Identifying Dynamic Regulation with Adversarial Surrogates

Homeostasis, the ability to maintain a stable internal environment in the face of perturbations, is essential for the functioning of living systems. Given observations of a system, or even a detailed model of one, it is both valuable and extremely challenging to extract the control objectives of the homeostatic mechanisms. Lacking a clear separation between plant and controller, frameworks such as inverse optimal control and inverse reinforcement learning are unable to identify the homeostatic mechanisms. A recently developed data-driven algorithm, Identifying Regulation with Adversarial Surrogates (IRAS), detects highly regulated or conserved quantities as the solution of a min-max optimization scheme that automates classical surrogate data methods. Yet, the definition of homeostasis as regulation within narrow limits is too strict for biological systems which show sustained oscillations such as circadian rhythms. In this work, we introduce Identifying Dynamic Regulation with Adversarial Surrogates (IDRAS), a generalization of the IRAS algorithm, capable of identifying control objectives that are regulated with respect to a dynamical reference value. We test the algorithm on simulation data from realistic biological models and benchmark physical systems, demonstrating excellent empirical results.