A Symbolic Construction  Work Flow Based on State Transition Analysis Using Simplified Primitive Static States

Mitsuhiro Kamezaki; Hiroyasu Iwata; Shigeki Sugano

doi:10.20965/jrm.2012.p0939

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JRM Vol.24 No.6 pp. 939-948

doi: 10.20965/jrm.2012.p0939

(2012)

Paper:

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A Symbolic Construction Work Flow Based on State Transition Analysis Using Simplified Primitive Static States

Mitsuhiro Kamezaki^, Hiroyasu Iwata^, and Shigeki Sugano^

^*Department of Modern Mechanical Engineering, School of Creative Science and Engineering, Waseda University, 17 Kikui-cho, Shinjuku-ku, Tokyo 162-0044, Japan

^**Faculty of Science and Engineering, Waseda University, 27 Waseda-cho, Shinjuku-ku, Tokyo 162-0042, Japan

^***Department of Modern Mechanical Engineering, School of Creative Science and Engineering, Waseda University, 3-4-1 Okubo, Shinjuku-ku, Tokyo 169-8555, Japan

Received:

April 20, 2012

Accepted:

August 10, 2012

Published:

December 20, 2012

Keywords:

construction machinery, work analysis, comprehensive work flow, state transition

Abstract

In this paper, a quantitative analysis method for a comprehensive work flow in construction work for identifying work states in more detail is proposed. The proposed method is based on analyzing state transitions of simplified primitive static states (s-PSS), which consist of four symbolic work states defined by using the on-off state of lever operations and manipulator loads. First, practical state transitions (PST), which are common and frequent transitions in arbitrary construction work, are defined on the basis of the transition rules, according to which an operation flag changes arbitrarily and a load flag changes only during a lever operation. Second, PST is notionally classified into essential (EST) and nonessential (NST) state transitions whose definitions change depending on the task phase, including reaching, contacting, loadworking, and releasing. Third, closed loops formed by EST represent work content and those formed by NST represent wasted movements. In work-analysis experiments using our instrumented setup, results indicated that all s-PSS definitely changes on the basis of PST under various experimental conditions and that work analysis using EST and NST easily reveals untrained tasks related to wasted movements.

Cite this article as:

M. Kamezaki, H. Iwata, and S. Sugano, “A Symbolic Construction Work Flow Based on State Transition Analysis Using Simplified Primitive Static States,” J. Robot. Mechatron., Vol.24 No.6, pp. 939-948, 2012.

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References

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[2] M. Kamezaki, H. Iwata, and S. Sugano, “A framework to identify task-phase and attentional-condition for supporting complicated dual-arm operations,” J. of Robotics and Mechatronics, Vol.22, No.4, pp. 447-455, 2010.
[3] M. Kamezaki, H. Iwata, and S. Sugano, “Primitive static states for intelligent operated-work machines,” Proc. IEEE Int. Conf. Robotics and Automation, pp. 1334-1339, 2009.
[4] G. Duchemin, P. Maillet, P. Poignet, E. Dombre, and F. Pierrot, “A hybrid position/force control approach for identification of deformation models of skin and underlying tissues,” IEEE Trans. Biomedical Eng., Vol.52, No.2, pp. 160-170, 2005.
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[6] M. Kamezaki, H. Iwata, and S. Sugano, “Development of an operation skill-training simulator for double-front work machine – training effect for house demolition work –,” J. of Robotics and Mechatronics, Vol.20, No.4, pp. 602-609, 2008.
[7] A. Tawari and M. M. Trivedi, “Speech emotion analysis: exploring the role of context,” IEEE Trans. Multimedia, Vol.12, No.6, pp. 502-509, 2010.
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[9] W. Yan and C. Baoxiang, “Fuzzy many-valued context analysis based on formal description,” Proc. Int. Conf. Software Eng., Artificial Intelligence, Networking, and Parallel/ Distributed Computing, pp. 888-892, 2007.
[10] H. Kai, Q. Zhengwei, and L. Bo, “Network anomaly detection based on statistical approach and time series analysis,” Proc. Int. Conf. Advanced Information Networking and Applications, pp. 205-211, 2009.
[11] A. Khatkhate, A. Ray, E. Keller, S. Gupta, and S. C. Chin, “Symbolic time-series analysis for anomaly detection in mechanical systems,” IEEE/ASME Trans. Mechatronics, Vol.11, No.4, pp. 439-447, 2006.
[12] M. Kamezaki, S. Hashimoto, H. Iwata, and S. Sugano, “Development of a dual robotic arm system to evaluate intelligent system for advanced construction machinery,” Proc. IEEE Int. Conf. Advanced Intelligent Mechatronics, pp. 1299-1304, 2010.

This article is published under a Creative Commons Attribution-NoDerivatives 4.0 Internationa License.

[1] [1] M. Kamezaki, H. Iwata, and S. Sugano, “Operator support system based on primitive static states in intelligent operated-work machines,” Advanced Robotics, Vol.23, No.10, pp. 1281-1297, 2009.

[2] [2] M. Kamezaki, H. Iwata, and S. Sugano, “A framework to identify task-phase and attentional-condition for supporting complicated dual-arm operations,” J. of Robotics and Mechatronics, Vol.22, No.4, pp. 447-455, 2010.

[3] [3] M. Kamezaki, H. Iwata, and S. Sugano, “Primitive static states for intelligent operated-work machines,” Proc. IEEE Int. Conf. Robotics and Automation, pp. 1334-1339, 2009.

[4] [4] G. Duchemin, P. Maillet, P. Poignet, E. Dombre, and F. Pierrot, “A hybrid position/force control approach for identification of deformation models of skin and underlying tissues,” IEEE Trans. Biomedical Eng., Vol.52, No.2, pp. 160-170, 2005.

[5] [5] S. Nagiri, Y. Amano, K. Fukui, and S. Doi, “The study of driving support system for individual driver,” Proc. IEEE Int. Conf. Systems, Man and Cybernetics, pp. 563-568, 2002.

[6] [6] M. Kamezaki, H. Iwata, and S. Sugano, “Development of an operation skill-training simulator for double-front work machine – training effect for house demolition work –,” J. of Robotics and Mechatronics, Vol.20, No.4, pp. 602-609, 2008.

[7] [7] A. Tawari and M. M. Trivedi, “Speech emotion analysis: exploring the role of context,” IEEE Trans. Multimedia, Vol.12, No.6, pp. 502-509, 2010.

[8] [8] W. Du and K. B. Hamed, “Context analysis of intensional languages,” Proc. IEEE Int. Conf. Computer Software and Applications, pp. 212-217, 2009.

[9] [9] W. Yan and C. Baoxiang, “Fuzzy many-valued context analysis based on formal description,” Proc. Int. Conf. Software Eng., Artificial Intelligence, Networking, and Parallel/ Distributed Computing, pp. 888-892, 2007.

[10] [10] H. Kai, Q. Zhengwei, and L. Bo, “Network anomaly detection based on statistical approach and time series analysis,” Proc. Int. Conf. Advanced Information Networking and Applications, pp. 205-211, 2009.

[11] [11] A. Khatkhate, A. Ray, E. Keller, S. Gupta, and S. C. Chin, “Symbolic time-series analysis for anomaly detection in mechanical systems,” IEEE/ASME Trans. Mechatronics, Vol.11, No.4, pp. 439-447, 2006.

[12] [12] M. Kamezaki, S. Hashimoto, H. Iwata, and S. Sugano, “Development of a dual robotic arm system to evaluate intelligent system for advanced construction machinery,” Proc. IEEE Int. Conf. Advanced Intelligent Mechatronics, pp. 1299-1304, 2010.

A Symbolic Construction Work Flow Based on State Transition Analysis Using Simplified Primitive Static States

Mitsuhiro Kamezaki*, Hiroyasu Iwata**, and Shigeki Sugano***

Mitsuhiro Kamezaki^, Hiroyasu Iwata^, and Shigeki Sugano^