IJCNS  Vol.5 No.11 , November 2012
Global Electronic Dominance with Spatial Grasp
Abstract: A high-level control technology will be revealed that can dynamically establish overwhelming dominance over distributed networked systems with embedded electronic devices and any communications between them. It is based on implanting of universal control modules (that may be concealed) into key system points which collectively interpret complex but compact mission scenarios in a special high-level Distributed Scenario language (DSL). Self-evolving and self-spreading in networks, matching them in a super-virus mode, DSL scenarios can analyze their structures and states and set up any behavior needed, including creation of benign or elimination of unwanted infrastructures. The scalable technology allows us to convert any distributed networked systems into a sort of integral spatial brain capable of analyzing and withstanding unpredictable situations in a variety of important domains.
Cite this paper: P. Simon Sapaty, "Global Electronic Dominance with Spatial Grasp," International Journal of Communications, Network and System Sciences, Vol. 5 No. 11, 2012, pp. 724-735. doi: 10.4236/ijcns.2012.511076.

[1]   P. S. Sapaty, “Over-Operability in Distributed Simulation and Control,” The MSIAC’s M&S Journal Online, Vol. 4, No. 2, 2002, 8 p.

[2]   P. Sapaty, “The Over-Operability Organization of Distributed Dynamic Systems for Asymmetric Operations,” Proceedings of IMA Conference on Mathematics in Defence, Farnborough, 19 November 2009.

[3]   M. Wertheimer, “Gestalt Theory,” Erlangen, Berlin, 1925.

[4]   P. Sapaty, “Gestalt-Based Ideology and Technology for Spatial Control of Distributed Dynamic Systems,” International Gestalt Theory Congress, 16th Scientific Convention of the GTA, University of Osnabrück, Osnabrück, 26-29 March 2009.

[5]   P. Sapaty, “Gestalt-Based Integrity of Distributed Networked Systems,” SPIE Europe Security + Defence, bcc Berliner Congress Centre, Berlin, 2009.

[6]   P. Sapaty, “Grasping the Whole by Spatial Intelligence: A Higher Level for Distributed Avionics,” Military Avionics, London, 30 January-1 February 2008.

[7]   M. Minsky, “The Society of Mind,” Simon and Schuster, New York, 1988.

[8]   P. S. Sapaty, “Distributed Air & Missile Defense with Spatial Grasp Technology,” Intelligent Control and Automation, Vol. 3, No. 2, 2012, pp. 117-131. doi:10.4236/ica.2012.32014

[9]   P. S. Sapaty, “Withstanding Asymmetric Situations in Distributed Dynamic Worlds,” Proceedings of 17th International Symposium on Artificial Life and Robotics, Oita, 19-21 January 2012.

[10]   P. S. Sapaty, “Meeting the World Challenges with Advanced System Organizations,” Informatics in Control Automation and Robotics, Lecture Notes in Electrical Engineering, 1st Edition, Vol. 85, Springer, Berlin, 2011. doi:10.1007/978-3-642-19730-7_3

[11]   P. S. Sapaty, “Distributed Technology for Global Dominance,” In: R. Suresh, Ed., Defense Transformation and Net-Centric Systems, Proceedings of SPIE, Vol. 6981, 2008, 69810T. doi:10.1117/12.769162

[12]   P. S. Sapaty, “Ruling Distributed Dynamic Worlds,” John Wiley & Sons, New York, 2005. doi:10.1002/0471656356

[13]   P. S. Sapaty, “Mobile Processing in Distributed and Open Environments,” John Wiley & Sons, New York, 1999.

[14]   P. Sapaty, “A Distributed Processing System,” European Patent No. 0389655, Publ. 10.11.93, European Patent Office, 1993.

[15]   U. Schade and M. R Hieb, “Formalizing Battle Management Language: A Grammar for Specifying Orders,” Spring Simulation Interoperability Workshop, Huntsville, 2-7 April 2006, Paper 06S-SIW-068.

[16]   U. Schade, M. R. Hieb, M. Frey and K. Rein, “Command and Control Lexical Grammar (C2LG) Specification,” FKIE Technical Report ITF/2010/02, 2010.

[17]   P. S. Sapaty, M. J. Corbin and S. Seidensticker, “Mobile Intelligence in Distributed Simulations,” Proceedings of 14th Workshop on Standards for the Interoperability of Distributed Simulations, IST UCF, Orlando, 11-15 March 1995.

[18]   P. Sapaty, V. Klimenko and M. Sugisaka, “Dynamic Air Traffic Management Using Distributed Brain Concept,” Proceedings of 9th International Symposium on Artificial Life and Robotics, Beppu, 28-30 January 2004.

[19]   P. Sapaty and M. Sugisaka, “Optimized Space Search by Distributed Robotic Teams,” Proceedings of World Symposium Unmanned Systems, Baltimore Convention Center, Baltimore, 15-17 July 2003.

[20]   P. Sapaty, M. Sugisaka, J. Delgado-Frias, J. Filipe and N. Mirenkov, “Intelligent Management of Distributed Dynamic Sensor Networks,” Artificial Life and Robotics, Vol. 12, No. 1-2, 2008, pp. 1614-7456. doi:10.1007/s10015-007-0446-8

[21]   P. Sapaty, A. Morozov, R. Finkelstein, M. Sugisaka and D. Lambert, “A New Concept of Flexible Organization for Distributed Robotized Systems,” Proceedings of 12th International Symposium on Artificial Life and Robotics, Beppu, 25-27 January 2007.

[22]   P. Sapaty and M. Sugisaka, “Countering Asymmetric Situations with Distributed Artificial Life and Robotics Approach,” Proceedings of 15th International Symposium on Artificial Life and Robotics, B-Con Plaza, Oita, 5-7 February 2010.

[23]   P. Sapaty, K.-D. Kuhnert, M. Sugisaka and R. Finkelstein, “Developing High-Level Management Facilities for Distributed Unmanned Systems,” Proceedings of 14th International Symposium on Artificial Life and Robotics, Beppu, 5-7 February 2009.

[24]   P. Sapaty, M. Sugisaka, R. Finkelstein, J. Delgado-Frias and N. Mirenkov, “Advanced IT Support of Crisis Relief Missions,” Journal of Emergency Management, Vol. 4, No. 4, 2006, pp. 29-36.

[25]   P. Sapaty, A. Morozov and M. Sugisaka, “DEW in a Network Enabled Environment,” Proceedings of International Conference Directed Energy Weapons, London, 28 February-1 March 2007.