Research on Moving Target Monitoring Collaborative Simulation Technology Based on Multi-Channel

Tian Yuan; Shang Guan Wei; Zhi Zhong Lu

doi:10.4028/www.scientific.net/AMM.20-23.700

Paper Titles

The Research of Equal Probability Chaos Sequence Newton Iterative Methods and its Application to Mechanism Synthesis
p.676

Recognizing Polygons under Affine Transformation Based on Principle of Homograph
p.682

A PCA Based Fault Detection and Isolation Method for Train Locating System
p.688

Optimization of Sensor Array Data with Various Pattern Recognition Techniques
p.694

Research on Moving Target Monitoring Collaborative Simulation Technology Based on Multi-Channel
p.700

Study on Public Verifiability in Signcryption Scheme
p.706

Research on Community Informationization Development Model in City Community Construction
p.713

Research on the Problems and Strategies for the Community Informationization Construction in the Process of Digital City
p.719

Robust Image Corner Detection Using Curvature Product in Direct Curvature Scale Space
p.725

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 20-23Research on Moving Target Monitoring Collaborative...

Research on Moving Target Monitoring Collaborative Simulation Technology Based on Multi-Channel

Abstract:

Multi-channel Virtual reality simulation technology is a kind of simulation technology, which support the grand scene and high degree of immersion, has better visualization effect. In this paper, a moving target monitoring collaboratory simulation technology based on multi-channel is studied. Firstly, study the mathematical modeling foundation of Multi-Channel technology systematically, based on the mobile target spatial model and co-simulation technology, select the appropriate applications of multi-channel technology, building laboratory simulation platform and achieved a space-based six-degree of freedom simulation of multi-channel moving target monitoring simulation. The experiment has proved that in multi-channel target monitoring co-simulation technology used in this paper has strong practicality, combine with a moving target-space model and co-simulation technology, the advantages of objective observation to solve the requirements like large-scale, realism, immersion requirements, etc.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volumes 20-23)

Pages:

700-705

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.20-23.700

Citation:

Cite this paper

Online since:

January 2010

Authors:

Tian Yuan, Shang Guan Wei, Zhi Zhong Lu

Keywords:

Collaborative Simulation Technology, Multi-Channel, Six Degrees of Freedom Model, Target Monitoring

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] Shi Jiaoying. Virtual reality technology and application algorithm [M]. Science Press. (2002).

Google Scholar

[2] C. Cruz-Neira,D. Sandin and T. DeFanti. Surround-Screen Projection-Based Virtual Reality: The Design and Implementation of the CAVE [A]. In Computer Graphics. SIG GRAPH, (1993).

DOI: 10.1145/166117.166134

Google Scholar

[3] Kruger, Wolfgang. The Responsive Workbench: A Virtual Work Environment [J]. IEEE Computer Society, IEEE Computer, 1995, 28(7): 42-48P.

Google Scholar

[4] Czernuszenko, Pape, et al. The ImmersaDesk and Infinity Wall Projection-Based Virtual Reality Displays [J]. Computer Graphics, (1997).

DOI: 10.1145/271283.271303

Google Scholar

[5] Park, Kim, et al. The Design and Implementation of Kyongju VR Theater [A]. VRAI. (2002).

Google Scholar

[6] Yin Yong, Ren Hongxiang. Graphic Technology of Distributed Marine Simulation System-V. Dragon 2000. Journal of system simulation. 2002. 5, 14(5): 617-619, 625P.

Google Scholar

[7] Su Hu. Research on Real-Time Algorithm of Viewing Scene in Distributed Train Simulation System [D]. Southwest Jiaotong University, PhD thesis. 2002: 1-23P.

Google Scholar

[8] G. Humphreys, M. Eldridge, I. Buck, G. Stoll, M. Everett, and P. Hanrahan. WireGL: A Scalable Graphics System for Clusters [A]. Computer Graphics, ACM SIGGRAPH2001. 2002, 129-140P.

DOI: 10.1145/383259.383272

Google Scholar

[9] G. Humphreys, M. Houston, R. Ng, R. Frank, S. Ahern, P. D. Kirchner, and J. T. Klosowski. Chromium: A streamprocessing framework for interactive rendering on clusters [A]. In Proceedings of SIGGRAPH 2002. 2002, 129-140P.

DOI: 10.1145/1508044.1508087

Google Scholar

[10] Zhou Lin, Zhao Jie, Zi Shouchun. Research into the Trajectory Simulation Model of Ground to Air Missile. Fire Control & Command Control. 2006. 10. 31(10): 69-72P.

Google Scholar

[11] Zhou Yan, Dai Jianwei. HLA Simulation Program Design [M]. Beijing, Electronic Industry Press. (2004).

Google Scholar

[12] Chen Xiaobo, Xiong Guangleng, ChaiXudong. Distributed Collaboration Modeling Research Based on Distributed Simulation Model Object [J]. Journal of system simulation, 2002, (14) 5: 576 -580P.

Google Scholar

[13] Wang Jiangyun, Wang Xingren, Chai Xudong. Research and Implementation of COSIM Run-time M anagement Platform [J]. Journal of system simulation, 2002, 14(5): 584-587P.

Google Scholar