连续室内导航与RFID和INS

G. Retscher, Q. Fu
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引用次数: 27

摘要

一些导航应用,如盲人用户的导航,需要在城市室外和室内环境相结合的情况下进行连续定位,并具有一定的定位精度。对于室外城市环境,通常采用GNSS和航位推算,并且已被证明是令人满意的。然而,在室内环境中,在1到2米的范围内确定绝对位置仍然是非常具有挑战性的。为了确定室内位置,已经开发了许多不同的定位方法。在我们的方法中,选择并研究了射频识别(RFID)。使用RFID最常见的是基于小区的定位。除此之外,我们还研究了基于周围环境中RFID标签的信号强度测量(即RSSI,即接收信号强度指示的缩写)的三边测量和位置指纹识别。然而,这两种定位方法的缺点是,在三边测量的情况下,需要在离线或训练阶段进行校准,以从RSSI测量值推断出标签的范围,或者在位置指纹的情况下,需要在整个建筑物的已知位置建立RSSI数据库。因此,我们开发了一种新的基于cell-based positioning的定位方法,该方法利用在线或定位阶段测量的RSSI,即所谓的基于时间的Cell-of-Origin (CoO)。与普通CoO相比,本文进行了两项修改,并将在本文中进行讨论。这种新方法随后在维也纳科技大学的一栋办公楼的室内环境中进行了测试。可以看出,将基于RFID时间的CoO与基于低成本mems的INS结合定位,可以实现1 ~ 2米级别的定位精度。在这个贡献中描述和讨论了在试验台进行的不同实验。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Continuous indoor navigation with RFID and INS
Some navigation applications, such as the navigation of blind users, require that a continuous positioning is performed in combined outdoor urban and indoor environments with a certain positioning accuracy. For outdoor urban environments usually GNSS and dead reckoning are employed and has proven to be satisfactory. In indoor environments, however, absolute position determination with an accuracy in the range of 1 to 2 meters is still very challenging. For indoor location determination, a number of different positioning methods have been developed. In our approach, Radio Frequency Identification (RFID) has been selected and investigated. Using RFID most commonly cell-based positioning is performed. Apart from that we have also investigated trilateration and location fingerprinting based on signal strength measurements (i.e., RSSI short for Received Signal Strength Indication) from the RFID tags in the surrounding environment. The disadvantage of these two positioning methods, however, is the required calibration in the off-line or training phase to deduce ranges to the tags from the RSSI measurements in the case of trilateration or the establishment of the RSSI database at known locations throughout the building in the case of location fingerprinting. Therefore we have developed a new location method based on cell-based positioning which makes use of the measured RSSI in the on-line or positioning phase, i.e., the so-called time-based Cell-of-Origin (CoO). Two modifications have been implemented in comparison to common CoO and will be discussed in the paper. The new approach was then be tested in an indoor environment in an office building of the Vienna University of Technology. It could be seen that for a combined positioning of RFID time-based CoO and a low-cost MEMS-based INS positioning accuracies on the 1 to 2 meter level can be achieved. The different experiments performed in the test bed are described and discussed in this contribution.
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