Rational difference equation

A rational difference equation is a nonlinear difference equation of the form^[1][2][3][4]

${\displaystyle x_{n+1}=\frac{\alpha +{\displaystyle \sum _{i=0}^k}{\beta }_i{x}_{n-i}}{A+{\displaystyle \sum _{i=0}^k}{B}_i{x}_{n-i}},}$

where the initial conditions ${\displaystyle x_0,x_{-1},\dots ,x_{-k}}$ are such that the denominator never vanishes for any n.

A first-order rational difference equation is a nonlinear difference equation of the form

${\displaystyle w_{t+1}=\frac{a{w}_t+b}{c{w}_t+d}.}$

When ${\displaystyle a,b,c,d}$ and the initial condition ${\displaystyle w_0}$ are real numbers, this difference equation is called a Riccati difference equation.^[3]

Such an equation can be solved by writing ${\displaystyle w_t}$ as a nonlinear transformation of another variable ${\displaystyle x_t}$ which itself evolves linearly. Then standard methods can be used to solve the linear difference equation in ${\displaystyle x_t}$.

Equations of this form arise from the infinite resistor ladder problem.^[5][6]

One approach^[7] to developing the transformed variable ${\displaystyle x_t}$, when ${\displaystyle ad-bc\ne 0}$, is to write

${\displaystyle y_{t+1}=\alpha -\frac{\beta }{y_t}}$

where ${\displaystyle \alpha =(a+d)/c}$ and ${\displaystyle \beta =(ad-bc)/c^2}$ and where ${\displaystyle w_t=y_t-d/c}$.

Further writing ${\displaystyle y_t=x_{t+1}/x_t}$ can be shown to yield

${\displaystyle x_{t+2}-\alpha x_{t+1}+\beta x_t=0.}$

This approach^[8] gives a first-order difference equation for ${\displaystyle x_t}$ instead of a second-order one, for the case in which ${\displaystyle (d-a{)}^2+4bc}$ is non-negative. Write ${\displaystyle x_t=1/(\eta +w_t)}$ implying ${\displaystyle w_t=(1-\eta x_t)/x_t}$, where ${\displaystyle \eta }$ is given by ${\displaystyle \eta =(d-a+r)/2c}$ and where ${\displaystyle r=\sqrt{(d-a{)}^2+4bc}}$. Then it can be shown that ${\displaystyle x_t}$ evolves according to

${\displaystyle x_{t+1}=\left(\frac{d-\eta c}{\eta c+a}\right)x_t+\frac{c}{\eta c+a}.}$

The equation

${\displaystyle w_{t+1}=\frac{a{w}_t+b}{c{w}_t+d}}$

can also be solved by treating it as a special case of the more general matrix equation

${\displaystyle X_{t+1}=-(E+B{X}_t)(C+A{X}_t{)}^{-1},}$

where all of A, B, C, E, and X are n × n matrices (in this case n = 1); the solution of this is^[9]

${\displaystyle X_t=N_t{D}_t^{-1}}$

where

${\displaystyle \left(\begin{array}{c}{N}_t\\ D_t\end{array}\right)={\left(\begin{array}{cc}-B& -E\\ A& C\end{array}\right)}^t\left(\begin{array}{c}{X}_0\\ I\end{array}\right).}$

It was shown in ^[10] that a dynamic matrix Riccati equation of the form

${\displaystyle H_{t-1}=K+A^{\prime }{H}_{t}A-A^{\prime }{H}_{t}C(C^{\prime }{H}_{t}C{)}^{-1}{C}^{\prime }{H}_{t}A,}$

which can arise in some discrete-time optimal control problems, can be solved using the second approach above if the matrix C has only one more row than column.

• Simons, Stuart, "A non-linear difference equation," Mathematical Gazette 93, November 2009, 500–504.

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