The bremsstrahlung emitted from thermal plasmas which coexist with a flux of energetic (suprathermal) electrons is calculated. It is found that under some circumstances the radiation emitted can be greatly increased c...
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The bremsstrahlung emitted from thermal plasmas which coexist with a flux of energetic (suprathermal) electrons is calculated. It is found that under some circumstances the radiation emitted can be greatly increased compared to the emission from a Maxwellian plasma with no energetic particles present. The enhanced emission occurs at the fundamental and second harmonic of the electron plasma frequency.
The multi-core architecture has revolutionized the parallel computing. Despite this, the modern age compilers have a long way to achieve auto-parallelization. Through this paper, we introduce a language that encouragi...
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The multi-core architecture has revolutionized the parallel computing. Despite this, the modern age compilers have a long way to achieve auto-parallelization. Through this paper, we introduce a language that encouraging the auto-parallelization. We are also introducing Front-End for our auto-parallelizing compiler. Later, we examined our compiler employing a different number of core and verify results based on different metrics based on total compilation time, memory utilization, power utilization and CPU utilization. At last, we learned that parallelizing multiple files engage more CPU resources, memory and energy, but it finishes the task at hand in less time. In this paper, we have proposed a loop code generation technique that makes the generation of nested loop IR code faster by dividing the blocks into some extra code blocks using a modular approach. Our TAM compiler technique speedup by 7.506, 5.283 and 2.509 against sequential compilation when we utilized 8, 4 and 2 cores respectively. We observed that the CPU utilization of the TAM compiler reaches the maximum permissible limit when an optimal parallelizable instance is compiled.
作者:
GRANET, IRVINGThe Author received his B.M.E. from The Cooper Unionhis M.M.E. from Polytechnic Institute of Brooklynhas taken Pre-Doctoral Studies at Polytechnic Institute of Brooklynand is a graduate of the Oak Ridge School of Reactor Technology.He has worked in Republic's Power Conversion Department on nuclear propulsion systems
space radiators thermodynamic power cycle considerations for generating electric power and system design and operation for space propulsion. He is currently studying direct power conversion utilizing nuclear thermionics for both earth and space applications. He was formerly Director of Staff Engineering Nuclear Energy Department of Foster Wheeler Corporation where he directed engineering design and analysis for complete nuclear plants. Mr. Granet has taught thermodynamics and heat transfer at the Polytechnic Institute of Brooklyn and at present is Adjunct Assistant Professor of Engineering and Physics at Long Island University. He has published over 50 articles in the fields of thermodynamics
applied mechanics heat transfer and nuclear energy. He is the author of Elementary Applied Thermodynamics John Wiley 1965 and is currently writing a second book on fluid mechanics. He is a member of the American Society of Mechanical Engineers National Society of Professional Engineers Pi Tau Sigma and Sigma Xi. He is a licensed Professional Engineer in the State of New York. Mr. Granet is listed in American Men of Science Leaders in American Science and Who's Who in World Engineering. He is a member of the Advisory Council for the Technologies of Queensborough Community College and is a reviewer for the American Chemical Society's technical publications.
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