Abstract
Correspondence techniques start from the assumption, based on the Lambertian reflection model, that the apparent brightness of a surface is independent of the observer’s angle of view. From this, a grey value constancy assumption is derived, which states that a change in brightness of a particular image pixel is proportional to a change in its position. This constancy assumption can be extended directly for vector valued images, such as RGB. It is clear that the grey value constancy assumption does not hold for surfaces with a non-Lambertian behaviour and, therefore, the underlying image representation is crucial when using real image sequences under varying lighting conditions and noise from the imaging device. In order for the correspondence methods to produce good, temporally coherent results, properties such as robustness to noise, illumination invariance, and stability with respect to small geometrical deformations are all desired properties of the representation. In this article, we study how different image representation spaces complement each other and how the chosen representations benefit from the combination in terms of both robustness and accuracy. The model used for establishing the correspondences, based on the calculus of variations, is itself considered robust. However, we show that considerable improvements are possible, especially in the case of real image sequences, by using an appropriate image representation. We also show how optimum (or near optimum) parameters, related to each representation space, can be efficiently found.
Highlights
The optical flow constraint [1], based on the Lambertian reflection model, states that a change in the brightness of a pixel is proportional to a change in its position, i.e., the grey level of a pixel is assumed to stay constant temporally
We argue that in order to properly rank a set of representation spaces or different algorithms, with respect to any performance measure, optimum parameters related to each case need to be searched consistently, with minimum human interference, avoiding over-fitting
Where our study differs from the rest is that (a) we use an advanced optimisation scheme to automatically optimise the parameters related to each image representation space, (b) image sets for optimisation and testing are different in order to avoid over-fitting, (c) we study the robustness of each representation space with respect to several image noise and illumination error models, and (d) we combine the results for both noise and illumination errors
Summary
The optical flow constraint [1], based on the Lambertian reflection model, states that a change in the brightness of a pixel is proportional to a change in its position, i.e., the grey level of a pixel is assumed to stay constant temporally. This same constancy concept can be used in disparity calculation by taking into account the epipolar geometry of the imaging devices (e.g., a stereo-rig). We argue that in order to properly rank a set of representation spaces or different algorithms, with respect to any performance measure, optimum parameters related to each case need to be searched consistently, with minimum human interference, avoiding over-fitting
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
