Numerical continuation is a method of computing approximate solutions of a system of parameterized nonlinear equations,
F(u,λ)=0.
λ
u
λ
Often the original mapping
F
A steady state, or fixed point, of a parameterized family of flows or maps are of this form, and by discretizing trajectories of a flow or iterating a map, periodic orbits and heteroclinic orbits can also be posed as a solution of
F=0
In some nonlinear systems, parameters are explicit. In others they are implicit, and the system of nonlinear equations is written
F(u)=0
u
F(u)
This formulation, without an explicit parameter space is not usually suitable for the formulations in the following sections, because they refer to parameterized autonomous nonlinear dynamical systems of the form:
u'=F(u,λ).
However, in an algebraic system there is no distinction between unknowns
u
A periodic motion is a closed curve in phase space. That is, for some period
T
u'=F(u,λ),u(0)=u(T).
The textbook example of a periodic motion is the undamped pendulum.
If the phase space is periodic in one or more coordinates, say
u(t)=u(t+\Omega)
\Omega
u'=F(u,λ),u(0)=u(T+N.\Omega)
for every integer
N
The first step in writing an implicit system for a periodic motion is to move the period
T
u'=TF(u,λ),u(0)=u(1+N.\Omega).
The second step is to add an additional equation, a phase constraint, that can be thought of as determining the period. This is necessary because any solution of the above boundary value problem can be shifted in time by an arbitrary amount (time does not appear in the defining equations—the dynamical system is called autonomous).
There are several choices for the phase constraint. If
u0(t)
λ0
λ
\langleu(0)-u0(0),F(u0(0),λ0)\rangle=0.
which states that
u
For a general problem a better phase constraint is an integral constraint introduced by Eusebius Doedel, which chooses the phase so that the distance between the known and unknown orbits is minimized:
1 | |
\int | |
0 |
\langleu(t)-u0(t),F(u0(t),λ0)\rangledt=0.
A solution component
\Gamma(u0,λ0)
F
(u,λ)
F(u,λ)=0
(u0,λ0)
(u(s),λ(s))
(u(0),λ(0))=(u0,λ0),(u(1),λ(1))=(u,λ)
F(u(s),λ(s))=0
A numerical continuation is an algorithm which takes as input a system of parametrized nonlinear equations and an initial solution
(u0,λ0)
F(u0,λ0)=0
\Gamma(u0,λ0)
A regular point of
F
(u,λ)
F
(n)
Near a regular point the solution component is an isolated curve passing through the regular point (the implicit function theorem). In the figure above the point
(u0,λ0)
A singular point of
F
(u,λ)
Near a singular point the solution component may not be an isolated curve passing through the regular point. The local structure is determined by higher derivatives of
F
In general solution components
\Gamma
For finite-dimensional systems (as defined above) the Lyapunov-Schmidt decomposition may be used to produce two systems to which the Implicit Function Theorem applies. The Lyapunov-Schmidt decomposition uses the restriction of the system to the complement of the null space of the Jacobian and the range of the Jacobian.
If the columns of the matrix
\Phi
J=\left[ \begin{array}{cc} Fx&Fλ\\ \end{array} \right]
\Psi
J
F(x,λ)=0
\left[ \begin{array}{l} (I-\Psi\PsiT)F(x+\Phi\xi+η)\\ \PsiTF(x+\Phi\xi+η)\\ \end{array} \right]=0,
η
J
(\PhiTη=0)
In the first equation, which is parametrized by the null space of the Jacobian (
\xi
η
η(\xi)
η(0)=0
(I-\Psi\PsiT)F(x+\Phi\xi+η(\xi))=0)
η(\xi)
The bifurcation equation has a Taylor expansion which lacks the constant and linear terms. By scaling the equations and the null space of the Jacobian of the original system a system can be found with non-singular Jacobian. The constant term in the Taylor series of the scaled bifurcation equation is called the algebraic bifurcation equation, and the implicit function theorem applied the bifurcation equations states that for each isolated solution of the algebraic bifurcation equation there is a branch of solutions of the original problem which passes through the singular point.
Another type of singular point is a turning point bifurcation, or saddle-node bifurcation, where the direction of the parameter
λ
Most methods of solution of nonlinear systems of equations are iterative methods. For a particular parameter value
λ0
u0
F(u,λ0)=0
Natural parameter continuation is a very simple adaptation of the iterative solver to a parametrized problem. The solution atone value of
λ
λ+\Deltaλ
\Deltaλ
One advantage of natural parameter continuation is that it uses the solution method for the problem as a black box. All that is required is that an initial solution be given (some solvers used to always start at a fixed initial guess). There has been a lot of work in the area of large scale continuation on applying more sophisticated algorithms to black box solvers (see e.g. LOCA).
However, natural parameter continuation fails at turning points, where the branch of solutions turns round. So for problems with turning points, a more sophisticated method such as pseudo-arclength continuation must be used (see below).
See main article: Piecewise linear continuation.
Simplicial Continuation, or Piecewise Linear Continuation (Allgower and Georg) is based on three basic results.
The first is
If F(x) maps IR^n into IR^(n-1), there is a unique linear interpolant on an (n-1)-dimensional simplex which agrees with the function values at the vertices of the simplex. |
The second result is:
An (n-1)-dimensional simplex can be tested to determine if the unique linear interpolant takes on the value 0 inside the simplex. |
Please see the article on piecewise linear continuation for details.
With these two operations this continuation algorithm is easy to state (although of course an efficient implementation requires a more sophisticated approach. See [B1]). An initial simplex is assumed to be given, from a reference simplicial decomposition of
Rn
References: Allgower and Georg [B1] provides a crisp, clear description of the algotihm.
This method is based on the observation that the "ideal" parameterization of a curve is arclength. Pseudo-arclength is an approximation of the arclength in the tangent space of the curve. The resulting modified natural continuation method makes a step in pseudo-arclength (rather than
λ
Pseudo-arclength continuation was independently developed by Edward Riks and Gerald Wempner for finite element applications in the late 1960s, and published in journals in the early 1970s by H.B. Keller. A detailed account of these early developments isprovided in the textbook by M. A. Crisfield: Nonlinear Finite Element Analysis of Solids and Structures, Vol 1: Basic Concepts, Wiley, 1991. Crisfield was one of the most active developers of this class of methods, which are by now standard procedures of commercial nonlinear finite element programs.
The algorithm is a predictor-corrector method. The prediction step finds the point (in IR^(n+1)) which is a step
\Deltas
\begin{array}{l} F(u,λ)=0\\ u |
* | |
0(u-u |
|
0(λ-λ0)=\Deltas\\ \end{array}
(u |
|
0)
(u0,λ0)
\left[ \begin{array}{cc} Fu&Fλ\\
u |
*&
λ\\ \end{array} \right] |
This method is a variant of pseudo-arclength continuation. Instead of using the tangent at the initial point in the arclength constraint, the tangent at the current solution is used. This is equivalent to using the pseudo-inverse of the Jacobian in Newton's method, and allows longer steps to be made. [B17]
The parameter
λ
λ
The same terminology applies. A regular solution is a solution at which the Jacobian is full rank
(n)
A regular solution lies on a k-dimensional surface, which can be parameterized by a point in the tangent space (the null space of the Jacobian). This is again a straightforward application of the Implicit Function Theorem.
Numerical continuation techniques have found a great degree of acceptance in the study of chaotic dynamical systems and various other systems which belong to the realm of catastrophe theory. The reason for such usage stems from the fact that various non-linear dynamical systems behave in a deterministic and predictable manner within a range of parameters which are included in the equations of the system. However, for a certain parameter value the system starts behaving chaotically and hence it became necessary to follow the parameter in order to be able to decipher the occurrences of when the system starts being non-predictable, and what exactly (theoretically) makes the system become unstable.
Analysis of parameter continuation can lead to more insights about stable/critical point bifurcations. Study of saddle-node, transcritical, pitch-fork, period doubling, Hopf, secondary Hopf (Neimark) bifurcations of stable solutions allows for a theoretical discussion of the circumstances and occurrences which arise at the critical points. Parameter continuation also gives a more dependable system to analyze a dynamical system as it is more stable than more interactive, time-stepped numerical solutions. Especially in cases where the dynamical system is prone to blow-up at certain parameter values (or combination of values for multiple parameters).[2]
It is extremely insightful as to the presence of stable solutions (attracting or repelling) in the study of nonlinear differential equations where time stepping in the form of the Crank Nicolson algorithm is extremely time consuming as well as unstable in cases of nonlinear growth of the dependent variables in the system. The study of turbulence is another field where the Numerical Continuation techniques have been used to study the advent of turbulence in a system starting at low Reynolds numbers. Also, research using these techniques has provided the possibility of finding stable manifolds and bifurcations to invariant-tori in the case of the restricted three-body problem in Newtonian gravity and have also given interesting and deep insights into the behaviour of systems such as the Lorenz equations.
(Under Construction) See also The SIAM Activity Group on Dynamical Systems' list http://www.dynamicalsystems.org/sw/sw/
λ\isinR
This problem, of finding the points which F maps into the origin appears in computer graphics as the problems of drawing contour maps (n=2), or isosurface(n=3). The contour with value h is the set of all solution components of F-h=0
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[B2] "Numerical Methods for Bifurcations of Dynamical Equilibria", Willy J. F. Govaerts, SIAM 2000.
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[B7] "Elementary Stability and Bifurcation Theory", Gerard Iooss and Daniel D. Joseph, Springer-Verlag Undergraduate Texts in Mathematics, 1980.
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[B10] "Singularities and Groups in Bifurcation Theory, volume I", Martin Golubitsky and David G. Schaeffer, Springer-Verlag Applied Mathematical Sciences 51, 1985.
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[B12] "Solving Polynomial Systems Using Continuation for Engineering and Scientific Problems", Alexander Morgan, Prentice-Hall, Englewood Cliffs, N.J. 1987.
[B13] "Pathways to Solutions, Fixed Points and Equilibria", C. B. Garcia and W. I. Zangwill, Prentice-Hall, 1981.
[B14] "The Implicit Function Theorem: History, Theory and Applications", Steven G. Krantz and Harold R. Parks, Birkhauser, 2002.
[B15] "Nonlinear Functional Analysis", J. T. Schwartz, Gordon and Breach Science Publishers, Notes on Mathematics and its Applications, 1969.
[B16] "Topics in Nonlinear Functional Analysis", Louis Nirenberg (notes by Ralph A. Artino), AMS Courant Lecture Notes in Mathematics 6, 1974.
[B17] "Newton Methods for Nonlinear Problems -- Affine Invariance and Adaptive Algorithms", P. Deuflhard,Series Computational Mathematics 35, Springer, 2006.
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[A12] "The Computation of Simplicial Approximations of Implicitly Defined p-Manifolds", M. L. Brodzik, Computers and Mathematics with Applications, 36(6):93-113, 1998.
[A13] "New Algorithm for Two-Dimensional Numerical Continuation", R. Melville and D. S. Mackey, Computers and Mathematics with Applications, 30(1):31-46, 1995.
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