Software:SORCER

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SORCER
LicenseApache License
Official websitesorcersoft.org/project/site/

The service-oriented computing environment (SORCER)[upper-alpha 1] is a distributed computing platform implemented in Java. It allows writing network-programs (called "exertions") that operate on wrapped applications (services) to spread across the network. SORCER is often utilized in scenarios similar to those where grids are used (grid computing) in order to run parallel tasks.

SORCER's predecessor was the federated intelligent product environment (FIPER), which was software for a GE aircraft-engine-design project funded from 1999 to 2003 by the National Institute of Standards and Technology's Advanced Technology Program. The project followed the principal investigator, and thus SORCER Labs was founded in November 2002 at Texas Tech University (TTU);[upper-alpha 2] SORCER core's source code was made public in 2013 under the open source Apache license.[upper-alpha 3] SORCER (and FIPER) were developed at GE from 1994 to 2002, at TTU through 2009, and since then at the United States Air Force Research Laboratory (AFRL). Other groups which have made use of SORCER include Beijing Jiaotong University in China, Cranfield University in the United Kingdom, and Ulyanovsk State University in Russia.

Overview

SORCER is a computing platform that allows the end user to program dynamic front-end compound services, called exertionsTemplate:Neologism inline, bound at runtime by the SORCER OS (SOS) to federations of service providers as new back-end dynamic services.[clarification needed] The SOS utilizes the service object-orient architecture (SOOA)Template:Neologism inline and a federated method invocation.[1] The front-end services created by the end users are service collaborations of users' applications, tools, and utilities with their data and corresponding control strategies.[2] The end users in understandable domain specific languages (DSL) define only their service-oriented process expressions and the SOS makes that process expressions actualized by the corresponding dynamic service federations in the network.[clarification needed]

SORCER is a federated service-oriented platform with a front-end federated service-oriented programming environment, a matching operating system, and a federated virtual processor. The architecture of SORCER is based on the concept: Everything Anywhere Anytime As a Service (EaaaS). Therefore, the end user service requests (front-end expression) as well service providers (back-end federations) are treated as services. SORCER is the first platform that created front-end service-oriented mogrammingTemplate:Neologism inline (programming or modeling or both) as the key element of its federated service orientation. SORCER mogramsTemplate:Neologism inline are called exertionsTemplate:Neologism inline. The exertion-oriented programmingTemplate:Neologism inline has its roots in the FIPER project.[3] An exertionTemplate:Neologism inline as the front-end service composition defined by the user is bound by the SORCER OS (SOS) to service providers (local and/or remote) to form a matching collaborative service federation at runtime - a virtual service processor of the SORCER platform.

File:SORCER Operating System.tif

SORCER Operating System

The SORCER Operating System (SOS) manages execution of front-end service-oriented mogramsTemplate:Neologism inline and related resources including required service providers. The SOOA kernel by itself is the service-oriented system made up of system service providers architecturally equivalent to domain specific service providers. A service provider is a container for service beans[clarification needed] that is responsible for deploying services in the network, publishing their proxies to registries, and allowing the SOS to access proxies of deployed providers. Providers maintain their availability in the network continuously by renewing leases for their registered object proxies; registries intercept these announcements and cache/remove proxy objects per providers’ requests. The SOS looks up proxies by sending queries to registries and making selections from the currently available providers or provisions on-demand required ones.[4] Queries generally contain search criteria related to the type and quality of service. Registries facilitate searching by storing proxy objects of services and making them available to the SOS. Providers use discovery/join protocols to publish services in the network and the SOS uses discovery/join protocols to discover registries and lookup proxies in those registries.

Applications

The basic exertion-oriented platformTemplate:Neologism inline was developed at GE Global Research Center with the partners of the FIPER project (1999-2003). FIPER was used at that time to design aircraft engines.[5][6][7] The Multidisciplinary Science and Technology Center, the United States Air Force Research Laboratory/WPAFB is using SORCER to address the physics-based distributed collaborative design for aerospace vehicle development.[8][9][10] SORCER was selected for comparative study of evolutionary computing of optimization techniques at the Cranfield University, UK.[11] In China, SORCER is used as noise mapping platform for urban traffic,[12] a resource integration platform,[13] engineering collaborative design and manufacturing environment,[14][15] and at the Wright State University as a collaborative computational framework for multidisciplinary and reliability-based analysis and optimization.[16]

History

SORCER follows up on the FIPER project (1999-2003) - funded by National Institute of Standards and Technology Advanced Technology Program[17]Template:Primary-source-inline[failed verification]. The FIPER software environment was developed and demonstrated at the GE Global Research Center (Chief software architect and lead developer Michael Sobolewski [1][18] and engineering application development led by R. Kolonay) in collaboration with GE Aviation (Cincinnati, OH), Goodrich Corporation Aerostructures Group (Chula Vista, CA), Parker Hannifin Corporation (Mentor, OH), Engineous Software, Inc. (Cary, NC) and Ohio University (Athens, OH). When the project was finished M. Sobolewski established the SORCER Laboratory[19]Template:Primary-source-inline at Texas Tech University (2002-2009) where he continued his FIPER-based research. The SORCER Laboratory was partially funded by General Electric, Texas Tech University, Sun Microsystems, Air Force Research Laboratory, and others.[citation needed] During that time 28 graduate research studies (M.S. and Ph.D.) were completed[citation needed] all of which contributed to the development of the SORCER platform and the foundations of federated service-oriented computing. In the meantime, a number of collaborative SORCER-based projects (2007-2010) were realized together with universities from other countries (Beijing Jiaotong University, China[20]Template:Primary-source-inline; Beihang University, China[21]Template:Primary-source-inline; Ulyanovsk State University and Samara State Aerospace University, Russia[22]Template:Primary-source-inline).

Since 2008 M. Sobolewski continues his SORCER applied research at the Multidisciplinary Science and Technology Center, Air Force Research Laboratory/WPAFB[9][failed verification] and starting in 2010 simultaneously at the Polish Japanese Institute of Information Technology.[citation needed] In 2010 the SORCER Laboratory became an independent research organization focused on the development federated service-oriented computing.[citation needed]

Since 2013 the development of SORCER is continued simultaneously by Sorcersoft.com in cooperation with the Polish-Japanese Institute of Information Technology and SMT Software.[citation needed]

Notes

References

  1. Sobolewski, Michael (2009). "Metacomputing with Federated Method Invocation". Advances in Computer Science and IT. In-Tech. pp. 337–363. ISBN 978-953-7619-51-0. http://sorcersoft.org/publications/papers/2009/metacomputingwithfmi.pdf. Retrieved 2010-01-27. 
  2. Thompson, Ernest D (2012). "Incorporation of computational fluid dynamics into flight vehicle preliminary design". University of Dayton, 2012. University of Dayton. pp. 230–241. http://rave.ohiolink.edu/etdc/view?acc_num=dayton1335270317. 
  3. Goteng, Gokop (2009). "Development of a Grid Service for Multi-objective Design Optimisation". School of Applied Sciences, 2009. Cranfield University. https://dspace.lib.cranfield.ac.uk/bitstream/1826/4423/1/Gokop_Goteng_thesis_2009.pdf. 
  4. Rubach, Paweł (2010-11-16). "Optimal Resource Allocation in Federated Metacomputing Environments". Ph.D. Dissertation. Warsaw University of Technology, Faculty of Electronics and Information Technology. http://iiigc2.sgh.waw.pl/prubach/wp-content/uploads/2021/01/PhD_Rubach.pdf. 
  5. Seeley, C.E.; Tangirila V.E.; Kolonay R.M.; Bailey M.W. (2001). "Multidisciplinary analysis and optimization of combustion sub-system using a network-centric approach". 42nd AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference AIAA-2001-1270. American Institute of Aeronautics and Astronautics. doi:10.2514/6.2001-1270. 
  6. Tappeta, R.V.; Kolonay R.M.; Burton S.A (2002). "Application of Approximate Optimization to Turbine Blade Design in a Network-Centric Environment". 43rd AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials Conference AIAA-2002-1588. American Institute of Aeronautics and Astronautics. doi:10.2514/6.2002-1588. ISBN 978-1-62410-117-5. 
  7. Liao, Li; Shashishekara Talya; Raymond Kolonay (2004). "2D/3D CFD Design Optimization Using the Federated Intelligent Product Environment (FIPER) Technology". 9th AIAA/ISSMO Symposium on Multidisciplinary Analysis and Optimization AIAA-2002-5479. IAIAA. doi:10.2514/6.2004-1847. ISBN 978-1-62410-079-6. http://arc.aiaa.org/doi/abs/10.2514/6.2002-5479. 
  8. Kolonay, Raymond; Scott Burton (2004). "Object Models for Distributed Multidisciplinary Analysis and Optimization (MAO) Environments that Promotes CAE Interoperability". 10th AIAA/ISSMO Multidisciplinary Analysis and Optimization Conference AIAA 2004-4599. AIAA. doi:10.2514/6.2004-4599. ISBN 978-1-62410-019-2. 
  9. 9.0 9.1 Kolonay, Raymond (2013). "Physics-Based Distributed Collaborative Design for Aerospace Vehicle Development and Technology Assessment". Proceedings of the 20th ISPE International Conference on Concurrent Engineering. IOS Press. pp. 381–390. ISBN 978-1-61499-301-8. http://ebooks.iospress.nl/publication/34808. 
  10. Scott A., Burton; Edward J. Alyanak; Raymond M. Kolonay (2012). "Efficient Supersonic Air Vehicle Analysis and Optimization Implementation using SORCER". 12th AIAA Aviation Technology, Integration, and Operations (ATIO) Conference and 14th AIAA/ISSM, AIAA 2012-5520. AIAA. pp. 381–390. doi:10.2514/6.2012-5520. ISBN 978-1-60086-930-3. 
  11. Tiwari, Ashutosh; Gokop Goteng; Rajkumar Roy (2007). "Evolutionary Computing within Grid Environment". Advances in Evolutionary Computing for System Design, Studies in Computational Intelligence Volume 66, 2007. Springer-Verlag. doi:10.2514/6.2004-4599. ISBN 978-1-62410-019-2. https://link.springer.com/chapter/10.1007%2F978-3-540-72377-6_10. 
  12. Li, Nan; Tao Feng; Bin Liu (2011). "ICDMA '11 Proceedings of the 2011 Second International Conference on Digital Manufacturing & Automation". A SOOA Based Distributed Computing Mechanism for Road Traffic Noise Mapping. IEEE Computer Society Washington, DC, USA. pp. 109–112. doi:10.1109/ICDMA.2011.34. ISBN 978-0-7695-4455-7. 
  13. Lingjun, Kong; Wensheng Xu; Jianzhong Cha; Jiaqing Yu; Nan Li (2011). "A resource integration platform for manufacturing grid based on SOOA". Electronic and Mechanical Engineering and Information Technology (EMEIT), 2011 International Conference on (Volume:3 ). pp. 1466–1469. doi:10.1109/EMEIT.2011.6023325. ISBN 978-1-61284-087-1. 
  14. ZHANG, Rui-hong; LI Nan; CHA Jian-zhong; LU Yi-ping (2008). "Engineering Collaborative Design Environment Based on Service-oriented Architecture". JOURNAL OF HEBEI UNIVERSITY OF TECHNOLOGY, Vol.37 No.4. pp. 40–44. http://en.cnki.com.cn/Article_en/CJFDTOTAL-HBGB200804012.htm. 
  15. 孔令军, (Kong Lingjun) (2013-06-01). "云制造环境下的设计资源服务化方法研究". Research on servitization method of design resources in the cloud manufacturing environment. 北京交通大学 (Beijing Jiaotong University) Ph.D. Dissertation. http://cdmd.cnki.com.cn/Article/CDMD-10004-1013279659.htm. 
  16. Aithala, Karkada Nagesha (2011). "A Collaborative Computational Framework for Multidisciplinary and Reliability-based Analysis and Optimization Using SORCER". Wright State University, 2011. Wright State University. https://etd.ohiolink.edu/ap:0:0:APPLICATION_PROCESS=DOWNLOAD_ETD_SUB_DOC_ACCNUM:::F1501_ID:wright1316463759,attachment. 
  17. "ATP Project Brief - 99-01-3079". http://jazz.nist.gov/atpcf/prjbriefs/prjbrief.cfm?ProjectNumber=99-01-3079. 
  18. Michael Sobolewski, Marquis Who's Who
  19. The Computer Science Alumni Newsletter - SORCER. 13. Texas Tech University. Fall 2002. p. 1. http://www.depts.ttu.edu/cs/department/docs/newsletter/fall_2002.pdf. "The Laboratory for Service-Oriented Computing EnviRonment (SORCER), headed up by Mike Sobolewski, is an interdisciplinary laboratory at the Computer Science Department at Texas Tech University.". 
  20. "Agreementfor Collaborative Research on SCoDProjectbetweenBeijingJiaotongUniversity(BJTU) and TexasTechUniversity (TTU)". Texas Tech University. July 2007. http://sorcersoft.org/docs/Agreement-Jiaotong.PDF. 
  21. "TheAgreement signed for Collaborative Research CoSEA Project between Beihang University @UAA) and TexasTech University(TTII)". 30 March 2007. http://sorcersoft.org/docs/Agreement-BeiHang.PDF. 
  22. "Agreementfor Collaborative Research on SCoDProjectbetweenBeijingJiaotongUniversity(BJTU) and TexasTechUniversity (TTU)". 9 July 2007. http://sorcersoft.org/docs/Agreement-Jiaotong.PDF. 

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