The Chebyshev Polynomial Series Frequency Modulation Model for Waveform Design and Analysis

Polynomial phase signals (PPS) are a staple of waveform design and analysis in sonar, radar, and communications fields. They also find application in the modeling of bioacoustic emissions, especially those of echolocating animals such as bats and odontocetes. This work presents a novel PPS waveform formulation that exploits some special properties of Chebyshev polynomials, such as orthogonality, recurrence relations, and equivalence to trigonometric functions. The result is the Chebyshev Polynomial Frequency Modulation (CPSFM) family of waveforms, which prove useful in the modeling of bioacoustic signals and the approximation of non-polynomial-phase signals such as hyperbolic chirps. We demonstrate that the CPSFM model admits compact analytic expressions for fundamental continuous-time signal processing functions such as the Fourier transform, the convolution and correlation operations, and the ambiguity function. Derivations for these expressions using CPSFM are presented, along with their application to the analysis of biosonar emissions of Mexican free-tailed bats.

System Identification Using the Signed Cumulative Distribution Transform In Structural Health Monitoring Applications

This paper presents a novel, data-driven approach to identifying partial differential equation (PDE) parameters of a dynamical system in structural health monitoring applications. Specifically, we adopt a mathematical "transport" model of the sensor data that allows us to accurately estimate the model parameters, including those associated with structural damage. This is accomplished by means of a newly-developed transform, the signed cumulative distribution transform (SCDT), which is shown to convert the general, nonlinear parameter estimation problem into a simple linear regression. This approach has the additional practical advantage of requiring no a priori knowledge of the source of the excitation (or, alternatively, the initial conditions). By using training sensor data, we devise a coarse regression procedure to recover different PDE parameters from a single sensor measurement. Numerical experiments show that the proposed regression procedure is capable of detecting and estimating PDE parameters with superior accuracy compared to a number of recently developed "Deep Learning" methods. The Python implementation of the proposed system identification technique is integrated as a part of the software package PyTransKit (https://github.com/rohdelab/PyTransKit).