Abstract
This paper describes an efficient background subtraction technique for detecting moving objects. The proposed approach is able to overcome difficulties like illumination changes and moving shadows. Our method introduces two discriminative features based on angular and modular patterns, which are formed by similarity measurement between two sets of RGB color vectors: one belonging to the background image and the other to the current image. We show how these patterns are used to improve foreground detection in the presence of moving shadows and in the case when there are strong similarities in color between background and foreground pixels. Experimental results over a collection of public and own datasets of real image sequences demonstrate that the proposed technique achieves a superior performance compared with state-of-the-art methods. Furthermore, both the low computational and space complexities make the presented algorithm feasible for real-time applications.
Highlights
Moving object detection is a crucial part of automatic video surveillance systems
Camouflage occurs when there is a strong similarity in color between background and foreground; so foreground pixels are classified as background
False Positive Error (FPE) means that the background pixels were set as Foreground while False Negative Error (FNE) indicates that foreground pixels were identified as Background
Summary
Moving object detection is a crucial part of automatic video surveillance systems. One of the most common and effective approach to localize moving objects is background subtraction, in which a model of the static scene background is subtracted from each frame of a video sequence. An area affected by cast shadow experiences a change of illumination In this case the background subtraction algorithm can misclassify background as foreground [4, 5]. We will show how these components are combined to improve the robustness and the discriminative sensitivity of the background subtraction algorithm in the presence of (i) moving shadows and (ii) strong similarities in color between background and foreground pixels. Another important advantage of our algorithm is its low computational complexity and its low space complexity that makes it feasible for real-time applications.
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