Loading...
|
Please use this identifier to cite or link to this item:
https://nccur.lib.nccu.edu.tw/handle/140.119/32705
|
| Title: | 以演化方式模擬人群運動行為
Simulating Crowd Motion with Evolutionary Computation |
| Authors: | 王智賢
Wang, Chih-Chien |
| Contributors: | 李蔡彥
Li, Tsai-Yen
王智賢
Wang, Chih-Chien |
| Keywords: | 電腦動畫
人群運動模擬
基因演算法
多代理人系統
運動隊伍組態
computer animation
crowd motion simulation
genetic algorithm
Multiple Agent System
Motion Formation |
| Date: | 2005 |
| Issue Date: | 2009-09-17 14:05:57 (UTC+8) |
| Abstract: | 近年來,在電腦動畫的應用中,虛擬人群模擬的需求越來越多;但人群運動的模擬對於動畫設計師而言,仍是一件十分繁瑣耗時的工作。過去有許多研究曾以虛擬力場模擬簡單的生物群聚行為,但所模擬出的動畫品質與虛擬力場的參數及虛擬環境息息相關,因此經常需要以人工的方式耗時地調整出適當的虛擬力場參數。因此,我們提議以此問題定義成一個基因演算法的問題,針對不同的移動行為,定義適切的適應函數,再由系統根據不同環境自動演化出適當的虛擬力權重組合,以供產生不同人群移動行為之動畫時參考。在本篇論文中,我們已完成基因演算法的設計及人群動畫模擬系統,並設計了不同的典型環境進行電腦模擬實驗,以驗證此方法的可行性。
The demands for virtual crowd simulation have been increasing in recent years but creating realistic crowd motions remains a complex and time-consuming task for a computer animator. In the literature、much work has been proposed to use virtual forces to simulate the motion of a group of virtual creatures such as birds and fishes. However、the quality of the simulations largely depends on the weights of the component virtual forces as well as the scene where the agents are situated. Usually it requires the animator to tune these parameters for a specific scene in order to obtain the desired result. In this thesis、we propose to use genetic algorithm to generate an optimal set of weighting parameters for composing virtual forces according to the given environment and desired movement behavior. We have implemented the proposed genetic algorithm as well as the crowd simulation system. Extensive experiments have also been conducted to study the effects of typical scenes and behaviors on the parameter sets and verify the feasibility of the approach. |
| Reference: | [1] AntZ.、http://www.antz.com
[2] ActiveWorld、http://www.activeworlds.com/
[3] R. Aylett and M. Cavazza、「Intelligent Virtual Environment a State of the Art Report,」 Proceedings of Eurographics 2001-STARs、2001.
[4] M. Anderson、E. McDaniel、and S. Chenney、「Constrained Animation of Flocks,」 Proceedings of ACM SIGGRAPH/Eurographics Symposium on Computer Animation 2003、pp. 286–297、2003.
[5] Bugs Life.、http://bugslife.com
[6] O. B. Bayazit、J.-M. Lien、and N. M. Amato,「Better Flocking Behaviors in Complex Environments Using Global Roadmaps,」 Proceedings of the 1995 IEEE/RSJ International Conference on Intelligent Robots and Systems、pp. 528-534、1995.
[7] E. Bouvier、E. Cohen、and L. Najman.、「From Crowd Simulation to Airbag Deployment: Particle Systems、a New Paradigm of Simulation,」 Journal of Electronic Imaging、Vol. 6、No.1、pp. 94-107、1997.
[8] D. Brogan and J. Hodgins、「Group Behaviors for Systems with Significant Dynamics,」 Autonomous Robots、4、pp. 137-153、1997.
[9] D.C. Brogan、R.A. Metoyer、and J.K. Hodgins、「Dynamically Simulated Characters in Virtual Environments,」 IEEE Computer Graphics and Applications、Vol. 18、No5、pp. 58-69、1998.
[10] A. Braun、S. R. Musse、L. P. L. de Oliveira、and B. E. J. Bodmann、「Modeling Individual Behaviors in Crowd Simulation,」 Proceedings of CASA: Computer Animation & Social Agents、pp. 143-148、2003.
[11] J. J. Fruin、Pedestrian Planning and Design. Metropolitan Association of Urban Designers and Environmental Planners、1971.
[12] J. Funge、X. Tu、and D. Terzopoulos、「Cognitive Model: Knowledge、Reasoning、and Planning for Intelligent Characters,」 Proceedings of ACM SIGGRAPH、pp. 29-38、1999.
[13] N. Farenc、R. Boulic、and D. Thalman、「An Informed Environment Dedicated to the Simulation of Virtual Humans in Urban Context,」 Proceedings of EUROGRAPHICS、pp. 309-318、1999.
[14] N.Farenc、S. Musse、and E. Schweiss、「A Paradigm for Controlling Virtual Humans in Urban Environment Simulations,」 Applied Artificial Intelligence、Vol. 14、pp. 69-91、2000.
[15] J. Grefenstette、「Optimization of Control Parameters for Genetic Algorithms」、IEEE Transactions on Systems、Man and Cybernetics、Vol.16 、pp. 122-128、1986.
[16] J.H. Holland、Adaptation in Natural and Artificial Systems. The University of Michigan Press、Ann Arbor、MI、1975.
[17] D. Helbing and P. Molnar、「Social Force Model for Pedestrian Dynamics,」 Physical Review、pp. 4282-4286、1995.
[18] D. Helbing、I. Farkas、and T. Vicsek、「Simulating Dynamical Features of Escape Panic,」 Nature、407(28):487–490、2000.
[19] J.C. Latombe、Robot Motion Planning、Kluwer、Boston、MA、1991.
[20] T.Y. Li、Y.J Jeng、and S.I Chang、「Simulating Virtual Human Crowds with a Leader-Follower Model,」 Proceedings of the Computer Animation Conference、pp. 93-102、2001.
[21] J.R. Koza、Genetic Programming: On the Programming of Computers by Means of Natural Selection、Cambridge、MA、MIT Press、1992.
[22] M. Kallmann、A. Aubel、T. Abaci、and D. Thalmann、「Planning Collision-Free Reaching Motions for Interactive Object Manipulation and Grasping,」 Computer 86 Graphic Forum、Vol. 22、pp. 313-322、2003.
[23] A. Kamphuis and M. H. Overmars、「Finding Path for Coherent Groups using Clearance,」 ACM SIGGRAPH/Eurographics Symposium on Computer Animation、pp.193-202、2004.
[24] M. Mitchell、An Introduction to Genetic Algorithms、Cambridge、MA 、MIT Press、1998.
[25] G. A. Miller、「The Magical Number Seven、Plus or Minus Two: Some :Limits on Our Capacity for Processing Information」 Psychological Review、Vol. 63、pp. 81–97、1956.
[26] Massive、http://www.massivesoftware.com
[27] S.R. Musse and D. Thalmann、「Hierarchical Model for Real Time Simulation of Virtual Human Crowds,」 IEEE Transactions on Visualization and Computer Graphics、7(2)、pp. 152–164、2001.
[28] G. Mitsuo and C. Runwei、Gentic Algorithms & Engineering Design、John Wily & Sons. Inc、1997.
[29] T.Osaragi、「Modeling of Pedestrian Behavior and Its Application to Spatial Evaluation,」 Proceedings of Autonomous Agents and Multiagent Systems、Vol. 2、pp. 836–843、2004.
[30] C.W. Reynolds、「Flocks、Herds、and Schools: A Distributed Behavioral Model,」 Computer Graphics、pp. 25-34、1987.
[31] C.W. Reynolds、「Steering Behaviors for Autonomous Characters,」 Proceedings of Game Developers Conference、pp. 763-782、1999.
[32] S. J. Rymill and N. A. Dodgson、「Psychologically-Based Vision and Attention for the Simulation of Human Behaviour,」 Proceedings of the 3rd international conference on Computer graphics and interactive techniques in Australasia and South East Asia、pp. 229-236、2005.
[33] M. Sung、M. Gleicher、and S. Chenney.、「Scalable Behaviors for Crowd Simulation,」 Computer Graphics Forum、23(3):519–528、2004.
[34] G. K. Still、Crowd Dynamics、PhD thesis、University of Warwick、UK、2000.
[35] N. Saiwaki、T. Komatsu、T. Yoshida、and S. Nishida、「Automatic Generation of Moving Crowd Using Chaos Model,」 Proceedings of IEEE Conference on System、Man and Cybernetics、pp. 3715-3721、1997.
[36] F. Tecchia、C. Loscos、Y. Chrysanthou、「Visualizing Crowds in Real-Time,」 Computer Graphics Forum、Vol. 21、2002.
[37] Takeshi Sakuma、Tomohiko Mukai、and Shigeru Kuriyama、「Psychological Model for Animating Crowded Pedestrians,」 Proceedings of CASA: Computer Animation & Social Agents、pp. 343-351、2005.
[38] J.B. Victor and J.L. Adler、「Emergent Fundamental Pedestrian Flows from Cellular Automata Microsimulation,」 Transportation Research Record 1644、pp. 29-36、1998.
[39] J.B. Victor and J.L. Adler、「Cellular Automata Microsimulation for Modeling Bi-directional Pedestrian Walkways,」 Transportation Research Part B、35、pp. 293-312、2001. |
| Description: | 碩士
國立政治大學
資訊科學學系
90750322
94 |
| Source URI: | http://thesis.lib.nccu.edu.tw/record/#G0907530222 |
| Data Type: | thesis |
| Appears in Collections: | [資訊科學系] 學位論文
|
All items in 政大典藏 are protected by copyright, with all rights reserved.
|
