Distributed Koopman Learning using Partial Trajectories for Control
This work addresses privacy-preserving dynamics learning for multi-agent control systems, but it is incremental as it builds on existing Koopman operator and distributed learning methods.
The paper tackles the problem of learning unknown dynamics in multi-agent systems without sharing private training data, achieving consensus on a global dynamics model and enabling accurate model-based optimal control for reference-tracking tasks.
This paper proposes a distributed data-driven framework for dynamics learning, termed distributed deep Koopman learning using partial trajectories (DDKL-PT). In this framework, each agent in a multi-agent system is assigned a partial trajectory offline and locally approximates the unknown dynamics using a deep neural network within the Koopman operator framework. By exchanging local estimated dynamics rather than training data, agents achieve consensus on a global dynamics model without sharing their private training trajectories. Simulation studies on a surface vehicle demonstrate that DDKL-PT achieves consensus on the learned dynamics, and each agent attains reasonably small approximation errors on the testing dataset. Furthermore, a model predictive control scheme is developed by integrating the learned Koopman dynamics with known kinematic relations. Results on a reference-tracking task indicate that the distributedly learned dynamics are sufficiently accurate for model-based optimal control.