Your search keyword '"Chamfer"' showing total 3 results

1. Euclidean Distance Approximations From Replacement Product Graphs.

Author

Terlep, T. Arthur, Bell, Mark R., Talavage, Thomas M., and Smith, Douglas L.

Subjects

*IMAGE processing, *GRAPH theory, *CELLULAR automata, *COMPUTATIONAL complexity, *EIKONAL equation, *EUCLIDEAN distance

Abstract

We introduce a new chamfering paradigm, locally connecting pixels to produce path distances that approximate Euclidean space by building a small network (a replacement product) inside each pixel. These “ RE-grid graphs” maintain near-Euclidean polygonal distance contours even in noisy data sets, making them useful tools for approximation when exact numerical solutions are unobtainable or impractical. The RE-grid graph creates a modular global architecture with lower pixel-to-pixel valency and simplified topology at the cost of increased computational complexity due to its internal structure. We present an introduction to chamfering replacement products with a number of case study examples to demonstrate the potential of these graphs for path-finding in high frequency and low resolution image spaces which motivate further study. Possible future applications include morphology, watershed segmentation, halftoning, neural network design, anisotropic image processing, image skeletonization, dendritic shaping, and cellular automata. [ABSTRACT FROM AUTHOR]

Published

2022

2. Euclidean Distance Approximations From Replacement Product Graphs.

Author

Terlep, T. Arthur, Bell, Mark R., Talavage, Thomas M., and Smith, Douglas L.

Subjects

*IMAGE processing, *COMPUTATIONAL complexity, *CELLULAR automata, *GRAPH theory, *EIKONAL equation, *EUCLIDEAN distance

Abstract

We introduce a new chamfering paradigm, locally connecting pixels to produce path distances that approximate Euclidean space by building a small network (a replacement product) inside each pixel. These “ $RE$ -grid graphs” maintain near-Euclidean polygonal distance contours even in noisy data sets, making them useful tools for approximation when exact numerical solutions are unobtainable or impractical. The $RE$ -grid graph creates a modular global architecture with lower pixel-to-pixel valency and simplified topology at the cost of increased computational complexity due to its internal structure. We present an introduction to chamfering replacement products with a number of case study examples to demonstrate the potential of these graphs for path-finding in high frequency and low resolution image spaces which motivate further study. Possible future applications include morphology, watershed segmentation, halftoning, neural network design, anisotropic image processing, image skeletonization, dendritic shaping, and cellular automata. [ABSTRACT FROM AUTHOR]

Published

2021

3. Optimum design of chamfer distance transforms

Author

M. Akmal Butt and Petros Maragos

Subjects

Approximation theory, Mathematical optimization, Chamfer, Approximation error, Binary image, Digital image processing, Geometric transformation, Image processing, Computer Graphics and Computer-Aided Design, Algorithm, Distance transform, Software, Mathematics

Abstract

The distance transform has found many applications in image analysis. Chamfer distance transforms are a class of discrete algorithms that offer a good approximation to the desired Euclidean distance transform at a lower computational cost. They can also give integer-valued distances that are more suitable for several digital image processing tasks. The local distances used to compute a chamfer distance transform are selected to minimize an approximation error. A new geometric approach is developed to find optimal local distances. This new approach is easier to visualize than the approaches found in previous work, and can be easily extended to chamfer metrics that use large neighborhoods. A new concept of critical local distances is presented which reduces the computational complexity of the chamfer distance transform without increasing the maximum approximation error.

Published

1998