TY - JOUR
T1 - Semi-cooperative strategies for differential games
JF - Internat. J. Game Theory 32 (2004) 561-593
Y1 - 2004
A1 - Alberto Bressan
A1 - Wen Shen
AB - The paper is concerned with a non-cooperative differential game for two players. We first consider Nash equilibrium solutions in feedback form. In this case, we show that the Cauchy problem for the value functions is generically ill-posed. Looking at vanishing viscosity approximations, one can construct special solutions in the form of chattering controls, but these also appear to be unstable. In the second part of the paper we propose an alternative \\\"semi-cooperative\\\" pair of strategies for the two players, seeking a Pareto optimum instead of a Nash equilibrium. In this case, we prove that the corresponding Hamiltonian system for the value functions is always weakly hyperbolic.
PB - Springer
UR - http://hdl.handle.net/1963/2893
U1 - 1807
U2 - Mathematics
U3 - Functional Analysis and Applications
ER -
TY - JOUR
T1 - Small BV solutions of hyperbolic noncooperative differential games
JF - SIAM J. Control Optim. 43 (2004) 194-215
Y1 - 2004
A1 - Alberto Bressan
A1 - Wen Shen
AB - The paper is concerned with an n-persons differential game in one space dimension. We state conditions for which the system of Hamilton-Jacobi equations for the value functions is strictly hyperbolic. In the positive case, we show that the weak solution of a corresponding system of conservation laws determines an n-tuple of feedback strategies. These yield a Nash equilibrium solution to the non-cooperative differential game.
PB - SIAM
UR - http://hdl.handle.net/1963/2917
U1 - 1783
U2 - Mathematics
U3 - Functional Analysis and Applications
ER -
TY - JOUR
T1 - BV estimates for multicomponent chromatography with relaxation
JF - Discrete Contin. Dynam. Systems 6 (2000) 21-38
Y1 - 2000
A1 - Alberto Bressan
A1 - Wen Shen
AB - We consider the Cauchy problem for a system of $2n$ balance laws which arises from the modelling of multi-component chromatography: $$\\\\left\\\\{ \\\\eqalign{u_t+u_x&=-{1\\\\over\\\\ve}\\\\big( F(u)-v\\\\big),\\\\cr v_t&={1\\\\over\\\\ve}\\\\big( F(u)-v\\\\big),\\\\cr}\\\\right. \\\\eqno(1)$$ This model describes a liquid flowing with unit speed over a solid bed. Several chemical substances are partly dissolved in the liquid, partly deposited on the solid bed. Their concentrations are represented respectively by the vectors $u=(u_1,\\\\ldots,u_n)$ and $v=(v_1,\\\\ldots,v_n)$. We show that, if the initial data have small total variation, then the solution of (1) remains with small variation for all times $t\\\\geq 0$. Moreover, using the $\\\\L^1$ distance, this solution depends Lipschitz continuously on the initial data, with a Lipschitz constant uniform w.r.t.~$\\\\ve$. Finally we prove that as $\\\\ve\\\\to 0$, the solutions of (1) converge to a limit described by the system $$\\\\big(u+F(u)\\\\big)_t+u_x=0,\\\\qquad\\\\qquad v=F(u).\\\\eqno(2)$$ The proof of the uniform BV estimates relies on the application of probabilistic techniques. It is shown that the components of the gradients $v_x,u_x$ can be interpreted as densities of random particles travelling with speed 0 or 1. The amount of coupling between different components is estimated in terms of the expected number of crossing of these random particles. This provides a first example where BV estimates are proved for general solutions to a class of $2n\\\\times 2n$ systems with relaxation.
PB - SISSA Library
UR - http://hdl.handle.net/1963/1336
U1 - 3119
U2 - Mathematics
U3 - Functional Analysis and Applications
ER -
TY - JOUR
T1 - Uniqueness for discontinuous ODE and conservation laws
JF - Nonlinear Analysis 34 (1998) 637-652
Y1 - 1998
A1 - Alberto Bressan
A1 - Wen Shen
AB - Consider a scalar O.D.E. of the form $\\\\dot x=f(t,x),$ where $f$ is possibly discontinuous w.r.t. both variables $t,x$. Under suitable assumptions, we prove that the corresponding Cauchy problem admits a unique solution, which depends H\\\\\\\"older continuously on the initial data.\\nOur result applies in particular to the case where $f$ can be written in the form $f(t,x)\\\\doteq g\\\\big( u(t,x)\\\\big)$, for some function $g$ and some solution $u$ of a scalar conservation law, say $u_t+F(u)_x=0$. In turn, this yields the uniqueness and continuous dependence of solutions to a class of $2\\\\times 2$ strictly hyperbolic systems, with initial data in $\\\\L^\\\\infty$.
PB - Elsevier
UR - http://hdl.handle.net/1963/3699
U1 - 606
U2 - Mathematics
U3 - Functional Analysis and Applications
ER -