pith. sign in

Pulsar timing arrays as imaging gravitational wave telescopes: angular resolution and source (de)confusion

4 Pith papers cite this work. Polarity classification is still indexing.

4 Pith papers citing it
abstract

Pulsar timing arrays (PTAs) will be sensitive to a finite number of gravitational wave (GW) "point" sources (e.g. supermassive black hole binaries). N quiet pulsars with accurately known distances d_{pulsar} can characterize up to 2N/7 distant chirping sources per frequency bin \Delta f_{gw}=1/T, and localize them with "diffraction limited" precision \delta\theta \gtrsim (1/SNR)(\lambda_{gw}/d_{pulsar}). Even if the pulsar distances are poorly known, a PTA with F frequency bins can still characterize up to (2N/7)[1-(1/2F)] sources per bin, and the quasi-singular pattern of timing residuals in the vicinity of a GW source still allows the source to be localized quasi-topologically within roughly the smallest quadrilateral of quiet pulsars that encircles it on the sky, down to a limiting resolution \delta\theta \gtrsim (1/SNR) \sqrt{\lambda_{gw}/d_{pulsar}}. PTAs may be unconfused, even at the lowest frequencies, with matched filtering always appropriate.

citation-role summary

background 1

citation-polarity summary

years

2026 1 2025 3

verdicts

UNVERDICTED 4

roles

background 1

polarities

background 1

clear filters

representative citing papers

Testing General Relativity with Individual Supermassive Black Hole Binaries

gr-qc · 2026-05-06 · unverdicted · novelty 6.0

A framework is developed to test beyond-GR effects in nanohertz continuous waves from individual SMBHBs, deriving modified inter-pulsar correlations, antenna responses, and phase delays for three deviation classes, validated by injection-recovery simulations showing parameter recovery and no GR bias

citing papers explorer

Showing 1 of 1 citing paper after filters.

  • Testing General Relativity with Individual Supermassive Black Hole Binaries gr-qc · 2026-05-06 · unverdicted · none · ref 70

    A framework is developed to test beyond-GR effects in nanohertz continuous waves from individual SMBHBs, deriving modified inter-pulsar correlations, antenna responses, and phase delays for three deviation classes, validated by injection-recovery simulations showing parameter recovery and no GR bias