Machinable volume extraction for automatic process planning

References

• Ambardekar . V.P. ( 1993 ) Automatic machining volume extraction from a CAD model. M.Sc (Engg.) dissertation. Department of Mechanical Engineering. , Indian Institute of Science. Bangalore . India .
   Google Scholar
• Arbab . F. ( 1982 ) Requirements and architecture of CAM oriented CAD systems for design and manufacture of mechanical pans. , Ph.D. Dissertation. University of California at Los Angeles. CA . USA .
   Google Scholar
• Chamberlain . M.A. , Joneja . A. and Chang . T.C. ( 1993 ) Protrusionfeatures handling in design and manufacturing planning. Compurer Aided Design. , 25 ( 1 ). 19 – 28 .
   Web of Science ®Google Scholar
• Choi , B.K. , Barash , M.M. and Anderson . D.C. ( 1984 ) Automatic recognition of machined surface from a 3-D solid model. Computer Aided Design. 16 ( 2 ). 81 – 86 .
   Web of Science ®Google Scholar
• Cutkosky , M. , Tenenbaum . J. and Miller , D. ( 1988 ) Features in process based design. in Proceedings of The A SAIE Computers in Engineering Conference. , Tipnis . V.A. and Patton . E.M. (eds), ASME. New York , pp. 557 – 562 .
   Google Scholar
• Grayer . A.R. ( 1977 ) The automatic production of machined component starting from a stored geometric description. in Advances in Computer Aided Manufacture , McPherson . D. (ed.). North Holland . Amsterdam . The Netherlands , pp. 137 – 150 .
   Google Scholar
• Gupta . S.K. , Nau . O.S. and Zhang . G. ( 1993 ) Interpreting product designs for manufacturability evaluation. in Proceedings of the ASME Winter Annual Meeting. , ASME. New York . NY , pp. 33 – 44 .
   Google Scholar
• Hanada . T. and Hoshi , T. ( 1992 ) Block-like component CAD/CAM system for fully automated CAM processing. Annals of the CIRP. , 41 ( 1 ), 551 – 556 .
   Google Scholar
• Kim . Y.S. ( 1992 ) Recognition of form-features using convex decemposition. Computer Aided Design , 24 ( 9 ). 461 – 476 .
   Web of Science ®Google Scholar
• Pande . S.S. and Walvekar , M.G. ( 1990 ) PRICAPP: a computer assisted process planning system for prismatic components. International Journal of Production Research. , 28 ( 2 ). 279 – 292 .
   Web of Science ®Google Scholar
• Perng . D‐B. , Zen . C. and Li . R.K. ( 1990 ) Automatic 3D machining feature extraction from 3D CSG solid input. Computer Aided Design , 22 ( 5 ). 285 – 295 .
   Web of Science ®Google Scholar
• Pratt . M. ( 1993 ) Automated feature recognition and its role in product modelling, in Geometric Modelling for CAD Applications , Farin , G. , Hagen , H. and Noltemcicr . H. (eds.), Springer-Verlag. New York .
   Google Scholar
• Sakurai . H. (1995) Volume decomposition and feature recognition: part I - polyhedral objects. Computer Aided Design. , 27(11). 833–843.
   Web of Science ®Google Scholar
• Sakurai . H. and Dave . P. (y19%) Volume decomposition and feature recognition: part II - curved objects. Computer Aided Design. , 28 ( 6/7 ). 519 – 537 .
   Web of Science ®Google Scholar
• Sakurai . H. and Gossard . D.C. ( 1990 ) Recognizing shape features in solid models. IEEE Computer Graphics lind Applications , September , 22 – 32 .
   Web of Science ®Google Scholar
• Salomons , O.W. , Van Houtcn , F.J.A.M. and Kals , H.J.J. ( 1993 ) Review of research in feature-based design. Journal of Manufacturing Systems , 12 ( 2 ). 113 – 132 .
   Web of Science ®Google Scholar
• Shah . J.J. ( 1988 ) Feature transformations between application-specific feature spaces. Computer-Aided Engineering Journal. , 5 ( 6 ), 247 – 255 .
   Google Scholar
• Shah . J.J. ( 1991 ) Assessment of features technology. Computer Aided Design. , 23 ( 5 ). 331 – 342 .
   Web of Science ®Google Scholar
• Shah . J.J. , Shen , Y. and Sirur , A. ( 1994 ) Determination of machining volumes from extensible sets of design features in Advances in Featun: Based Manufacturing. Shah . I. , Mantyla . M. and Nau , D. (eds.). Elsevier. Amsterdam . The Netherlands . pp. 129 – 157 .
   Google Scholar
• Shpitalni . M. and Fischer . A. ( 1991 ) CSG representation as a basis for extraction of machining features. Annals of the CIRP. , 40 ( 1 ). 157 – 160 .
   Google Scholar
• Subruhmunyam . S. and Wozny . M. ( 1995 ) Overview of automatic feature recognition techniques for computer-aided process planning. Computers in Industry , 26 ( 1 ). 1 – 21 .
   Web of Science ®Google Scholar
• Tseng . Y.I. and Joshi . S.B. ( 1994 ) Recognizing multiple interpretations of interacting machining features. Computer Aided Design. , 26 ( 9 ), 667 – 688 .
   Web of Science ®Google Scholar
• Van den Brande . I.H. and Rcquicha , A.A.G. ( 1993 ) Spatial reasoning for the automatic recognition of machinable features in solid models. IEEE Transactions on Pattern Analysis and Machine Intelligence , 15 ( 12 ). 1269 – 1285 .
   Web of Science ®Google Scholar
• Vujosevic . R. and Kusiak . A. ( 1993 ) Selection of machinable volumes. an object-oriented approach. Expert Systems with Applications. , 4 ( 3 ). 273 – 283 .
   Web of Science ®Google Scholar
• Waco . D.L. and Kim , Y.S. ( 1994 ) Geometric reasoning for machining features using convex decomposition. Computer Aided Design. , 26 ( 6 ). 477 – 489 .
   Web of Science ®Google Scholar
• Wang . M.T. ( 1990 ) A geometric reasoning methodology for manufaciuring feature extraction from a 3-D CAD model. , Ph.D. thesis. Purdue University. West Lafayette . IN 47907. USA .
   Google Scholar
• Woo , T. ( 1982 ) Feature extraction by volume decomposition. in Proceedings of the Conference On CAD/CAM Technology in Mechanical Engineering , MIT. Cambridge . MA . pp. 76 – 94 .
   Google Scholar