Towards biomimetic stereo vision

Proceedings of the IEEE 2010 National Aerospace & Electronics Conference Pub Date : 2010-07-14 DOI:10.1109/NAECON.2010.5712981

B. L. Raskob, A. C. Parker

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Abstract

Though much is known about how binocular neurons in the primary visual cortex respond to stereo imagery, there has yet to be a consensus on how these responses are actually used to compute stereo disparity, the difference in the position of an object between the right image and left image in a stereo pair. We describe a new theory for neural stereo disparity computation using a reformulation of the well-known binocular energy model as an energy response of complex continuous wavelets. These wavelets are used to detect disparity phase interference (DPI), local sinusoidal patterns created in the frequency spectrum when a pair of stereo images are added together. The magnitude of disparity can be approximated mathematically from the frequency of the DPI. Once the disparity is determined for each object, the 3D localization of the object can occur. Describing the binocular complex cell responses with the wavelet transform offers a powerful means of analyzing information content in images, and is highly amenable to the detection of DPI. We believe that this technique represents a promising step towards biomimetic stereo vision.

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走向仿生立体视觉

虽然人们对初级视觉皮层中的双眼神经元如何对立体图像做出反应已经有了很多了解，但对于这些反应如何实际用于计算立体视差，即立体图像中物体在右图像和左图像之间的位置差异，还没有达成共识。我们描述了一种新的神经立体视差计算理论，使用众所周知的双目能量模型的重新表述作为复杂连续小波的能量响应。这些小波被用来检测视差相位干涉(DPI)，当一对立体图像被加在一起时，在频谱中产生的局部正弦模式。视差的大小可以从DPI的频率数学近似。一旦确定了每个对象的视差，就可以进行对象的3D定位。用小波变换描述双眼复杂细胞的响应，为分析图像中的信息含量提供了一种强有力的手段，并且非常适合DPI的检测。我们相信这项技术代表了朝着仿生立体视觉迈出的有希望的一步。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings of the IEEE 2010 National Aerospace & Electronics Conference

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