A Proximal Neurodynamic Network With Fixed-Time Convergence for Equilibrium Problems and Its Applications

This article proposes a novel fixed-time converging proximal neurodynamic network (FXPNN) via a proximal operator to deal with equilibrium problems (EPs). A distinctive feature of the proposed FXPNN is its better transient performance in comparison to most existing proximal neurodynamic networks. It is shown that the FXPNN converges to the solution of the corresponding EP in fixed-time under some mild conditions. It is also shown that the settling time of the FXPNN is independent of initial conditions and the fixed-time interval can be prescribed, unlike existing results with asymptotical or exponential convergence. Moreover, the proposed FXPNN is applied to solve composition optimization problems (COPs), l(1)-regularized least-squares problems, mixed variational inequalities (MVIs), and variational inequalities (VIs). It is further shown, in the case of solving COPs, that the fixed-time convergence can be established via the Polyak-Lojasiewicz condition, which is a relaxation of the more demanding convexity condition. Finally, numerical examples are presented to validate the effectiveness and advantages of the proposed neurodynamic network.

Automated summary

This article proposes a novel fixed-time converging proximal neurodynamic network (FXPNN) to deal with equilibrium problems (EPs). The FXPNN shows better transient performance compared to most existing proximal neurodynamic networks and converges to the solution in fixed-time. It is applied to solve various optimization problems and inequalities, and its effectiveness and advantages are validated through numerical examples.