The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences. Vol. XXXVII. Part B6b. Beijing 2008
344
Symposium on Close-range Photogrammetry, pp. 1-18. Falls
Church, VA: American Society of Photogrammetry.
Beddow, T.A., Ross, L.G., 1996a. Predicting biomass of
Atlantic salmon from morphometric lateral measurement^].
Journal of Fish Biology, 49(3), pp. 469-482.
Beddow, T.A., Ross, L.G., Marchant, J.A., 1996b. Predicting
salmon biomass remotely using a digital stereo-imaging
technique[J]. Aquaculture, 146(3), pp. 189-203.
Chen, L., Armstrong, C.W., Raftopoulos, D.D., 1994. An
investigation on the accuracy of three-dimensional space
reconstruction using the direct linear transformation technique.
J. Biomech, 27, pp. 493-500.
Harvey, E., Cappo, M., Shortis, M., 2003. The accuracy and
precision of underwater measurements of length and maximum
body depth of southern bluefin tuna (Thunnusmaccoyii) with a
stereo—video camera system[J], Fisheries Research, 63(3), pp.
315-326.
Janne Heikkil, Olli Silven, 1997. A four-step camera calibration
procedure with implicit image correction[C], Proceedings of
IEEE Computer Society Conference on Computer Vision and
Pattern Recognition, pp. 1106~ 1112.
Melen, T., 1994. Geometrical modeling and calibration of video
cameras for underwater navigation. Dr.ing thesis. Norges
tekniske hegskole, Institutt for teknisk kybemetikk.
Tsai, R.Y., 1987. A versatile camera calibration technique for
high-accuracy 3D machine vision metrology using off the shelf
TV cameras and lenses. IEEE Journal of Robotics and Auto
motion, RA-3(4), pp. 323-344.
ACKNOWLEDGMENTS
This research was partially supported by the Natural Science
Foundation of China, General Research, 10774021, 2008; the
Science Research Project of Dalian Fisheries University,
SY2004104 and 015609.
