微波近场成像的进展:原型、系统与应用
Advances in Microwave Near-Field Imaging: Prototypes, Systems, and Applications.
作者信息
Shao Wenyi, McCollough Todd
机构信息
Johns Hopkins University, Baltimore, Maryland, United States.
Ellumen, Inc., Arlington, Virginia, United States.
出版信息
IEEE Microw Mag. 2020 May;21(5):94-119. doi: 10.1109/mmm.2020.2971375. Epub 2020 Mar 31.
Abstract
Microwave imaging employs detection techniques to evaluate hidden or embedded objects in a structure or media using electro-magnetic (EM) waves in the microwave range, 300 MHz-300 GHz. Microwave imaging is often associated with radar detection such as target location and tracking, weather-pattern recognition, and underground surveillance, which are far-field applications. In recent years, due to microwaves' ability to penetrate optically opaque media, short-range applications, including medical imaging, nondestructive testing (NDT) and quality evaluation, through-the-wall imaging, and security screening, have been developed. Microwave near-field imaging most often occurs when detecting the profile of an object within the short range (when the distance from the sensor to the object is less than one wavelength to several wave-lengths) and depends on the electrical size of the antenna(s) and target.
摘要
微波成像采用检测技术,利用300兆赫兹至300吉赫兹微波频段的电磁波来评估结构或介质中隐藏或嵌入的物体。微波成像通常与雷达探测相关,如目标定位与跟踪、天气模式识别以及地下监测等,这些都是远场应用。近年来,由于微波能够穿透光学不透明介质,已开发出包括医学成像、无损检测(NDT)与质量评估、穿墙成像以及安全筛查等在内的短程应用。微波近场成像大多出现在近距离检测物体轮廓时(当传感器到物体的距离小于一个波长至几个波长时),并且取决于天线和目标的电气尺寸。
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