Displacement and Illumination Levels Effect on Short-distance Measurement Errors of Using a Camera

Authors

  • Eduardo D. Piedad Jr. University of San Jose-Recoletos
  • Ricky B. Villeta University of San Jose-Recoletos

DOI:

https://doi.org/10.32871/rmrj1604.01.06

Keywords:

short-distance measurement error, camera-to-lens displacement, illumination, computer vision, camera, descriptive and comparative analysis

Abstract

Using a camera for measurement reading is simplified through the incorporation of computer vision application. The variations in the environment’s setting, however, may constitute to the occurrence of measurement errors. A study investigated the significant effect of changing the camera-to-lens displacements and the variations of the illumination level on the short-distance measurement reading. This is performed initially by developing an actual setup calibrated though the comparison with the hypothesized values. Then, an experiment on this calibrated setup generates the measurement results of varying the displacement positions and the illumination levels. Through descriptive and comparative statistical analysis, there is evidence that the variations of the displacement alone do not significantly change the measurement results. Similarly, the variations in the illumination levels do not also constitute significant changes on the measurement results. Hence, each of the variables bears no contribution on the occurrence of the measurement error of using camera. It is further confirmed through the two way analysis of variance that there is no significant difference on the displacement positions and illumination levels, and on their interactions. These results verified that a camera can be used as a short-distance measurement tool adequately regardless on the object-to-lens displacement positions and on the illumination levels.

Author Biography

Eduardo D. Piedad Jr., University of San Jose-Recoletos

Faculty, University of San Jose-Recoletos

References

Abaya, W. F., Basa, J., Sy, M., Abad, A. C., & Dadios, E. P. (2014, November). Low cost smart security camera with night vision capability using Raspberry Pi and OpenCV. In 2014 International Conference on Humanoid, Nanotechnology, Information Technology, Communication and Control, Environment and Management (HNICEM), (pp. 1-6). IEEE. Palawan, Philippines.

Alegria, E. C., & Serra, A. C. (2000).Automatic calibration of analog and digital measuring instruments using computer vision. IEEE transactions on instrumentation and measurement, 49(1), 94-99. Bradski,

G., & Kaehler, A. (2008). Learning OpenCV: Computer vision with the OpenCV library. California: Learning OpenCV: Computer vision with the OpenCV library.

Heng, L., Lee, G. H., &Pollefeys, M. (2015).Selfcalibration and visual slam with a multi-camera system on a micro aerial vehicle. Autonomous Robots, 39(3), 259- 277.

Laganière, R. (2011). OpenCV 2 Computer Vision Application Programming Cookbook: Over 50 recipes to master this library of programming functions for real-time computer vision. Birmingham: Packt Publishing Ltd.

Lee, K. W. (2014). Implementation of Video Surveillance System with Motion Detection based on Network Camera Facilities. The Journal of the Institute of Internet, Broadcasting and Communication, 14(1), 169-177.

Lei, Z., Xue-fei, Z., & Yin-ping, L. (2008, December). Research of the real-time detection of traffic flow based on OpenCV. In Computer Science and Software Engineering, 2008 International Conference on Computer Science and Software Engineering (Vol. 2, pp. 870- 873). IEEE.Wuhan, China.

Liu, X., Su, H., Kang, S., Kane, T. D., &Shekhar, R. (2015, March). Application of single-image camera calibration for ultrasound augmented laparoscopic visualization. In SPIE Medical Imaging (pp. 94151T-94151T).International Society for Optics and Photonics.

Luccheseyz, L., &Mitray, S. K. (2001). Color image segmentation: A state-of-theart survey. Proceedings of the Indian National Science Academy (INSA-A), 67(2), 207-221.

Luhmann, T., Fraser, C., & Maas, H. G. (2016).Sensor modelling and camera calibration for close-range photogrammetry. ISPRS Journal of Photogrammetry and Remote Sensing, 115, 37-46.

Meyer, F., &Beucher, S. (1990).Morphological segmentation. Journal of visual communication and image representation, 1(1), 21-46.Fontainebleau, France.

Rathi, Y., Vaswani, N., Tannenbaum, A., &Yezzi, A. (2007). Tracking deforming objects using particle filtering for geometric active contours. IEEE transactions on pattern analysis and machine intelligence, 29(8), 1470-1475.

Szeliski, R. (2010). Computer vision: algorithms and applications. New York: Springer Science & Business Media.

Tuohy, S., O’Cualain, D., Jones, E., &Glavin, M. (2010, June). Distance determination for an automobile environment using inverse perspective mapping in OpenCV. In Proc. Irish Signals and Systems Conference (Vol. 2010).

Xin, Y., Ruishuang, Z., & Li, S. (2011). A calibration method based on OpenCV. 3rd International Workshop on Intelligent Systems and Applications, (pp. 1-4). Wuhan, China.

Downloads

Published

2016-06-30

How to Cite

Piedad Jr., E. D., & Villeta, R. B. (2016). Displacement and Illumination Levels Effect on Short-distance Measurement Errors of Using a Camera. Recoletos Multidisciplinary Research Journal, 4(1). https://doi.org/10.32871/rmrj1604.01.06

Issue

Vol. 4 No. 1 (2016)

Section

Articles

License

Copyright of the Journal belongs to the University of San Jose-Recoletos

Most read articles by the same author(s)

1 2 > >>