Geometric Algorithms for Digitized Pictures on a Mesh-Connected Computer

Although mesh-connected computers are used almost exclusively for low-level local image processing, they are also suitable for higher level image processing tasks. We illustrate this by presenting new optimal (in the O-notational sense) algorithms for computing several geometric properties of figure...

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Bibliographic Details
Published in:IEEE transactions on pattern analysis and machine intelligence 1985-03, Vol.PAMI-7 (2), p.216-228
Main Authors: Miller, Russ, Stout, Quentin F.
Format: Article
Language:English
Subjects:
Applied sciences
Artificial intelligence
Computational geometry
Computer science
control theory
systems
convexity
Exact sciences and technology
Filtering algorithms
Image edge detection
Image processing
Labeling
mesh-connected computer
Parallel processing
Pattern recognition
Pattern recognition. Digital image processing. Computational geometry
Pixel
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Summary:Although mesh-connected computers are used almost exclusively for low-level local image processing, they are also suitable for higher level image processing tasks. We illustrate this by presenting new optimal (in the O-notational sense) algorithms for computing several geometric properties of figures. For example, given a black/white picture stored one pixel per processing element in an n × n mesh-connected computer, we give θ(n) time algorithms for determining the extreme points of the convex hull of each component, for deciding if the convex hull of each component contains pixels that are not members of the component, for deciding if two sets of processors are linearly separable, for deciding if each component is convex, for determining the distance to the nearest neighboring component of each component, for determining internal distances in each component, for counting and marking minimal internal paths in each component, for computing the external diameter of each component, for solving the largest empty circle problem, for determining internal diameters of components without holes, and for solving the all-points farthest point problem. Previous mesh-connected computer algorithms for these problems were either nonexistent or had worst case times of θ(n 2 ). Since any serial computer has a best case time of θ(n 2 ) when processing an n × n image, our algorithms show that the mesh-connected computer provides significantly better solutions to these problems.
ISSN:0162-8828
1939-3539
2160-9292
DOI:10.1109/TPAMI.1985.4767645