小林 亮Ryo Kobayashi

Last Updated :2017/09/01

所属・職名
大学院理学研究科 数理計算理学講座 教授
メールアドレス
ryomath.sci.hiroshima-u.ac.jp
その他連絡先
東広島市鏡山一丁目3番1号 理学部 C棟606号室
TEL:082-424-7335 FAX:082-424-7335

基本情報

学位

  • 博士(数理科学) (東京大学)

研究分野

  • 数物系科学 / 数学 / 数学基礎・応用数学

教育活動

授業担当

  1. 2017年, 教養教育, セメスター(後期), *情報数理概説【理】
  2. 2017年, 教養教育, セメスター(後期), 微分積分学Ⅱ[1理化,1理地]
  3. 2017年, 学部専門, セメスター(前期), 計算数理A
  4. 2017年, 学部専門, セメスター(前期), 計算数理A演習
  5. 2017年, 学部専門, セメスター(前期), 数学情報課題研究
  6. 2017年, 学部専門, セメスター(後期), 数学情報課題研究
  7. 2017年, 修士課程・博士課程前期, セメスター(前期), 数理分子生命理学特別研究
  8. 2017年, 修士課程・博士課程前期, セメスター(後期), 数理分子生命理学特別研究
  9. 2017年, 修士課程・博士課程前期, セメスター(前期), 複雑系数理学
  10. 2017年, 修士課程・博士課程前期, セメスター(前期), 複雑系数理学セミナー
  11. 2017年, 修士課程・博士課程前期, セメスター(後期), 複雑系数理学セミナー

研究活動

学術論文(★は代表的な論文)

  1. Signal propagation and failure in one-dimensional FitzHugh-Nagumo equations with periodic stimuli, PHYSICAL REVIEW E, 71巻, 3号, MAR 2005
  2. Physarum solver: A biologically inspired method of road-network navigation, PHYSICA A-STATISTICAL MECHANICS AND ITS APPLICATIONS, 363巻, 1号, pp.115-pp.119, APR 15 2006
  3. Mathematical model for rhythmic protoplasmic movement in the true slime mold, JOURNAL OF MATHEMATICAL BIOLOGY, 53巻, 2号, pp.273-pp.286, AUG 2006
  4. Flow-network adaptation in Physarum amoebae, THEORY IN BIOSCIENCES, 127巻, 2号, pp.89-pp.94, JUN 2008
  5. Fully decentralized control of a soft-bodied robot inspired by true slime mold, BIOLOGICAL CYBERNETICS, 102巻, 3号, pp.261-pp.269, MAR 2010
  6. A mathematical model of cleavage, JOURNAL OF THEORETICAL BIOLOGY, 264巻, 1号, pp.84-pp.94, MAY 7 2010
  7. ★, Extending phase field models of solidification to polycrystalline materials, Acta Materialia, 51巻, pp.6035-pp.6058, 20030401
  8. On Constrained Equations with Singular Diffusivity, Methods and Applications of Analysis, 10巻, 2号, pp.253-pp.278, 20030401
  9. Periodic Precipitation during Droplet Evaporation on a Substrate, J. Phys. Soc. Jpn., 72巻, 10号, pp.2468-pp.2471, 20030401
  10. 真性粘菌変形体の運動の数理モデル, 数理解析研究所講究録, 1305巻, pp.8-pp.14, 20030401
  11. 粘菌変形体の流路ネットワ-クの形態形成, 数理解析研究所講究録, 1305巻, pp.1-pp.7, 20030401
  12. 膨潤赤血球の体積減少に伴う形状変化の数値シミュレーション, 日本機械学会論文集(A編), 69巻, pp.14-pp.21, 20030401
  13. Collective Movement of Epithelial Cells on a Collagen Gel Substrate, Biophysical Journal, TBP巻, 20050401
  14. A coupled-oscillator model with a conservation law for the rhythmic amoeboid movements of plasmodial slime molds, Physica D, TBP巻, 20050401
  15. Total varietion flow with value constraints, 数理解析研究所講究録, 1323巻, 20030401
  16. アスコルビン酸の結晶化におけるパターン形成, 数理解析研究所講究録, 1313巻, pp.25-pp.35, 20030401
  17. マランゴニ対流の2次元モデルで見られるパターンとダイナミクス, 応用数理, 16巻, pp.20-pp.30, 20060901
  18. ★, A mathematical model for adaptive transport network in path finding by the true slime mold, Journal of Theretical Biology, 244巻, pp.553-pp.564, 20070201
  19. Minimum-risk path finding by an adaptive amoebal network, Physical Review Letters, 99巻, pp.068104, 20070810
  20. Modeling the formation and dynamics of polycrystals in 3D, Physica A, 356巻, 1号, pp.127-pp.132, 20051001
  21. 粘菌の作る輸送ネットワークのダイナミクス, 第21回生体・生理工学シンポジウム論文集, 20060401
  22. 粘菌による迷路の解法, 細胞工学, 26巻, 7号, pp.769-pp.773, 20070622
  23. アメーバに学ぶ経路探索の方法, Materials Integration, 20巻, 5号, pp.55-pp.60, 20070831
  24. 樹枝状結晶の形づくり, 形の科学百科事典, pp.305-pp.306, 20041010
  25. Effects of food amount on path selection in transport network of an amoeboid organism, Topological Aspects of Critical Systems and Networks, pp.94-pp.100, 20070915
  26. 真正粘菌変形体による最適ネットワーク, 数理解析研究所講究録, 1499巻, pp.159-pp.166, 20060420
  27. Collective movement of epithelial cells on a collagen gel substrate, Biophysical Journal, 88巻, pp.2250-pp.2256, 20050301
  28. Obtainning multiple separate food sources: Behavioural intelligence in the Physarum plasmodium, 20041001
  29. アメーバの迷路解きに学ぼう, 数理科学, 535巻, pp.7-pp.11, 20080101
  30. アメーバに学ぶ最短経路探索法, 数学セミナー, 560巻, pp.20-pp.21, 20080501
  31. Computational ability of cells based on dynamics and adaptability, New Generation Computing, 27巻, pp.57-pp.81, 20081001
  32. A modular robot driven by protoplasmic streaming, DISTRIBUTED AUTONOMOUS ROBOTIC SYSTEMS 8 (Eds. H.Asama et al.) Springer, pp.193-pp.202, 20090401
  33. A fully decentralized morphology control of an amoeboid robot by exploiting the law of conservation of protoplasmic mass, Proceedings of IROS WS 2008, 20090801
  34. Taming Many Degrees of Freedom: Fully Decentralized Control of a Soft-bodied Robot Inspired by True Slime Mold, 2009 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS) Workshop/Tutorial Proceedings, 20091201
  35. ★, Rules for biologically-inspired adaptive network design, Science, 327巻, pp.439-pp.442, 20100101
  36. Effects of High Magnetic Field on Water Surface Phenomena, Journal of Physical Chemistry C, 20070701
  37. A Method Inspired by Physarum for Solving the Steiner Problem, 0巻, pp.1-pp.15, 20090101
  38. フェーズフィールド法のおもしろさ, 計算工学, 15巻, pp.2287-pp.2290, 20100401
  39. Taming Large Degrees of Freedom -A Case Study with an Amoeboid Robot, The proceedings of 2010 IEEE International Conference on Robotics and Automation, 20101001
  40. A Soft Deformable Amoeboid Robot Inspired by Plasmodium of True Slime Mold, INTERNATIONAL JOURNAL OF UNCONVENTIONAL COMPUTING, 7巻, 6号, pp.449-pp.462, 20110101
  41. Collective movement of epithelial cells on a collagen gel substrate, BIOPHYSICAL JOURNAL, 88巻, 3号, pp.2250-pp.2256, MAR 2005
  42. A coupled-oscillator model with a conservation law for the rhythmic amoeboid movements of plasmodial slime molds, PHYSICA D-NONLINEAR PHENOMENA, 205巻, 1-4号, pp.125-pp.135, JUN 1 2005
  43. Modeling the formation and dynamics of polycrystals in 3D, PHYSICA A-STATISTICAL MECHANICS AND ITS APPLICATIONS, 356巻, 1号, pp.127-pp.132, OCT 1 2005
  44. Resonance and the formation of death-spot in one-dimensional FitzHugh-Nagumo equations, PROGRESS OF THEORETICAL PHYSICS SUPPLEMENT, 161号, pp.393-pp.396, 2006
  45. A mathematical model for adaptive transport network in path finding by true slime mold, JOURNAL OF THEORETICAL BIOLOGY, 244巻, 4号, pp.553-pp.564, FEB 21 2007
  46. Minimum-risk path finding by an adaptive amoebal network, PHYSICAL REVIEW LETTERS, 99巻, 6号, AUG 10 2007
  47. Computational Ability of Cells based on Cell Dynamics and Adaptability, NEW GENERATION COMPUTING, 27巻, 1号, pp.57-pp.81, NOV 2008
  48. Rules for Biologically Inspired Adaptive Network Design, SCIENCE, 327巻, 5964号, pp.439-pp.442, JAN 22 2010
  49. A Method Inspired by Physarum for Solving the Steiner Problem, INTERNATIONAL JOURNAL OF UNCONVENTIONAL COMPUTING, 6巻, 2号, pp.109-pp.123, 2010
  50. Mechanics of peristaltic locomotion and role of anchoring, JOURNAL OF THE ROYAL SOCIETY INTERFACE, 9巻, 67号, pp.222-pp.233, FEB 7 2012
  51. A Soft Deformable Amoeboid Robot Inspired by Plasmodium of True Slime Mold, INTERNATIONAL JOURNAL OF UNCONVENTIONAL COMPUTING, 7巻, 6号, pp.449-pp.462, 2011
  52. Local reflexive mechanisms essential for snakes' scaffold-based locomotion, BIOINSPIRATION & BIOMIMETICS, 7巻, 4号, DEC 2012
  53. Reconstruction of Active Regular Motion in Amoeba Extract: Dynamic Cooperation between Sol and Gel States, PLOS ONE, 8巻, 8号, AUG 5 2013
  54. Common mechanics of mode switching in locomotion of limbless and legged animals, JOURNAL OF THE ROYAL SOCIETY INTERFACE, 11巻, 95号, JUN 6 2014
  55. The advantage of mucus for adhesive locomotion in gastropods, JOURNAL OF THEORETICAL BIOLOGY, 353巻, pp.133-pp.141, JUL 21 2014
  56. Decentralized control scheme for adaptive earthworm locomotion using continuum-model-based analysis, ADVANCED ROBOTICS, 28巻, 3号, pp.197-pp.202, FEB 1 2014
  57. Enhancing adaptability of amoeboid robot by synergetically coupling two decentralized controllers inspired by true slime mold, ADAPTIVE BEHAVIOR, 23巻, 2号, pp.109-pp.121, APR 2015
  58. Phase-Field Modeling of Step Dynamics on Growing Crystal Surface: Direct Integration of Growth Units to Step Front, CRYSTAL GROWTH & DESIGN, 15巻, 5号, pp.2165-pp.2175, MAY 2015
  59. Autonomy and Non-autonomy of Angiogenic Cell Movements Revealed by Experiment-Driven Mathematical Modeling, CELL REPORTS, 13巻, 9号, pp.1814-pp.1827, DEC 1 2015
  60. Mathematical model for rhythmic protoplasmic movement in the true slime mold., Mathematical model for rhythmic protoplasmic movement in the true slime mold., 53巻, 2号, 2006
  61. A mathematical model of cleavage., A mathematical model of cleavage., 264巻, 1号, 2010
  62. The advantage of mucus for adhesive locomotion in gastropods., The advantage of mucus for adhesive locomotion in gastropods., 353巻, 2014
  63. 真核細胞の核構造パターン形成における数理モデル, 計算工学講演会論文集 Proceedings of the Conference on Computational Engineering and Science, 19巻, 201406
  64. Mathematical analysis to coupled oscillators system with a conservation law (Applications of Renormalization Group Methods in Mathematical Sciences), 数理解析研究所講究録別冊 = RIMS Kokyuroku Bessatsu, 21巻, pp.129-pp.147, 201012
  65. ヒラムシに見る柔構造と渦構造の相互作用による効率的な遊泳メカニズム (生物流体力学における流れ構造の解析と役割), 数理解析研究所講究録, 1900巻, pp.120-pp.127, 201406
  66. A mathematical model for adaptive transport network in path finding by true slime mold., A mathematical model for adaptive transport network in path finding by true slime mold., 244巻, 4号, 2007
  67. Synchronization of Two Self-Oscillating Gels Based on Chemo-Mechanical Coupling, JOURNAL OF PHYSICAL CHEMISTRY B, 120巻, 11号, pp.2977-pp.2983, MAR 24 2016
  68. A new mathematical model for pattern formation by cranial sutures, JOURNAL OF THEORETICAL BIOLOGY, 408巻, pp.66-pp.74, NOV 7 2016
  69. A new application of the phase-field method for understanding the mechanisms of nuclear architecture reorganization, JOURNAL OF MATHEMATICAL BIOLOGY, 74巻, 1-2号, pp.333-pp.354, JAN 2017
  70. Exogenous Cellulase Switches Cell Interdigitation to Cell Elongation in an RIC1-dependent Manner in Arabidopsis thaliana Cotyledon Pavement Cells, PLANT AND CELL PHYSIOLOGY, 58巻, 1号, pp.106-pp.119, JAN 2017