Tracking a phantom's lung tumour target using optical flow algorithm and electronic portal imaging devices

2012 IEEE International Conference on Imaging Systems and Techniques Proceedings Pub Date : 2012-07-16 DOI:10.1109/IST.2012.6295540

P. Teo, R. Crow, S. Van Nest, S. Pistorius

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引用次数: 3

Abstract

This paper investigates the feasibility and accuracy of tracking the motion of a lung tumour in a breathing phantom using a computer vision algorithm and electronic portal images. A multi-resolution optical flow algorithm that incorporates weighting based on the differences between frames is used to obtain a set of vectors corresponding to the motion between two frames. A global value representing the average motion is obtained by computing the average weighted mean from the set of vectors. The tracking accuracy of the optical flow algorithm is compared to potentiometer measurements. A self-resetting technique has been used to offset the drift observed in the cumulative position of the target. For a 12 breaths/min motion, a maximum average inter-frame velocity error of (1.06 ± 0.61) mm/s is obtained. A correlation coefficient of 0.97 bounded by a 95% prediction interval of (0.96, 0.98) is established between the optical flow and potentiometer results. Maximum absolute average positional error of 0.42 ± 0.21 mm is achieved. This approach offers the potential of real-time tumour motion tracking.

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利用光流算法和电子门静脉成像设备跟踪一个幻影的肺肿瘤目标

本文探讨了利用计算机视觉算法和电子传送门图像跟踪呼吸幻象中肺肿瘤运动的可行性和准确性。采用基于帧间差分的加权多分辨率光流算法，得到两帧间运动对应的一组向量。通过计算向量集的加权平均值，得到一个表示平均运动的全局值。将光流算法的跟踪精度与电位器测量结果进行了比较。一种自复位技术被用来抵消在目标的累积位置观察到的漂移。对于12次呼吸/min的运动，最大平均帧间速度误差为(1.06±0.61)mm/s。光流与电位计结果之间的相关系数为0.97,95%的预测区间为(0.96,0.98)。最大绝对平均位置误差为0.42±0.21 mm。这种方法提供了实时肿瘤运动跟踪的潜力。

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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2012 IEEE International Conference on Imaging Systems and Techniques Proceedings

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