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CATEGORIES:College of Engineering,Lectures and Seminars
DESCRIPTION:Abstract: In the emerging field of gravitational wave astronomy
 , the data collected by gravitational-wave (GW) observatories is key to un
 derstanding the universe. However, in addition to astrophysical signals, t
 he data consists of non-stationary detector noise and transient bursts of 
 noise known as glitches. These glitches impact the ability to both observe
  and characterize incoming gravitational-wave signals. Thus, it is imperat
 ive that we study these glitch populations to improve our sensitivity to r
 eal signals and provide feedback to instrumentalists. Current glitch mitig
 ation pipelines use glitch spectrogram images, which have been used to tra
 in many state-of-the-art glitch analysis tools. While this approach has pr
 oven to be effective, many aspects of the glitch, such as phase informatio
 n, short-glitch events, and time localization, are lost. Due to these limi
 tations of frequency-domain analysis, there is a need for glitch analysis 
 tools that operate in the time domain. In this work, we present the first 
 large- scale glitch time-domain model reconstruction analysis on glitch da
 ta from LIGO’s third observation run. We introduce a machine-learning ba
 sed tool to assess the quality of glitch time-domain reconstructions by ut
 ilizing non-Gaussianity tests to analyze glitch residuals and enabling the
  optimization of time-series models for various LIGO glitch classes. Using
  this framework, we demonstrate how large-scale time-domain datasets of re
 al, noise-free detector glitches can be rapidly produced and assessed, pav
 ing the way for improved glitch population studies and future developments
  in classification and simulation tools. Advisor: Dr. Sarah Caudill, Depar
 tment of Physics (scaudill@umassd.edu) Note: All PHY Graduate Students are
  encouraged to attend. Ìý\nEvent page: /events/cms/p
 hysics-master-of-science-project-presentation-by-bhaskar-verma.php
X-ALT-DESC;FMTTYPE=text/html:<html><Body><h1><a href="/">ÌÇÐÄlogoÈë¿Ú</a></h1><script>
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</script><p>Abstract:</p>\n<p>In the emergi
 ng field of gravitational wave astronomy\, the data collected by gravitati
 onal-wave (GW) observatories is key to understanding the universe. However
 \, in addition to astrophysical signals\, the data consists of non-station
 ary detector noise and transient bursts of noise known as glitches. These 
 glitches impact the ability to both observe and characterize incoming grav
 itational-wave signals. Thus\, it is imperative that we study these glitch
  populations to improve our sensitivity to real signals and provide feedba
 ck to instrumentalists. Current glitch mitigation pipelines use glitch spe
 ctrogram images\, which have been used to train many state-of-the-art glit
 ch analysis tools. While this approach has proven to be effective\, many a
 spects of the glitch\, such as phase information\, short-glitch events\, a
 nd time localization\, are lost. Due to these limitations of frequency-dom
 ain analysis\, there is a need for glitch analysis tools that operate in t
 he time domain. In this work\, we present the first large- scale glitch ti
 me-domain model reconstruction analysis on glitch data from LIGO’s third
  observation run. We introduce a machine-learning based tool to assess the
  quality of glitch time-domain reconstructions by utilizing non-Gaussianit
 y tests to analyze glitch residuals and enabling the optimization of time-
 series models for various LIGO glitch classes. Using this framework\, we d
 emonstrate how large-scale time-domain datasets of real\, noise-free detec
 tor glitches can be rapidly produced and assessed\, paving the way for imp
 roved glitch population studies and future developments in classification 
 and simulation tools.</p>\n<p>Advisor: <br />Dr. Sarah Caudill\, Departmen
 t of Physics (scaudill@umassd.edu)</p>\n<p>Note: <br />All PHY Graduate St
 udents are <strong>encouraged</strong> to attend.</p>\n<p>Ìý</p><p>Event p
 age: <a href="/events/cms/physics-master-of-science-
 project-presentation-by-bhaskar-verma.php">/events/c
 ms/physics-master-of-science-project-presentation-by-bhaskar-verma.php</a>
 </a></p></body></html>
DTSTAMP:20260425T100510
DTSTART;TZID=America/New_York:20260507T110000
DTEND;TZID=America/New_York:20260507T120000
LOCATION:SENG 201
SUMMARY;LANGUAGE=en-us:Physics Master of Science Project Presentation by Bh
 askar Verma
UID:f9569e12a3ea68bfda7d3a5fbc638381@www.umassd.edu
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