The Robotics Institute

Carnegie Mellon Robotics Institute

Uniform Coverage of Automotive Surface Patches

Prasad Atkar, Aaron L. Greenfield, David C. Conner, Howie Choset, and Alfred Rizzi
The International Journal of Robotics Research, Vol. 24, No. 11, November, 2005, pp. 883 - 898.


Download
  • Adobe portable document format (pdf) (1.1MB)
Copyright notice: This material is presented to ensure timely dissemination of scholarly and technical work. Copyright and all rights therein are retained by authors or by other copyright holders. All persons copying this information are expected to adhere to the terms and constraints invoked by each author's copyright. These works may not be reposted without the explicit permission of the copyright holder.
Abstract
In spray painting applications, it is essential to generate a spray gun trajectory such that the entire surface is completely covered and receives an acceptably uniform layer of paint deposition; we call this the "uniform coverage" problem. The uniform coverage problem is challenging because the atomizer emits a non-trivial paint distribution, thus making the relationships between the spray gun trajectory and the deposition uniformity complex. To understand the key issues involved in uniform coverage, we consider surface patches that are geodesically convex and topologically simple as representative of subsets of realistic automotive surfaces. In addition to ensuring uniform paint deposition on the surface, our goal is to also minimize the associated process cycle time and paint waste. Based on the relationships between the spray gun trajectory and the output characteristics (i.e., uniformity, cycle time and paint waste), our approach decomposes the coverage trajectory generation problem into three subproblems: (1) selecting a seed curve, (2) determining a speed profile along each pass, and (3) selecting the spacing between successive passes. Using concepts such as area magnification and the Gauss-Bonnet theorem from differential geometry, as well as standard optimization procedures, we present procedures to solve each subproblem independently from the others. We demonstrate our trajectory planning procedures by approximating real automotive surfaces by simple surfaces in simulation, and finally evaluate the effectiveness of our algorithms experimentally on real automotive surfaces.
Notes
Associated Lab(s)/Group(s): Biorobotics and Microdynamic Systems Laboratory
Associated Project(s): Controlled Coverage for Auto-Body Painting
Number of pages: 16
Text Reference
Prasad Atkar, Aaron L. Greenfield, David C. Conner, Howie Choset, and Alfred Rizzi, "Uniform Coverage of Automotive Surface Patches," The International Journal of Robotics Research, Vol. 24, No. 11, November, 2005, pp. 883 - 898.

BibTeX Reference
@article{Atkar_2005_6151,
   author = "Prasad Atkar, Aaron L. Greenfield, David C. Conner, Howie Choset, and Alfred Rizzi",
   journal = "Uniform Coverage of Automotive Surface Patches",
   booktitle = "The International Journal of Robotics Research",
   pages = "883 - 898",
   month = "November",
   year = "2005",
   volume = "24",
   number = "1",
}

The Robotics Institute is part of the School of Computer Science, Carnegie Mellon University.
Contact Us | Site Map | Update Instructions