Asynchronous Event-Based Hebbian Epipolar Geometry

Epipolar geometry, the cornerstone of perspective stereo vision, has been studied extensively since the advent of computer vision. Establishing such a geometric constraint is of primary importance, as it allows the recovery of the 3-D structure of scenes. Estimating the epipolar constraints of nonpe...

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Bibliographic Details
Published in:IEEE transaction on neural networks and learning systems 2011-11, Vol.22 (11), p.1723-1734
Main Authors: Benosman, R., Sio-Hoï Ieng, Rogister, P., Posch, C.
Format: Article
Language:English
Subjects:
Activation
Algorithms
Applied sciences
Arrays
Artificial Intelligence
Asynchronous acquisition
asynchronous sensing
Biomimetic Materials
Cameras
Computer science
control theory
systems
Equations
Estimating
event-based vision
Exact sciences and technology
frame-free
frameless vision
Geometry
Image Interpretation, Computer-Assisted
Jitter
Light
Lighting
Neural networks
Neural Networks (Computer)
neuromorphic electronics
Pattern Recognition, Automated
Pattern recognition. Digital image processing. Computational geometry
Retina
Sensation
Sensors
Space Perception
stereovision
Studies
Three dimensional
time impulse codification
time-based imaging
Vision
Vision, Binocular
Voltage control
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Summary:Epipolar geometry, the cornerstone of perspective stereo vision, has been studied extensively since the advent of computer vision. Establishing such a geometric constraint is of primary importance, as it allows the recovery of the 3-D structure of scenes. Estimating the epipolar constraints of nonperspective stereo is difficult, they can no longer be defined because of the complexity of the sensor geometry. This paper will show that these limitations are, to some extent, a consequence of the static image frames commonly used in vision. The conventional frame-based approach suffers from a lack of the dynamics present in natural scenes. We introduce the use of neuromorphic event-based-rather than frame-based-vision sensors for perspective stereo vision. This type of sensor uses the dimension of time as the main conveyor of information. In this paper, we present a model for asynchronous event-based vision, which is then used to derive a general new concept of epipolar geometry linked to the temporal activation of pixels. Practical experiments demonstrate the validity of the approach, solving the problem of estimating the fundamental matrix applied, in a first stage, to classic perspective vision and then to more general cameras. Furthermore, this paper shows that the properties of event-based vision sensors allow the exploration of not-yet-defined geometric relationships, finally, we provide a definition of general epipolar geometry deployable to almost any visual sensor.
ISSN:1045-9227
2162-237X
1941-0093
2162-2388
DOI:10.1109/TNN.2011.2167239