Vol: 58(72) No: 1 / March 2013 Data Representation for Communication Networks Information Integration and Programmability Stefano-Niko Orzen Department of Computers, “Politehnica” University of Timişoara, Faculty of Automation and Computers, 300223, Timişoara, România, e-mail: niko.orzen@cs.upt.ro Ştefan Holban Department of Computers, “Politehnica” University of Timişoara, Faculty of Automation and Computers, 300223, Timişoara, România, e-mail: stefan.holban@cs.upt.ro Keywords: representation, infrastructure, topology, network, frame, integrity Abstract This paper has the central characteristic in proving that communication networks formed of digital signal processing devices, computers and telecommunication hardware, having also analog processing components, represent information to their users in conformance with criterion’s and technical requirements. While all the technology aspects move to automated functions, which ease the administration process of any type of computerized networks, every central technology that is essential, is specialized and generalized to the case of a good applicability in the sections which deal with the necessities of building communication networks. The representation of meaning through measurement of information flow is given in topologies that convey a significance to the overall infrastructure which must be integral, concerning the value of communication. The results of current research on information carrier mediums and logical description of how data is ascertained a signifying context, are all dependent of the testing on hardware, which must comply to it\'s purpose that is designed with special described rules meeting a limit to which a reliability feature is standardized. Networking is a structural task to achieve, when more techniques are put together, to allow the interconnection of devices, through information flow at a logical level. The programmability of switched and/or routed networks, is a feature of integrated information which is computable, while traversing the specified path from one node to another in a system. References [1] H. Zimmermann, OSI Reference Model – The ISO Model of Architecture for Open Systems Interconnection, IEEE Transactions on Communications, Vol. Com-28, No. 4, April 1980. [2] C. Pavan, R. M. Morais, J. R. Ferreira da Rocha, A. N. Pinto, Generating Realistic Optical Transport Network Topologies, Journal of Optical Communication Networks/Vol. 2, No. 1/January 2010, Optical Society of America, 2010. [3] A. Babakhouya, Y. Challal, A. Bouabdallah, A Simulation Analysis of Routing Misbehaviour in Mobile Ad Hoc Networks, NGMAST/Workshop on Mobile Security, Europe, 2008. [4] L. Frank, M. Hamdi, C. Giraldo Rodriguez, Topology Modeling on Emergency Communication Networks: Caveats and Pitfalls, Telecom Bretagne – Institut Telecom, Site of Toulouse, France. [5] S. Wagner-Dibuz, Frames for Protocol Description, Central Research Institute for Physics, 1st Finnish-Hungarian Workshop on Programming Languages and Software Tools, Szeged Hungary, 8 – 11, 1989. [6] G. Casale, M. Gribaudo, G. Serazzi, Tools for Performance Evaluation of Computer Systems: Historical Evolution and Perspectives, Imperial College London, Politecnico di Milano. [7] S. J. Cho, An Empirical Model of Mainframe Computer Investment, Department of Economics, Yale University, September 2001. [8] T. Garfinkel, M. Rosenblum, A Virtual Machine Introspection Based Architecture for Intrusion Detection, Computer Science Department, Stanford University. |