2010 IEEE/IFIP International Conference on Embedded and Ubiquitous Computing
LocaToR: Locating Passive RFID Tags with the Relative Neighborhood Graph
Yiyang Zhao, S. C. Cheung and Lionel M. Ni Department of Computer Science and Engineering The Hong Kong University of Science and Technology Hong Kong, China {zhaoyy, scc, ni}@cse.ust.hk modification. Those features have enabled RFID technology to become a popular choice for object tracking. One typical application is locating merchandise in a large warehouse. Generally, we put things on a particular shelf. If we want to find something, we need to know its location. Otherwise, we need to make a big effort to find it. Another application scenario is in a supermarket. When a customer checks out, the salesperson may want to check some dubious goods, the commodity location then becomes very important information. In a large scale warehouse or during a stock take of goods, if we want find a specific object, an intuitive way is to scan all tags and guess the position of the target. However, the cost of this method is too high. Existing approaches for locating a specific object suffer the following drawbacks: cost, latency and inaccuracy. For example, there are two types of reader deployments used to detect a tag. One is to deploy many fixed readers or antennas, which cover particular regions. The deployment fee of this method is very costly. Another way is to use a handheld reader to do location sensing. Recently, some handheld RFID readers are available on the market. Since those types of readers are portable and easy to use, it is suitable for location sensing in a large warehouse. In general, the reading range of a handheld reader is around a few meters with an additional modular [6]. In the near future, the ability of readers will have improved due to new antenna designs and backing materials. Therefore, the mobile localization scheme based on passive systems may become a widely used approach. Our work is driven by observations during experiments. To estimate the localization performance of a passive RFID system, we conduct several preliminary studies. By analyzing experimental results, we have made a few interesting observations as follows. x The readability of passive tags is sensitive to the transmission power of the reader. For a given distance, the reading state of a tag under different power levels of a reader is different. For example, a tag can either be read or not within a 1 dBm range. x Incomplete reading of tags refers hidden information. From the physical layer viewpoint, even if a tag is not recognized by a reader, some information still can still be sent to the reader. x The antenna of the reader is directional, which is different to RFID systems. . Although it means that the traditional disc model does not work for directional
Abstract—Passive tags are widely used in many applications, for example, the supply chain, the food industry and warehouse management. In such applications, the location information of tags is very important. However, the uncertain properties of Received Signal Strength Indicators (RSSI), various backscattering events on different power levels and the directivity of readers prevent traditional ranging-based approaches working well in passive RFID systems. In accordance with our observations during experiments, we create a novel approach to locate a specific tag among objects. Although absolute positions are difficult to obtain, we can estimate locations by building a relative relationship between tags. To reduce the effect of the above limitations, we propose a range-free approach named LocaToR to establish a relative neighborhood graph. We implement our method on a real passive system. Taking environmental factors into consideration, we look at two situations: a controlled chamber and a semi-open space. Experimental results show that our approach can obviously improve the accuracy of the localization system as well as save readers’ energy. Keywords- Range-free localization; Passive RFID system; Relative location
I.
INTRODUCTION
Radio Frequency Identification (RFID) is a type of automatic identification system. It is widely used in various applications, such as supply chain management, inventory tracking, transportation payments, mobile payment, people and animal tracking, access control, warehouse management, health care, food safety guaranties and so on [1]. Since an RFID system not only provides identification information, but also generates extra information to help in location sensing, such as RSSI [2], RF phase status [3], reading range [4] and identification rate [5], the information can be directly applied in Real Time Locating Systems (RTLS), which supports the tracking and locating of objects. In a general case, some inexpensive nodes, such as badges or tags, are attached to or embedded in objects. At the same time, readers receive wireless signals from those tags and calculate their locations. RFID technology has a number of advantages for location sensing. First of all, RFID enables the identification of objects from a distance out of the line of sight. Secondly, RFID storage is larger than that of its counterpart, the bar code, and can incorporate additional information. This capability allows RFID to adapt the requests of many applications. Thirdly, because tags can be rewritten in a short period, they can satisfy some applications which require frequent data 978-0-7695-4322-2/10 $26.00 © 2010 IEEE DOI 10.1109/EUC.2010.31
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