ode
ordinary differential equation solver
Syntax
y = ode(y0, t0, t, f) [y, w, iw] = ode([type,] y0, t0, t [,rtol [,atol]], f [,jac] [,w, iw]) [y, rd, w, iw] = ode("root", y0, t0, t [,rtol [,atol]], f [,jac],ng, g [,w,iw]) y = ode("discrete", y0, k0, kvect, f)
Arguments
- y0
a real vector or matrix: initial state, at
t0
.- t0
a real scalar, the initial time.
- t
a real vector, the times at which the solution is computed.
- f
a function, external, string or list, the right hand side of the differential equation.
- type
a string, the solver to use. The available solvers are
"adams"
,"stiff"
,"rk"
,"rkf"
,"fix"
,"discrete"
,"root"
.- atol, rtol
absolute and relative tolerances on the final solution
y
(decimal numbers). If each is a single value, it applies to each component ofy
. Otherwise, it must be a vector of same size as size(y), and is applied element-wise toy
.- jac
a function, external, string or list, the Jacobian of the function
f
.- ng
an integer.
- g
an external (function or character string or list).
- k0
an integer (initial time).
- kvect
an integer vector.
- y
a real vector or matrix. The solution.
- rd
a real vector
- w, iw
real vectors. (INPUT/OUTPUT). See ode() optional output
Description
ode
solves explicit Ordinary Different Equations defined by:
It is an interface to various solvers, in particular to ODEPACK.
In this help, we only describe the use of ode
for
standard explicit ODE systems.
The simplest call of ode
is:
y = ode(y0,t0,t,f)
where y0
is the
vector of initial conditions, t0
is the initial
time, t
is the vector of times at which the
solution y
is computed and y
is
matrix of solution vectors
y=[y(t(1)),y(t(2)),...]
.
The input argument f
defines the right hand side of the
first order differential equation. This argument is a function with a specific header.
If
f
is a Scilab function, its syntax must beydot = f(t,y)
where
t
is a real scalar (the time) andy
is a real vector (the state) andydot
is a real vector (the first order derivative dy/dt).If
f
is a string, it is the name of a Fortran subroutine or a C compiled function. For example, if we callode(y0,t0,t,"fex")
, then the subroutinefex
is called.The Fortran routine must have the header:
fex(n,t,y,ydot)
where
n
is an integer,t
is a double precision scalar,y
andydot
are double precision vectors.The C function must have the header:
fex(int *n,double *t,double *y,double *ydot)
where
t
is the time,y
the state andydot
is the state derivative (dy/dt).This external can be build in a OS independent way using ilib_for_link and dynamically linked to Scilab by the link function.
It may happen that the simulator
f
needs extra arguments. In this case, we can use the following feature. Thef
argument can also be a listlst=list(simuf,u1,u2,...un)
wheresimuf
is a Scilab function with syntax:ydot = f(t,y,u1,u2,...,un)
andu1
,u2
, ...,un
are extra arguments which are automatically passed to the simulatorsimuf
.
The function f
can return a p-by-q matrix instead of a vector.
With this matrix notation, we
solve the n=p+q
ODE's system
dY/dt=F(t,Y)
where Y
is a
p x q
matrix. Then initial conditions,
Y0
, must also be a p x q
matrix
and the result of ode
is the p-by-q(T+1)
matrix
[Y(t_0),Y(t_1),...,Y(t_T)]
.
The tolerances rtol
and atol
are
thresholds for relative and absolute estimated errors. The estimated
error on y(i)
is:
rtol(i)*abs(y(i))+atol(i)
and integration is carried out as far as this error is small for
all components of the state. If rtol
and/or
atol
is a constant rtol(i)
and/or atol(i)
are set to this constant value.
Default values for rtol
and atol
are respectively rtol=1.d-5
and
atol=1.d-7
for most solvers and
rtol=1.d-3
and atol=1.d-4
for
"rfk"
and "fix"
.
For stiff problems, it is better to give the Jacobian of the RHS
function as the optional argument jac
.
The Jacobian is an external i.e. a function with specified syntax, or the name of a
Fortran subroutine or a C function (character string) with specified
calling sequence or a list.
If
jac
is a function the syntax should beJ=jac(t,y)
wheret
is a real scalar (time) andy
a real vector (state). The result matrixJ
must evaluate to df/dx i.e.J(k,i) = dfk/dxi
wherefk
is thek
-th component off
.If
jac
is a character string it refers to the name of a Fortran subroutine or a C function.The Fortran routine must have the header:
subroutine fex(n,t,y,ml,mu,J,nrpd) integer n,ml,mu,nrpd double precision t,y(*),J(*)
The C function must have the header:
void fex(int *n,double *t,double *y,int *ml,int *mu,double *J,int *nrpd,)
In most cases you have not to refer
ml
,mu
andnrpd
.If
jac
is a list the same conventions as forf
apply.
Optional arguments w
and
iw
are vectors for storing information returned by
the integration routine (see ode_optional_output for details).
When these vectors are provided in RHS of ode
the
integration re-starts with the same parameters as in its previous
stop.
More options can be given to ODEPACK solvers by using
%ODEOPTIONS
variable. See odeoptions.
The solvers
The type of problem solved and
the method used depend on the value of the first optional argument
type
which can be one of the following strings:
- <not given>:
lsoda
solver of package ODEPACK is called by default. It automatically selects between nonstiff predictor-corrector Adams method and stiff Backward Differentiation Formula (BDF) method. It uses nonstiff method initially and dynamically monitors data in order to decide which method to use.- "adams":
This is for nonstiff problems.
lsode
solver of package ODEPACK is called and it uses the Adams method.- "stiff":
This is for stiff problems.
lsode
solver of package ODEPACK is called and it uses the BDF method.- "rk":
Adaptive Runge-Kutta of order 4 (RK4) method.
- "rkf":
The Shampine and Watts program based on Fehlberg's Runge-Kutta pair of order 4 and 5 (RKF45) method is used. This is for non-stiff and mildly stiff problems when derivative evaluations are inexpensive. This method should generally not be used when the user is demanding high accuracy.
- "fix":
Same solver as
"rkf"
, but the user interface is very simple, i.e. onlyrtol
andatol
parameters can be passed to the solver. This is the simplest method to try.- "root":
ODE solver with rootfinding capabilities. The
lsodar
solver of package ODEPACK is used. It is a variant of thelsoda
solver where it finds the roots of a given vector function. See help on ode_root for more details.- "discrete":
Discrete time simulation. See help on ode_discrete for more details.
Examples
In the following example, we solve the Ordinary Differential Equation
dy/dt=y^2-y*sin(t)+cos(t)
with the initial
condition y(0)=0
.
We use the default solver.
function ydot=f(t, y) ydot=y^2-y*sin(t)+cos(t) endfunction y0=0; t0=0; t=0:0.1:%pi; y = ode(y0,t0,t,f); plot(t,y)
In the following example, we solve the equation dy/dt=A*y
.
The exact solution is y(t)=expm(A*t)*y(0)
, where
expm
is the matrix exponential.
The unknown is the 2-by-1 matrix y(t).
function ydot=f(t, y) ydot=A*y endfunction function J=Jacobian(t, y) J=A endfunction A=[10,0;0,-1]; y0=[0;1]; t0=0; t=1; ode("stiff",y0,t0,t,f,Jacobian) // Compare with exact solution: expm(A*t)*y0
In the following example, we solve the ODE dx/dt = A x(t) + B u(t)
with u(t)=sin(omega*t)
.
Notice the extra arguments of f
:
A
, u
, B
,
omega
are passed to function f
in a list.
function xdot=linear(t, x, A, u, B, omega) xdot=A*x+B*u(t,omega) endfunction function ut=u(t, omega) ut=sin(omega*t) endfunction A=[1 1;0 2]; B=[1;1]; omega=5; y0=[1;0]; t0=0; t=[0.1,0.2,0.5,1]; ode(y0,t0,t,list(linear,A,u,B,omega))
In the following example, we solve the Riccati differential equation
dX/dt=A'*X + X*A - X'*B*X + C
where initial
condition X(0)
is the 2-by-2 identity matrix.
function Xdot=ric(t, X, A, B, C) Xdot=A'*X+X*A-X'*B*X+C endfunction A=[1,1;0,2]; B=[1,0;0,1]; C=[1,0;0,1]; y0=eye(A); t0=0; t=0:0.1:%pi; X = ode(y0,t0,t,list(ric,A,B,C))
In the following example, we solve the differential equation
dY/dt=A*Y
where the unknown Y(t)
is a 2-by-2 matrix.
The exact solution is Y(t)=expm(A*t)
, where
expm
is the matrix exponential.
With a compiler
The following example requires a C compiler.
// ---------- Simple one dimension ODE (C coded external) ccode=['#include <math.h>' 'void myode(int *n,double *t,double *y,double *ydot)' '{' ' ydot[0]=y[0]*y[0]-y[0]*sin(*t)+cos(*t);' '}'] mputl(ccode,TMPDIR+'/myode.c') //create the C file // Compile cd TMPDIR ilib_for_link('myode','myode.c',[],'c',[],'loader.sce'); exec('loader.sce') //incremental linking y0=0; t0=0; t=0:0.1:%pi; y = ode(y0,t0,t,'myode');
See also
- odeoptions — set options for ode solvers
- ode_optional_output — ode solvers optional outputs description
- ode_root — ordinary differential equation solver with roots finding
- ode_discrete — ordinary differential equation solver, discrete time simulation
- dassl — differential algebraic equation
- impl — differential algebraic equation
- odedc — discrete/continuous ode solver
- csim — simulation (time response) of linear system
- ltitr — discrete time response (state space)
- rtitr — discrete time response (transfer matrix)
- intg — definite integral
Bibliography
Alan C. Hindmarsh, "lsode and lsodi, two new initial value ordinary differential equation solvers", ACM-Signum newsletter, vol. 15, no. 4 (1980), pp. 10-11.
Used Functions
The associated routines can be found in SCI/modules/differential_equations/src/fortran directory: lsode.f lsoda.f lsodar.f
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