Projected dynamical systems is a

mathematical Mathematics is an area of knowledge that includes the topics of numbers, formulas and related structures, shapes and the spaces in which they are contained, and quantities and their changes. These topics are represented in modern mathematics ...

theory investigating the behaviour of

dynamical system In mathematics, a dynamical system is a system in which a Function (mathematics), function describes the time dependence of a Point (geometry), point in an ambient space. Examples include the mathematical models that describe the swinging of a ...

s where solutions are restricted to a constraint set. The discipline shares connections to and applications with both the static world of

optimization Mathematical optimization (alternatively spelled ''optimisation'') or mathematical programming is the selection of a best element, with regard to some criterion, from some set of available alternatives. It is generally divided into two subfi ...

and equilibrium problems and the dynamical world of

ordinary differential equations In mathematics, an ordinary differential equation (ODE) is a differential equation whose unknown(s) consists of one (or more) function(s) of one variable and involves the derivatives of those functions. The term ''ordinary'' is used in contrast w ...

. A projected dynamical system is given by the

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to the projected differential equation :

\frac = \Pi_K(x(t),-F(x(t)))

where ''K'' is our constraint set. Differential equations of this form are notable for having a discontinuous vector field.

History of projected dynamical systems

Projected dynamical systems have evolved out of the desire to dynamically model the behaviour of nonstatic solutions in equilibrium problems over some parameter, typically take to be time. This dynamics differs from that of ordinary differential equations in that solutions are still restricted to whatever constraint set the underlying equilibrium problem was working on, e.g. nonnegativity of investments in

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modeling,

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polyhedral sets in

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, etc. One particularly important class of equilibrium problems which has aided in the rise of projected dynamical systems has been that of

variational inequalities In mathematics, a variational inequality is an inequality involving a functional, which has to be solved for all possible values of a given variable, belonging usually to a convex set. The mathematical theory of variational inequalities was initial ...

. The formalization of projected dynamical systems began in the 1990s. However, similar concepts can be found in the mathematical literature which predate this, especially in connection with variational inequalities and differential inclusions.

Projections and Cones

Any solution to our projected differential equation must remain inside of our constraint set ''K'' for all time. This desired result is achieved through the use of projection operators and two particular important classes of

convex cone In linear algebra, a ''cone''—sometimes called a linear cone for distinguishing it from other sorts of cones—is a subset of a vector space that is closed under scalar multiplication; that is, is a cone if x\in C implies sx\in C for every . ...

s. Here we take ''K'' to be a

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subset of some

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''X''. The ''normal cone'' to the set ''K'' at the point ''x'' in ''K'' is given by :

N_K(x) = \.

The ''

tangent cone In geometry, the tangent cone is a generalization of the notion of the tangent space to a manifold to the case of certain spaces with singularities. Definitions in nonlinear analysis In nonlinear analysis, there are many definitions for a tangen ...

'' (or ''contingent cone'') to the set ''K'' at the point ''x'' is given by :

T_K(x) = \overline.

The ''projection operator'' (or ''closest element mapping'') of a point ''x'' in ''X'' to ''K'' is given by the point

P_K(x)

in ''K'' such that :

\,  x-P_K(x) \,  \leq \,  x-y \,

for every ''y'' in ''K''. The ''vector projection operator'' of a vector ''v'' in ''X'' at a point ''x'' in ''K'' is given by :

\Pi_K(x,v)=\lim_ \frac.

Which is just the Gateaux Derivative computed in the direction of the Vector field

Projected Differential Equations

Given a closed, convex subset ''K'' of a Hilbert space ''X'' and a vector field ''-F'' which takes elements from ''K'' into ''X'', the projected differential equation associated with ''K'' and ''-F'' is defined to be :

\frac = \Pi_K(x(t),-F(x(t))).

On the

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of ''K'' solutions behave as they would if the system were an unconstrained ordinary differential equation. However, since the vector field is discontinuous along the boundary of the set, projected differential equations belong to the class of discontinuous ordinary differential equations. While this makes much of ordinary differential equation theory inapplicable, it is known that when ''-F'' is a Lipschitz continuous vector field, a unique

absolutely continuous In calculus, absolute continuity is a smoothness property of functions that is stronger than continuity and uniform continuity. The notion of absolute continuity allows one to obtain generalizations of the relationship between the two central oper ...

solution exists through each initial point ''x(0)=x₀'' in ''K'' on the interval

[0,\infty)

. This differential equation can be alternately characterized by :

\frac = P_(-F(x(t)))

or :

\frac = -F(x(t))-P_{N_K(x(t))}(-F(x(t))).

The convention of denoting the vector field ''-F'' with a negative sign arises from a particular connection projected dynamical systems shares with variational inequalities. The convention in the literature is to refer to the vector field as positive in the variational inequality, and negative in the corresponding projected dynamical system.

References

* Aubin, J.P. and Cellina, A., ''Differential Inclusions'', Springer-Verlag, Berlin (1984). * Nagurney, A. and Zhang, D., ''Projected Dynamical Systems and Variational Inequalities with Applications'', Kluwer Academic Publishers (1996). * Cojocaru, M., and Jonker L., ''Existence of solutions to projected differential equations on Hilbert spaces'', Proc. Amer. Math. Soc., 132(1), 183-193 (2004). * Brogliato, B., and Daniilidis, A., and Lemaréchal, C., and Acary, V., "On the equivalence between complementarity systems, projected systems and differential inclusions", ''Systems and Control Letters'', vol.55, pp.45-51 (2006) Differential equations Dynamical systems

History of projected dynamical systems

Projections and Cones

Projected Differential Equations

See also

References