Abstract :
Automated recognition of patterns in data is constrained by tradeoffs among speed, cost, and accuracy. A new reconfigurable VLSI processor architecture decouples the speed/accuracy tradeoff, and renders the cost/accuracy tradeoff negligible, enabling new performance and new applications. The architecture features massively-parallel, dynamically configurable finite-state-machines which simultaneously process the same data stream. Low cost VLSI fabrication, unbounded scalability, and high speed constant-rate throughput independent of pattern number and complexity breaks current trade space constraints. This paper introduces features of the processor architecture responsible for the decoupling, and shows how current tradeoff structure is altered.
Keywords :
VLSI; finite state machines; pattern recognition; reconfigurable architectures; finite state machines; pattern recognition; reconfigurable VLSI processor architecture; scalable accuracy; speed-accuracy tradeoff; Computer security; Costs; Couplings; Fabrication; Field programmable gate arrays; Intrusion detection; Pattern recognition; Phase detection; Terrorism; Very large scale integration; Hardware-Assisted System Security Monitor; pattern recognition;
