , so that $u(x)=c_{1}+c_{2}x+c_{3}x^{2}+\cdots +c_{k}x^{k-1}$ .^[4] Since $y(x)=ue^{r_{1}x}\,$ , the part of the general solution corresponding to $r_{1}$ is

y_{R}(x)=e^{r_{1}x}(c_{1}+c_{2}x+\cdots +c_{k}x^{k-1})

Complex roots

If the characteristic equation has complex roots of the form $r_{1}=a+bi$ and $r_{2}=a-bi$ , then the general solution is accordingly $y(x)=c_{1}e^{(a+bi)x}+c_{2}e^{(a-bi)x}\,$ . However, by Euler's formula, which states that $e^{i\theta }=\cos \theta +i\sin \theta \,$ , this solution can be rewritten as follows:

y(x)=c_{1}e^{(a+bi)x}+c_{2}e^{(a-bi)x}=c_{1}e^{ax}(\cos bx+i\sin bx)+c_{2}e^{ax}(\cos bx-i\sin bx)=(c_{1}+c_{2})e^{ax}\cos bx+i(c_{1}-c_{2})e^{ax}\sin bx\,

where $c_{1}\,$ and $c_{2}\,$ are constants that can be complex.^[4] Note that if $c_{1}=c_{2}={\tfrac {1}{2}}$ , then the particular solution $y_{1}(x)=e^{ax}\cos bx\,$ is formed. Similarly, if $c_{1}={\tfrac {1}{2}}i$ and $c_{2}=-{\tfrac {1}{2}}i$ , then the independent solution formed is $y_{2}(x)=e^{ax}\sin bx\,$ . Thus by the superposition principle for linear homogeneous differential equations with constant coefficients, the following general solution results for the part of a differential equation having complex roots $r=a\pm bi\,$

y_{C}(x)=e^{ax}(c_{1}\cos bx+c_{2}\sin bx)\,

References

^ ^a ^b ^c ^d ^e ^f ^g Edwards, C. Henry. "3". Differential Equations: Computing and Modeling. David Calvis. Upper Saddle River, New Jersey: Pearson Education. pp. 156–170. ISBN 978-0-13-600438-7. {{cite book}}: |access-date= requires |url= (help); Unknown parameter |coauthors= ignored (|author= suggested) (help)
^ ^a ^b ^c Smith, David Eugene. "History of Modern Mathematics: Differential Equations". University of South Florida. Retrieved 2 March 2011.
^ ^a ^b Chu, Herman. "Linear Homogeneous Ordinary Differential Equations with Constant Coefficients". eFunda. Retrieved 1 March 2011. {{cite web}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
^ ^a ^b ^c ^d ^e Cohen, Abraham (1906). An Elementary Treatise on Differential Equations. D. C. Heath and Company. {{cite book}}: |access-date= requires |url= (help)
^ Dawkins, Paul. "Differential Equation Terminology". Paul's Online Math Notes. Retrieved 2 March 2011.

[edwards-1] ^ ^a ^b ^c ^d ^e ^f ^g Edwards, C. Henry. "3". Differential Equations: Computing and Modeling. David Calvis. Upper Saddle River, New Jersey: Pearson Education. pp. 156–170. ISBN 978-0-13-600438-7. {{cite book}}: |access-date= requires |url= (help); Unknown parameter |coauthors= ignored (|author= suggested) (help)

[smith-2] Smith, David Eugene. "History of Modern Mathematics: Differential Equations". University of South Florida. Retrieved 2 March 2011.

[eFunda-3] Chu, Herman. "Linear Homogeneous Ordinary Differential Equations with Constant Coefficients". eFunda. Retrieved 1 March 2011. {{cite web}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)

[cohen-4] Cohen, Abraham (1906). An Elementary Treatise on Differential Equations. D. C. Heath and Company. {{cite book}}: |access-date= requires |url= (help)

[dawkins-5] Dawkins, Paul. "Differential Equation Terminology". Paul's Online Math Notes. Retrieved 2 March 2011.

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