Exploration of motion inhibition for the suppression of false positives in biologically inspired small target detection algorithms from a moving platform.

IF 1.7 4区 工程技术 Q3 COMPUTER SCIENCE, CYBERNETICS
Biological Cybernetics Pub Date : 2022-12-01 Epub Date: 2022-10-28 DOI:10.1007/s00422-022-00950-9
Aaron Melville-Smith, Anthony Finn, Muhammad Uzair, Russell S A Brinkworth
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引用次数: 0

Abstract

Detecting small moving targets against a cluttered background in visual data is a challenging task. The main problems include spatio-temporal target contrast enhancement, background suppression and accurate target segmentation. When targets are at great distances from a non-stationary camera, the difficulty of these challenges increases. In such cases the moving camera can introduce large spatial changes between frames which may cause issues in temporal algorithms; furthermore targets can approach a single pixel, thereby affecting spatial methods. Previous literature has shown that biologically inspired methods, based on the vision systems of insects, are robust to such conditions. It has also been shown that the use of divisive optic-flow inhibition with these methods enhances the detectability of small targets. However, the location within the visual pathway the inhibition should be applied was ambiguous. In this paper, we investigated the tunings of some of the optic-flow filters and use of a nonlinear transform on the optic-flow signal to modify motion responses for the purpose of suppressing false positives and enhancing small target detection. Additionally, we looked at multiple locations within the biologically inspired vision (BIV) algorithm where inhibition could further enhance detection performance, and look at driving the nonlinear transform with a global motion estimate. To get a better understanding of how the BIV algorithm performs, we compared to other state-of-the-art target detection algorithms, and look at how their performance can be enhanced with the optic-flow inhibition. Our explicit use of the nonlinear inhibition allows for the incorporation of a wider dynamic range of inhibiting signals, along with spatio-temporal filter refinement, which further increases target-background discrimination in the presence of camera motion. Extensive experiments shows that our proposed approach achieves an improvement of 25% over linearly conditioned inhibition schemes and 2.33 times the detection performance of the BIV model without inhibition. Moreover, our approach achieves between 10 and 104 times better detection performance compared to any conventional state-of-the-art moving object detection algorithm applied to the same, highly cluttered and moving scenes. Applying the nonlinear inhibition to other algorithms showed that their performance can be increased by up to 22 times. These findings show that the application of optic-flow- based signal suppression should be applied to enhance target detection from moving platforms. Furthermore, they indicate where best to look for evidence of such signals within the insect brain.

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探索运动抑制,以抑制来自移动平台的生物启发式小目标检测算法中的误报。
在视觉数据中检测杂乱背景下的小型移动目标是一项具有挑战性的任务。主要问题包括时空目标对比度增强、背景抑制和精确目标分割。当目标距离非稳态摄像机很远时,这些挑战的难度就会增加。在这种情况下,移动的摄像头会在帧与帧之间带来巨大的空间变化,这可能会给时间算法带来问题;此外,目标可能会接近单个像素,从而影响空间方法。以往的文献表明,基于昆虫视觉系统的生物启发方法对此类情况具有鲁棒性。还有研究表明,在这些方法中使用分裂光流抑制,可以提高对小目标的检测能力。然而,在视觉通路中应用抑制的位置并不明确。在本文中,我们研究了一些视流滤波器的调谐,并使用视流信号的非线性变换来改变运动反应,以抑制假阳性并增强小目标的检测能力。此外,我们还研究了生物启发视觉(BIV)算法中的多个位置,在这些位置进行抑制可进一步提高检测性能,并研究了用全局运动估计来驱动非线性变换的方法。为了更好地了解 BIV 算法的性能,我们将其与其他最先进的目标检测算法进行了比较,并研究了如何利用视流抑制来提高其性能。我们对非线性抑制的明确使用,使得抑制信号的动态范围更广,同时还能对时空滤波器进行细化,从而在摄像机运动的情况下进一步提高目标-背景分辨能力。大量实验表明,我们提出的方法比线性条件抑制方案提高了 25%,是无抑制 BIV 模型检测性能的 2.33 倍。此外,与应用于相同、高度杂乱和移动场景的任何传统先进移动物体检测算法相比,我们的方法的检测性能提高了 10 到 104 倍。将非线性抑制应用于其他算法的结果表明,它们的性能最多可提高 22 倍。这些研究结果表明,应该应用基于光流的信号抑制来增强移动平台的目标检测能力。此外,它们还指出了在昆虫大脑中寻找此类信号证据的最佳位置。
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来源期刊
Biological Cybernetics
Biological Cybernetics 工程技术-计算机:控制论
CiteScore
3.50
自引率
5.30%
发文量
38
审稿时长
6-12 weeks
期刊介绍: Biological Cybernetics is an interdisciplinary medium for theoretical and application-oriented aspects of information processing in organisms, including sensory, motor, cognitive, and ecological phenomena. Topics covered include: mathematical modeling of biological systems; computational, theoretical or engineering studies with relevance for understanding biological information processing; and artificial implementation of biological information processing and self-organizing principles. Under the main aspects of performance and function of systems, emphasis is laid on communication between life sciences and technical/theoretical disciplines.
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