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引用次数: 0
摘要
在这项工作中,我们通过对模拟和测量结果的评论,分析了伊利诺伊大学芝加哥分校开发的射频(RF)断层扫描系统的分辨率性能。射频层析成像(见L. Lo Monte等人,“隧道探测的射频层析成像”,IEEE译。地球科学与遥感,Vol. 48, No. 3, 2010年3月,pp. 1128-1137)有望成为一种非常有吸引力的成像技术,因为它是窄带的,它利用了分布式廉价的传感器,并提供了亚波长分辨率。一些关键的应用包括地下勘探、医学成像、搜索和救援、考古和穿墙成像,这要归功于一个非常灵活的正向模型。所有这些不同的应用程序都通过传感器测量的信息重建图像来共享目标搜索。通过这种系统所能达到的分辨率会影响对目标大小和位置的估计,因此是判断系统整体性能的主要标准之一。
Resolution analysis of a Radio Frequency Tomography system
In this work, we analyze the resolution performance of a Radio Frequency (RF) Tomography system developed at the University of Illinois at Chicago, by commenting on results obtained from both simulations and measurements. RF Tomography (see L. Lo Monte et al., “Radio Frequency Tomography for Tunnel Detection,” IEEE Trans. Geoscience and Remote Sensing, Vol. 48, No. 3, Mar. 2010, pp. 1128-1137) promises to be a very attractive imaging technology because it is narrowband, it makes use of distributed inexpensive sensors and offers sub-wavelength resolution. Some crucial applications include underground exploration, medical imaging, search and rescue, archeology, and thru-wall imaging, thanks to a very flexible forward model. All these different application share the search of a target by reconstructing images through information measured by the sensors. The resolution achievable through a system of this kind can affect the estimation of the size and the location of the target, and it is therefore one of the main criteria used to judge the overall performance of the system.
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