Development of a high resolution pattern-projection system using linescan cameras

authored by: B. Denkena, P. Huke
Abstract: The development of a modified stripe-pattern projection system that uses linescan cameras is presented. The system measures complex-shaped sheet metal parts (<3 m²) and enables the detection of dents (>30 μm) and other defects. Therefore, the measurement system is moved and the parts are scanned line by line. The parallel investigation of a simulation environment in order to optimize the system is shown. The simulation combines optical ray tracing based on the matrix formalism [1] and projective transformation to get an image equivalent to the measured image in the laboratory setup. In order to extract the object's shape from the measured and the simulated line Fourier-Profilometry is used [2]. Therefore a FFT is applied to the data. The power spectra show a central frequency phase modulated with the object's shape. A filtering algorithm, an IFFT and a phase unwrapping algorithm deliver the shape. Both, experimental data and results from the simulation are shown and the noise effects are considered.
Organisation(s): Institute of Production Engineering and Machine Tools
Type: Conference contribution
Publication date: 17.07.2009
Publication status: Published
Peer reviewed: Yes
ASJC Scopus subject areas: Electronic, Optical and Magnetic Materials, Condensed Matter Physics, Computer Science Applications, Applied Mathematics, Electrical and Electronic Engineering
Electronic version(s): https://doi.org/10.1117/12.823837 (Access: Unknown)

BibTeX

@inproceedings{3e04a302f83d4970b2ccf4dd4dd8be0e,
title = "Development of a high resolution pattern-projection system using linescan cameras",
abstract = "The development of a modified stripe-pattern projection system that uses linescan cameras is presented. The system measures complex-shaped sheet metal parts (<3 m2) and enables the detection of dents (>30 μm) and other defects. Therefore, the measurement system is moved and the parts are scanned line by line. The parallel investigation of a simulation environment in order to optimize the system is shown. The simulation combines optical ray tracing based on the matrix formalism [1] and projective transformation to get an image equivalent to the measured image in the laboratory setup. In order to extract the object's shape from the measured and the simulated line Fourier-Profilometry is used [2]. Therefore a FFT is applied to the data. The power spectra show a central frequency phase modulated with the object's shape. A filtering algorithm, an IFFT and a phase unwrapping algorithm deliver the shape. Both, experimental data and results from the simulation are shown and the noise effects are considered.",
author = "B. Denkena and P. Huke",
year = "2009",
month = jul,
day = "17",
doi = "10.1117/12.823837",
language = "English",
isbn = "9780819476722",
series = "Proceedings of SPIE - The International Society for Optical Engineering",
booktitle = "Optical Measurement Systems for Industrial Inspection VI",
note = "Optical Measurement Systems for Industrial Inspection VI ; Conference date: 15-06-2009 Through 18-06-2009",
}