Your search keyword '"93E20, 92B20, 65K10"' showing total 3 results

1. Optimal control of mean field equations with monotone coefficients and applications in neuroscience

Author

Hocquet, Antoine and Vogler, Alexander

Subjects

Mathematics - Probability, Mathematics - Numerical Analysis, Mathematics - Optimization and Control, 93E20, 92B20, 65K10

Abstract

We are interested in the optimal control problem associated with certain quadratic cost functionals depending on the solution $X=X^\alpha$ of the stochastic mean-field type evolution equation in $\mathbb R^d$ $dX_t=b(t,X_t,\mathcal L(X_t),\alpha_t)dt+\sigma(t,X_t,\mathcal L(X_t),\alpha_t)dW_t,$ $X_0\sim \mu$ given, under assumptions that enclose a sytem of FitzHugh-Nagumo neuron networks, and where for practical purposes the control $\alpha_t$ is deterministic. To do so, we assume that we are given a drift coefficient that satisfies a one-sided Lipshitz condition, and that the dynamics is subject to a (convex) level set constraint of the form $\pi(X_t)\leq0$. The mathematical treatment we propose follows the lines of the recent monograph of Carmona and Delarue for similar control problems with Lipshitz coefficients. After addressing the existence of minimizers via a martingale approach, we show a maximum principle and then numerically investigate a gradient algorithm for the approximation of the optimal control., Comment: 32 pages; 11 figures

Published

2020

2. Optimal Control of Mean Field Equations with Monotone Coefficients and Applications in Neuroscience

Author

Antoine Hocquet and Alexander Vogler

Subjects

93E20, 92B20, 65K10, Control and Optimization, Applied Mathematics, Probability (math.PR), Sigma, Numerical Analysis (math.NA), Type (model theory), Optimal control, Lipschitz continuity, Combinatorics, Monotone polygon, Maximum principle, Mathematics::Probability, Optimization and Control (math.OC), Mean field equation, FOS: Mathematics, Mathematics - Numerical Analysis, ddc:510, Martingale (probability theory), Mathematics - Optimization and Control, Mathematics - Probability, Mathematics

Abstract

We are interested in the optimal control problem associated with certain quadratic cost functionals depending on the solution $X=X^\alpha$ of the stochastic mean-field type evolution equation in $\mathbb R^d$ $dX_t=b(t,X_t,\mathcal L(X_t),\alpha_t)dt+\sigma(t,X_t,\mathcal L(X_t),\alpha_t)dW_t,$ $X_0\sim \mu$ given, under assumptions that enclose a sytem of FitzHugh-Nagumo neuron networks, and where for practical purposes the control $\alpha_t$ is deterministic. To do so, we assume that we are given a drift coefficient that satisfies a one-sided Lipshitz condition, and that the dynamics is subject to a (convex) level set constraint of the form $\pi(X_t)\leq0$. The mathematical treatment we propose follows the lines of the recent monograph of Carmona and Delarue for similar control problems with Lipshitz coefficients. After addressing the existence of minimizers via a martingale approach, we show a maximum principle and then numerically investigate a gradient algorithm for the approximation of the optimal control., Comment: 32 pages; 11 figures

Published

2021

3. Optimal control of mean field equations with monotone coefficients and applications in neuroscience

Abstract

We are interested in the optimal control problem associated with certain quadratic cost functionals depending on the solution $X=X^\alpha$ of the stochastic mean-field type evolution equation in $\mathbb R^d$ $dX_t=b(t,X_t,\mathcal L(X_t),\alpha_t)dt+\sigma(t,X_t,\mathcal L(X_t),\alpha_t)dW_t,$ $X_0\sim \mu$ given, under assumptions that enclose a sytem of FitzHugh-Nagumo neuron networks, and where for practical purposes the control $\alpha_t$ is deterministic. To do so, we assume that we are given a drift coefficient that satisfies a one-sided Lipshitz condition, and that the dynamics is subject to a (convex) level set constraint of the form $\pi(X_t)\leq0$. The mathematical treatment we propose follows the lines of the recent monograph of Carmona and Delarue for similar control problems with Lipshitz coefficients. After addressing the existence of minimizers via a martingale approach, we show a maximum principle and then numerically investigate a gradient algorithm for the approximation of the optimal control., Comment: 32 pages; 11 figures

Published

2020