Abstract
Modeling nonstationary processes is of paramount importance to many scientific disciplines including environmental science, ecology, and finance, among others. Consequently, flexible methodology that provides accurate estimation across a wide range of processes is a subject of ongoing interest. We propose a novel approach to model-based time–frequency estimation using time-varying autoregressive models. In this context, we take a fully Bayesian approach and allow both the autoregressive coefficients and innovation variance to vary over time. Importantly, our estimation method uses the lattice filter and is cast within the partial autocorrelation domain. The marginal posterior distributions are of standard form and, as a convenient by-product of our estimation method, our approach avoids undesirable matrix inversions. As such, estimation is extremely computationally efficient and stable. To illustrate the effectiveness of our approach, we conduct a comprehensive simulation study that compares our method with other competing methods and find that, in most cases, our approach performs superior in terms of average squared error between the estimated and true time-varying spectral density. Lastly, we demonstrate our methodology through three modeling applications; namely, insect communication signals, environmental data (wind components), and macroeconomic data (US gross domestic product (GDP) and consumption).
Highlights
Recent advances in technology have lead to the extensive collection of complex high-frequency nonstationary signals across a wide array of scientific disciplines
The time-varying autoregressive (TVAR) model corresponds to a nonstationary AR model with the AR coefficients and variances evolving through time
Because this model generally allows both slow and rapid changes in the parameters, it can flexibly model the stochastic pattern changes often exhibited by complex nonstationary signals
Summary
Recent advances in technology have lead to the extensive collection of complex high-frequency nonstationary signals across a wide array of scientific disciplines. Model-based approaches typically proceed through the time-domain in order to produce a time-frequency representation for a given nonstationary signal In this setting common approaches include fitting piecewise autoregressive (AR) models as well as time-varying autoregressive (TVAR) models. At each stage of the lattice filter, they assume that the residual at each time between the forward and backward prediction errors follows a Cauchy distribution, and that the PARCOR coefficient is modeled as a Gaussian random walk This produces a non-Gaussian state space model at each stage and a numeric algorithm is conducted for estimation. One novel aspect of our approach is that we model both the PARCOR coefficients and the TVAR innovation variances within the lattice structure and estimate them simultaneously This is different from the frequentist twostage method of Kitagawa (1988) and Kitagawa and Gersch (1996). Details surrounding the estimation algorithms and additional figures are left to an Appendix
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