Bootstrap Inference for Hawkes and General Point Processes

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Bootstrap Inference for Hawkes and General Point Processes. / Cavaliere, Giuseppe; Lu, Ye; Rahbek, Anders; Østergaard, Jacob.

In: Journal of Econometrics, Vol. 235, No. 1, 2023, p. 133-165.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Cavaliere, G, Lu, Y, Rahbek, A & Østergaard, J 2023, 'Bootstrap Inference for Hawkes and General Point Processes', Journal of Econometrics, vol. 235, no. 1, pp. 133-165. https://doi.org/10.1016/j.jeconom.2022.02.006

APA

Cavaliere, G., Lu, Y., Rahbek, A., & Østergaard, J. (2023). Bootstrap Inference for Hawkes and General Point Processes. Journal of Econometrics, 235(1), 133-165. https://doi.org/10.1016/j.jeconom.2022.02.006

Vancouver

Cavaliere G, Lu Y, Rahbek A, Østergaard J. Bootstrap Inference for Hawkes and General Point Processes. Journal of Econometrics. 2023;235(1):133-165. https://doi.org/10.1016/j.jeconom.2022.02.006

Author

Cavaliere, Giuseppe ; Lu, Ye ; Rahbek, Anders ; Østergaard, Jacob. / Bootstrap Inference for Hawkes and General Point Processes. In: Journal of Econometrics. 2023 ; Vol. 235, No. 1. pp. 133-165.

Bibtex

@article{0d85ddf304b942b199ec8ec37cf2ffa9,
title = "Bootstrap Inference for Hawkes and General Point Processes",
abstract = "Inference and testing in general point process models such as the Hawkes model is predominantly based on asymptotic approximations for likelihood-based estimators and tests. As an alternative, and to improve finite sample performance, this paper considers bootstrap-based inference for interval estimation and testing. Specifically, for a wide class of point process models we consider a novel bootstrap scheme labeled {\textquoteleft}fixed intensity bootstrap{\textquoteright} (FIB), where the conditional intensity is kept fixed across bootstrap repetitions. The FIB, which is very simple to implement and fast in practice, extends previous ideas from the bootstrap literature on time series in discrete time, where the so-called {\textquoteleft}fixed design{\textquoteright} and {\textquoteleft}fixed volatility{\textquoteright} bootstrap schemes have shown to be particularly useful and effective. We compare the FIB with the classic recursive bootstrap, which is here labeled {\textquoteleft}recursive intensity bootstrap{\textquoteright} (RIB). In RIB algorithms, the intensity is stochastic in the bootstrap world and implementation of the bootstrap is more involved, due to its sequential structure. For both bootstrap schemes, we provide new bootstrap (asymptotic) theory which allows to assess bootstrap validity, and propose a {\textquoteleft}non-parametric{\textquoteright} approach based on resampling time-changed transformations of the original waiting times. We also establish the link between the proposed bootstraps for point process models and the related autoregressive conditional duration (ACD) models. Lastly, we show effectiveness of the different bootstrap schemes in finite samples through a set of detailed Monte Carlo experiments, and provide applications to both financial data and social media data to illustrate the proposed methodology.",
keywords = "Faculty of Social Sciences, Bootstrap Theory, Hawkes processes, Point processes, Twitter Data, Power law model, ACD models",
author = "Giuseppe Cavaliere and Ye Lu and Anders Rahbek and Jacob {\O}stergaard",
year = "2023",
doi = "10.1016/j.jeconom.2022.02.006",
language = "English",
volume = "235",
pages = "133--165",
journal = "Journal of Econometrics",
issn = "0304-4076",
publisher = "Elsevier",
number = "1",

}

RIS

TY - JOUR

T1 - Bootstrap Inference for Hawkes and General Point Processes

AU - Cavaliere, Giuseppe

AU - Lu, Ye

AU - Rahbek, Anders

AU - Østergaard, Jacob

PY - 2023

Y1 - 2023

N2 - Inference and testing in general point process models such as the Hawkes model is predominantly based on asymptotic approximations for likelihood-based estimators and tests. As an alternative, and to improve finite sample performance, this paper considers bootstrap-based inference for interval estimation and testing. Specifically, for a wide class of point process models we consider a novel bootstrap scheme labeled ‘fixed intensity bootstrap’ (FIB), where the conditional intensity is kept fixed across bootstrap repetitions. The FIB, which is very simple to implement and fast in practice, extends previous ideas from the bootstrap literature on time series in discrete time, where the so-called ‘fixed design’ and ‘fixed volatility’ bootstrap schemes have shown to be particularly useful and effective. We compare the FIB with the classic recursive bootstrap, which is here labeled ‘recursive intensity bootstrap’ (RIB). In RIB algorithms, the intensity is stochastic in the bootstrap world and implementation of the bootstrap is more involved, due to its sequential structure. For both bootstrap schemes, we provide new bootstrap (asymptotic) theory which allows to assess bootstrap validity, and propose a ‘non-parametric’ approach based on resampling time-changed transformations of the original waiting times. We also establish the link between the proposed bootstraps for point process models and the related autoregressive conditional duration (ACD) models. Lastly, we show effectiveness of the different bootstrap schemes in finite samples through a set of detailed Monte Carlo experiments, and provide applications to both financial data and social media data to illustrate the proposed methodology.

AB - Inference and testing in general point process models such as the Hawkes model is predominantly based on asymptotic approximations for likelihood-based estimators and tests. As an alternative, and to improve finite sample performance, this paper considers bootstrap-based inference for interval estimation and testing. Specifically, for a wide class of point process models we consider a novel bootstrap scheme labeled ‘fixed intensity bootstrap’ (FIB), where the conditional intensity is kept fixed across bootstrap repetitions. The FIB, which is very simple to implement and fast in practice, extends previous ideas from the bootstrap literature on time series in discrete time, where the so-called ‘fixed design’ and ‘fixed volatility’ bootstrap schemes have shown to be particularly useful and effective. We compare the FIB with the classic recursive bootstrap, which is here labeled ‘recursive intensity bootstrap’ (RIB). In RIB algorithms, the intensity is stochastic in the bootstrap world and implementation of the bootstrap is more involved, due to its sequential structure. For both bootstrap schemes, we provide new bootstrap (asymptotic) theory which allows to assess bootstrap validity, and propose a ‘non-parametric’ approach based on resampling time-changed transformations of the original waiting times. We also establish the link between the proposed bootstraps for point process models and the related autoregressive conditional duration (ACD) models. Lastly, we show effectiveness of the different bootstrap schemes in finite samples through a set of detailed Monte Carlo experiments, and provide applications to both financial data and social media data to illustrate the proposed methodology.

KW - Faculty of Social Sciences

KW - Bootstrap Theory

KW - Hawkes processes

KW - Point processes

KW - Twitter Data

KW - Power law model

KW - ACD models

U2 - 10.1016/j.jeconom.2022.02.006

DO - 10.1016/j.jeconom.2022.02.006

M3 - Journal article

VL - 235

SP - 133

EP - 165

JO - Journal of Econometrics

JF - Journal of Econometrics

SN - 0304-4076

IS - 1

ER -

ID: 298121803