Fast autofocusing based on single-pixel moment detection

Huiling Chen, Dongfeng Shi, Zijun Guo, Runbo Jiang, Linbin Zha, Yingjian Wang, Jan Flusser
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Abstract

Traditional image processing-based autofocusing techniques require the acquisition, storage, and processing of large amounts of image sequences, constraining focusing speed and cost. Here we propose an autofocusing technique, which directly and exactly acquires the geometric moments of the target object in real time at different locations by means of a proper image modulation and detection by a single-pixel detector. An autofocusing criterion is then formulated using the central moments, and the fast acquisition of the focal point is achieved by searching for the position that minimizes the criterion. Theoretical analysis and experimental validation of the method are performed and the results show that the method can achieve fast and accurate autofocusing. The proposed method requires only three single-pixel detections for each focusing position of the target object to evaluate the focusing criterion without imaging the target object. The method does not require any active object-to-camera distance measurement. Comparing to local differential methods such as contrast or gradient measurement, our method is more stable to noise and requires very little data compared with the traditional image processing methods. It may find a wide range of potential applications and prospects, particularly in low-light imaging and near-infra imaging, where the level of noise is typically high. Dongfeng Shi and colleagues design an autofocusing algorithm which required fewer sampling pixels. Their method performs well in low light high noise imaging.

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基于单像素瞬间检测的快速自动对焦功能
传统的基于图像处理的自动对焦技术需要采集、存储和处理大量的图像序列,从而限制了对焦速度和成本。在此,我们提出一种自动对焦技术,通过适当的图像调制和单像素检测器的检测,直接准确地实时获取目标物体在不同位置的几何矩。然后利用中心矩制定自动对焦准则,并通过搜索使该准则最小化的位置来实现焦点的快速获取。对该方法进行了理论分析和实验验证,结果表明该方法可以实现快速准确的自动对焦。所提出的方法只需要对目标物体的每个对焦位置进行三个单像素检测,就能评估对焦准则,而无需对目标物体成像。该方法不需要主动测量目标物到相机的距离。与对比度或梯度测量等局部差分方法相比,我们的方法对噪声的影响更稳定,而且与传统的图像处理方法相比,只需要很少的数据。该方法具有广泛的应用前景,尤其是在低光成像和近红外成像等噪声水平通常较高的领域。
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