Shinjiro Toyoda scite author profile

We have developed a new three-dimensional stacking technology using the wafer-to-wafer stacked method. Electrical conductivity between each wafer is almost 100% and contact resistance is less than 0.7 between a through-silicon via (TSV) and a microbump. We have also created a prototype of a three-layer stacking device using our technology, where each wafer for the stacking is fabricated by using 0.18um CMOS technology based on 8-inch wafers. The device is operated by two times the frequency of the multichip module (MCM) device case using a two-dimensional device with identical functions and minimally different power consumption. The yields obtained from the results comprising all functional tests are over 60%.

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Development of hardware accelerator for molecular dynamics simulations: A computation board that calculates nonbonded interactions in cooperation with fast multipole method

Amisaki

Toyoda

Miyagawa

et al. 2003

J Comput Chem

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Evaluation of long-range Coulombic interactions still represents a bottleneck in the molecular dynamics (MD) simulations of biological macromolecules. Despite the advent of sophisticated fast algorithms, such as the fast multipole method (FMM), accurate simulations still demand a great amount of computation time due to the accuracy/speed trade-off inherently involved in these algorithms. Unless higher order multipole expansions, which are extremely expensive to evaluate, are employed, a large amount of the execution time is still spent in directly calculating particle-particle interactions within the nearby region of each particle. To reduce this execution time for pair interactions, we developed a computation unit (board), called MD-Engine II, that calculates nonbonded pairwise interactions using a specially designed hardware. Four custom arithmetic-processors and a processor for memory manipulation ("particle processor") are mounted on the computation board. The arithmetic processors are responsible for calculation of the pair interactions. The particle processor plays a central role in realizing efficient cooperation with the FMM. The results of a series of 50-ps MD simulations of a protein-water system (50,764 atoms) indicated that a more stringent setting of accuracy in FMM computation, compared with those previously reported, was required for accurate simulations over long time periods. Such a level of accuracy was efficiently achieved using the cooperative calculations of the FMM and MD-Engine II. On an Alpha 21264 PC, the FMM computation at a moderate but tolerable level of accuracy was accelerated by a factor of 16.0 using three boards. At a high level of accuracy, the cooperative calculation achieved a 22.7-fold acceleration over the corresponding conventional FMM calculation. In the cooperative calculations of the FMM and MD-Engine II, it was possible to achieve more accurate computation at a comparable execution time by incorporating larger nearby regions.

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Two Algorithms Designed for Realizing Efficient Combination of Fast Multipole Method and Dedicated Hardware for Molecular Dynamics Simulations

Amisaki

Toyoda

Miyagawa

et al. 2002

J. Comput. Chem. Jpn.

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Shinjiro Toyoda

Development of MD Engine: High-speed accelerator with parallel processor design for molecular dynamics simulations

Molecular simulation of an amorphous poly(methyl methacrylate)–poly(tetrafluoroethylene) interface

Multilayer stacking technology using wafer-to-wafer stacked method

Development of hardware accelerator for molecular dynamics simulations: A computation board that calculates nonbonded interactions in cooperation with fast multipole method

Two Algorithms Designed for Realizing Efficient Combination of Fast Multipole Method and Dedicated Hardware for Molecular Dynamics Simulations

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