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1 - Computer Vision, Some Definitions, and Some History

from Part I - Preliminaries

Published online by Cambridge University Press:  25 October 2017

Wesley E. Snyder
Affiliation:
North Carolina State University
Hairong Qi
Affiliation:
University of Tennessee
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Summary

No object is mysterious. The mystery is your eye.

– Elizabeth Bowen

Introduction

There are two fundamentally different philosophies concerning understanding the brain. (1) Understand the brain first. If we can understand how the brain works, we can build smart machines. (2) Using any technique we can think of, make a smart machine. If we can accomplish that, it will give us some hints about how the brain works. This book is all about the second approach, although it draws from current understanding of biological computing. In this chapter, however, we define a few terms, introduce the greater localglobal problem, and then give a very brief introduction to the function of the mammalian brain.

  • • (Section 1.2) From signal and systems perspective, we describe the differences between Computer Vision and some other closely related fields of studies, including, e.g., image processing and pattern recognition.

  • • (Section 1.3) Since almost all problems in Computer Vision involve the issue of localness versus globalness, we briefly explain the “local-global” problem and the “consistency” principle used to solve this problem.

  • • (Section 1.4) Computer Vision is deep-rooted in biological vision. Therefore, in this section, we discuss the biological motivation of Computer Vision and some amazing discoveries from the study of the human visual system.

  • Some Definitions

    Computer Vision is the process whereby a machine, usually a digital computer, automatically processes an image and reports “what is in the image.” That is, it recognizes the content of the image. For example, the content may be a machined part, and the objective may be not only to locate the part but to inspect it as well.

    Students tend to get confused by other terms that often appear in the literature, such as Image Processing, Machine Vision, Image Understanding, and Pattern Recognition.

    We can divide the entire process of Image Processing into Low-Level Image Processing and High-Level Image Processing. If we interpret these processes from signal and systems perspective, it is more clear to describe their difference and similarity from the format of input/output of the system. When a Low-Level Image Processing system processes an input image, the output is still an image, but a somewhat different image. For example, it may be an image with noise removed, an image that does not take as much storage space as the input image, an image that is sharper than the input image, etc.

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    Publisher: Cambridge University Press
    Print publication year: 2017

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    References

    [1.1] D., Hubel and T., Wiesel. Receptive fields, binocular interaction, and functional architecture in the cat's visual cortex. Journal of Physiology (London), 160, 1962.Google Scholar
    [1.2] W., McCulloch and W., Pitts. A logical calculus of the ideas immanent in nervous activity. Bulletin of Mathematical Biophysics, 5, 1943.Google Scholar
    [1.3] M., Minsky and S., Papert. Perceptrons: An Introduction to Computational Geometry. MIT Press, 1969.
    [1.4] R., Ranjan, V., Patel, and R., Chellappa. Hyperface: A deep multi-task learning framework for face detection, landmark localization, pose estimation, and gender recognition. IEEE Transactions on Pattern Analysis and Machine Intelligence, 2016.
    [1.5] F., Rosenblatt. The Perceptron –a perceiving and recognizing automaton. Technical Report 85-460-1, Cornell Aeronautical Laboratory, 1957.
    [1.6] D., Rumelhart. Parallel Distributed Processing: Explorations in the Microstructure of Cognition. MIT Press, 1982.
    [1.7] M., Tovée. An Introduction to the Visual System. Cambridge University Press, 2008.
    [1.8] P., Werbos. Beyond Regression: New Tools for Prediction and Analysis in the Behavioral Sciences. PhD thesis.

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