Документ взят из кэша поисковой машины. Адрес оригинального документа : http://hea-www.harvard.edu/AstroStat/AAS224/
Дата изменения: Unknown
Дата индексирования: Sun Apr 10 03:20:50 2016
Кодировка:

Поисковые слова: п п п п п п п п п п п п п п п п р п р п р п р п р п п р п п р п п р п п р п п р п п р п п р п п р п п р п п р п п р п п р п п р п п р п п р п п р п п р п
Topics in AstroStatistics
 
Last Updated: 20140530

AAS 224 : Special Session

Topics in AstroStatistics

10:00 AM - 11:30 AM, June 2, 2014

St. George AB, Westin Copley Place, Boston, MA

hea-www.harvard.edu/AstroStat/AAS224/
| Description | Schedule | Ask-A-Statistician | Contacts | changelog |

Description

Modern AstroStatistics has emerged as a new field in recent times, informed by a Bayesian foundation, utilizing powerful computational tools like MCMC, and applied to diverse analysis and inference problems in Astronomy. The use of statistics to validate results and evaluate models is pervasive in modern astronomy and advanced statistical techniques have been extensively applied across cosmology, high-energy astrophysics, solar physics, large surveys, etc. Poisson techniques have proliferated, and the use of MCMC is common today. The diversity of astronomical data has also had positive feedback on Statistics, and has influenced the development of new algorithms and insights. Now, new methods of data collection, and the rapidly increasing amounts of data that are collected (the "Big Data" problem), pose new challenges of analysis and interpretation. The goal of our Special Session is to review current practices, highlight modern techniques, and explore how the transition into the realm of Big Data Astronomy can be facilitated. Analysis and interpretation of the terabyte and petabyte data streams from forthcoming surveys and missions is a major challenge to the practice of Astronomy, and possibly requires a significant restructuring of the types of problems that are addressed. A secondary purpose of this Session is to build broad community awareness about the risks and rewards of principled analysis. We will explore the pitfalls of using advanced and powerful techniques as black boxes, and will highlight the complexities that arise from implementations and broad usage among Astronomers.

The session will be complemented by an informal interactive discussion session hosted at the Chandra Booth as part of a program initiated by the SAO/Harvard-based CHASC AstroStatistics Collaboration. CHASC will arrange for Statisticians to be available at specified times to answer questions and discuss AstroStatistical issues with Astronomers.

Schedule

Special Session (Mon, Jun 2, 10-11:30am):

Chair: Aneta Siemiginowska (CfA)
 
105.01. Towards Good Statistical Practices in Astronomical Studies
Eric Feigelson (PennState)
Abstract:
Astronomers do not receive strong training in statistical methodology and are therefore sometimes prone to analyze data in ways that are discouraged by modern statisticians. A number of such cases are reviewed involving the Kolmogorov-Smirnov test, histograms and other binned statistics, various issues with regression, model selection with the likelihood ratio test, over-reliance on `3-sigma' criteria, under-use of multivariate clustering algorithms, and other issues.
 
105.02. Big Computing in Astronomy: Perspectives and Challenges
Viktor Pankratius (MIT)
Abstract:
Hardware progress in recent years has led to astronomical instruments gathering large volumes of data. In radio astronomy for instance, the current generation of antenna arrays produces data at Tbits per second, and forthcoming instruments will expand these rates much further. As instruments are increasingly becoming software-based, astronomers will get more exposed to computer science. This talk therefore outlines key challenges that arise at the intersection of computer science and astronomy and presents perspectives on how both communities can collaborate to overcome these challenges. Major problems are emerging due to increases in data rates that are much larger than in storage and transmission capacity, as well as humans being cognitively overwhelmed when attempting to opportunistically scan through Big Data. As a consequence, the generation of scientific insight will become more dependent on automation and algorithmic instrument control. Intelligent data reduction will have to be considered across the entire acquisition pipeline. In this context, the presentation will outline the enabling role of machine learning and parallel computing.
Bio:
Victor Pankratius is a computer scientist who joined MIT Haystack Observatory following his passion for astronomy. He is currently leading efforts to advance astronomy through cutting-edge computer science and parallel computing. Victor is also involved in projects such as ALMA Phasing to enhance the ALMA Observatory with Very-Long Baseline Interferometry capabilities, the Event Horizon Telescope, as well as in the Radio Array of Portable Interferometric Detectors (RAPID) to create an analysis environment using parallel computing in the cloud. He has an extensive track record of research in parallel multicore systems and software engineering, with contributions to auto-tuning, debugging, and empirical experiments studying programmers. Victor has worked with major industry partners such as Intel, Sun Labs, and Oracle. He holds a distinguished doctorate and a Habilitation degree in Computer Science from the University of Karlsruhe. Contact him at pankrat@mit.edu, victorpankratius.com, or Twitter @vpankratius.
 
105.03. The Full Monte Carlo: A Live Performance with Stars
Xiao-Li Meng (Harvard)
Abstract:
Markov chain Monte Carlo (MCMC) is being applied increasingly often in modern Astrostatistics. It is indeed incredibly powerful, but also very dangerous. It is popular because of its apparent generality (from simple to highly complex problems) and simplicity (the availability of out-of-the-box recipes). It is dangerous because it always produces something but there is no surefire way to verify or even diagnosis that the "something" is remotely close to what the MCMC theory predicts or one hopes. Using very simple models (e.g., conditionally Gaussian), this talk starts with a tutorial of the two most popular MCMC algorithms, namely, the Gibbs Sampler and the Metropolis-Hasting Algorithm, and illustrates their good, bad, and ugly implementations via live demonstration. The talk ends with a story of how a recent advance, the Ancillary-Sufficient Interweaving Strategy (ASIS) (Yu and Meng, 2011, http://www.stat.harvard.edu/Faculty_Content/meng/jcgs.2011-article.pdf) reduces the danger. It was discovered almost by accident during a Ph.D. student's (Yaming Yu) struggle with fitting a Cox process model for detecting changes in source intensity of photon counts observed by the Chandra X-ray telescope from a (candidate) neutron/quark star.
 

Ask-A-Statistician (located at Chandra booth):
Mon, Jun 2 Xiao-Li Meng
 
Noon - 2 pm
Tue, Jun 3 David Jones
Yang Chen
 
1:30 pm - 5:30 pm
Wed, Jun 4 Keli Liu
Yang Chen
 
11:30 am - 3:30 pm

Contacts

Vinay Kashyap (vkashyap @ cfa . harvard . edu)
Aneta Siemiginowska (asiemiginowska @ cfa . harvard . edu)

changelog

2014-may-30: set up page.




Special Session
AAS 224
Topics in
AstroStatistics
Jun 2, 2014
Description
Schedule
Ask-a-Statistician
Contacts
changelog


CHASC