A Bayesian Approach for Discovering Time- Delayed Differential Equation from Data (2501.02934v1)

Abstract: Time-delayed differential equations (TDDEs) are widely used to model complex dynamic systems where future states depend on past states with a delay. However, inferring the underlying TDDEs from observed data remains a challenging problem due to the inherent nonlinearity, uncertainty, and noise in real-world systems. Conventional equation discovery methods often exhibit limitations when dealing with large time delays, relying on deterministic techniques or optimization-based approaches that may struggle with scalability and robustness. In this paper, we present BayTiDe - Bayesian Approach for Discovering Time-Delayed Differential Equations from Data, that is capable of identifying arbitrarily large values of time delay to an accuracy that is directly proportional to the resolution of the data input to it. BayTiDe leverages Bayesian inference combined with a sparsity-promoting discontinuous spike-and-slab prior to accurately identify time-delayed differential equations. The approach accommodates arbitrarily large time delays with accuracy proportional to the input data resolution, while efficiently narrowing the search space to achieve significant computational savings. We demonstrate the efficiency and robustness of BayTiDe through a range of numerical examples, validating its ability to recover delayed differential equations from noisy data.

• The paper introduces the BayTiDe framework, which accurately discovers time-delayed differential equations from noisy data using Bayesian inference.
• It employs a spike-and-slab prior to promote sparsity and adaptively determines time delays, significantly enhancing computational efficiency and robustness.
• Numerical tests on diverse systems, including the Mackey-Glass model, demonstrate that BayTiDe outperforms traditional methods in recovering complex dynamics.

A Bayesian Framework for Discovering Time-Delayed Differential Equations from Data

The paper introduces BayTiDe, a comprehensive Bayesian framework designed for deducing governing time-delayed differential equations (TDDEs) from data characterized by noise and nonlinearity. Time-delayed systems are widespread in diverse domains such as neuroscience, epidemiology, and economics, where future states depend on past conditions with inherent delays. Traditional equation discovery methods struggle with such systems due to challenges posed by large time delays, scalability issues, and data noise. Leveraging Bayesian inference, BayTiDe enhances the ability to identify TDDEs effectively, regardless of the magnitude of the delay, while also being computationally efficient.

Core Methodology and Contributions

The paper proposes the BayTiDe framework, which implements a novel Bayesian approach to tackle time-delayed differential systems. Key innovations encompass an efficient representation of the search space, an ability to deal with significant delays, and an integrated mechanism for noise robustness. A few highlights include:

• Bayesian Inference and Sparsity: The framework utilizes Bayesian inference with a sparsity-promoting spike-and-slab prior. This combination enables the accurate identification of the system dynamics by narrowing down the candidate functions and eliminating unnecessary complexity, which is crucial for robustness and interpretability.
• Adaptive Time Delay Determination: BayTiDe treats time delays as random variables, allowing for their adaptive determination as part of the algorithm itself. The approach employs a discontinuous spike-and-slab prior, which efficiently reduces the search space and focuses computational resources on the most plausible parameter estimates.
• Numerical Validation: The paper validates BayTiDe using multiple numerical examples, including exponential systems, the Mackey-Glass system, and coupled linear systems. The framework demonstrated consistent efficacy in recovering delayed differential equations from noisy data. The results showcase that BayTiDe can manage a wide range of scenarios, including large time delays and complex nonlinear relationships in the data. Additionally, the method displays superior error tolerance compared to traditional methods such as SINDy, even when exact delays are supplied to SINDy.

Broader Implications and Future Directions

The proposed framework provides a significant step toward developing automated methodologies for deducing the mathematical foundations of systems subject to time delays. In terms of practical implications, BayTiDe can benefit fields that require predictive modeling and system identification under uncertainty and time-lagged dynamics. This includes not only theoretical endeavors but also applications in engineering systems monitoring, biological feedback systems, and economic forecasting models.

Theoretically, the paper opens avenues for enhancing Bayesian methods in control and systems identification technologies, especially as systems continue to grow more complex and as data availability constraints vary across applications. Future advancements could explore extending the framework to handle multi-variate, time-dependent, or even unknown delays in a model-free context, potentially integrating deep learning-based prior insights.

Conclusively, BayTiDe's framework contributes a robust toolset to the toolkit of dynamic system theorists and engineers, promoting both deepened understanding and real-world application readiness across numerous fields reliant on dynamic modeling of delayed systems.