Characteristic equation (calculus)

Starting with a linear homogeneous differential equation with constant coefficients a_n, a_n − 1, ..., a₁, a₀,

${\displaystyle a_{n}y^{(n)}+a_{n-1}y^{(n-1)}+\cdots +a_{1}y^{\prime }+a_{0}y=0,}$ 

it can be seen 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″ = r²e^rx, and y⁽ⁿ⁾ = rⁿe^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.^[5] In order to solve for r, one can substitute y = e^rx and its derivatives into the differential equation to get

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

Since e^rx can never equal zero, it can be divided out, giving the characteristic equation

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

By solving for the roots, r, in this characteristic equation, one can find the general solution to the differential equation.^[1][6] For example, if r has roots equal to 3, 11, and 40, then the general solution will be ${\displaystyle y(x)=c_{1}e^{3x}+c_{2}e^{11x}+c_{3}e^{40x}}$ , where ${\displaystyle c_{1}}$ , ${\displaystyle c_{2}}$ , and ${\displaystyle c_{3}}$  are arbitrary constants which need to be determined by the boundary and/or initial conditions.

Solving the characteristic equation for its roots, r₁, ..., r_n, allows one to find the general solution of the differential equation. The roots may be real or complex, as well as distinct or repeated. If a characteristic equation has parts with distinct real roots, h repeated roots, or k complex roots corresponding to general solutions of y_D(x), y_R1(x), ..., y_Rh(x), and y_C1(x), ..., y_Ck(x), respectively, then the general solution to the differential equation is

${\displaystyle y(x)=y_{\mathrm {D} }(x)+y_{\mathrm {R} _{1}}(x)+\cdots +y_{\mathrm {R} _{h}}(x)+y_{\mathrm {C} _{1}}(x)+\cdots +y_{\mathrm {C} _{k}}(x)}$ 

The linear homogeneous differential equation with constant coefficients

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

has the characteristic equation

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

By factoring the characteristic equation into^{[further explanation needed]}

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

one can see that the solutions for r are the distinct single root r₁ = 3 and the double complex roots r_2,3,4,5 = 1 ± i. This corresponds to the real-valued general solution

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

with constants c₁, ..., c₅.

The superposition principle for linear homogeneous says that if u₁, ..., u_n are n linearly independent solutions to a particular differential equation, then c₁u₁ + ⋯ + c_nu_n is also a solution for all values c₁, ..., c_n.^[1][7] Therefore, if the characteristic equation has distinct real roots r₁, ..., r_n, then a general solution will be of the form

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

If the characteristic equation has a root r₁ that is repeated k times, then it is clear that y_p(x) = c₁e^r₁x is at least one solution.^[1] However, this solution lacks linearly independent solutions from the other k − 1 roots. Since r₁ has multiplicity k, the differential equation can be factored into^[1]

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

The fact that y_p(x) = c₁e^r₁x is one solution allows one to presume that the general solution may be of the form y(x) = u(x)e^r₁x, where u(x) is a function to be determined. Substituting ue^r₁x gives

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

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

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

By dividing out e^r₁x, it can be seen that

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

Therefore, the general case for u(x) is a polynomial of degree k − 1, so that u(x) = c₁ + c₂x + c₃x² + ⋯ + c_kx^k −1.^[6] Since y(x) = ue^r₁x, the part of the general solution corresponding to r₁ is

${\displaystyle y_{\mathrm {R} }(x)=e^{r_{1}x}\!\left(c_{1}+c_{2}x+\cdots +c_{k}x^{k-1}\right).}$ 

If a second-order differential equation has a characteristic equation with complex conjugate roots of the form r₁ = a + bi and r₂ = a − bi, then the general solution is accordingly y(x) = c₁e^{(a + bi )x} + c₂e^{(a − bi )x}. By Euler's formula, which states that e^iθ = cos θ + i sin θ, this solution can be rewritten as follows:

${\displaystyle {\begin{aligned}y(x)&=c_{1}e^{(a+bi)x}+c_{2}e^{(a-bi)x}\\&=c_{1}e^{ax}(\cos bx+i\sin bx)+c_{2}e^{ax}(\cos bx-i\sin bx)\\&=\left(c_{1}+c_{2}\right)e^{ax}\cos bx+i(c_{1}-c_{2})e^{ax}\sin bx\end{aligned}}}$ 

where c₁ and c₂ are constants that can be non-real and which depend on the initial conditions.^[6] (Indeed, since y(x) is real, c₁ − c₂ must be imaginary or zero and c₁ + c₂ must be real, in order for both terms after the last equals sign to be real.)

For example, if c₁ = c₂ = ⁠1/2⁠, then the particular solution y₁(x) = e^ax cos bx is formed. Similarly, if c₁ = ⁠1/2i⁠ and c₂ = −⁠1/2i⁠, then the independent solution formed is y₂(x) = e^ax sin bx. Thus by the superposition principle for linear homogeneous differential equations, a second-order differential equation having complex roots r = a ± bi will result in the following general solution:

${\displaystyle y_{\mathrm {C} }(x)=e^{ax}(C_{1}\cos bx+C_{2}\sin bx)}$ 

This analysis also applies to the parts of the solutions of a higher-order differential equation whose characteristic equation involves non-real complex conjugate roots.

• Characteristic polynomial