| Using simulation techniques to improve skeletal plans for the control of a vertical internal grinding machine |
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Annual Simulation Symposium
archive
Proceedings of the 22nd annual symposium on Simulation
table of contents
Tampa, Florida, United States
Pages: 153 - 160
Year of Publication: 1989
ISBN:0-8186-1946-5
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Authors
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Barbara H. Roberts
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MITRE, Bedford, MA
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David C. Brown
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Artificial Intelligence Research Group, Computer Science Department, Worcester Polytechnic Institute, Worcester, MA
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IEEE Computer Society Press
Los Alamitos, CA, USA
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Downloads (6 Weeks): 1, Downloads (12 Months): 9, Citation Count: 0
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 ABSTRACT
This research investigates the use of simulation techniques for the improvement of skeletal plans selected by a planner. These plans are used for control of a vertical internal grinding machine. Plans are selected using a description of the grinding task. These plans reflect the machinist's grinding knowledge. Once selected the plan is instantiated with the proper parameter values. The instantiated plans are passed to the grinding simulation where simulated force sensor readings emulate real-time signals. Feedback from the simulation is used by a knowledge-based system to modify successful plans and to identify failed plans.
REFERENCES
Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.
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A. Agogino, S. Russell & R. Guha (1988) Sensor Fusion using Influence Diagrams and Reasoning by Analogy: Application to Milling Machine Monitoring and Control. In: Artificial Intelligence in Engineering: Diagnosis and Learning, (Ed.) J. S. Gero, Elsevier/Computational Mechanics Publications, pp. 333-357.
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G. Amitay, S. Malkin & Y. Koren (1981) Adaptive Control and Optimization of Grinding, Jnl. of Eng. for Industry, Trans. ASME, pp. 103-108.
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D. C. Brown & B. Chandrasekaran (1985) Plan selection in design problem solving. AIRG-DCB85-AISB, Computer Science Dept., Worcester Polytechnic Institute, Worcester, MA.
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R. I. King & R. S. Hahn (1986) Handbook of Modern Grinding Technology, Chapman and Hall, NY.
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R. P. Lindsay (1971) On the Metal Removal and Wheel Removal Parameters Surface Finish, Geometry and Thermal Damage in Precision Grinding, Ph.D. Thesis, Worcester Polytechnic Institute, Worcester, MA.
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R. P. Lindsay (1984) The Effect of Contact on Forces, Power and Metal Removal Rate in Precision Grinding. International Gr/nding Conference, Lake Geneva, Wis., Society of Manufacturing Engineers, Dearborn, MI.
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C. Hayes & P. K. Wright (1986) Automated Planning in the Machining Domain. Proceedings of ASME Meeting on Knowledge Based Expert Systems for Man~lfacturing, PED-Vol. 24, pp. 221- 232.
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S. Malkin (1981)Grinding Cycle Optimization, Annuals of CIRP, Vol. 30.
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S. Malkin & Y. Koren (1980) Off-line Grinding Optimization with a Microcomputer, Annuals of CIRP, Vol. 29, pp. 213-216.
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