PlanetPhysics/Riccati Equation 2: Difference between revisions

The nonlinear [[../DifferentialEquations/|differential equation]]

${\displaystyle \begin{array}{c}\frac{dy}{dx}=f(x)+g(x)y+h(x)y^2\end{array}}$

is called the Riccati equation .\, If\, ${\displaystyle h(x)\equiv 0}$,\, it becomes a linear differential equation; if\, ${\displaystyle f(x)\equiv 0}$,\, then it becomes a Bernoulli equation.\, There is no general method for integrating explicitely the equation (1), but via the substitution ${\displaystyle y:=-\frac{w^{\prime }(x)}{h(x)w(x)}}$ one can convert it to a second order homogeneous linear differential equation with non-constant coefficients.\\

If one can find a particular solution \,${\displaystyle y_0(x)}$,\, then one can easily verify that the substitution

${\displaystyle \begin{array}{c}y:=y_0(x)+\frac{1}{w(x)}\end{array}}$

converts (1) to

${\displaystyle \begin{array}{c}\frac{dw}{dx}+[g(x)+2h(x)y_0(x)]w+h(x)=0,\end{array}}$

which is a linear differential equation of first order with respect to the [[../Bijective/|function]] \,${\displaystyle w=w(x)}$.\\

Example. \, The Riccati equation

${\displaystyle \begin{array}{c}\frac{dy}{x}=3+3x^{2}y-x{y}^2\end{array}}$

has the particular solution\, ${\displaystyle y:=3x}$.\, Solve the equation.

We substitute\, ${\displaystyle y:=3x+\frac{1}{w(x)}}$\, to (4), getting ${\displaystyle \frac{dw}{dx}-3x^{2}w-x=0.}$ For solving this first order equation we can put\, ${\displaystyle w=uv}$,\, ${\displaystyle w^{\prime }=u{v}^{\prime }+u^{\prime }v}$,\, writing the equation as

${\displaystyle \begin{array}{c}u\cdot (v^{\prime }-3x^{3}v)+u^{\prime }v=x,\end{array}}$

where we choose the value of the expression in parentheses equal to 0: ${\displaystyle \frac{dv}{dx}-3x^{2}v=0}$ After separation of variables and integrating, we obtain from here a solution\, ${\displaystyle v=e^{x^3}}$,\, which is set to the equation (5): ${\displaystyle \frac{du}{dx}{e}^{x^3}=x}$ Separating the variables yields ${\displaystyle du=\frac{x}{e^{x^3}}dx}$ and integrating: ${\displaystyle u=C+\int x{e}^{-x^3}dx.}$ Thus we have ${\displaystyle w=w(x)=uv=e^{x^3}[C+\int x{e}^{-x^3}dx],}$ whence the general solution of the Riccati equation (4) is Failed to parse (syntax error): {\displaystyle y \,:=\, 3x+\frac{e^{-x^3}}{C+\int xe^{-x^3}\,dx}.\\}

It can be proved that if one knows three different solutions of Riccati equation (1), then any other solution may be expressed as a rational function of the three known solutions.

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