Rapid parameter estimation of discrete decaying signals using autoencoder networks
In this work we demonstrate the use of autoencoder networks for rapid extraction of the signal parameters of discretely sampled signals. In particular, we use dense autoencoder networks to extract the parameters of interest from exponentially decaying signals and decaying oscillations. Using a three-stage training method and careful choice of the neural network size, we are able to retrieve the relevant signal parameters directly from the latent space of the autoencoder network at significantly improved rates compared to traditional algorithmic signal-analysis approaches. We show that the achievable precision and accuracy of this method of analysis is similar to conventional, algorithm-based signal analysis methods, by demonstrating that, the extracted signal parameters are approaching their fundamental parameter estimation limit as provided by the Cramér-Rao lower bound. Furthermore, we demonstrate that autoencoder networks are able to achieve signal analysis, and, hence, parameter extraction, at rates of 75 kHz, orders-of-magnitude faster than conventional techniques with equal precision. Finally, we explore the limitations of our approach, demonstrating that analysis rates of >200 kHz are feasible with further optimization of the transfer rate between the data-acquisition system and data-analysis system.
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