R. Sinnott, Christopher Bayliss, T. Doherty, David B. Martin, C. Millar, G. Stewart, J. Watt, A. Asenov, G. Roy, Scott Roy, C. Davenhall, B. Harbulot, M. Jones
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Similarly, the project also demands seamless access to large scale high performance compute resources for atomic scale device simulations and the capability to manage the hundreds of thousands of files and the metadata associated with these simulations. Within this context, the project has explored a wide range of authentication and authorization infrastructures facilitating compute resource access and providing fine-grained security over numerous distributed file stores and files. We conclude that no single security solution meets the needs of the project. This paper describes the experiences of applying X.509-based certificates and public key infrastructures, VOMS, PERMIS, Kerberos and the Internet2 Shibboleth technologies for nanoCMOS security. We outline how we are integrating these solutions to provide a complete end-to-end security framework meeting the demands of the nanoCMOS electronics domain.","PeriodicalId":345341,"journal":{"name":"2008 IEEE International Symposium on Parallel and Distributed Processing with Applications","volume":"1 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"2008-12-10","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"6","resultStr":"{\"title\":\"Integrating Security Solutions to Support nanoCMOS Electronics Research\",\"authors\":\"R. Sinnott, Christopher Bayliss, T. Doherty, David B. Martin, C. Millar, G. Stewart, J. Watt, A. Asenov, G. Roy, Scott Roy, C. Davenhall, B. Harbulot, M. Jones\",\"doi\":\"10.1109/ISPA.2008.132\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"The UK Engineering and Physical Sciences Research Council (EPSRC) funded project ¿Meeting the Design Challenges of nanoCMOS Electronics¿ (nanoCMOS) is developing a research infrastructure for collaborative electronics research across multiple institutions in the UK with especially strong industrial and commercial involvement. Unlike other domains, the electronics industry is driven by the necessity of protecting the intellectual property of the data, designs and software associated with next generation electronics devices and therefore requires fine-grained security. Similarly, the project also demands seamless access to large scale high performance compute resources for atomic scale device simulations and the capability to manage the hundreds of thousands of files and the metadata associated with these simulations. Within this context, the project has explored a wide range of authentication and authorization infrastructures facilitating compute resource access and providing fine-grained security over numerous distributed file stores and files. We conclude that no single security solution meets the needs of the project. This paper describes the experiences of applying X.509-based certificates and public key infrastructures, VOMS, PERMIS, Kerberos and the Internet2 Shibboleth technologies for nanoCMOS security. 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Integrating Security Solutions to Support nanoCMOS Electronics Research
The UK Engineering and Physical Sciences Research Council (EPSRC) funded project ¿Meeting the Design Challenges of nanoCMOS Electronics¿ (nanoCMOS) is developing a research infrastructure for collaborative electronics research across multiple institutions in the UK with especially strong industrial and commercial involvement. Unlike other domains, the electronics industry is driven by the necessity of protecting the intellectual property of the data, designs and software associated with next generation electronics devices and therefore requires fine-grained security. Similarly, the project also demands seamless access to large scale high performance compute resources for atomic scale device simulations and the capability to manage the hundreds of thousands of files and the metadata associated with these simulations. Within this context, the project has explored a wide range of authentication and authorization infrastructures facilitating compute resource access and providing fine-grained security over numerous distributed file stores and files. We conclude that no single security solution meets the needs of the project. This paper describes the experiences of applying X.509-based certificates and public key infrastructures, VOMS, PERMIS, Kerberos and the Internet2 Shibboleth technologies for nanoCMOS security. We outline how we are integrating these solutions to provide a complete end-to-end security framework meeting the demands of the nanoCMOS electronics domain.