Quasi-Likelihood for Spatial Point Processes

Guan, Yongtao; Jalilian, Abdollah; Waagepetersen, Rasmus

doi:10.1111/rssb.12083

Cited by 34 publications

(38 citation statements)

References 29 publications

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“…This approach has been widely adopted in many previous articles. Examples include Guan and Loh (2007), Guan and Shen (2010), Waagepetersen andGuan (2009), Guan, Jalilian, andWaagepetersen (2015), Prekešová and Jensen (2013), and Schoenberg (2005).…”

Section: Asymptotic Distributionmentioning

confidence: 99%

Testing First-Order Spherical Symmetry of Spatial Point Processes

Zhang¹,

Mateu²

2020

STAT SINICA

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This article proposes a Kolmogorov-Smirnov-type test to assess spherical symmetry of the first-order intensity function of a spatial point process (SPP).Spherical symmetry, which is an important assumption in the well-known ETAS (epidemic type aftershock sequence) model, means that the intensity function of an SPP is invariant under a spherical transformation in an Euclidean space. An important property of first-order spherical symmetry is that the expected number of points within a sector region is proportional to the angle measure of the region.This provides a way to construct our test statistic. The asymptotic distribution of the test statistic is obtained under the framework of increasing domain asymptotics with weak dependence. We show that the resulting test statistic converges weakly to the absolute maximum of a zero mean Gaussian process under the null hypothesis and it is also consistent under the alternative hypothesis. A simulation study shows that the type I error probability of the test is close to the significance level, and the power increases to one as the magnitude of non-spherical symmetry increases.In an application of the ETAS model to Japan earthquakes, the article concludes that the first-order spherical symmetry assumption can be roughly accepted.

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Section: Asymptotic Distributionmentioning

confidence: 99%

Testing First-Order Spherical Symmetry of Spatial Point Processes

Zhang¹,

Mateu²

2020

STAT SINICA

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“…The case p = 1 is relevant if interest is focused on estimation of the intensity function

λ_{θ} false(u false) = ρ_{θ}^{false(1 false)}

. Several papers have discussed choices of h and studied asymptotic properties of

{\overset{θ}{true}}_{n}

for the case p = 1 (see, for instance, Guan et al, ; Guan & Shen, ; Waagepetersen, ). A popular and simple choice is h θ ( u ) = ∇ θ λ θ ( u )/ λ θ ( u ), where ∇ θ denotes the gradient with respect to θ .…”

Section: Variance Estimation For Estimating Functionsmentioning

confidence: 99%

“…One approach uses Bernstein's blocking technique and a telescoping argument that goes back to Ibragimov and Linnik (, Chapter 18, Section 4). This approach has been used in a number of papers such as Guan and Sherman (); Guan and Loh (); Prokešová and Jensen (); Guan, Jalilian, and Waagepetersen (); and Xu, Waagepetersen, and Guan (). The other approach is due to Bolthausen () who considered stationary random fields and whose proof was later generalised to nonstationary random fields by Guyon () and Karácsony ().…”

Section: Introductionmentioning

confidence: 99%

A general central limit theorem and a subsampling variance estimator for α‐mixing point processes

Biscio

Waagepetersen

2019

Scandinavian J Statistics

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We establish a central limit theorem for multivariate summary statistics of nonstationary α‐mixing spatial point processes and a subsampling estimator of the covariance matrix of such statistics. The central limit theorem is crucial for establishing asymptotic properties of estimators in statistics for spatial point processes. The covariance matrix subsampling estimator is flexible and model free. It is needed, for example, to construct confidence intervals and ellipsoids based on asymptotic normality of estimators. We also provide a simulation study investigating an application of our results to estimating functions.

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“…Besag, 1977;Fiksel, 1984;Takacs, 1986;Jensen & Møller, 1991;Billiot, 1997;Baddeley & Turner, 2000;Billiot et al, 2008;Coeurjolly et al, 2012) and various types of minimum contrast, composite likelihood, Palm likelihood and estimating functions for Cox and cluster processes and DPPs (e.g. Schoenberg, 2005;Guan, 2006;Waagepetersen, 2007;Tanaka et al, 2008;Waagepetersen & Guan, 2009;Prokešová & Jensen, 2013;Prokešová et al, 2014;Guan et al, 2015;Zhuang, 2015;Lavancier et al, 2014Lavancier et al, , 2015. As discussed in Sections 4.1-4.3, all of these methods belong to a common framework of estimating functions based on signed innovation measures Waagepetersen, 2005;Zhuang, 2006).…”

Section: Estimationmentioning

confidence: 99%

Some Recent Developments in Statistics for Spatial Point Patterns

Møller

Waagepetersen

2017

Annu. Rev. Stat. Appl.

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This paper reviews developments in statistics for spatial point processes obtained within roughly the last decade. These developments include new classes of spatial point process models such as determinantal point processes, models incorporating both regularity and aggregation, and models where points are randomly distributed around latent geometric structures. Regarding parametric inference the main focus is on various types of estimating functions derived from so-called innovation measures. Optimality of such estimating functions is discussed as well as computational issues. Maximum likelihood inference for determinantal point processes and Bayesian inference are briefly considered too. Concerning non-parametric inference, we consider extensions of functional summary statistics to the case of inhomogeneous point processes as well as new approaches to simulation based inference.

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Quasi-Likelihood for Spatial Point Processes

Cited by 34 publications

References 29 publications

Testing First-Order Spherical Symmetry of Spatial Point Processes

Testing First-Order Spherical Symmetry of Spatial Point Processes

A general central limit theorem and a subsampling variance estimator for α‐mixing point processes

Some Recent Developments in Statistics for Spatial Point Patterns

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