Shooting method

In numerical analysis, the shooting method is a method for solving a boundary value problem by reducing it to the solution of an initial value problem. Roughly speaking, we 'shoot' out trajectories in different directions until we find a trajectory that has the desired boundary value. The following exposition may be clarified by this illustration of the shooting method.

For a boundary value problem of a second-order ordinary differential equation, the method is stated as follows. Let

${\displaystyle y''(t)=f(t,y(t),y'(t)),\quad y(t_{0})=y_{0},\quad y(t_{1})=y_{1}}$

be the boundary value problem. Let y(t; a) denote the solution of the initial value problem

${\displaystyle y''(t)=f(t,y(t),y'(t)),\quad y(t_{0})=y_{0},\quad y'(t_{0})=a}$

Define the function F(a) as the difference between y(t₁; a) and the specified boundary value y₁.

${\displaystyle F(a)=y(t_{1};a)-y_{1}\,}$

If F has a root a then the solution y(t; a) of the corresponding initial value problem is also a solution of the boundary value problem. Conversely, if the boundary value problem has a solution y(t), then y(t) is also the unique solution y(t; a) of the initial value problem where a = y'(t₀), thus a is a root of F.

The usual methods for finding roots may be employed here, such as the bisection method or Newton's method.

The boundary value problem is linear if f has the form

${\displaystyle f(t,y(t),y'(t))=p(t)y'(t)+q(t)y(t)+r(t).\,}$

In this case, the solution to the boundary value problem is usually given by:

${\displaystyle y(t)=y_{(1)}(t)+{\frac {y_{1}-y_{(1)}(t_{1})}{y_{(2)}(t_{1})}}y_{(2)}(t)}$

where ${\displaystyle y_{(1)}(t)}$ is the solution to the initial value problem:

${\displaystyle y_{(1)}''(t)=p(t)y_{(1)}'(t)+q(t)y_{(1)}(t)+r(t),\quad y_{(1)}(t_{0})=y_{0},\quad y_{(1)}'(t_{0})=0,}$

and ${\displaystyle y_{(2)}(t)}$ is the solution to the initial value problem:

${\displaystyle y_{(2)}''(t)=p(t)y_{(2)}'(t)+q(t)y_{(2)}(t),\quad y_{(2)}(t_{0})=0,\quad y_{(2)}'(t_{0})=1.}$

See the proof for the precise condition under which this result holds.

–== Example ==

A boundary value problem is given as follows by Stoer and Burlisch (Section 7.3.1).

${\displaystyle w''(t)={\frac {3}{2}}w^{2},\quad w(0)=4,\quad w(1)=1}$

The initial value problem

${\displaystyle w''(t)={\frac {3}{2}}w^{2},\quad w(0)=4,\quad w'(0)=s}$

was solved for s = −1, −2, −3, ..., −100, and F(s) = w(1;s) − 1 plotted in the first figure. Inspecting the plot of F, we see that there are roots near −8 and −36. Some trajectories of w(t;s) are shown in the second figure.

Stoer and Bulirsch state that there are two solutions, which can be found by algebraic method

• Direct multiple shooting method
• Computation of radiowave attenuation in the atmosphere

• Josef Stoer and Roland Bulirsch. Introduction to Numerical Analysis. New York: Springer-Verlag, 1980. (See Section 7.3.)
• Press, WH; Teukolsky, SA; Vetterling, WT; Flannery, BP (2007). "Section 18.1. The Shooting Method". Numerical Recipes: The Art of Scientific Computing (3rd ed.). New York: Cambridge University Press. ISBN 978-0-521-88068-8.

• Brief Description of ODEPACK (at Netlib; contains LSODE)
• Shooting method of solving boundary value problems – Notes, PPT, Maple, Mathcad, Matlab, Mathematica at Holistic Numerical Methods Institute [1]
• Shooting Method for Boundary Value Problems