Your search keyword '"Biggio L"' showing total 6 results

1. Time delay estimation in unresolved lensed quasars

Author

Biggio, L., Domi, A., Tosi, S., Vernardos, G., Ricci, D., Paganin, L., and Bracco, G.

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

Time-delay cosmography can be used to infer the Hubble parameter $H_0$ by measuring the relative time delays between multiple images of gravitationally-lensed quasars. A few of such systems have already been used to measure $H_0$: their time delays were determined from the multiple images light curves obtained by regular, years long, monitoring campaigns. Such campaigns can hardly be performed by any telescope: many facilities are often over-subscribed with a large amount of observational requests to fulfill. While the ideal systems for time-delay measurements are lensed quasars whose images are well resolved by the instruments, several lensed quasars have a small angular separation between the multiple images, and would appear as a single, unresolved, image to a large number of telescopes featuring poor angular resolutions or located in not privileged geographical locations. Methods allowing to infer the time delay also from unresolved light curves would boost the potential of such telescopes and greatly increase the available statistics for $H_0$ measurements. This work presents a study of unresolved lensed quasar systems to estimate the time delay using a deep learning-based approach that exploits the capabilities of one-dimensional convolutional neural networks. Experiments on state-of-the-art simulations of unresolved light curves show the potential of the proposed method and pave the way for future applications in time-delay cosmography.

Published

2021

2. Accelerating galaxy dynamical modeling using a neural network for joint lensing and kinematic analyses

Author

Gomer, M. R., primary, Ertl, S., additional, Biggio, L., additional, Wang, H., additional, Galan, A., additional, Van de Vyvere, L., additional, Sluse, D., additional, Vernardos, G., additional, and Suyu, S. H., additional

Published

2023

3. Modeling lens potentials with continuous neural fields in galaxy-scale strong lenses

Author

Biggio, L., primary, Vernardos, G., additional, Galan, A., additional, Peel, A., additional, and Courbin, F., additional

Published

2023

4. Time-delay estimation in unresolved lensed quasars

Author

Biggio, L, primary, Domi, A, additional, Tosi, S, additional, Vernardos, G, additional, Ricci, D, additional, Paganin, L, additional, and Bracco, G, additional

Published

2022

5. GEMTELLIGENCE: Accelerating gemstone classification with deep learning.

Author

Bendinelli T, Biggio L, Nyfeler D, Ghosh A, Tollan P, Kirschmann MA, and Fink O

Abstract

The value of luxury goods, particularly investment-grade gemstones, is influenced by their origin and authenticity, often resulting in differences worth millions of dollars. Traditional methods for determining gemstone origin and detecting treatments involve subjective visual inspections and a range of advanced analytical techniques. However, these approaches can be time-consuming, prone to inconsistencies, and lack automation. Here, we propose GEMTELLIGENCE, a novel deep learning approach enabling streamlined and consistent origin determination of gemstone origin and detection of treatments. GEMTELLIGENCE leverages convolutional and attention-based neural networks that combine the multi-modal heterogeneous data collected from multiple instruments. The algorithm attains predictive performance comparable to expensive laser-ablation inductively-coupled-plasma mass-spectrometry analysis and expert visual examination, while using input data from relatively inexpensive analytical methods. Our methodology represents an advancement in gemstone analysis, greatly enhancing automation and robustness throughout the analytical process pipeline., (© 2024. The Author(s).)

Published

2024

6. Prognostics and Health Management of Industrial Assets: Current Progress and Road Ahead.

Author

Biggio L and Kastanis I

Abstract

Prognostic and Health Management (PHM) systems are some of the main protagonists of the Industry 4.0 revolution. Efficiently detecting whether an industrial component has deviated from its normal operating condition or predicting when a fault will occur are the main challenges these systems aim at addressing. Efficient PHM methods promise to decrease the probability of extreme failure events, thus improving the safety level of industrial machines. Furthermore, they could potentially drastically reduce the often conspicuous costs associated with scheduled maintenance operations. The increasing availability of data and the stunning progress of Machine Learning (ML) and Deep Learning (DL) techniques over the last decade represent two strong motivating factors for the development of data-driven PHM systems. On the other hand, the black-box nature of DL models significantly hinders their level of interpretability, de facto limiting their application to real-world scenarios. In this work, we explore the intersection of Artificial Intelligence (AI) methods and PHM applications. We present a thorough review of existing works both in the contexts of fault diagnosis and fault prognosis, highlighting the benefits and the drawbacks introduced by the adoption of AI techniques. Our goal is to highlight potentially fruitful research directions along with characterizing the main challenges that need to be addressed in order to realize the promises of AI-based PHM systems., (Copyright © 2020 Biggio and Kastanis.)

Published

2020