2018
DOI: 10.1007/s11222-018-9843-1
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An approximate fractional Gaussian noise model with $$\mathcal {O}(n)$$ O ( n ) computational cost

Abstract: Fractional Gaussian noise (fGn) is a stationary time series model with long memory properties applied in various fields like econometrics, hydrology and climatology. The computational cost in fitting an fGn model of length n using a likelihood-based approach is O(n 2), exploiting the Toeplitz structure of the covariance matrix. In most realistic cases, we do not observe the fGn process directly but only through indirect Gaussian observations, so the Toeplitz structure is easily lost and the computational cost … Show more

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Cited by 9 publications
(4 citation statements)
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“…Clearly, there is a slight discrepancy at high frequencies between the two spectra. Indeed, a fGn can only be approximated as a sum of k AR processes of first order (Sørbye et al 2019). This sum is itself modellable as an autoregressive process with moving average (ARMA) of order (k, k − 1) for the AR and MA components, respectively.…”
Section: Discussionmentioning
confidence: 99%
“…Clearly, there is a slight discrepancy at high frequencies between the two spectra. Indeed, a fGn can only be approximated as a sum of k AR processes of first order (Sørbye et al 2019). This sum is itself modellable as an autoregressive process with moving average (ARMA) of order (k, k − 1) for the AR and MA components, respectively.…”
Section: Discussionmentioning
confidence: 99%
“…This is not the case when the noise term ǫ is fGn having an LRD structure, but the precision matrix of an AR1 process is tridiagonal. In Sørbye et al (2019), the fGn process is approximated using a weighted sum of AR1 processes where the weights and the first-lag autocorrelation coefficients of the approximation are optimized such that the covariance function of the approximation matches the exact covariance function of fGn defined in Equation 4. The latent field x is extended to include the AR(1) components that make up the approximation.…”
Section: Bayesian Inferencementioning
confidence: 99%
“…Second, due to the LRD assumption, the precision matrix, defined as the inverse covariance matrix, is dense and therefore unsuited for the computationally efficient algorithms that INLA applies. In order to retain sparsity we have to introduce an approximation such as that introduced by Sørbye et al (2019). The model with these modifications are available in the R-package INLA.climate which can be downloaded from the GitHub repository eirikmn/INLA.climate.…”
Section: Data Availabilitymentioning
confidence: 99%
“…First, the LRD properties of the fGn process make the precision matrix of the latent field dense. To ensure computational efficiency, this is circumvented by approximating the fGn as a weighted sum of four AR(1) processes as introduced in [27]. Second, the mean of the observation vector, E(∆T) = σ f G(β) (F 0 + F) has a non-standard form.…”
Section: Parameter Estimationmentioning
confidence: 99%