Soma Mukherjee GWDAW8, Milwaukee, Dec. 17-20'03 Interferometric Data Modeling: Issues in realistic data generation. Soma Mukherjee CGWA University of Texas.

Slides:



Advertisements
Similar presentations
A walk through some statistic details of LSC results.
Advertisements

Median Based Line Tracker Soumya D. Mohanty Max Planck Insitut für Gravitationsphysik LIGO-G Z.
GWDAW-10 (December 14, 2005, University of Texas at Brownsville, U.S.A.) Data conditioning and veto for TAMA burst analysis Masaki Ando and Koji Ishidoshiro.
GWDAW-8 (December 17-20, 2003, Milwaukee, Wisconsin, USA) Search for burst gravitational waves with TAMA data Masaki Ando Department of Physics, University.
Wavelet Transform A very brief look.
1 Status of Unbiased Search for Continuous-Wave Sources Dave Chin, Vladimir Dergachev, Keith Riles (University of Michigan) LIGO Scientific Collaboration.
Noise Floor Non-stationarity Monitor Roberto Grosso*, Soma Mukherjee + + University of Texas at Brownsville * University of Nuernburg, Germany Detector.
Searching for pulsars using the Hough transform Badri Krishnan AEI, Golm (for the pulsar group) LSC meeting, Hanford November 2003 LIGO-G Z.
A VOICE ACTIVITY DETECTOR USING THE CHI-SQUARE TEST
Detector Characterization in GEO 600 by Alicia M. Sintes-Olives on behalf of the GEO-DC team Universitat de les Illes Balears
Soma Mukherjee, GWDAW7, Kyoto, Japan, 19/12/02, LIGO-G Z1 Robust Detection of Noise Floor Drifts in Interferometric Data Soma Mukherjee Max Planck.
The “probability event horizon” and probing the astrophysical GW background School of Physics University of Western Australia Research is funded by the.
UF S.Klimenko LIGO-G Z l Introduction l Goals of this analysis l Coherence of power monitors l Sign X-Correlation l H2-L1 x-correlation l Conclusion.
LIGO-G Z Detector characterization for LIGO burst searches Shourov K. Chatterji for the LIGO Scientific Collaboration 10 th Gravitational Wave.
21 Feb 2002Soumya D. Mohanty, AEI1 DCR Plan of presentation Soumya Mohanty: Overview, aims & work done R. Balasubramanian: Details of Hardware, Database.
New data analysis for AURIGA Lucio Baggio Italy, INFN and University of Trento AURIGA.
S.Klimenko, G Z, December 21, 2006, GWDAW11 Coherent detection and reconstruction of burst events in S5 data S.Klimenko, University of Florida.
Data Characterization in Gravitational Waves Soma Mukherjee Max Planck Institut fuer Gravitationsphysik Golm, Germany. Talk at University of Texas, Brownsville.
Search for gravitational-wave bursts associated with gamma-ray bursts using the LIGO detectors Soumya D. Mohanty On behalf of the LIGO Scientific Collaboration.
June 1, 2001GEO DC Workshop Detector Characterization Robot (Progress Since January 2001) Design (Already exists) Algorithmic and Statistical studies (In.
A coherent null stream consistency test for gravitational wave bursts Antony Searle (ANU) in collaboration with Shourov Chatterji, Albert Lazzarini, Leo.
Applications of change point detection in Gravitational Wave Data Analysis Soumya D. Mohanty AEI.
Analysis of nonstationarity in LIGO S5 data using the NoiseFloorMon output A proposal for a seismic Data Quality flag. R. Stone for the LSC The Center.
Improving the sensitivity of searches for an association between Gamma Ray Bursts and Gravitational Waves Soumya D. Mohanty The University of Texas at.
Multidimensional classification of burst triggers from the fifth science run of LIGO Soma Mukherjee CGWA, UTB GWDAW11, Potsdam, 12/18/06 LIGO-G
S.Klimenko, December 2003, GWDAW Performance of the WaveBurst algorithm on LIGO S2 playground data S.Klimenko (UF), I.Yakushin (LLO), G.Mitselmakher (UF),
Chapter 6. Effect of Noise on Analog Communication Systems
S.Klimenko, August 2005, LSC, G Z Constraint likelihood analysis with a network of GW detectors S.Klimenko University of Florida, in collaboration.
S.Klimenko, July 14, 2007, Amaldi7,Sydney, G Z Detection and reconstruction of burst signals with networks of gravitational wave detectors S.Klimenko,
18/01/01GEO data analysis meeting, Golm Issues in GW bursts Detection Soumya D. Mohanty AEI Outline of the talk Transient Tests (Transient=Burst) Establishing.
Dec 16, 2005GWDAW-10, Brownsville Population Study of Gamma Ray Bursts S. D. Mohanty The University of Texas at Brownsville.
Multidimensional classification of burst triggers from LIGO S5 run Soma Mukherjee for the LSC Center for Gravitational Wave Astronomy University of Texas.
Searching for Gravitational Waves from Binary Inspirals with LIGO Duncan Brown University of Wisconsin-Milwaukee for the LIGO Scientific Collaboration.
LIGO-G Z Status of MNFTmon Soma Mukherjee +, Roberto Grosso* + University of Texas at Brownsville * University of Nuernberg, Germany LSC Detector.
GEO++ Online Detector Characterization System. LIGO-G Z GEO++ working group GEO++ working group Cardiff University: Birmingham University Cardiff.
LIGO-G Z The Q Pipeline search for gravitational-wave bursts with LIGO Shourov K. Chatterji for the LIGO Scientific Collaboration APS Meeting.
T.Akutsu, M.Ando, N.Kanda, D.Tatsumi, S.Telada, S.Miyoki, M.Ohashi and TAMA collaboration GWDAW10 UTB Texas 2005 Dec. 13.
S.Klimenko, G Z, December 2006, GWDAW11 Coherent detection and reconstruction of burst events in S5 data S.Klimenko, University of Florida for.
APPLICATION OF A WAVELET-BASED RECEIVER FOR THE COHERENT DETECTION OF FSK SIGNALS Dr. Robert Barsanti, Charles Lehman SSST March 2008, University of New.
S.Klimenko, G Z, December 21, 2006, GWDAW11 Coherent detection and reconstruction of burst events in S5 data S.Klimenko, University of Florida.
S.Klimenko, G Z, March 20, 2006, LSC meeting First results from the likelihood pipeline S.Klimenko (UF), I.Yakushin (LLO), A.Mercer (UF),G.Mitselmakher.
LIGO-G Z Confidence Test for Waveform Consistency of LIGO Burst Candidate Events Laura Cadonati LIGO Laboratory Massachusetts Institute of Technology.
Data Analysis Algorithm for GRB triggered Burst Search Soumya D. Mohanty Center for Gravitational Wave Astronomy University of Texas at Brownsville On.
Multidimensional classification analysis of kleine Welle triggers in LIGO S5 run Soma Mukherjee for the LSC University of Texas at Brownsville GWDAW12,
S.Klimenko, March 2003, LSC Burst Analysis in Wavelet Domain for multiple interferometers LIGO-G Z Sergey Klimenko University of Florida l Analysis.
S.Klimenko, December 2003, GWDAW Burst detection method in wavelet domain (WaveBurst) S.Klimenko, G.Mitselmakher University of Florida l Wavelets l Time-Frequency.
LIGO- G Z AJW, Caltech, LIGO Project1 A Coherence Function Statistic to Identify Coincident Bursts Surjeet Rajendran, Caltech SURF Alan Weinstein,
Comparison of filters for burst detection M.-A. Bizouard on behalf of the LAL-Orsay group GWDAW 7 th IIAS-Kyoto 2002/12/19.
Validation of realistically simulated non-stationary data. Soma Mukherjee Centre for Gravitational Wave Astronomy University of Texas at Brownsville. GWDAW9,
SymbolMeaning Frequency of the Input Signal Frequency of the Lock-in Reference Frequency of the Additional Sinusoidal Input Signal (or Coherent Noise)
Soma Mukherjee GWDAW8, Milwaukee, December'03 Interferometric Data Modeling: Issues in realistic data generation. Soma Mukherjee CGWA Dept. of Physics.
Soma Mukherjee LSC, Hanford, Aug.19 '04 Generation of realistic data segments: production and application. Soma Mukherjee Centre for Gravitational Wave.
WAVELET NOISE REMOVAL FROM BASEBAND DIGITAL SIGNALS IN BANDLIMITED CHANNELS Dr. Robert Barsanti SSST March 2010, University of Texas At Tyler.
The first AURIGA-TAMA joint analysis proposal BAGGIO Lucio ICRR, University of Tokyo A Memorandum of Understanding between the AURIGA experiment and the.
2 June 2003Soumya D. Mohanty et al, LIGO-G D1 LASER INTERFEROMETER GRAVITATIONAL WAVE OBSERVATORY - LIGO – CALIFORNIA INSTITUTE OF TECHNOLOGY.
Martin Hewitson and the GEO team Measuring gravitational waves with GEO600.
SEARCH FOR INSPIRALING BINARIES S. V. Dhurandhar IUCAA Pune, India.
Locating a Shift in the Mean of a Time Series Melvin J. Hinich Applied Research Laboratories University of Texas at Austin
MNFT : Robust detection of slow nonstationarity in LIGO Science data Soma Mukherjee Max Planck Institut fuer Gravitationsphysik Germany. LSC Meeting, Livingston,
LIGO-G Z The Q Pipeline search for gravitational-wave bursts with LIGO Shourov K. Chatterji for the LIGO Scientific Collaboration APS Meeting.
LIGO-G05????-00-Z Detector characterization for LIGO burst searches Shourov K. Chatterji For the LIGO Scientific Collaboration 10 th Gravitational Wave.
PERFORMANCE OF A WAVELET-BASED RECEIVER FOR BPSK AND QPSK SIGNALS IN ADDITIVE WHITE GAUSSIAN NOISE CHANNELS Dr. Robert Barsanti, Timothy Smith, Robert.
A 2 veto for Continuous Wave Searches
Searching for pulsars using the Hough transform
The Q Pipeline search for gravitational-wave bursts with LIGO
Soma Mukherjee Centre for Gravitational Wave Astronomy
Coherent detection and reconstruction
Soma Mukherjee for LIGO Science Collaboration
Fundamentals Data.
Excess power trigger generator
Presentation transcript:

Soma Mukherjee GWDAW8, Milwaukee, Dec '03 Interferometric Data Modeling: Issues in realistic data generation. Soma Mukherjee CGWA University of Texas Brownsville

Soma Mukherjee GWDAW8, Milwaukee, Dec '03 Why ? Astrophysical searches estimate efficiency from playground data. Extrig search – how representative is the’off-source’ segment of the ‘on- source’ one ?

Soma Mukherjee GWDAW8, Milwaukee, Dec '03 Data Modeling: Basis Interferometric data has three components : lines, transients and noise floor. As a first approximation, the three components are independent and appear additively. Physically different sources for each Basic idea is to split a channel into these components with mutual exclusion Classify Transients, fit ARMA models to line amplitude and phase modulation, ARMA models for noise floor rms

Soma Mukherjee GWDAW8, Milwaukee, Dec '03 Issue I :Slowly drifting noise floor Data from present generation of interferometers is non-stationary. Results obtained by running MNFT 1 on a stretch of LIGO S2 data.[ 1 Mukherjee, CQG, 2003] Low pass and resample Estimate spectral Noise floor with Running Median Whiten data using FIR whitening Filter. Clean lines and Highpass Compute Running Median of the Squared timeseries Set threshold

Soma Mukherjee GWDAW8, Milwaukee, Dec '03 Issue II : Modeling ALL lines MBLT 1 : Non-parametric Line estimation. [ 1 Mohanty CQG, 2001 ]

Soma Mukherjee GWDAW8, Milwaukee, Dec '03 KSCD Kolmogorv-Smirnov test based Change point Detector Mohanty, PRD (2000); Mohanty, GWDAW (2002) Issue III : Transient Clasification 12 top wavelet coefficients of data surrounding each KSCD trigger. Visualized using GGobi. (Preliminary). Mukherjee, 2003, Amaldi, Pisa

Soma Mukherjee GWDAW8, Milwaukee, Dec '03

MNFT outline: Algorithm: 1. Lowpass and resample given timeseries x(k). 2. Construct FIR filter that whitens the noise floor. Resulting timeseries : w(k) 3. Remove lines using notch filter. Cleaned timeseries : c(k) 4. Track variation in second moment of c(k) using Running Median and apply smoothing (SRM). 5. Obtain significance levels of the sampling distribution via Monte Carlo simulations.

Soma Mukherjee GWDAW8, Milwaukee, Dec '03 Model Noise Generation Model Noise Floor (low order ARMA). Estimate lines, model amplitude and phase, add reconstructed lines to synthetic data. Add transients. Use MNFT to Compute smoothed Running Median Fit ARMA to the SRM

Soma Mukherjee GWDAW8, Milwaukee, Dec '03 ARMA (p,q) A(q) y(t) = C(q) e(t) Y(t) : Output e(t) : White noise C(q)/A(q) : Transfer function q: Time shift operator A and C : Polynomials

Soma Mukherjee GWDAW8, Milwaukee, Dec '03 How faithful is the model ? Apply statistical tests of hypothesis Kolmogorov-Smirnov Akaike Information criterion I akaike (p,q) = ln  2 p,q + 2 (p+q)/N

Soma Mukherjee GWDAW8, Milwaukee, Dec '03 Result I : Noise floor model – ARMA (12,7)

Soma Mukherjee GWDAW8, Milwaukee, Dec '03 Result II : Line Amplitude - ARMA (27,11)

Soma Mukherjee GWDAW8, Milwaukee, Dec '03 Line model : Amplitude & Phase

Soma Mukherjee GWDAW8, Milwaukee, Dec '03 Comments Applicable to band limited data. Use as an ‘infinite’ playground for astrophysical searches. Gives a better handle on non-stationarity and hence testing the robustness of the search algorithm. Allows us to do ‘controlled tests’. Signal injection and efficiency estimation

Feedback: Privacy Policy Feedback
Do Not Sell My Personal Information
About project: SlidePlayer Terms of Service

© 2025 SlidePlayer.com. Inc. All rights reserved.