Solve delay differential equations (DDEs) with constant delays
sol = dde23(ddefun,lags,history,tspan)
sol = dde23(ddefun,lags,history,tspan,options)
| Function handle that evaluates the right side of the differential equations . The function must have the form dydt = ddefun(t,y,Z) where |
| Vector of constant, positive delays τ1, ..., τk. |
| Specify
|
| Interval of integration from |
| Optional integration argument. A structure you create
using the |
sol = dde23(ddefun,lags,history,tspan) integrates
the system of DDEs
on the interval [t0,tf],
where τ1, ..., τk are
constant, positive delays and t0,tf.
The input argument, ddefun, is a function handle.
Parameterizing Functions explains how to provide additional
parameters to the function ddefun, if necessary.
dde23 returns the solution as a structure sol.
Use the auxiliary function deval and
the output sol to evaluate the solution at specific
points tint in the interval tspan = [t0,tf].
yint = deval(sol,tint)
The structure sol returned by dde23 has
the following fields.
| Mesh selected by |
| Approximation to y(x)
at the mesh points in |
| Approximation to y′(x)
at the mesh points in |
| Solver name, |
sol = dde23(ddefun,lags,history,tspan,options) solves
as above with default integration properties replaced by values in options,
an argument created with ddeset. See ddeset and Solving Delay Differential Equations for
more information.
Commonly used options are scalar relative error tolerance 'RelTol' (1e-3 by
default) and vector of absolute error tolerances 'AbsTol' (all
components are 1e-6 by default).
Use the 'Jumps' option to solve problems
with discontinuities in the history or solution. Set this option to
a vector that contains the locations of discontinuities in the solution
prior to t0 (the history) or in coefficients of
the equations at known values of t after t0.
Use the 'Events' option to specify a function
that dde23 calls to find where functions vanish. This function must be
of the form
[value,isterminal,direction] = events(t,y,Z)
and contain an event function for each event to be tested. For
the kth event function in events:
value(k) is the value of the kth
event function.
isterminal(k) = 1 if you want the
integration to terminate at a zero of this event function and 0 otherwise.
direction(k) = 0 if you want dde23 to
compute all zeros of this event function, +1 if
only zeros where the event function increases, and -1 if
only zeros where the event function decreases.
If you specify the 'Events' option and events
are detected, the output structure sol also includes
fields:
| Row vector of locations of all events, i.e., times when an event function vanished |
| Matrix whose columns are the solution values corresponding
to times in |
| Vector containing indices that specify which event occurred
at the corresponding time in |
This example solves a DDE on the interval [0, 5] with lags 1
and 0.2. The function ddex1de computes the delay
differential equations, and ddex1hist computes
the history for t <= 0.
Note
The file, ddex1.m,
contains the complete code for this example. To see the code in an
editor, type edit ddex1 at the command line. To
run it, type ddex1 at the command line.
sol = dde23(@ddex1de,[1, 0.2],@ddex1hist,[0, 5]);
This code evaluates the solution at 100 equally spaced points
in the interval [0,5], then plots the result.
tint = linspace(0,5); yint = deval(sol,tint); plot(tint,yint);
ddex1 shows how you can code this problem
using local functions. For more examples see ddex2.
dde23 tracks discontinuities and integrates
with the explicit Runge-Kutta (2,3) pair and interpolant of ode23.
It uses iteration to take steps longer than the lags.
[1] Shampine, L.F. and S. Thompson, “Solving DDEs in MATLAB,” Applied Numerical Mathematics, Vol. 37, 2001, pp. 441-458.
[2] Kierzenka, J., L.F. Shampine, and S. Thompson, “Solving Delay Differential Equations with dde23”