Organisation/Company: CNRS, CentraleSupelec
Department: Computer Sciences
Research Field: Engineering » Control engineering Mathematics
Researcher Profile: Recognised Researcher (R2)
Positions: Postdoc Positions
Country: France
Application Deadline: 15 Dec 2024 - 00:00 (Europe/Paris)
Type of Contract: Temporary
Job Status: Full-time
Hours Per Week: 40
Offer Starting Date: 17 Oct 2024
Is the job funded through the EU Research Framework Programme? Not funded by a EU programme
Is the Job related to staff position within a Research Infrastructure? No
Offer Description Subject: Scientific machine learning, with a focus on developing and analyzing surrogate models for the efficient approximation and control of multi-agent systems.
Desired profile: PhD in applied math or computer science or equivalent.
Duration: 12 months (with possibility to extend)
Gross Salary: around 3000€ to 3300 € monthly, according to experience.
Application deadline: Open until filled. A National Security clearance is needed, and it can require approximately 2 months.
Work place: L2S, CentraleSupélec, Paris-Saclay University.
Address: 3 rue Joliot Curie, 91190 Gif-sur-Yvette, France.
Introduction:
Multi-agent systems (MAS) consist of multiple autonomous agents, interacting within a shared environment and depending on several parameters describing the current configuration. Modeling MAS involves capturing both the dynamics of individual agents and their interactions to understand the emergent behavior of the collective system as a unicum. Depending on the scale of the observed quantities and the required level of detail, MAS can be modeled using different mathematical tools. In practice, hybrid approaches that combine microscopic and macroscopic scales are often adopted to comprehensively capture MAS evolution. These strategies leverage insights from both perspectives to develop more accurate and scalable models. For example, agent-based models may be coupled with fluid dynamics equations to study traffic flow and crowd evacuation during emergencies, enabling researchers to simultaneously analyze both individual vehicle/person behavior and macroscopic traffic/crowd patterns.
Usually, at the microscopic level, agent behavior and interactions are explicitly modeled using Ordinary Differential Equations (ODEs). These equations describe the dynamics of individual agents in terms of their state variables, such as position, velocity, and internal states. In contrast, the macroscopic perspective focuses on describing the collective behavior of the entire system rather than individual agents. Here, the emphasis is on understanding global patterns, such as traffic flow, crowd dynamics, or information dissemination, emerging from the interactions of many agents. Macroscopic models often rely on Partial Differential Equations (PDEs) to describe how aggregated quantities, such as density, flow, or concentration, evolve over space and time. However, many MAS applications involve nonlinear interactions and complex spatial-temporal dynamics thus leading to high, if not prohibitive, computational costs, particularly when dealing with large-scale systems or highly heterogeneous environments with evolving boundary conditions. These issues may render it intractable for applying analytical tools, commonly found in optimal control literature.
The successful postdoc will be expected to work on the development of deep learning-based surrogate models (SM) for the solution of the parametrized time-dependent nonlinear PDE (tacking into account the MAS macroscopic perspective) thus enabling real-time control. The SM should maintain a high level of accuracy, comparable to the one provided by high fidelity models, e.g. analytical solutions or finite element method, with a significantly lower computational cost, thereby facilitating more efficient and scalable MAS simulations. Deep learning techniques rooted in physics will be exploited, leading to the integration of the governing equations describing the simulated phenomena, in the form of either hard constraints in the definition of the neural networks, either as weak constraints in the loss function formulation. These constraints will ensure the connection between ODE and PDE descriptions, so to inform the SM with fine-grained phenomena (the dynamics of individual agents) described by the ODEs.
Desired experience PhD in applied math or computer science or equivalent;
Experience in scientific machine learning, reinforcement learning, control theory;
Experience in publishing high-quality research papers;
Knowledge of libraries for deep learning (PyTorch, Tensorflow, Keras, JAX);
Experience in the design and analysis of networked control systems is a plus.
Languages ENGLISH: Level Excellent
Internal Application form(s) needed
Postdoc position L2S - Control of multi-agent systems via deep learning-based surrogate models.pdf
#J-18808-Ljbffr