ACTA

Classification and Prediction of Wave Chaotic Systems with Machine Learning Techniques

S. Ma^a, B. Xiao^b, R. Hong^c, B.D. Addissie^c, Z.B. Drikas^c, T.M. Antonsen^{a, b}, E. Ott^{a, b}, S.M. Anlage^{a, b}
^aDepartment of Physics, University of Maryland, College Park, Maryland 20742-4111, USA
^bDepartment of Electrical and Computer Engineering, University of Maryland, College Park, Maryland 20742-3285, USA
^cU.S. Naval Research Laboratory, Washington, DC 20375, USA

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The wave properties of complex scattering systems that are large compared to the wavelength, and show chaos in the classical limit, are extremely sensitive to system details. A solution to the wave equation for a specific configuration can change substantially under small perturbations. Due to this extreme sensitivity, it is difficult to discern basic information about a complex system simply from scattering data as a function of energy or frequency, at least by eye. In this work, we employ supervised machine learning algorithms to reveal and classify hidden information about the complex scattering system presented in the data. As an example we are able to distinguish the total number of connected cavities in a linear chain of weakly coupled lossy enclosures from measured reflection data. A predictive machine learning algorithm for the future states of a perturbed complex scattering system is also trained with a recurrent neural network. Given a finite training data series, the reflection/transmission properties can be forecast by the proposed algorithm.

DOI:10.12693/APhysPolA.136.757
topics: wave chaotic system, machine learning, neural network