Rubin-LSST

The Simons Observatory: validation of reconstructed power spectra from simulated filtered maps for the small aperture telescope survey

Journal of Cosmology and Astroparticle Physics IOP Publishing 2025:06 (2025) 055

Authors:

Carlos Hervías-Caimapo, Kevin Wolz, Adrien La Posta, Susanna Azzoni, David Alonso, Kam Arnold, Carlo Baccigalupi, Simon Biquard, Michael L Brown, Erminia Calabrese, Yuji Chinone, Samuel Day-Weiss, Jo Dunkley, Rolando Dünner, Josquin Errard, Giulio Fabbian, Ken Ganga, Serena Giardiello, Emilie Hertig, Kevin M Huffenberger, Bradley R Johnson, Baptiste Jost, Reijo Keskitalo, Theodore S Kisner

Abstract:

We present a transfer function-based method to estimate angular power spectra from filtered maps for cosmic microwave background (CMB) surveys. This is especially relevant for experiments targeting the faint primordial gravitational wave signatures in CMB polarisation at large scales, such as the Simons Observatory (SO) small aperture telescopes. While timestreams can be filtered to mitigate the contamination from low-frequency noise, usual methods that calculate the mode coupling at individual multipoles can be challenging for experiments covering large sky areas or reaching few-arcminute resolution. The method we present here, although approximate, is more practical and faster for larger data volumes. We validate it through the use of simulated observations approximating the first year of SO data, going from half-wave plate-modulated timestreams to maps, and using simulations to estimate the mixing of polarisation modes induced by an example of time-domain filtering. We show its performance through an example null test and with an end-to-end pipeline that performs inference on cosmological parameters, including the tensor-to-scalar ratio r. The performance demonstration uses simulated observations at multiple frequency bands. We find that the method can recover unbiased parameters for our simulated noise levels.

The Simons Observatory: Validation of reconstructed power spectra from simulated filtered maps for the Small Aperture Telescope survey

(2025)

Authors:

Carlos Hervías-Caimapo, Kevin Wolz, Adrien La Posta, Susanna Azzoni, David Alonso, Kam Arnold, Carlo Baccigalupi, Simon Biquard, Michael L Brown, Erminia Calabrese, Yuji Chinone, Samuel Day-Weiss, Jo Dunkley, Rolando Dünner, Josquin Errard, Giulio Fabbian, Ken Ganga, Serena Giardiello, Emilie Hertig, Kevin M Huffenberger, Bradley R Johnson, Baptiste Jost, Reijo Keskitalo, Theodore S Kisner, Thibaut Louis, Magdy Morshed, Lyman A Page, Christian L Reichardt, Erik Rosenberg, Max Silva-Feaver, Wuhyun Sohn, Yoshinori Sueno, Dan B Thomas, Ema Tsang King Sang, Amalia Villarrubia-Aguilar, Kyohei Yamada

Accelerating Long-period Exoplanet Discovery by Combining Deep Learning and Citizen Science

Astronomical Journal American Astronomical Society 170:1 (2025) 39

Authors:

Shreshth A Malik, Nora L Eisner, Ian R Mason, Sofia Platymesi, Suzanne Aigrain, Stephen J Roberts, Yarin Gal, Chris J Lintott

Abstract:

Automated planetary transit detection has become vital to identify and prioritize candidates for expert analysis and verification given the scale of modern telescopic surveys. Current methods for short-period exoplanet detection work effectively due to periodicity in the transit signals, but a robust approach for detecting single-transit events is lacking. However, volunteer-labeled transits collected by the Planet Hunters TESS (PHT) project now provide an unprecedented opportunity to investigate a data-driven approach to long-period exoplanet detection. In this work, we train a 1D convolutional neural network to classify planetary transits using PHT volunteer scores as training data. We find that this model recovers planet candidates (TESS objects of interest; TOIs) at a precision and recall rate exceeding those of volunteers, with a 20% improvement in the area under the precision-recall curve and 10% more TOIs identified in the top 500 predictions on average per sector. Importantly, the model also recovers almost all planet candidates found by volunteers but missed by current automated methods (PHT community TOIs). Finally we retrospectively utilise the model to simulate live deployment in PHT to reprioritize candidates for analysis. We also find that multiple promising planet candidates, originally missed by PHT, would have been found using our approach, showing promise for upcoming real-world deployment.

Massive stars exploding in a He-rich circumstellar medium. XI. Diverse evolution of five Ibn SNe 2020nxt, 2020taz, 2021bbv, 2023utc and 2024aej

(2025)

Authors:

Z-Y Wang, A Pastorello, Y-Z Cai, M Fraser, A Reguitti, W-L Lin, L Tartaglia, D Andrew Howell, S Benetti, E Cappellaro, Z-H Chen, N Elias-Rosa, J Farah, A Fiore, D Hiramatsu, E Kankare, Z-T Li, P Lundqvist, PA Mazzali, C McCully, J Mo, S Moran, M Newsome, E Padilla Gonzalez, C Pellegrino, Z-H Peng, SJ Smartt, S Srivastav, MD Stritzinger, G Terreran, L Tomasella, G Valerin, G-J Wang, X-F Wang, T de Boer, KC Chambers, H Gao, F-Z Guo, CP Guti'errez, T Kangas, E Karamehmetoglu, G-C Li, C-C Lin, TB Lowe, X-R Ma, EA Magnier, P Minguez, S-P Pei, TM Reynolds, RJ Wainscoat, B Wang, S Williams, C-Y Wu, J-J Zhang, X-H Zhang, X-J Zhu

Thermal electrons in the radio afterglow of relativistic tidal disruption event ZTF22aaajecp/AT2022cmc

(2025)

Authors:

Lauren Rhodes, Ben Margalit, Joe S Bright, Hannah Dykaar, Rob Fender, David A Green, Daryl Haggard, Assaf Horesh, Alexander J van der Horst, Andrew Hughes, Kunal Mooley, Itai Sfaradi, David Titterington, David WIlliams-Baldwin