Abstract. During the last few years, a considerable effort has been devoted to the development of reconfigurable computers, machines that are based on the close interoperation of traditional microprocessors and Field Programmable Gate Arrays (FPGAs). Several prototype machines of this type have been designed, and demonstrated significant speedups compared to conventional workstations for computationally intensive problems, such as codebreaking. Nevertheless, the efficient use and programming of such machines is still an unresolved problem. In this paper, we demonstrate an efficient implementation of an Elliptic Curve scalar multiplication over GF(2 m ), using one of the leading reconfigurable computers available on the market, SRC-6E. We show how the hardware architecture and programming model of this reconfigurable computer has influenced the choice of the algorithm partitioning strategy for this application. A detailed analysis of the control, data transfer, and reconfiguration overheads is given in the paper, together with the performance comparison of our implementation against an optimized microprocessor implementation.
Human Science is a small R&D start-up for-profit innovation center; its missions focus on the survival of mankind by diversifying human colonies throughout the known universe. We present our interactive technological developments in these key areas enabling human cosmic flight: Topology and Transformation of Complex Spacetime, Blackhole-Bigbang Hybrid model, Mechanics of Circumstellar Exo-planetary Formation, FTL micro-Gravitational Hyper-drives, Quantum Probabilistic Collisions in Hyper-space, FTL Navigation method, micro-Gravity Assist Technologies, FTL Quantum communication Systems, Complex Primary Element Periodic table, Wireless Power Transfer System, Charting Exo-Alien Civilization Epoch, and Economics of Planetary Settlements.
It is observed that human body responses positively in or near 1G constant environments, both real and stimulated, on Earth or in space. Popular stimulated 1G life support for orbital spacecraft involves centrifugal living space. These centrifugal systems are not homogenous gravitational flux field and required constant circular motions orthogonal to traveling vector. To support enduring space travel, theorists had proposed various gravity dampening systems normal with traveling vector and stimulated 1G living space with micro-gravity drives. This paper proposes a new concept of transforming near-field micro-gravity systems into far-field, stimulated environments that human enjoyed on the surface of the Earth. Near-field micro-gravity is defined as >75% flux field exerted on a standard 1.7 meter human length with 1G average accelerating vector; far-field is <25% flux. The author exploited non-linear relationship of human flux sensing that is proportional to accelerating frequency and inversely proportional to average accelerating force and cumulative time. The paper discusses single micro-gravity dampening system in linear accelerating mode with inversed distance and power configuration normal to traveling vector. The paper also discusses minimum four micro-gravity source system in a linear-offset quaternion configuration to stimulate sub-optimal far-field 1G living space on a traveling spacecraft, in either open-loop and tracking mode.
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