Beecroft Institute for Particle Astrophysics and Cosmology

Cosmic evolution of black hole-spin and galaxy orientations: clues from the NewHorizon and Galactica simulations

(2024)

Authors:

Sebastien Peirani, Yasushi Suto, Ricarda S Beckmann, Marta Volonteri, Yen-Ting Lin, Yohan Dubois, Sukyoung K Yi, Christophe Pichon, Katarina Kraljic, Minjung Park, Julien Devriendt, San Han, Wei-Huai Chen

The origin of the H$α$ line profiles in simulated disc galaxies

ArXiv 2401.0416 (2024)

Authors:

Timmy Ejdetjärn, Oscar Agertz, Göran Östlin, Martin P Rey, Florent Renaud

The Inefficiency of Genetic Programming for Symbolic Regression

Chapter in Parallel Problem Solving from Nature – PPSN XVIII, Springer Nature 15148 (2024) 273-289

Authors:

Gabriel Kronberger, Fabricio Olivetti de Franca, Harry Desmond, Deaglan J Bartlett, Lukas Kammerer

A deep neural network based reverse radio spectrogram search algorithm

RAS Techniques and Instruments Oxford University Press 3:1 (2023) 33-43

Authors:

Peter Xiangyuan Ma, Steve Croft, Chris Lintott, Andrew PV Siemion

Abstract:

Modern radio astronomy instruments generate vast amounts of data, and the increasingly challenging radio frequency interference (RFI) environment necessitates ever-more sophisticated RFI rejection algorithms. The ‘needle in a haystack’ nature of searches for transients and technosignatures requires us to develop methods that can determine whether a signal of interest has unique properties, or is a part of some larger set of pernicious RFI. In the past, this vetting has required onerous manual inspection of very large numbers of signals. In this paper, we present a fast and modular deep learning algorithm to search for lookalike signals of interest in radio spectrogram data. First, we trained a β-variational autoencoder on signals returned by an energy detection algorithm. We then adapted a positional embedding layer from classical transformer architecture to a embed additional metadata, which we demonstrate using a frequency-based embedding. Next we used the encoder component of the β-variational autoencoder to extract features from small (∼715 Hz, with a resolution of 2.79 Hz per frequency bin) windows in the radio spectrogram. We used our algorithm to conduct a search for a given query (encoded signal of interest) on a set of signals (encoded features of searched items) to produce the top candidates with similar features. We successfully demonstrate that the algorithm retrieves signals with similar appearance, given only the original radio spectrogram data. This algorithm can be used to improve the efficiency of vetting signals of interest in technosignature searches, but could also be applied to a wider variety of searches for ‘lookalike’ signals in large astronomical data sets.

Glueball dark matter

Physical Review D American Physical Society (APS) 108:12 (2023) 123027

Authors:

Pierluca Carenza, Tassia Ferreira, Roman Pasechnik, Zhi-Wei Wang