The NANOGrav 15-year Gravitational-Wave Background Methods

Aaron D. Johnson; Patrick M. Meyers; Paul T. Baker; Neil J. Cornish; Jeffrey S. Hazboun; Tyson B. Littenberg; Joseph D. Romano; Stephen R. Taylor; Michele Vallisneri; Sarah J. Vigeland; Ken D. Olum; Xavier Siemens; Justin A. Ellis; Rutger van Haasteren; Sophie Hourihane; Gabriella Agazie; Akash Anumarlapudi; Anne M. Archibald; Zaven Arzoumanian; Laura Blecha; Adam Brazier; Paul R. Brook; Sarah Burke-Spolaor; Bence B\'ecsy; J. Andrew Casey-Clyde; Maria Charisi; Shami Chatterjee; Katerina Chatziioannou; Tyler Cohen; James M. Cordes; Fronefield Crawford; H. Thankful Cromartie; Kathryn Crowter; Megan E. DeCesar; Paul B. Demorest; Timothy Dolch; Brendan Drachler; Elizabeth C. Ferrara; William Fiore; Emmanuel Fonseca; Gabriel E. Freedman; Nate Garver-Daniels; Peter A. Gentile; Joseph Glaser; Deborah C. Good; Kayhan G\"ultekin; Ross J. Jennings; Megan L. Jones; Andrew R. Kaiser; David L. Kaplan; Luke Zoltan Kelley; Matthew Kerr; Joey S. Key; Nima Laal; Michael T. Lam; William G. Lamb; T. Joseph W. Lazio; Natalia Lewandowska; Tingting Liu; Duncan R. Lorimer; Ryan S. Lynch; Chung-Pei Ma; Dustin R. Madison; Alexander McEwen; James W. McKee; Maura A. McLaughlin; Natasha McMann; Bradley W. Meyers; Chiara M. F. Mingarelli; Andrea Mitridate; Cherry Ng; David J. Nice; Stella Koch Ocker; Timothy T. Pennucci; Benetge B. P. Perera; Nihan S. Pol; Henri A. Radovan; Scott M. Ransom; Paul S. Ray; Shashwat C. Sardesai; Carl Schmiedekamp; Ann Schmiedekamp; Kai Schmitz; Brent J. Shapiro-Albert; Joseph Simon; Magdalena S. Siwek; Ingrid H. Stairs; Daniel R. Stinebring; Kevin Stovall; Abhimanyu Susobhanan; Joseph K. Swiggum; Jacob E. Turner; Caner Unal; Haley M. Wahl; Caitlin A. Witt; Olivia Young (for the NANOGrav Collaboration)

arXiv:2306.16223·astro-ph.HE·May 14, 2025

The NANOGrav 15-year Gravitational-Wave Background Methods

Aaron D. Johnson, Patrick M. Meyers, Paul T. Baker, Neil J. Cornish, Jeffrey S. Hazboun, Tyson B. Littenberg, Joseph D. Romano, Stephen R. Taylor, Michele Vallisneri, Sarah J. Vigeland, Ken D. Olum, Xavier Siemens, Justin A. Ellis, Rutger van Haasteren, Sophie Hourihane

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TL;DR

This paper rigorously tests and updates methods for detecting nanohertz gravitational waves using pulsar timing arrays, introducing a faster likelihood computation and validating analysis techniques over 15 years of data.

Contribution

It introduces a novel two-step marginalization likelihood method and provides comprehensive validation of PTA analysis techniques for gravitational wave background detection.

Findings

01

Validated current PTA analysis methods.

02

Introduced faster likelihood computation technique.

03

Confirmed consistency of Bayesian and frequentist approaches.

Abstract

Pulsar timing arrays (PTAs) use an array of millisecond pulsars to search for gravitational waves in the nanohertz regime in pulse time of arrival data. This paper presents rigorous tests of PTA methods, examining their consistency across the relevant parameter space. We discuss updates to the 15-year isotropic gravitational-wave background analyses and their corresponding code representations. Descriptions of the internal structure of the flagship algorithms Enterprise and PTMCMCSampler are given to facilitate understanding of the PTA likelihood structure, how models are built, and what methods are currently used in sampling the high-dimensional PTA parameter space. We introduce a novel version of the PTA likelihood that uses a two-step marginalization procedure that performs much faster in gravitational wave searches, reducing the required resources facilitating the computation of…

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