T. Jaeschke, M. Vogt, C. Baer, C. Bredendiek, N. Pohl
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引用次数: 20
摘要
由于技术的进步,导致覆盖范围更高,很少使用,低成本半导体的频率区域,超宽带雷达系统在几种应用中变得越来越可行。在这篇贡献中,讨论了使用超高空间分辨率的雷达系统,结合高精度距离测量,特别是固体块状材料,以及近距离合成孔径雷达(SAR)成像的影响。此外,在这些应用中使用宽带(24.5GHz带宽)雷达传感器进行了测量,以证明高分辨率的优势。特别是在有许多目标或干扰散射体的距离测量应用中,宽频带是非常有利的。在这里,对于测量场景,通过将带宽从4GHz增加到24.5 GHz,精度提高了4到8倍。此外,还获得了近各向同性分辨率的近距离SAR图像,距离分辨率为1.3 cm,方位角分辨率为1.5 cm (Hanning窗宽度为- 6 dB)。使用24.5 GHz带宽,以及相应的更好的距离分辨率(现在与方位角分辨率处于同一维度),与使用4 GHz带宽拍摄的图像相比,大大提高了图像质量。
Improvements in distance measurement and SAR-imaging applications by using ultra-high resolution mm-wave FMCW radar systems
Due to advances in technology, resulting in coverage of even higher, and rarely used, frequency regions with low-cost semiconductors, ultra wideband radar systems are getting more feasible for several kinds of applications. In this contribution, the effects of using radar systems with an ultra high spatial resolution, in combination with high precision distance measurements, especially for solid bulk material, and short range synthetic aperture radar (SAR) imaging are discussed. Furthermore, measurements with a wideband (24.5GHz bandwidth) radar sensor in these applications have been done to demonstrate the advantages, of the high resolution. Especially distance measurement applications with many targets or disturbing scatterers benefit from the wide bandwidth. Here, for the measured scenario an accuracy enhancement of a factor 4 to 8 has been obtained by increasing the bandwidth from 4GHz to 24.5 GHz. Furthermore, short range SAR images with a nearly isotropic resolution of 1.3 cm in range, and 1.5 cm in azimuth direction (−6 dB width, Hanning window) are presented. The use of 24.5 GHz bandwidth, and the accordingly better range resolution, which is now in the same dimension as the azimuth resolution, drastically increases the image quality compared to images taken with 4 GHz bandwidth.