Asymptotic Variance of Newton–Cotes Quadratures Based on Randomized Sampling Points

Mads  Stehr; Markus Kiderlen

doi:10.1017/apr.2020.41

Asymptotic Variance of Newton–Cotes Quadratures Based on Randomized Sampling Points

Mads Stehr, Markus Kiderlen

Aarhus Universitet

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

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Abstract

We consider the problem of numerical integration when the sampling nodes form a stationary point process on the real line. In previous papers it was argued that a naïve Riemann sum approach can cause a severe variance inflation when the sampling points are not equidistant. We show that this inflation can be avoided using a higher-order Newton–Cotes quadrature rule which exploits smoothness properties of the integrand. Under mild assumptions, the resulting estimator is unbiased and its variance asymptotically obeys a power law as a function of the mean point distance. If the Newton–Cotes rule is of sufficiently high order, the exponent of this law turns out to only depend on the point process through its mean point distance. We illustrate our findings with the stereological estimation of the volume of a compact object, suggesting alternatives to the well-established Cavalieri estimator.

Originalsprog	Engelsk
Tidsskrift	Advances in Applied Probability
Vol/bind	52
Udgave nummer	4
Sider (fra-til)	1284-1307
Antal sider	24
ISSN	0001-8678
DOI	https://doi.org/10.1017/apr.2020.41
Status	Udgivet - dec. 2020
Udgivet eksternt	Ja

Emneord

Point process
Stationary stochastic process
Randomized Newton-Cotes quadrature
Numerical integration
Asymptotic variance bounds
Renewal process

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AB - We consider the problem of numerical integration when the sampling nodes form a stationary point process on the real line. In previous papers it was argued that a naïve Riemann sum approach can cause a severe variance inflation when the sampling points are not equidistant. We show that this inflation can be avoided using a higher-order Newton–Cotes quadrature rule which exploits smoothness properties of the integrand. Under mild assumptions, the resulting estimator is unbiased and its variance asymptotically obeys a power law as a function of the mean point distance. If the Newton–Cotes rule is of sufficiently high order, the exponent of this law turns out to only depend on the point process through its mean point distance. We illustrate our findings with the stereological estimation of the volume of a compact object, suggesting alternatives to the well-established Cavalieri estimator.

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