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Hikaru Inoue
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2020 – today
- 2022
- [c13]Tsuyoshi Ichimura, Kohei Fujita, Kentaro Koyama, Ryota Kusakabe, Yuma Kikuchi, Takane Hori, Muneo Hori, Lalith Maddegedara, Noriyuki Ohi, Tatsuo Nishiki, Hikaru Inoue, Kazuo Minami, Seiya Nishizawa, Miwako Tsuji, Naonori Ueda:
152K-computer-node parallel scalable implicit solver for dynamic nonlinear earthquake simulation. HPC Asia 2022: 18-29 - [c12]Tsuyoshi Ichimura, Kohei Fujita, Ryota Kusakabe, Kentaro Koyama, Sota Murakami, Yuma Kikuchi, Takane Hori, Muneo Hori, Hikaru Inoue, Takafumi Nose, Takahiro Kawashima, Maddegedara Lalith:
Extreme Scale Earthquake Simulation with Uncertainty Quantification. SC 2022: 4:1-4:11 - 2021
- [j6]Jaewoon Jung, Chigusa Kobayashi, Kento Kasahara, Cheng Tan, Akiyoshi Kuroda, Kazuo Minami, Shigeru Ishiduki, Tatsuo Nishiki, Hikaru Inoue, Yutaka Ishikawa, Michael Feig, Yuji Sugita:
New parallel computing algorithm of molecular dynamics for extremely huge scale biological systems. J. Comput. Chem. 42(4): 231-241 (2021) - [j5]Kohei Fujita, Kentaro Koyama, Kazuo Minami, Hikaru Inoue, Seiya Nishizawa, Miwako Tsuji, Tatsuo Nishiki, Tsuyoshi Ichimura, Muneo Hori, Lalith Maddegedara:
High-fidelity nonlinear low-order unstructured implicit finite-element seismic simulation of important structures by accelerated element-by-element method. J. Comput. Sci. 49: 101277 (2021) - [c11]Tsuyoshi Ichimura, Kohei Fujita, Kentaro Koyama, Yuma Kikuchi, Ryota Kusakabe, Kazuo Minami, Hikaru Inoue, Seiya Nishizawa, Miwako Tsuji, Tatsuo Nishiki, Muneo Hori, Lalith Maddegedara, Naonori Ueda:
Fast scalable implicit solver with convergence of equation-based modeling and data-driven learning: earthquake city simulation on low-order unstructured finite element. PASC 2021: 12:1-12:12 - 2020
- [c10]Hisashi Yashiro, Koji Terasaki, Yuta Kawai, Shuhei Kudo, Takemasa Miyoshi, Toshiyuki Imamura, Kazuo Minami, Hikaru Inoue, Tatsuo Nishiki, Takayuki Saji, Masaki Satoh, Hirofumi Tomita:
A 1024-member ensemble data assimilation with 3.5-km mesh global weather simulations. SC 2020: 1
2010 – 2019
- 2019
- [j4]Satoshi Ito, Masaaki Yadome, Tatsuo Nishiki, Shigeru Ishiduki, Hikaru Inoue, Rui Yamaguchi, Satoru Miyano:
Virtual Grid Engine: a simulated grid engine environment for large-scale supercomputers. BMC Bioinform. 20-S(16): 591:1-591:10 (2019) - [c9]Lalith Maddegedara, Amit Gill, Sebastian Poledna, Muneo Hori, Hikaru Inoue, Tomoyuki Noda, Toda Koyo, Tsuyoshi Ichimura:
Distributed Memory Parallel Implementation of Agent-Based Economic Models. ICCS (2) 2019: 419-433 - 2018
- [c8]Satoshi Ito, Masaaki Yadome, Tatsuo Nishiki, Shigeru Ishiduki, Hikaru Inoue, Rui Yamaguchi, Satoru Miyano:
Virtual Grid Engine: Accelerating thousands of omics sample analyses using large-scale supercomputers. BIBM 2018: 387-392 - [c7]Tsuyoshi Ichimura, Kohei Fujita, Masashi Horikoshi, Larry Meadows, Kengo Nakajima, Takuma Yamaguchi, Kentaro Koyama, Hikaru Inoue, Akira Naruse, Keisuke Katsushima, Muneo Hori, Lalith Maddegedara:
A Fast Scalable Implicit Solver with Concentrated Computation for Nonlinear Time-Evolution Problems on Low-Order Unstructured Finite Elements. IPDPS 2018: 620-629 - 2017
- [c6]Kohei Fujita, Tsuyoshi Ichimura, Kentaro Koyama, Hikaru Inoue, Muneo Hori, Lalith Maddegedara:
Fast and Scalable Low-Order Implicit Unstructured Finite-Element Solver for Earth's Crust Deformation Problem. PASC 2017: 11:1-11:10 - 2016
- [j3]Kazuto Ando, Mamoru Hyodo, Toshitaka Baba, Takane Hori, Toshihiro Kato, Masaru Watanabe, Shin'ichi Ichikawa, Hisakuni Kitahara, Hitoshi Uehara, Hikaru Inoue:
Parallel-algorithm extension for tsunami and earthquake-cycle simulators for massively parallel execution on the K computer. Int. J. High Perform. Comput. Appl. 30(4): 454-468 (2016) - [c5]Takayuki Muranushi, Seiya Nishizawa, Hirofumi Tomita, Keigo Nitadori, Masaki Iwasawa, Yutaka Maruyama, Hisashi Yashiro, Yoshifumi Nakamura, Hideyuki Hotta, Junichiro Makino, Natsuki Hosono, Hikaru Inoue:
Automatic generation of efficient codes from mathematical descriptions of stencil computation. FHPC@ICFP 2016: 17-22 - [c4]Takayuki Muranushi, Hideyuki Hotta, Junichiro Makino, Seiya Nishizawa, Hirofumi Tomita, Keigo Nitadori, Masaki Iwasawa, Natsuki Hosono, Yutaka Maruyama, Hikaru Inoue, Hisashi Yashiro, Yoshifumi Nakamura:
Simulations of below-ground dynamics of fungi: 1.184 pflops attained by automated generation and autotuning of temporal blocking codes. SC 2016: 23-33 - 2014
- [j2]Yasuhiro Idomura, Motoki Nakata, Susumu Yamada, Masahiko Machida, Toshiyuki Imamura, Tomohiko Watanabe, Masanori Nunami, Hikaru Inoue, Shigenobu Tsutsumi, Ikuo Miyoshi, Naoyuki Shida:
Communication-overlap techniques for improved strong scaling of gyrokinetic Eulerian code beyond 100k cores on the K-computer. Int. J. High Perform. Comput. Appl. 28(1): 73-86 (2014) - [j1]Yukihiro Hasegawa, Jun-ichi Iwata, Miwako Tsuji, Daisuke Takahashi, Atsushi Oshiyama, Kazuo Minami, Taisuke Boku, Hikaru Inoue, Yoshito Kitazawa, Ikuo Miyoshi, Mitsuo Yokokawa:
Performance evaluation of ultra-large-scale first-principles electronic structure calculation code on the K computer. Int. J. High Perform. Comput. Appl. 28(3): 335-355 (2014) - 2012
- [c3]Yasuhiro Idomura, Motoki Nakata, Susumu Yamada, Masahiko Machida, Toshiyuki Imamura, Tomohiko Watanabe, Masanori Nunami, Hikaru Inoue, Shigenobu Tsutsumi, Ikuo Miyoshi, Naoyuki Shida:
Abstract: Communication Overlap Techniques for Improved Strong Scaling of Gyrokinetic Eulerian Code beyond 100k Cores on the K-Computer. SC Companion 2012: 1373-1374 - [c2]Yasuhiro Idomura, Motoki Nakata, Susumu Yamada, Masahiko Machida, Toshiyuki Imamura, Tomohiko Watanabe, Masanori Nunami, Hikaru Inoue, Shigenobu Tsutsumi, Ikuo Miyoshi, Naoyuki Shida:
Poster: Communication Overlap Techniques for Improved Strong Scaling of Gyrokinetic Eulerian Code beyond 100k Cores on the K-Computer. SC Companion 2012: 1375-1376 - 2011
- [c1]Yukihiro Hasegawa, Jun-ichi Iwata, Miwako Tsuji, Daisuke Takahashi, Atsushi Oshiyama, Kazuo Minami, Taisuke Boku, Fumiyoshi Shoji, Atsuya Uno, Motoyoshi Kurokawa, Hikaru Inoue, Ikuo Miyoshi, Mitsuo Yokokawa:
First-principles calculations of electron states of a silicon nanowire with 100, 000 atoms on the K computer. SC 2011: 1:1-1:11
Coauthor Index
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