TY - GEN
T1 - Local or global minima
T2 - 1st International Workshop on Computer Vision for Biomedical Image Applications, CVBIA 2005
AU - Li, Hua
AU - Yezzi, Anthony
PY - 2005
Y1 - 2005
N2 - Most variationsl active contour models are designed to find the "desirable" local minima of data-dependent energy functionals with the hope of avoiding undesirable configurations due to noise or complex image structure. As such, there has been much research into the design of complex region-based energy functionals that are less likely to yield undesirable local minima. Unfortunately, most of these more "robust" region-based energy functionals are applicable to a much narrower class of imagery due to stronger assumptions about the underlying image data. Devising new implementation algorithms for active contours that attempt to capture more global minimizers of already proposed imagebased energies would allow us to choose an energy that makes sense for a particular class of energy without concern over its sensitivity to local minima. However, sometimes the completely-global minimum is just as undesirable as a minimum that is too local. In this paper, we propose a novel, fast and flexible dual front implementation of active contours, motivated by minimal path techniques and utilizing fast sweeping algorithms, which is easily manipulated to yield minima with variable "degrees" of localness and globalness. The ability to gracefully move from capturing minima that are more local (according to the initial placement of the active contour/surface) to minima that are more global makes it much easier to obtain "desirable" minimizers (which often are neither the most local nor the most global). As the examples, we illustrate the 2D and 3D implementations of this dual-front active contour for image segmentation from MRI imagery.
AB - Most variationsl active contour models are designed to find the "desirable" local minima of data-dependent energy functionals with the hope of avoiding undesirable configurations due to noise or complex image structure. As such, there has been much research into the design of complex region-based energy functionals that are less likely to yield undesirable local minima. Unfortunately, most of these more "robust" region-based energy functionals are applicable to a much narrower class of imagery due to stronger assumptions about the underlying image data. Devising new implementation algorithms for active contours that attempt to capture more global minimizers of already proposed imagebased energies would allow us to choose an energy that makes sense for a particular class of energy without concern over its sensitivity to local minima. However, sometimes the completely-global minimum is just as undesirable as a minimum that is too local. In this paper, we propose a novel, fast and flexible dual front implementation of active contours, motivated by minimal path techniques and utilizing fast sweeping algorithms, which is easily manipulated to yield minima with variable "degrees" of localness and globalness. The ability to gracefully move from capturing minima that are more local (according to the initial placement of the active contour/surface) to minima that are more global makes it much easier to obtain "desirable" minimizers (which often are neither the most local nor the most global). As the examples, we illustrate the 2D and 3D implementations of this dual-front active contour for image segmentation from MRI imagery.
UR - http://www.scopus.com/inward/record.url?scp=33646676961&partnerID=8YFLogxK
U2 - 10.1007/11569541_36
DO - 10.1007/11569541_36
M3 - Conference contribution
AN - SCOPUS:33646676961
SN - 3540294112
SN - 9783540294115
T3 - Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)
SP - 356
EP - 366
BT - Computer Vision for Biomedical Image Applications - First International Workshop, CVBIA 2005, Proceedings
PB - Springer Verlag
Y2 - 21 October 2005 through 21 October 2005
ER -