Abstract
This paper presents an automatic solution to the problem of detecting and counting cars in unmanned aerial vehicle (UAV) images. This is a challenging task given the very high spatial resolution of UAV images (on the order of a few centimetres) and the extremely high level of detail, which require suitable automatic analysis methods. Our proposed method begins by segmenting the input image into small homogeneous regions, which can be used as candidate locations for car detection. Next, a window is extracted around each region, and deep learning is used to mine highly descriptive features from these windows. We use a deep convolutional neural network (CNN) system that is already pre-trained on huge auxiliary data as a feature extraction tool, combined with a linear support vector machine (SVM) classifier to classify regions into “car” and “no-car” classes. The final step is devoted to a fine-tuning procedure which performs morphological dilation to smooth the detected regions and fill any holes. In addition, small isolated regions are analysed further using a few sliding rectangular windows to locate cars more accurately and remove false positives. To evaluate our method, experiments were conducted on a challenging set of real UAV images acquired over an urban area. The experimental results have proven that the proposed method outperforms the state-of-the-art methods, both in terms of accuracy and computational time.
Highlights
Unmanned aerial vehicles (UAV) are increasingly used as a cost effective and timely method of capturing remote sensing (RS) images
We propose a novel car detection framework in UAV images that is based on an effective combination of segmentation techniques and deep learning approaches to achieve higher detection rates and lower computational times
As for the average car size in pixels Savg, given that the UAV images at hand have a resolution of 2 cm ground sample distance (GSD), Savg can be estimated as 200 × 90 pixels
Summary
Unmanned aerial vehicles (UAV) are increasingly used as a cost effective and timely method of capturing remote sensing (RS) images. The advance of UAV technology has reached the stage of being able to provide extremely high resolution remote sensing images encompassing abundant spatial and contextual information. This has enabled studies proposing many novel applications for UAV image analysis, including vegetation monitoring [2,3], urban site analysis [4,5], disaster management, oil and gas pipeline monitoring, detection and mapping of archaeological sites [6], and object detection [7,8,9,10]. Zhao and Nevatia [11]
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