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Open source middleware system for volunteer and grid computing From Wikipedia, the free encyclopedia
The Berkeley Open Infrastructure for Network Computing[2] (BOINC, pronounced /bɔɪŋk/ – rhymes with "oink"[3]) is an open-source middleware system for volunteer computing (a type of distributed computing).[4] Developed originally to support SETI@home,[5] it became the platform for many other applications in areas as diverse as medicine, molecular biology, mathematics, linguistics, climatology, environmental science, and astrophysics, among others.[6] The purpose of BOINC is to enable researchers to utilize processing resources of personal computers and other devices around the world.
Developer(s) | University of California, Berkeley |
---|---|
Initial release | 10 April 2002 |
Stable release | |
Preview release | 8.0.4
/ 23 July 2024 |
Repository | |
Written in | C++ (client/server) PHP (project CMS) Java/Kotlin (Android client) |
Operating system | Windows macOS Linux Android FreeBSD Raspberry Pi OS |
Type | Grid computing and volunteer computing |
License | LGPL-3.0-or-later[1] Project licensing varies |
Website | boinc |
BOINC development began with a group based at the Space Sciences Laboratory (SSL) at the University of California, Berkeley, and led by David P. Anderson, who also led SETI@home. As a high-performance volunteer computing platform, BOINC brings together 34,236 active participants employing 136,341 active computers (hosts) worldwide, processing daily on average 20.164 PetaFLOPS as of 16 November 2021[update][7] (it would be the 21st largest processing capability in the world compared with an individual supercomputer).[8] The National Science Foundation (NSF) funds BOINC through awards SCI/0221529,[9] SCI/0438443[10] and SCI/0721124.[11] Guinness World Records ranks BOINC as the largest computing grid in the world.[12]
BOINC code runs on various operating systems, including Microsoft Windows, macOS, Android,[13] Linux, and FreeBSD.[14] BOINC is free software released under the terms of the GNU Lesser General Public License (LGPL).
BOINC was originally developed to manage the SETI@home project. David P. Anderson has said that he chose its name because he wanted something that was not "imposing", but rather "light, catchy, and maybe - like 'Unix' - a little risqué", so he "played around with various acronyms and settled on 'BOINC'".[15]
The original SETI client was a non-BOINC software exclusively for SETI@home. It was one of the first volunteer computing projects, and not designed with a high level of security. As a result, some participants in the project attempted to cheat the project to gain "credits", while others submitted entirely falsified work. BOINC was designed, in part, to combat these security breaches.[16]
The BOINC project started in February 2002, and its first version was released on April 10, 2002. The first BOINC-based project was Predictor@home, launched on June 9, 2004. In 2009, AQUA@home deployed multi-threaded CPU applications for the first time,[17] followed by the first OpenCL application in 2010.
As of 15 August 2022, there are 33 projects on the official list.[18] There are also, however, BOINC projects not included on the official list. Each year, an international BOINC Workshop is hosted to increase collaboration among project administrators. In 2021, the workshop was hosted virtually.[19]
While not affiliated with BOINC officially, there have been several independent projects that reward BOINC users for their participation, including Charity Engine (sweepstakes based on processing power with prizes funded by private entities who purchase computational time of CE users), Bitcoin Utopia (now defunct), and Gridcoin (a blockchain which mints coins based on processing power).
BOINC is software that can exploit the unused CPU and GPU cycles on computer hardware to perform scientific computing. In 2008, BOINC's website announced that Nvidia had developed a language called CUDA that uses GPUs for scientific computing. With NVIDIA's assistance, several BOINC-based projects (e.g., MilkyWay@home. SETI@home) developed applications that run on NVIDIA GPUs using CUDA. BOINC added support for the ATI/AMD family of GPUs in October 2009. The GPU applications run from 2 to 10 times faster than the former CPU-only versions. GPU support (via OpenCL) was added for computers using macOS with AMD Radeon graphic cards, with the current BOINC client supporting OpenCL on Windows, Linux, and macOS. GPU support is also provided for Intel GPUs.[20]
BOINC consists of a server system and client software that communicate to process and distribute work units and return results.
A BOINC app also exists for Android, allowing every person owning an Android device – smartphone, tablet and/or Kindle – to share their unused computing power. The user is allowed to select the research projects they want to support, if it is in the app's available project list.
By default, the application will allow computing only when the device is connected to a WiFi network, is being charged, and the battery has a charge of at least 90%.[21] Some of these settings can be changed to users needs. Not all BOINC projects are available[22] and some of the projects are not compatible with all versions of Android operating system or availability of work is intermittent. Currently available projects[22] are Asteroids@home, Einstein@Home, LHC@home, Moo! Wrapper, Rosetta@home, Universe@Home, World Community Grid and Yoyo@home . As of September 2021, the most recent version of the mobile application can only be downloaded from the BOINC website or the F-Droid repository as the official Google Play store does not allow downloading and running executables not signed by the app developer and each BOINC project has their own executable files.
BOINC can be controlled remotely by remote procedure calls (RPC), from the command line, and from a BOINC Manager. BOINC Manager currently has two "views": the Advanced View and the Simplified GUI. The Grid View was removed in the 6.6.x clients as it was redundant. The appearance (skin) of the Simplified GUI is user-customizable, in that users can create their own designs.
A BOINC Account Manager is an application that manages multiple BOINC project accounts across multiple computers (CPUs) and operating systems. Account managers were designed for people who are new to BOINC or have several computers participating in several projects. The account manager concept was conceived and developed jointly by GridRepublic and BOINC. Current and past account managers include:
BOINC is used by many groups and individuals. Some BOINC projects are based at universities and research labs while others are independent areas of research or interest.[24]
Project Name | Publications | Launched | Status | Operating System | GPU App | Sponsor | Category | Research Focus |
---|---|---|---|---|---|---|---|---|
climateprediction.net | 142 papers[25] | 2003-12-09 | 307,359 volunteers[26] | Windows, Linux, ARM, macOS[27] | No | Oxford University | Climate change | Improve climate prediction models. Sub-project: Seasonal Attribution Project. |
DENIS@home | 6 papers[28] | 2015-03-16 | 6,111 volunteers[29] | Windows, Linux, ARM, macOS[30] | No | Universidad San Jorge , Zaragoza, Spain | Medical physiology | Simulate electrical activity of cardiac cells |
Einstein@Home | 41 papers[31] | 2005-02-19 | 1,041,796 volunteers[32] | Windows, Linux, ARM, macOS, Android[33] | GPU CPU | University of Wisconsin–Milwaukee, Max Planck Institute | Astrophysics | Search for pulsars using radio signals and gravitational wave data |
Gerasim@Home | 9 papers[34] | 2007-02-10 | 6,811 volunteers[35] | Windows, Linux[36] | No | Southwest State University (Russia) | Multiple applications | Research in discrete mathematics and logic control systems |
GPUGRID.net | 53 papers[37] | 2007-12-05 | 46,874 volunteers[38] | Windows, Linux, macOS[39] | NVIDIA GPU only | Barcelona Biomedical Research Park | Molecular biology | Perform full-atom molecular simulations of proteins on Nvidia GPUs for biomedical research |
IThena.Measurements | paper[40] | 2019-09-25[41] | 751[42] volunteers | Windows, Linux, ARM[43] | No | Cyber-Complex Foundation | Computer science | Map internet nodes |
iThena.Computational | 2021-10-31 | 301 volunteers[44] | Windows, Linux[45] | No | Cyber-Complex Foundation | Computer science | Calculate data from iThena.measurements | |
LHC@home | 68 papers[46] | 2004-01-09 | 178,623 volunteers[47] | Windows, Linux, ARM, macOS, Android, FreeBSD[48] | No | CERN | Physics | Help construct and test the Large Hadron Collider and search for fundamental particles |
MilkyWay@home | 25 papers[49] | 2007-07-07 | 250,447 volunteers[50] | Windows, Linux, macOS[51] | No | Rensselaer Polytechnic Institute | Astronomy | Create a simulation of the Milky Way galaxy using data from the Sloan Digital Sky Survey |
MindModeling@Home | 6 papers[52] | 2007-07-07 | 24,574 volunteers[53] | Windows, Linux, macOS[54] | No | University of Dayton Research Institute and Wright State University | Cognitive science | Making cognitive models of the human mind |
PrimeGrid | 3 papers[55] | 2005-06-12 | 353,261 volunteers[56] | Windows, Linux, macOS[57] | GPU CPU | Independent | Mathematics | Search for primes such as Generalized Fermat primes, 321 primes, Sierpinski numbers, Cullen-Woodall primes, Proth prime, and Sophie Germain primes. Subprojects include Seventeen or Bust, Riesel Sieve, and AP27 Search. |
RALPH@Home | Rosetta@home | 2006-02-15 | 5548 volunteers[58] | Windows, Linux, ARM, macOS, Android[59] | GPU CPU | University of Washington | Molecular biology | Test project for Rosetta@home |
Rosetta@home | 181 papers[60] | 2005-10-06 | 1,373,480 volunteers[61] | Windows, Linux, ARM, macOS, Android[62] | No | University of Washington | Molecular biology | Protein structure prediction for disease research |
Tn-grid | 8 papers[63] | 2013-12-19 | 3,201 volunteers[64] | Windows, Linux, macOS[65] | No | University of Trento | Genetics | Currently deploying gene@home work to expand gene networks |
Universe@Home | 14 papers[66] | 2015-02-21 | 51,651 volunteers[67] | Windows, Linux, ARM, macOS, Android[68] | No | University of Warsaw | Astronomy | Research in Physics and Astronomy |
World Community Grid | 77 papers[69] | 2004-11-16 | 85,119 volunteers[70] | Windows, Linux, ARM, macOS, Android[71] | GPU CPU | Krembil Research Institute | Multiple applications | Subprojects: Open Pandemics - COVID-19. Clean Energy Project, GO Drug Search for Leishmaniasis, Fight Against Malaria, Computing for Clean Water, Discovering Dengue Drugs - Together, OpenZika, Help Cure Muscular Dystrophy, Help Defeat Cancer, Help Conquer Cancer, Help Fight Childhood Cancer, Smash Childhood Cancer, Human Proteome Folding Project, Uncovering Genome Mysteries, FightAIDS@Home, Let's outsmart Ebola together, Mapping Cancer Markers, Help Stop TB. |
Yoyo@home | 9 papers[72] | 2007-07-19 | 94,236 volunteers[73] | Windows, Linux, macOS, Android, ARM, Solaris, Sony Playstation 3[74] | No | Independent | Multiple applications | Using the BOINC Wrapper with existing volunteer projects |
Project Name | Publications | Launched | Status | Operating System | GPU app | Sponsor | Category | Research Focus |
---|---|---|---|---|---|---|---|---|
SETI@home | 12 papers[75] | 1999-05-17 | 1,808,938 volunteers[76] | Windows, Linux, macOS, Android[77] | GPU CPU | University of California, Berkeley | Astronomy | Analyzing radio frequencies from space to search for extraterrestrial life. Sub project: Astropulse |
SETI@home beta | see above | 2006-01-12 | GPU CPU | University of California, Berkeley | Software testing | Test project for SETI@home | ||
ABC@Home | paper[78] | 2006-11-21 | No | Mathematical Institute of Leiden University | Mathematics | Find triples of the ABC conjecture | ||
AQUA@home | 4 papers[79] | 2008-12-10 | GPU CPU | D-Wave Systems | Computer science | Predict the performance of Quantum computers | ||
Artificial Intelligence System | No | Intelligence Realm Inc | Artificial intelligence | Simulate the brain using Hodgkin–Huxley models via an artificial neural network | ||||
Big and Ugly Rendering Project (BURP) | 2 papers[80] | 2004-06-17 | No | Independent | Rendering (computer graphics) | Use BOINC infrastructure with Blender (software) to render animated videos | ||
Cell Computing | No | NTT Data | Biomedical sciences | |||||
Collatz Conjecture project | paper[81] | 2009-01-06[82] | 67,719 volunteers[83] | Windows, Linux, macOS[84] | GPU CPU | Independent | Mathematics | Study the unsolved Collatz conjecture[85] |
Correlizer | 5 papers[86] | 2011[87] | No | Biology | Examining genome organization | |||
Cosmology@Home | 5 papers[88] | 2007-06-26 | 87,465 volunteers[89] | Windows, Linux, macOS[90] | No | Institut d'Astrophysique de Paris | Astronomy | Develop simulations that best describe The Universe |
DistrRTgen | 2008-01-12 | No | Independent | Cryptography | Analysis of hash strength for password security by developing rainbow tables. | |||
Docking@Home | 20 papers[91] | 2006-09-11[92] | No | University of Delaware | Molecular biology | Use the CHARMM program to model protein-ligand docking. The goal was the development of pharmaceutical drugs. | ||
EDGeS@Home | 12 papers[93] | 2009-10 | No | MTA SZTAKI Laboratory of Parallel and Distributed Systems | Multiple applications | Support of scientific applications developed by the EGEE and EDGeS community | ||
eOn | 6 papers[94] | No | University of Texas at Austin | Chemistry | Theoretical chemistry techniques to solve problems in condensed matter physics and materials science | |||
Evolution@Home | 6 papers[95] | No | Evolutionary Biology | Improve understanding of evolutionary processes | ||||
FreeHAL | 2006 | No | Independent | Artificial intelligence | Compute information for software to imitate human conversation | |||
GoofyxGrid@Home | 2016 | No | Independent | Mathematics | Mathematically implement the Infinite monkey theorem | |||
HashClash | 11 papers[96] | 2005-11-24 | No | Eindhoven University of Technology | Cryptography | Find collisions in the MD5 hash algorithm | ||
Ibercivis | 18 papers[97] | 2008-06-22 | No | Zaragoza, CETA-CIEMAT, CSIC, Coimbra | Multiple applications | Research in physics, material science and biomedicines | ||
Leiden Classical | 2 papers[98] | 2005-05-12 | No | Leiden University | Chemistry | Classical mechanics for students and scientists | ||
Malaria Control Project | 26 papers[99] | 2006-12-19 | No | Swiss Tropical and Public Health Institute | Model Diseases | Stochastic modelling of clinical epidemiology and the natural history of Plasmodium falciparum malaria | ||
uFluids@Home | 3 papers[100] | 2005-09-19 | No | Purdue University | Physics, Aeronautics | A computer simulation of two-phase flow behavior in microgravity and micro fluidics | ||
OProject@Home | paper[101] | 2012-08-13 | No | Olin Library, Rollins College | Mathematics | Algorithm analysis. The library is open and available in the Code.google.com SVN repository. | ||
orbit@home | paper[102] | 2008-04-03 | No | Planetary Science Institute | Astronomy | Monitor near-earth asteroids | ||
Pirates@home | 2004-06-02 | No | 1 Vassar College
2 Spy Hill Research |
Software testing | Mission 1: Test BOINC software and help to develop Einstein@Home screensaver[103]
Mission 2: Develop forum software for Interactions in Understanding the Universe[104] | |||
POEM@Home | 5 papers[105] | 2007-13-11 | No | University of Karlsruhe | Molecular biology | Model Protein folding using Anfinsen's dogma | ||
Predictor@home | 5 papers[106] | 2004-05-04 | No | The Scripps Research Institute | Molecular biology | Test new methods of protein structure prediction and algorithms in the context of the Sixth Biannual CASP[107] experiment | ||
proteins@home | 4 papers[108] | 2006-09-15 | No | École polytechnique | Protein structure prediction | Contribute to a better understanding of many diseases and pathologies and to progress in Medicine and Technology | ||
QMC@Home | 7 papers[109] | 2006-03-03 | No | University of Münster | Chemistry | Study the structure and reactivity of molecules using quantum chemistry and Monte Carlo techniques | ||
Quake-Catcher Network | 13 papers[110] | 2008-02-03 | No | Stanford University, then | Seismology | Use accelerometers connected to personal computers and devices to detect earthquakes and to educate about seismology | ||
Riesel Sieve | No | Mathematics | Prove that 509,203 is the smallest Riesel number by finding a prime of the form k × 2n − 1 for all odd k smaller than 509,203 | |||||
SAT@home | 8 papers[111] | 2011-09 | No | Siberian Branch of the Russian Academy of Sciences | Mathematics | Solve discrete problems by reducing them to the problem of satisfiability of Boolean formulas | ||
SIMAP | 5 papers[112] | 2006-04-26 | No | University of Vienna | Molecular biology | Investigated protein similarities | ||
SLinCA@Home | 2010-09-14 | No | National Academy of Sciences of Ukraine | Physics | Research in physics and materials science | |||
Spinhenge@home | 3 papers[113] | No | Technion – Israel Institute of Technology | genetic linkage | Used genetic linkage analysis to find disease resistant genes | |||
SZTAKI Desktop Grid | 5 papers[114] | 2005-05-26 | No | MTA SZTAKI Laboratory of Parallel and Distributed Systems | Mathematics | Find all the generalized binary number systems (in which bases are matrices and digits are vectors) up to dimension 11, understand basic universality classes of nonequilibrium system | ||
TANPAKU | 2 papers[115] | 2005-08-02[116] | No | Tokyo University of Science | Molecular biology | Protein structure prediction using the Brownian dynamics method | ||
The Lattice Project | 16 papers[117] | 2004-06-30[118] | No | University of Maryland, College Park | Life science | Multiple applications | ||
theSkyNet | 3 papers[119] | 2011-09-13 | No | International Centre for Radio Astronomy Research | Astronomy | Analysis of radio astronomy data from telescopes |
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