AstroStat Talks 2017-2018
Last Updated: 2018apr18

ICHASC

Topics in Astrostatistics

AY 2017-2018

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Presentations
Workshop
20 Sep 2017
10am-4pm EDT
Phillips Auditorium at CfA
AstroStat Day
10:00am - 12:10pm : Siemiginowska, Vikhlinin, Finkbeiner, Portillo, Daylan, Speagle, B. Johnson
12:30pm - 1:30pm : Reeves, Winter
(SolarStat, in conjunction with HEAD Lunch Talks)
2:00pm - 4:00pm : Grindlay, M. Johnson, Blackburn, Bouman, Avelino, Zucker
4:00pm - 5:00pm : Discussion
 
Josh Speagle (CfA)
26 Sep 2017
1:07pm EDT
Pratt (Perkin-G, CfA)
Dynamic Nested Sampling
Nested Sampling is a relatively new method for estimating the Bayesian evidence (with the posterior estimated as a byproduct) that integrates over the posterior by sampling in nested "shells" of constant likelihood. Its ability to sample from complex, multi-modal distributions in a flexible yet efficient way combined with several available sampling packages has contributed to its growing popularity in (astro)physics. In this talk I will outline the basic motivation and theory behind Nested Sampling, derive various statistical properties associated with the method, and discuss how it is applied in practice. I will then talk about how the overall framework can be extended in Dynamic Nested Sampling to accommodate adding samples "dynamically" during the course of a run. These samples can be allocated to maximize arbitrary objective functions, allowing Dynamic Nested Sampling to function as a posterior-oriented sampling method such as MCMC but with the added benefit of well-defined stopping criteria. I will end by applying Dynamic Nested Sampling to a variety of synthetic and real-world problems using an open-source Python package I've been developing (dynesty).
Presentation slides [.pdf]
See also: MultiNest ; PolyChord [url
 
Gabriel Collin (MIT)
21 Nov 2017
1:07pm EST
Pratt (Perkin-G, CfA)
Searching for the origin of astrophysical neutrinos using a non-Poissonian statistical method
Abstract: The IceCube neutrino observatory was designed to detect astrophysical neutrinos, which originate from outside of our solar system. IceCube has detected candidate astrophysical events, and measured a diffuse flux, but the source of these neutrinos so far remains unknown. Current approaches look for "hot spots" of neutrino events in the sky. It is also possible to describe a population of sources in terms of the number of observed events, forming a non-Poissonian statistical distribution. This distribution was used to show that the excess of gamma rays measured by Fermi-LAT around the galactic center was likely due to point sources rather than decaying dark matter. In this talk, I will present the application of this statistical method to the search for point sources in IceCube.
Evidence for Unresolved Gamma-Ray Point Sources in the Inner Galaxy, Lee et al. arxiv:1506.05124 [.url]
NPTfit github.com/bsafdi/NPTFit [.url]
 
Katy McKeough & Shihao Yang (Harvard)
28 Nov 2017
1:07pm EST
SciCen 706
Defining regions that contain X-ray jets in high-redshift quasars
Abstract: Using only the X-ray observation of a quasar and a jet, we are interested in creating an outline around an extended source (jet). Astronomers are interested in delineating jets from their quasar source and background radiation. This is particularly difficult in images of high redshift jets taken in X-ray where there are a limited number of pixel counts. McKeough et al. 2016 and Stein et al. 2015 proposes a method where jets are detected using previously defined regions of interest (ROI). However, we do not always have supplementary information to predetermine these ROI and the size and shape can greatly affect flux/luminosity measurements and power of detection. Low Count Image Reconstruction and Analysis (LIRA) has been tremendously successful in analyzing low counts images and extracting structure smeared out by the PSF. However, the intensities derived using it are pixellated. That is, LIRA is unaware of correlations that may exist between adjacent pixels in the real image. In order to group pixels of a similar nature, we impose a successor or post-model on the output of LIRA. We adopt the Ising model, which has been used extensively in Condensed Matter Physics to model electron spin states, as a prior on assigning the pixels to either the background or the ROI.
Presentation slides [.pdf]
 
Katy McKeough & Luis Campos (Harvard)
12 Dec 2017
12:37pm EST
CfA Library
Ask A Statistician: An oppportunity for astronomers at the CfA to ask statistics questions of statisticians; from the mundane to the philosophical, bring your statistics problems to be discussed by the panel
We will be going through several applications of statistics in astronomy. Each application will serve as the backdrop for discussing a different statistical technique. We will suggest partial solutions or new directions for each of these proposed issues that we hope will stimulate further questions and discussion.
The following examples are:
- Propagating asymmetrical error bars via parametric bootstrap.
- Correlation between two time series observations.
- Using external information as a prior in Bayesian inference.
- Explanation of shrinkage.
- Detection significance with multiple hypothesis testing.
Presentation Slides [url]
James-Stein Estimator R model [.rmd]
 
Michelle Ntampaka (DSI/CfA)
23 Jan 2018
1:07pm EDT
SciCen 706
Constraining Sigma-8 and Omega-Matter with the Velocity Distribution Function
Abstract: I will present the Velocity Distribution Function (VDF), a new approach for quantifying the abundance of galaxy clusters and constraining cosmological parameters using dynamical measurements. In this new method, the probability distribution of velocities for each cluster in the sample are summed to create a new test statistic, which can be measured more directly and precisely than the more standard halo mass function, and can be robustly predicted with cosmological simulations which capture the dynamics of subhalos or galaxies. I will present preliminary constraints on sigma-8 and omega-matter from spectroscopic observations of the HeCS-SZ clusters.
Presentation slides [.pdf]
 
Herman Marshall (MIT)
06 Feb 2018
1:07pm EDT
CGIS South -- S153
Computational Challenges from Imaging X-ray Polarimetry
Abstract: I will provide an overview of an approved NASA astrophysics mission called IXPE, the Imaging X-ray Polarimetry Explorer, scheduled for launch in 2021. IXPE will obtain X-ray polarization measurements for a wide variety of astrophysical objects. While many targets will be point-like, such as most active galaxies, X-ray binaries in the Galaxy, and isolated neutron stars, others will be resolved, such as scattering clouds, supernova remnants, and pulsar wind nebulae. I will outline three interesting problems where advanced statistical and numerical methods may be beneficial. The first problem relates to how X-ray events are measured to yield polarization information; we have begun a project to apply machine learning techniques to improve the result. The second problem involves the multidimensionality of the data, with each event carrying time, energy, sky position, and direction information, so Bayesian methods may help in the analysis by bringing in external data as priors. The third problem is devising efficient ways to test models against the multidimensioned event list.
Presentation slides [.pdf]
 
Daniela Huppenkothen (University of Washington)
06 Mar 2018
1:07pm EST
M-340, 160 Concord, CfA
Fun Statistics with Fourier Spectra
Abstract: In recent years, the cross spectrum has received considerable attention as a means of characterising the variability of astronomical sources as a function of wavelength. While much has been written about the statistics of time and phase lags, the cospectrum-the real part of the cross spectrum-has only recently been understood as means of mitigating instrumental effects dependent on temporal frequency in astronomical detectors, as well as a method of characterizing the coherent variability in two wavelength ranges on different time scales. In this talk, I will present research that started as small exercise to answer what seemed like a simple question-what is the statistical distribution of the cospectrum?-and took us on an adventure through 80 years of statistical research instead.
I will show recent advances made in understanding the statistical properties of cospectra, leading to much improved inferences for periodic and quasi-periodic signals. I will also present a new method to reliably mitigate instrumental effects such as dead time in X-ray detectors, and show how we can use the cospectrum to model highly variable sources such as X-ray binaries or Active Galactic Nuclei.
Presentation slides: [.pdf]
Yu Xixi (Imperial)
3 Apr 2018
1:07pm EDT
SciCen 706
Statistical methods in Solar Spectral Analyses with Uncertain Atomic Physical Models
Abstract: Information about the physical properties of astrophysical objects cannot be measured directly but is inferred by interpreting spectroscopic observations in the context of atomic physics calculations. A critical component of this analysis is understanding how uncertainties in the underlying atomic physics propagates to the uncertainties in the inferred plasma parameters. We previously introduced a fully Bayesian method to address this problem, where, in this model setting, we allowed for the observed data to update the atomic data uncertainties and there were only $1000$ equally likely emissivity curves as priori. Following that work, we assume a new model that the above emissivity curve samples come from a high dimensional distribution. We summarize this distribution with a Normal distribution via principal component analysis (PCA) to efficiently represent the uncertainty of the emissivity curves.
In the context of the first model using Hamiltonian Monte Carlo (HMC) via Stan, owing to an insufficient number of emissivity curves, we could not estimate the relative size of the modes right for the posterior distribution that come from assuming each of these emissivity curves was equally likely and there was nothing in between them. We proposed a computational trick by adding a few linear combinations of the selected emissivity curves to the original set. These linear combinations acted as a bridge to allow a perfet jump between the modes and to measure the relative size of these modes accurately. However, we cannot rely completely on the linear combinations since the emissivity curves can be off all of these linear combinations and we do not really know where the mass of their distribution is. Here, in the second model, PCA aggregates all possibilities and is a better representation of the full ensemble of the emissivity curves. HMC via Stan can be used to sample the corresponding posterior distribution so far.
Presentation slides [.pdf]
 
Rosanne DiStefano (CfA), Jennifer Yee (CfA), and Hyungsuk Tak (SAMSI)
17 Apr 2018
1:07pm EDT
SciCen 706
[RDS] On Microlensing
[JY] The Microlensing Challenge
[HT] Two data analytic challenges of gravitational lensing: From Micro to Macro
Abstract: Light emitted from distant objects -- ranging from stars to quasars -- is deflected when it moves through a gravitational field of an intervening object, such as planets or galaxies. According to the strength of the gravitational field, we observe various phenomena in the sky, e.g., microlensing and macrolensing. Astronomers have been interested in this gravitational deflection of light for various purposes, e.g., using microlensing as a tool to search for exo-planets (planets outside our solar system) and using macrolensing to probe the current expansion rate of the Universe (the Hubble constant). Two data analytic blind competitions are currently on-going as an effort to improve existing computational and statistical tools and to encourage the development of new methods. We introduce these data analytic challenges, describing the basics of microlensing and macrolensing, their data types (time series and image data), and challenging issues in analyzing these data.
Data Challenge [url]
Presentation slides:
Rosanne DiStefano -- [.pptx]
Jennifer Yee -- [.pdf] ; [.pptx]
Hyungsuk Tak -- [.pdf] ; [video1.mp4] ; [video2.mp4]
 
Arturo Avelino (CfA)
24 Apr 2018
1:15pm EDT
Phillips Auditorium, CfA
Near-infrared Type Ia Supernovae as standard candles
Abstract: Explosions of Type Ia Supernovae (SNe Ia) observed in the near infrared wavelengths (NIR) are very good "standard candles" to measure relative distances in the Universe. The investigation on NIR SNe Ia as standard candles is crucial to reconstruct the expansion history of the Universe and to determine its properties with more accuracy compared with traditional methods using optical data.
In this talk I will describe how to estimate the relative distances (the distance moduli) of NIR SNe Ia using a sample of photometric time-series observations in NIR, a Gaussian-Processes regression and a simple hierarchical Bayesian model. At the end, I will use the estimated distance moduli to quantify how good standard candles the NIR SNe Ia are compared with the optical SNe Ia observations.
Presentation slides [.pdf]
YouTube Video [url]
 
 
 
 

Archive
Fall/Winter 2004-2005
Siemiginowska, A. / Connors, A. / Kashyap, V. / Zezas, A. / Devor, J. / Drake, J. / Kolaczyk, E. / Izem, R. / Kang, H. / Yu, Y. / van Dyk, D.
Fall/Winter 2005-2006
van Dyk, D. / Ratner, M. / Jin, J. / Park, T. / CCW / Zezas, A. / Hong, J. / Siemiginowska, A. & Kashyap, V. / Meng, X.-L.
Fall/Winter 2006-2007
Lee, H. / Connors, A. / Protopapas, P. / McDowell, J., / Izem, R. / Blondin, S. / Lee, H. / Zezas, A., & Lee, H. / Liu, J.C. / van Dyk, D. / Rice, J.
Fall/Winter 2007-2008
Connors, A., & Protopapas, P. / Steiner, J. / Baines, P. / Zezas, A. / Aldcroft, T.
Fall/Winter 2008-2009
H. Lee / A. Connors, B. Kelly, & P. Protopapas / P. Baines / A. Blocker / J. Hong / H. Chernoff / Z. Li / L. Zhu (Feb) / A. Connors (Pt.1) / A. Connors (Pt.2) / L. Zhu (Mar) / E. Kolaczyk / V. Liublinska / N. Stein
Fall/Winter 2009-2010
A.Connors / B.Kelly / N.Stein, P.Baines / D.Stenning / J. Xu / A.Blocker / P.Baines, Y.Yu / V.Liublinska, J.Xu, J.Liu / Meng X.L., et al. / A. Blocker, et al. / A. Siemiginowska / D. Richard / A. Blocker / Xie X. / Xu J. / V. Liublinska / L. Jing
AcadYr 2010-2011
Astrostat Haiku / P. Protopapas / A. Zezas & V. Kashyap / A. Siemiginowska / K. Mandel / N. Stein / A. Mahabal / Hong J.S. / D. Stenning / A. Diaferio / Xu J. / B. Kelly / P. Baines & I. Udaltsova / M. Weber
AcadYr 2011-2012
A. Blocker / Astro for Stat / B. Kelly / R. D'Abrusco / E. Turner / Xu J. / T. Loredo / A. Blocker / P. Baines / A. Zezas et al. / Min S. & Xu J. / O. Papaspiliopoulos / Wang L. / T. Laskar
AcadYr 2012-2013
N. Stein / A. Siemiginowska / D. Cervone / R. Dawson / P. Protopapas / K. Reeves / Xu J. / J. Scargle / Min S. / Wang L. & D. Jones / J. Steiner / B. Kelly / K. McKeough
AcadYr 2013-2014
Meng X.-L. / Meng X.-L., K. Mandel / A. Siemiginowska / S. Vrtilek & L. Bornn / Lazhi W. / D. Jones / R. Wong / Xu J. / van Dyk D. / Feigelson E. / Gopalan G. / Min S. / Smith R. / Zezas A. / van Dyk D. / Hyungsuk T. / Czerny, B. / Jones D. / Liu K. / Zezas A.
AcadYr 2014-2015
Vegetabile, B. & Aldcroft, T., / H. Jae Sub / Siemiginowska, A. & Kashyap, V. / Pankratius, V. / Tak, H. / Brenneman, L. / Johnson, J. / Lynch, R.C. / Fan, M.J. / Meng, X.-L. / Gopalan, G. / Jiao, X. / Si, S. / Udaltsova, I. & Zezas, A. / Wang, L. / Tak, H. / Eadie, G. / Czekala, I. / Stenning, D. / Stampoulis, V. / Aitkin, M. / Algeri, S. / Barnacka, A.
AcadYr 2015-2016
DePasquale, J. / Tak, H. / Meng, X.-L. / Jones, D. / Huang, J. / Blanchard, P. / Chen, Y. & Wang, X. / Tak, H. / Mandel, K. / Jiao, X. / Wang, X. & Chen, Y. / IACHEC WG / Si, S. / Drake, J. / Stampoulis, V. / Algeri, S. / Stein, N. / Chunzhe, Z. / Andrews, J. / Vrtilek, S. / Udaltsova, I. & Stampoulis, V.
AcadYr 2016-2017
Wang, X. & Chen, Y. / Kashyap, V., Siemiginowska, A., & Zezas, A. / Stampoulis, V. / Portillo, S. / Zhang, K. / Mandel, K. / DiStefano, R. / Finkbeiner, D. & Meade, B. / Gong, R. / Shihao Y. / Zhirui, H. / Xufei, W. / Campos, L. / Tak, H. / Xufei, W. / Jones, D. / Algeri, S. / Speagle, J. / Czekala, I.
AcadYr 2017-2018
AstroStat Day / Speagle, J. / Collin, G. / McKeough, K. & Yang, S. / McKeough, K. & Campos, L. / M. Ntampaka / H. Marshall / D. Huppenkothen / X. Yu / R. DiStefano / J. Yee / H. Tak / A. Avelino

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