hep-aid: a Python library for sample efficient parameter scans in beyond the standard model phenomenology
hep-aid: a Python library for sample efficient parameter scans in beyond the standard model phenomenology
This paper presents hep-aid, a modular Python library conceived for utilising, implementing, and developing parameter scan algorithms. Originally devised for sample-efficient, multi-objective active search approaches in computationally expensive Beyond Standard Model (BSM) phenomenology, the library currently integrates three Machine Learning (ML)-based approaches: a Constraint Active Search (CAS) algorithm, a multi-objective Active Search (AS) method (called b-CASTOR), and a self-exploration method named Machine Learning Scan (MLScan). These approaches address the challenge of multi-objective optimisation in high-dimensional BSM scenarios by employing surrogate models and strategically exploring parameter spaces to identify regions that satisfy complex objectives with fewer evaluations. Additionally, a Markov-Chain Monte Carlo method using the Metropolis-Hastings algorithm (MCMC-MH) is implemented for method comparison. The library also includes a High Energy Physics (HEP) module based on SPheno as the spectrum calculator. However, the library modules and functionalities are designed to be easily extended and used also with other external software for phenomenology. This manual provides an introduction on how to use the main functionalities of hep-aid and describes the design and structure of the library. Demonstrations based on the aforementioned parameter scan methods show that hep-aid methodologies enhance the efficiency of BSM studies, offering a versatile toolset for complex, multi-objective searches for new physics in HEP contexts exploiting advanced ML-based approaches.
hep-ph
Diaz, Mauricio A.
b929a911-11c3-43c8-bd8a-eb2173a4b14e
Dasmahapatra, Srinandan
01c51318-4434-482a-9d46-8a6accfd7f8c
Moretti, Stefano
b57cf0f0-4bc3-4e02-96e3-071255366614
Diaz, Mauricio A.
b929a911-11c3-43c8-bd8a-eb2173a4b14e
Dasmahapatra, Srinandan
01c51318-4434-482a-9d46-8a6accfd7f8c
Moretti, Stefano
b57cf0f0-4bc3-4e02-96e3-071255366614
[Unknown type: UNSPECIFIED]
Abstract
This paper presents hep-aid, a modular Python library conceived for utilising, implementing, and developing parameter scan algorithms. Originally devised for sample-efficient, multi-objective active search approaches in computationally expensive Beyond Standard Model (BSM) phenomenology, the library currently integrates three Machine Learning (ML)-based approaches: a Constraint Active Search (CAS) algorithm, a multi-objective Active Search (AS) method (called b-CASTOR), and a self-exploration method named Machine Learning Scan (MLScan). These approaches address the challenge of multi-objective optimisation in high-dimensional BSM scenarios by employing surrogate models and strategically exploring parameter spaces to identify regions that satisfy complex objectives with fewer evaluations. Additionally, a Markov-Chain Monte Carlo method using the Metropolis-Hastings algorithm (MCMC-MH) is implemented for method comparison. The library also includes a High Energy Physics (HEP) module based on SPheno as the spectrum calculator. However, the library modules and functionalities are designed to be easily extended and used also with other external software for phenomenology. This manual provides an introduction on how to use the main functionalities of hep-aid and describes the design and structure of the library. Demonstrations based on the aforementioned parameter scan methods show that hep-aid methodologies enhance the efficiency of BSM studies, offering a versatile toolset for complex, multi-objective searches for new physics in HEP contexts exploiting advanced ML-based approaches.
Text
2412.17675v1
- Author's Original
More information
Accepted/In Press date: 23 December 2024
Keywords:
hep-ph
Identifiers
Local EPrints ID: 498163
URI: http://eprints.soton.ac.uk/id/eprint/498163
PURE UUID: 07afd608-e22c-4674-a744-8fd49cf91679
Catalogue record
Date deposited: 11 Feb 2025 18:00
Last modified: 12 Feb 2025 02:39
Export record
Altmetrics
Contributors
Author:
Mauricio A. Diaz
Author:
Srinandan Dasmahapatra
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
