Citation:
Jiande Zhang and Jingui Lu.Measuring Propeller Blade Width Using Binocular Stereo Vision[J].Journal of Marine Science and Application,2011,(2):246-251.
Click and Copy
Measuring Propeller Blade Width Using Binocular Stereo Vision
Jiande Zhang and Jingui Lu.Measuring Propeller Blade Width Using Binocular Stereo Vision[J].Journal of Marine Science and Application,2011,(2):246-251.
Info
- Title:
- Measuring Propeller Blade Width Using Binocular Stereo Vision
- Author(s):
- -
- Affilations:
- Keywords:
- blade width; binocular stereo vision; propeller; vision measurement
- DOI:
- -
- Abstract:
- Propeller blade width measurement has been extensively studied in the past using direct and indirect methods, and it plays a great role in determining the quality of the finished products. It has surveyed that previous techniques are usually time-consuming and erroneous due to a large number of points to be processed in blade width measurement. This paper proposes a new method of measuring blade width using two images acquired from different viewpoints of the same blade. And a new feature points matching approach for propeller blade image is proposed in stereo vision measurement. Based on these, pixel coordinates of contour points of the blade in two images are extracted and converted to real world coordinates by image algorithm and binocular stereo machine vision theory. Then, from the real world coordinates, the blade width at any position can be determined by simple geometrical method.
References:
Bartoli A, Sturm P (2005). Structure-from-motion using lines: Representation, triangulation, and bundle adjustment. Computer Vision and Image Understanding, 100(3), 16-441.
Carlton JS (1994). Marine propellers and propulsion. Butterworth Heinemann, 28-54.
Davis J, Nehab D, Ramamoothi R (2005). Space time stereo: a unifying framework for depth from triangulation. IEEE Trans. On Pattern Analysis and Machine Intelligence, 27(2), 296-302.
Fujisawa N, Nakamura Y, Matsuura F, Sato Y (2006). Pressure field evaluation of microchannel junction flows through PIV measurement. Microfluidics and Nanofluidics, 3, 447-453.
Fujisawa N, Verhoeckx M, Dabiri D, Gharib M, Hertzberg J (2007). Recent progress in flow visualization techniques toward the generation of fluid art. Journal of Visualization, 10(2), 163-170.
International Standards Organization(1981). Shipbuilding Ship Screw Propeller Manufacturing Tolerance, ISO 3715–1978 (E), 1st edn-1981–08–15.
Kiuchi M, Fujisawa N, Tomimatsu S(2005). Performance of a PIV system for combusting flow and its application to a spray combustor model. Journal of Visualization, 8(3), 269-276.
Lam MK, Lee SF, Iovenitti P, Masood H (2002). A cost and effective thickness measurement technique for engine propellers. International Journal of Advanced Manufacturing Technology, 20, 180-189.
Matsuura F, Fujisawa N (2008). Anaglyph stereo visualization by the use of a single image and depth information. Journal of Visualization, 11(1), 79-86.
Okada K, Inaba M, Inoue, H (2003). Integration of real-time binocular stereo vision and whole body information for dynamic walking navigation of humanoid robot. IEEE Conference on Multisensor Fusion and Integration for Intelligent Systems, Tokyo, 131-136.
Rother C, Carlsson S (2002). Linear multi view reconstruction and camera recovery using a reference plane. International Journal of Computer Vision, 49(2/3), 117-141.
Slama CC (1980). Manual of Photogrammetry. 4th ed. American Society of Photogrammetry, Falls Church, Virginia, 447-451.
Soloff S, Adrian R, Liu ZC (1997). Distortion compensation for generalized stereoscopic particle image velocimetry. Measurement Science and Technology, 8 , 1441-1454.
Tsai RY (1987). A versatile camera calibration technique for high-accuracy 3D machine vision metrology using off-the-shelf TV cameras and lenses. IEEE Trans. on RA, 3(4), 323–344.
Zhang GX(2000). The trend in development of coordinate measuring machines. Chinese Mechanical Engineering, 11(2), 222-227.
Memo
- Memo:
- -
