Turing Machines, Architectural Resilience of Cellular Organisms and DIME Network Architecture March 27, 2012

By introducing signaling and self- management in a Turing node and a signaling network as an overlay over the computing network, the current von-Neumann computing model is evolved to bring the architectural resiliency of cellular organisms to computing infrastructure. The new approach introduces the genetic transactions of replication, repair, recombination and reconfiguration to program self-resiliency in distributed computing systems executing a managed workflow. Perhaps, the injection of parallelism and network based composition of “Self” identity are the first steps in introducing the elements of homeostasis and self-management required for developing consciousness in the computing infrastructure.

Path to Self-managing Services: A Case for Deploying Managed Intelligent Services Using Dumb Infrastructure in a Stupid Network February 2, 2012

There have been many calls for a new computing model that combines computing and communication at an atomic computing element level which the Turing machine falls short. However, with high bandwidth communication and exploitation of the parallelism that is abundant in the new generation hardware, it is now possible to seriously look at new computing models. It seems the hardware advances have outpaced the software advances and perhaps it is about time to seriously take a second look at addressing the software short-fall

Will Virtual Machine Technology Go the Way of COBOL Programming, Frame Relays and Asynchronous Transfer Mode Switching into Oblivion? December 21, 2011

The advent of many-core severs with tens and even hundreds of computing cores with high bandwidth communication among them makes the current generation server, networking and storage equipment and their management systems which have evolved from server-centric and bandwidth limited architectures completely unsuited to use in the next generation computing infrastructure efficiently. WETICE 2012 Convergence of Distributed Clouds, Grids and their Management Conference Track is devoted to transform current labor intensive, software-heavy, and knowledge-professional-services dependent IT management into self-configuring, self-monitoring, self-protecting, self-healing and self-optimizing distributed workflow implementations with end-to-end resource management by facilitating the development of a Unified Theory of Computing.

Turing Machines, Cognition, Parallel Loosely Coupled Processes, and DIME Networks: August 22, 2011

Distributed transactions requiring sensing, analysis and control are highly temporal in nature requiring dynamic coupling between various elements of the system. Each change in one element continually influences some other element’s direction of change and has to be accounted for in any computational model. The DIME network architecture provides a framework for implementing a non-von Neumann computing model allowing dynamic distributed transaction management. The DIME computing model brings architectural resiliency of cellular organisms to business process implementation and decouples the services management from the computing infrastructure management.