Published November 1987 | Version v1
Report Open

Neural networks and cellular automata in experimental high energy physics

Description

Within the past few years, two novel computing techniques, cellular automata and neural networks, have shown considerable promise in the solution of problems of a very high degree of complexity, such as turbulent fluid flow, image processing, and pattern recognition. Many of the problems faced in experimental high energy physics are also of this nature. Track reconstruction in wire chambers and cluster finding in cellular calorimeters, for instance, involve pattern recognition and high combinatorial complexity since many combinations of hits or cells must be considered in order to arrive at the final tracks or clusters. Here we examine in what way connective network methods can be applied to some of the problems of experimental high physics. It is found that such problems as track and cluster finding adapt naturally to these approaches. When large scale hardwired connective networks become available, it will be possible to realize solutions to such problems in a fraction of the time required by traditional methods. For certain types of problems, faster solutions are already possible using model networks implemented on vector or other massively parallel machines. It should also be possible, using existing technology, to build simplified networks that will allow detailed reconstructed event information to be used in fast trigger decisions

Availability note (English)

MF available from INIS under the Report Number.

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Additional details

Publishing Information

Imprint Pagination
35 p.
Report number
LAL--87-56

INIS

Country of Publication
France
Country of Input or Organization
France
INIS RN
20013339
Subject category
GENERAL AND MISCELLANEOUS;
Quality check status
Yes
Descriptors DEI
ARTIFICIAL INTELLIGENCE; COMPUTER CALCULATIONS; COMPUTER NETWORKS; COMPUTERIZED SIMULATION; DATA PROCESSING; HIGH ENERGY PHYSICS;
Descriptors DEC
PHYSICS; SIMULATION;