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1. A multiphysics and multiscale software environment for modeling astrophysical systems

Author

Portegies Zwart, S., McMillan, S., Ó Nualláin, B., Heggie, D., Lombardi, J., Hut, P., Banerjee, S., Belkus, H., Fragos, T., Fregeau, J., Fuji, M., Gaburov, E., Glebbeek, E., Groen, D., Harfst, S., Izzard, R., Jurić, M., Justham, S., Teuben, P., van Bever, J., Yaron, O., Zemp, M., Bubak, M., van Albada, G.D., Dongarra, J., Sloot, P.M.A., High Energy Astrophys. & Astropart. Phys (API, FNWI), and Computational Science Lab (IVI, FNWI)

Subjects
Interface (Java), Computer science, Multiphysics, Astrophysics::Cosmology and Extragalactic Astrophysics, computer.software_genre, Galactic nuclei, 01 natural sciences, Computational science, Domain (software engineering), Software, Stellar dynamics, 0103 physical sciences, Radiative transfer, 010303 astronomy & astrophysics, Stellar evolution, Astrophysics::Galaxy Astrophysics, 010308 nuclear & particles physics, business.industry, Planetary system, Supercomputer, Galaxy, Software framework, Grid computing, Computer Science::Programming Languages, business, computer
Abstract

We present MUSE, a software framework for tying together existing computational tools for different astrophysical domains into a single multiphysics, multiscale workload. MUSE facilitates the coupling of existing codes written in different languages by providing inter-language tools and by specifying an interface between each module and the framework that represents a balance between generality and computational efficiency. This approach allows scientists to use combinations of codes to solve highly-coupled problems without the need to write new codes for other domains or significantly alter their existing codes. MUSE currently incorporates the domains of stellar dynamics, stellar evolution and stellar hydrodynamics for a generalized stellar systems workload. MUSE has now reached a "Noah’s Ark" milestone, with two available numerical solvers for each domain. MUSE can treat small stellar associations, galaxies and everything in between, including planetary systems, dense stellar clusters and galactic nuclei. Here we demonstrate an examples calculated with MUSE: the merger of two galaxies. In addition we demonstrate the working of MUSE on a distributed computer. The current MUSE code base is publicly available as open source at http://muse.li.

Published
2008

2. Astrophysics Source Code Library Enhancements

Author

Hanisch, R. J., Allen, A., Berriman, G. B., Duprie, K., Jessica Mink, Nemiroff, R. J., Schmidt, J., Shamir, L., Shortridge, K., Taylor, M., Teuben, P. J., and Wallin, J.

Subjects
FOS: Computer and information sciences, FOS: Physical sciences, Computer Science - Digital Libraries, Digital Libraries (cs.DL), Astrophysics - Instrumentation and Methods for Astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM)
Abstract

The Astrophysics Source Code Library (ASCL; ascl.net) is a free online registry of codes used in astronomy research; it currently contains over 900 codes and is indexed by ADS. The ASCL has recently moved a new infrastructure into production. The new site provides a true database for the code entries and integrates the WordPress news and information pages and the discussion forum into one site. Previous capabilities are retained and permalinks to ascl.net continue to work. This improvement offers more functionality and flexibility than the previous site, is easier to maintain, and offers new possibilities for collaboration. This presentation covers these recent changes to the ASCL., Comment: 4 pages; to be published in ADASS XXIV Proceedings. ASCL can be accessed at http://ascl.net/

Published
2014
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3. Ideas for Advancing Code Sharing (A Different Kind of Hack Day)

Author

Teuben, P., Allen, A., Berriman, B., Duprie, K., Hanisch, R. J., Mink, J., Robert Nemiroff, Shamir, L., Shortridge, K., Taylor, M. B., and Wallin, J. F.

Subjects
FOS: Computer and information sciences, FOS: Physical sciences, Digital Libraries (cs.DL), Computer Science - Digital Libraries, Astrophysics - Instrumentation and Methods for Astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM)
Abstract

How do we as a community encourage the reuse of software for telescope operations, data processing, and calibration? How can we support making codes used in research available for others to examine? Continuing the discussion from last year Bring out your codes! BoF session, participants separated into groups to brainstorm ideas to mitigate factors which inhibit code sharing and nurture those which encourage code sharing. The BoF concluded with the sharing of ideas that arose from the brainstorming sessions and a brief summary by the moderator., To be published in Proceedings of ADASS XXIII. Links to notes from brainstorming sessions are available here: http://asterisk.apod.com/wp/?p=543

Published
2013

5. Practices in Code Discoverability: Astrophysics Source Code Library

Author

Allen, A., Teuben, P., Robert Nemiroff, and Shamir, L.

Subjects
FOS: Physical sciences, Astrophysics - Instrumentation and Methods for Astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM)
Abstract

Here we describe the Astrophysics Source Code Library (ASCL), which takes an active approach to sharing astrophysical source code. ASCL's editor seeks out both new and old peer-reviewed papers that describe methods or experiments that involve the development or use of source code, and adds entries for the found codes to the library. This approach ensures that source codes are added without requiring authors to actively submit them, resulting in a comprehensive listing that covers a significant number of the astrophysics source codes used in peer-reviewed studies. The ASCL now has over 340 codes in it and continues to grow. In 2011, the ASCL (http://ascl.net) has on average added 19 new codes per month. An advisory committee has been established to provide input and guide the development and expansion of the new site, and a marketing plan has been developed and is being executed. All ASCL source codes have been used to generate results published in or submitted to a refereed journal and are freely available either via a download site or from an identified source. This paper provides the history and description of the ASCL. It lists the requirements for including codes, examines the benefits of the ASCL, and outlines some of its future plans., ASCL codes are now incoorporated into ADS

Published
2012

6. CO(1-0) imaging of M51 with CARMA and NRO45

Author

Koda, J., Sawada, T., Wright, M. C. H., Teuben, P., Corder, S. A., Patience, J., Scoville, N., Meyer, J. Donovan, and Egusa, F.

Subjects
Cosmology and Nongalactic Astrophysics (astro-ph.CO), Astrophysics::Instrumentation and Methods for Astrophysics, FOS: Physical sciences, Astrophysics - Instrumentation and Methods for Astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM), Astrophysics::Galaxy Astrophysics, Astrophysics - Cosmology and Nongalactic Astrophysics
Abstract

We report the CO(J=1-0) observations of M51 using both the Combined Array for Research in Millimeter Astronomy (CARMA) and the Nobeyama 45m telescope (NRO45). We describe a procedure for the combination of interferometer and single-dish data. In particular, we discuss (1) the joint imaging and deconvolution of heterogeneous data, (2) the weighting scheme based on the root-mean-square (RMS) noise in the maps, (3) the sensitivity and uv-coverage requirements, and (4) the flux recovery of a combined map. We generate visibilities from the single-dish map and calculate the noise of each visibility based on the RMS noise. Our weighting scheme, though it is applied to discrete visibilities in this paper, is applicable to grids in uv-space, and this scheme may advance in future software development. For a realistic amount of observing time, the sensitivities of the NRO45 and CARMA visibility data sets are best matched by using the single dish baselines only up to 4-6 kilo-lambda (about 1/4-1/3 of the dish diameter). The synthesized beam size is determined to conserve the flux between synthesized beam and convolution beam. The superior uv-coverage provided by the combination of CARMA long baseline data with 15 antennas and NRO45 short spacing data results in the high image fidelity, which is evidenced by the excellent overlap between even the faint CO emission and dust lanes in an optical HST image and PAH emission in an Spitzer 8 micron image., Comment: 24 pages, 11 figures. Accepted for publication in ApJS

Published
2011
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7. A retrospective view of Miriad

Author

Sault, R. J., Teuben, P. J., and Wright, M. C. H.

Subjects
Astrophysics (astro-ph), FOS: Physical sciences, Astrophysics
Abstract

Miriad is a radio interferometry data-reduction package, designed for taking raw data through to the image analysis stage. The Miriad project, begun in 1988, is now middle-aged. With the wisdom of hindsight, we review design decisions and some of Miriad's characteristics.

Published
2006
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8. Immersive 4-D Interactive Visualization of Large-Scale Simulations

Author

Teuben, P., Hut, P., Levy, S., Makino, J., McMillan, S., Portegies Zwart, S., Shara, M., Emmart, C., Harnden, F.R., Primini, F.A., Payne, H.E., High Energy Astrophys. & Astropart. Phys (API, FNWI), and Computational Science Lab (IVI, FNWI)

Abstract

In dense clusters a bewildering variety of interactions between stars can be observed, ranging from simple encounters to collisions and other mass-transfer encounters. With faster and special-purpose computers like GRAPE, the amount of data per simulation is now exceeding 1 TB. Visualization of such data has now become a complex 4-D data-mining problem, combining space and time, and finding interesting events in these large datasets. We have recently starting using the virtual reality simulator, installed in the Hayden Planetarium in the American Museum for Natural History, to tackle some of these problem. This work reports on our first ``observations,'' modifications needed for our specific experiments, and perhaps field ideas for other fields in science which can benefit from such immersion. We also discuss how our normal analysis programs can be interfaced with this kind of visualization.

Published
2001

9. Sgr A* and Company - Multiwavelength observations of Sgr A* and VLA search of 'Sgr A*'s' in LINERs

Author

Falcke, Heino, Goss, W. M., Ho, L. C., Matsuo, H., Teuben, P., Wilson, A. S., Zhao, J. -H., and Zylka, R.

Subjects
Astrophysics::High Energy Astrophysical Phenomena, Astrophysics (astro-ph), FOS: Physical sciences, Astrophysics::Cosmology and Extragalactic Astrophysics, Astrophysics, Astrophysics::Galaxy Astrophysics
Abstract

We report first results from a multiwavelength campaign to measure the simultaneous spectrum of Sgr A* from cm to mm wavelengths. The observations confirm that the previously detected submm-excess is not due to variability; the presence of an ultracompact component with a size of a few Schwarzschild radii is inferred. In a VLA survey of LINER galaxies, we found Sgr A*-like nuclei in one quarter of the galaxies searched, suggesting a link between those low-power AGN and the Galactic Center., Comment: Talk presented at the IAU Coll. 164, A. Zensus, G. Taylor, & J. Wrobel (eds.), PASP Conf. Proc., Latex, paspconf.sty, 2 pages, preprint also available at http://www.astro.umd.edu/~hfalcke/publications.html#iauc164

Published
1997
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10. Distance and metallicity of HVCS

Author

Wakker, BP, VanWoerden, H, Schwarz, UJ, Peletier, RF, Douglas, NG, Danly, L, DeBoer, KS, Blitz, L, Teuben, P, and Kapteyn Astronomical Institute

Published
1996

11. Is there a bulge distinct from the bar?

Author

Kuijken, K, Balcells, M, Weinberg, M, Blitz, L, Teuben, P, and Astronomy

Subjects
INSTABILITY, ROTATION, DISK GALAXIES, STELLAR BARS, GALACTIC-CENTER
Published
1996

14. The Astropy Project: Building an inclusive, open-science project and status of the v2.0 core package

Author

The Astropy Collaboration, Price-Whelan, A. M., Sipőcz, B. M., Günther, H. M., Lim, P. L., Crawford, S. M., Conseil, S., Shupe, D. L., Craig, M. W., Dencheva, N., Ginsburg, A., Vanderplas, J. T., Bradley, L. D., Pérez-Suárez, D., Val-Borro, M., Aldcroft, T. L., Cruz, K. L., Robitaille, T. P., Tollerud, E. J., Ardelean, C., Babej, T., Bachetti, M., Bakanov, A. V., Bamford, S. P., Barentsen, G., Barmby, P., Baumbach, A., Berry, K. L., Biscani, F., Boquien, M., Bostroem, K. A., Bouma, L. G., Brammer, G. B., Bray, E. M., Breytenbach, H., Buddelmeijer, H., Burke, D. J., Calderone, G., Cano Rodríguez, J. L., Cara, M., Cardoso, J. V. M., Cheedella, S., Yannick Copin, Crichton, D., Dávella, D., Deil, C., Depagne, É, Dietrich, J. P., Donath, A., Droettboom, M., Earl, N., Erben, T., Fabbro, S., Ferreira, L. A., Finethy, T., Fox, R. T., Garrison, L. H., Gibbons, S. L. J., Goldstein, D. A., Gommers, R., Greco, J. P., Greenfield, P., Groener, A. M., Grollier, F., Hagen, A., Hirst, P., Homeier, D., Horton, A. J., Hosseinzadeh, G., Hu, L., Hunkeler, J. S., Ivezić, Ž, Jain, A., Jenness, T., Kanarek, G., Kendrew, S., Kern, N. S., Kerzendorf, W. E., Khvalko, A., King, J., Kirkby, D., Kulkarni, A. M., Kumar, A., Lee, A., Lenz, D., Littlefair, S. P., Ma, Z., Macleod, D. M., Mastropietro, M., Mccully, C., Montagnac, S., Morris, B. M., Mueller, M., Mumford, S. J., Muna, D., Murphy, N. A., Nelson, S., Nguyen, G. H., Ninan, J. P., Nöthe, M., Ogaz, S., Oh, S., Parejko, J. K., Parley, N., Pascual, S., Patil, R., Patil, A. A., Plunkett, A. L., Prochaska, J. X., Rastogi, T., Reddy Janga, V., Sabater, J., Sakurikar, P., Seifert, M., Sherbert, L. E., Sherwood-Taylor, H., Shih, A. Y., Sick, J., Silbiger, M. T., Singanamalla, S., Singer, L. P., Sladen, P. H., Sooley, K. A., Sornarajah, S., Streicher, O., Teuben, P., Thomas, S. W., Tremblay, G. R., Turner, J. E. H., Terrón, V., Kerkwijk, M. H., La Vega, A., Watkins, L. L., Weaver, B. A., Whitmore, J. B., Woillez, J., and Zabalza, V.

Subjects
FOS: Physical sciences, Astrophysics - Instrumentation and Methods for Astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM)
Abstract

The Astropy project supports and fosters the development of open-source and openly-developed Python packages that provide commonly-needed functionality to the astronomical community. A key element of the Astropy project is the core package Astropy, which serves as the foundation for more specialized projects and packages. In this article, we provide an overview of the organization of the Astropy project and summarize key features in the core package as of the recent major release, version 2.0. We then describe the project infrastructure designed to facilitate and support development for a broader ecosystem of inter-operable packages. We conclude with a future outlook of planned new features and directions for the broader Astropy project., Minor changes to author list and title. Comments and feedback welcome through the paper source repository: https://github.com/astropy/astropy-v2.0-paper For more information about Astropy, see http://www.astropy.org/

15. Theory in a Virtual Observatory

Author

Teuben, P., Deyoung, D., Hut, P., Levy, S., Junichiro Makino, Mcmillan, S., Zwart, Sp, and Slavin, S.

Subjects
Astrophysics (astro-ph), FOS: Physical sciences, Astrophysics
Abstract

During the last couple of years, observers have started to make plans for a Virtual Observatory, as a federation of existing data bases, connected through levels of software that enable rapid searches, correlations, and various forms of data mining. We propose to extend the notion of a Virtual Observatory by adding archives of simulations, together with interactive query and visualization capabilities, as well as ways to simulate observations of simulations in order to compare them with observations. For this purpose, we have already organized two small workshops, earlier in 2001, in Tucson and Aspen. We have also provided concrete examples of theory data, designed to be federated with a Virtual Observatory. These data stem from a project to construct an archive for our large-scale simulations using the GRAPE-6 (a 32-Teraflops special purpose computer for stellar dynamics). We are constructing interfaces by which remote observers can observe these simulations. In addition, these data will enable detailed comparisons between different simulations., Comment: 4 pages, ADASS-XI conference, http://bima.astro.umd.edu/nemo/nvo/

17. Bring out your codes! Bring out your codes! (Increasing Software Visibility and Re-use)

Author

Allen, A., Berriman, B., Brunner, R., Burger, D., Duprie, K., Hanisch, R. J., Mann, R., Jessica Mink, Sandin, C., Shortridge, K., and Teuben, P.

Subjects
Software Engineering (cs.SE), FOS: Computer and information sciences, Computer Science - Software Engineering, FOS: Physical sciences, Computer Science - Digital Libraries, Digital Libraries (cs.DL), Astrophysics - Instrumentation and Methods for Astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM)
Abstract

Progress is being made in code discoverability and preservation, but as discussed at ADASS XXI, many codes still remain hidden from public view. With the Astrophysics Source Code Library (ASCL) now indexed by the SAO/NASA Astrophysics Data System (ADS), the introduction of a new journal, Astronomy & Computing, focused on astrophysics software, and the increasing success of education efforts such as Software Carpentry and SciCoder, the community has the opportunity to set a higher standard for its science by encouraging the release of software for examination and possible reuse. We assembled representatives of the community to present issues inhibiting code release and sought suggestions for tackling these factors. The session began with brief statements by panelists; the floor was then opened for discussion and ideas. Comments covered a diverse range of related topics and points of view, with apparent support for the propositions that algorithms should be readily available, code used to produce published scientific results should be made available, and there should be discovery mechanisms to allow these to be found easily. With increased use of resources such as GitHub (for code availability), ASCL (for code discovery), and a stated strong preference from the new journal Astronomy & Computing for code release, we expect to see additional progress over the next few years., Birds of a Feather session at ADASS XXII (Champaign, IL; November, 2012) for proceedings; 4 pages. Organized by the Astrophysics Source Code Library (ASCL), which is available at ascl.net Unedited notes taken at the session are available here: http://asterisk.apod.com/wp/?p=192

18. Astrophysics Source Code Library

Author

Alice Allen, Duprie, K., Berriman, B., Hanisch, R. J., Mink, J., and Teuben, P. J.

Subjects
FOS: Computer and information sciences, FOS: Physical sciences, Digital Libraries (cs.DL), Computer Science - Digital Libraries, Astrophysics - Instrumentation and Methods for Astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM)
Abstract

The Astrophysics Source Code Library (ASCL), founded in 1999, is a free on-line registry for source codes of interest to astronomers and astrophysicists. The library is housed on the discussion forum for Astronomy Picture of the Day (APOD) and can be accessed at http://ascl.net. The ASCL has a comprehensive listing that covers a significant number of the astrophysics source codes used to generate results published in or submitted to refereed journals and continues to grow. The ASCL currently has entries for over 500 codes; its records are citable and are indexed by ADS. The editors of the ASCL and members of its Advisory Committee were on hand at a demonstration table in the ADASS poster room to present the ASCL, accept code submissions, show how the ASCL is starting to be used by the astrophysics community, and take questions on and suggestions for improving the resource., Description of ASCL display table at ADASS XXII (Champaign, IL; November, 2012) for proceedings; 4 pages, 2 figures. The ASCL, indexed by ADS, is available at ascl.net A PowerPoint presentation running at the table is available online: http://asterisk.apod.com/wp/?p=194 Some of the resources and information made available at the table are listed online: http://asterisk.apod.com/wp/?p=216

21. Immersive 4-D interactive visualization of large-scale simulations

Author

Teuben, P., Hut, P., Levy, S., Junichiro Makino, Mcmillan, S., Zwart, Sp, Shara, M., and Emmart, C.

Subjects
Astrophysics (astro-ph), FOS: Physical sciences, Astrophysics
Abstract

In dense clusters a bewildering variety of interactions between stars can be observed, ranging from simple encounters to collisions and other mass-transfer encounters. With faster and special-purpose computers like GRAPE, the amount of data per simulation is now exceeding 1TB. Visualization of such data has now become a complex 4D data-mining problem, combining space and time, and finding interesting events in these large datasets. We have recently starting using the virtual reality simulator, installed in the Hayden Planetarium in the American Museum for Natural History, to tackle some of these problem. This work (http://www.astro.umd.edu/nemo/amnh/) reports on our first ``observations'', modifications needed for our specific experiments, and perhaps field ideas for other fields in science which can benefit from such immersion. We also discuss how our normal analysis programs can be interfaced with this kind of visualization., Comment: 4 pages, 1 figure, ADASS-X conference proceedings

22. Practices in Code Discoverability

Author

Teuben, P., Allen, A., Robert Nemiroff, and Shamir, L.

Subjects
FOS: Physical sciences, Astrophysics - Instrumentation and Methods for Astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM)
Abstract

Much of scientific progress now hinges on the reliability, falsifiability and reproducibility of computer source codes. Astrophysics in particular is a discipline that today leads other sciences in making useful scientific components freely available online, including data, abstracts, preprints, and fully published papers, yet even today many astrophysics source codes remain hidden from public view. We review the importance and history of source codes in astrophysics and previous efforts to develop ways in which information about astrophysics codes can be shared. We also discuss why some scientist coders resist sharing or publishing their codes, the reasons for and importance of overcoming this resistance, and alert the community to a reworking of one of the first attempts for sharing codes, the Astrophysics Source Code Library (ASCL). We discuss the implementation of the ASCL in an accompanying poster paper. We suggest that code could be given a similar level of referencing as data gets in repositories such as ADS., ASCL codes are now incoorporated into ADS

23. Image Processing in Python With Montage

Author

Good, John, Berriman, G. Bruce, Teuben, P. J., Pound, M. W., Thomas, B. A., and Warner, E. M.

Subjects
Astronomy, Image Processing, Image and Video Processing (eess.IV), FOS: Electrical engineering, electronic engineering, information engineering, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, FOS: Physical sciences, Electrical Engineering and Systems Science - Image and Video Processing, Astrophysics - Instrumentation and Methods for Astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM), Python
Abstract

he Montage image mosaic engine has found wide applicability in astronomy re- search, integration into processing environments, and is an examplar application for the development of advanced cyber-infrastructure. It is written in C to provide performance and portability. Linking C/C++ libraries to the Python kernel at run time as binary ex- tensions allows them to run under Python at compiled speeds and enables users to take advantage of all the functionality in Python. We have built Python binary extensions of the 59 ANSI-C modules that make up version 5 of the Montage toolkit. This has in- volved a turning the code into a C library, with driver code fully separated to reproduce the calling sequence of the command-line tools; and then adding Python and C linkage code with the Cython library, which acts as a bridge between general C libraries and the Python interface. We will demonstrate how to use these Python binary extensions to perform im- age processing, including reprojecting and resampling images, rectifying background emission to a common level, creation of image mosaics that preserve the calibration and astrometric fidelity of the input images, creating visualizations with an adaptive stretch algorithm, processing HEALPix images, and analyzing and managing image metadata., Funded by National Science Foundation (US) under Grant Number NSF.1642453

Published
2019

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