School of Information and Communication Engineering, Beijing University of Posts and Telecommunication, Beijing 100876, China.
Beijing Key Laboratory of Mobile Computing and Pervasive Device, Institute of Computing Technology Chinese Academy of Sciences, Beijing 100190, China.
Sensors (Basel). 2018 Oct 3;18(10):3317. doi: 10.3390/s18103317.
Accurate indoor positioning technology provides location-based service for a variety of applications. However, most existing indoor localization approaches (e.g., Wi-Fi and Bluetooth-based methods) rely heavily on positioning infrastructure, which prevents their large-scale deployment and limits the range at which they are applicable. Here, we proposed an infrastructure-free indoor positioning and tracking approach, termed LiMag, which used ubiquitous magnetic field and ambient lights (e.g., fluorescent, incandescent, and light-emitting diodes (LEDs)) without containing modulated information. We conducted an in-depth study on both the advantages and the challenges in leveraging magnetic field and ambient light intensity for indoor localization. Based on the insights from this study, we established a hybrid observation model that took full advantage of both the magnetic field and ambient light signals. To address the low discernibility of the hybrid observation model, LiMag first generated a single-step fingerprint model by vectorizing consecutive hybrid observations within each step. In order to accurately track users, a lightweight single-step tracking algorithm based on the single-step fingerprints and the particle filter framework was designed. LiMag leveraged the walking information of users and several single-step fingerprints to generate long trajectory fingerprints that exhibited much higher location differentiation ability than the single-step fingerprint. To accelerate particle convergence and eliminate the accumulative error of single-step tracking algorithm, a long trajectory calibration scheme based on long trajectory fingerprints was also introduced. An undirected weighted graph model was constructed to decrease the computational overhead resulting from this long trajectory matching. In addition to typical indoor scenarios including offices, shopping malls and parking lots, we also conducted experiments in more challenging scenarios, including large open-plan areas as well as environments characterized by strong sunlight. Our proposed algorithm achieved a 75th percentile localization accuracy of 1.8 m and 2.2 m, respectively, in the office and shopping mall tested. In conclusion, our LiMag algorithm provided location-based service of infrastructure-free with significantly improved localization accuracy and coverage, as well as satisfactory robustness inside complex indoor environments.
精准的室内定位技术为各种应用提供了基于位置的服务。然而,大多数现有的室内定位方法(如基于 Wi-Fi 和蓝牙的方法)严重依赖定位基础设施,这阻碍了它们的大规模部署,并限制了它们的适用范围。在这里,我们提出了一种无基础设施的室内定位和跟踪方法,称为 LiMag,它使用无处不在的磁场和环境光(如荧光灯、白炽灯和发光二极管(LED)),而不包含调制信息。我们深入研究了利用磁场和环境光强度进行室内定位的优势和挑战。基于这项研究的结果,我们建立了一个混合观测模型,充分利用了磁场和环境光信号。为了解决混合观测模型的低可分辨性问题,LiMag 首先通过在每个步骤内对连续的混合观测进行向量化,生成一步指纹模型。为了准确跟踪用户,设计了一种基于一步指纹和粒子滤波框架的轻量级一步跟踪算法。LiMag 利用用户的行走信息和几个一步指纹来生成长轨迹指纹,这些指纹比一步指纹具有更高的位置区分能力。为了加速粒子收敛并消除一步跟踪算法的累积误差,还引入了基于长轨迹指纹的长轨迹校准方案。构建了无向加权图模型来降低这种长轨迹匹配带来的计算开销。除了包括办公室、购物中心和停车场在内的典型室内场景外,我们还在更具挑战性的场景中进行了实验,包括大型开放式区域以及阳光强烈的环境。我们提出的算法在测试的办公室和购物中心场景中,分别实现了 75%分位数定位精度 1.8 米和 2.2 米。总之,我们的 LiMag 算法提供了无基础设施的基于位置的服务,具有显著提高的定位精度和覆盖范围,以及在复杂室内环境中令人满意的鲁棒性。
