In mathematics, a Riccati equation in the narrowest sense is any first-order ordinary differential equation that is quadratic in the unknown function. In other words, it is an equation of the form
y'(x)=q0(x)+q1(x)y(x)+q2(x)y2(x)
q0(x) ≠ 0
q2(x) ≠ 0
q0(x)=0
q2(x)=0
The equation is named after Jacopo Riccati (1676–1754).[1]
More generally, the term Riccati equation is used to refer to matrix equations with an analogous quadratic term, which occur in both continuous-time and discrete-time linear-quadratic-Gaussian control. The steady-state (non-dynamic) version of these is referred to as the algebraic Riccati equation.
The non-linear Riccati equation can always be converted to a second order linear ordinary differential equation (ODE):If
y'=q0(x)+q1(x)y+
| 2 | |
| q | |
| 2(x)y |
q2
v=yq2
v'=v2+R(x)v+S(x),
S=q2q0
| R=q | ||||
|
v'=(yq2)'=y'q2+yq2'=(q0+q1y+q2
| 2)q | |
| y | |
| 2 |
+v
| q2' | |
| q2 |
=q0q2
| +\left(q | ||||
|
\right)v+v2.
v=-u'/u
u
u''-R(x)u'+S(x)u=0
v'=-(u'/u)'=-(u''/u)+(u'/u)2=-(u''/u)+v2
u''/u=v2-v'=-S-Rv=-S+Ru'/u
u''-Ru'+Su=0.
y=-u'/(q2u)=
| -1 | |
| -q | |
| 2 |
(log(u))'
y=
| -1 | |
| -q | |
| 2 |
(log(c1u1+c2u2))'.
An important application of the Riccati equation is to the 3rd order Schwarzian differential equation
S(w):=(w''/w')'-(w''/w')2/2=f
S(w)
S((aw+b)/(cw+d))=S(w)
ad-bc
y=w''/w'
y'=y2/2+f.
y=-2u'/u
u
u''+(1/2)fu=0.
w''/w'=-2u'/u
w'=C/u2
C
U
U'u-Uu'
C
w'=(U'u-Uu')/u2=(U/u)'
w=U/u.
The correspondence between Riccati equations and second-order linear ODEs has other consequences. For example, if one solution of a 2nd order ODE is known, then it is known that another solution can be obtained by quadrature, i.e., a simple integration. The same holds true for the Riccati equation. In fact, if one particular solution
y1
y=y1+u
y1+u
y1'+u'=q0+q1 ⋅ (y1+u)+q2 ⋅ (y1+u)2,
y1'=q0+q1y1+q2
| 2, | |
| y | |
| 1 |
u'=q1u+2q2y1u+q2u2
u'-(q1+2q2y1)u=q2u2,
z=
| 1 | |
| u |
y=y1+
| 1 | |
| z |
z'+(q1+2q2y1)z=-q2
y=y1+
| 1 | |
| z |