基于rssi的室内定位改进的自适应距离调整最小-最大方法

IF 3.6 3区计算机科学 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS

IEEE Access Pub Date : 2025-08-29 DOI:10.1109/ACCESS.2025.3603986

Apidet Booranawong;Naruesorn Prakobboon;Hiroshi Saito

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引用次数: 0

摘要

在基于接收信号强度指标（RSSI）的距离定位系统中，通过测量所有参考节点与未知目标之间的RSSI水平来确定位置估计。RSSI水平表示目标和引用之间的距离。由于RSSI信号是时变的，并且由于多径效应而波动，特别是在室内环境中，这种变化可能导致距离计算和定位不准确。不充分的评估结果可能导致整个系统的错误判断。本文提出了一种改进的最小-最大方法来减小RSSI-to-distance误差，提高定位精度。本研究的新颖之处在于提出了一种自主参考节点识别、区域分离、区域选择和自适应距离调整的解决方案，并将其与传统的最小-最大方法相结合。目标和参考点之间的距离自动测量和补偿。使用2.4 GHz ZigBee/IEEE 802.15.4无线网络的真实场景实验已在不同的室内环境中进行，包括办公室、电机实验室和二楼步行走廊。实验结果表明，本文方法的估计误差比传统的最小-最大估计误差小：办公楼的估计误差为0.460 m和0.715 m，机器实验室的估计误差为0.735 m和1.503 m，走廊的估计误差为0.661 m和1.340 m。该方法显著优于min-max方法，分别高出35.623%、51.063%和50.627%。在移动目标场景下，该方法还提供了更高的跟踪结果估计精度。最后，从数学运算的角度对所提方法的计算成本进行了分析。文中还报道了最坏情况和实验结果。

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A Modified Min-Max Method With Adaptive Distance Adjustment for RSSI-Based Indoor Localization

In range-based localization systems based on received signal strength indicator (RSSI), position estimates are determined by measuring RSSI levels between all reference nodes and an unknown target. The RSSI level indicates the distance between the target and references. Because the RSSI signal is time-varying and fluctuates due to multipath effects, particularly in indoor contexts, this variation can cause distance calculation and localization inaccuracies. Inadequate estimation findings can lead to poor judgments throughout the system. In this paper, we present a modified min-max method to reduce RSSI-to-distance error and to improve localization precision. The novelty of this study is that an autonomous reference node identification, area separation, area selection, and adaptive distance adjustment solution are proposed and integrated with the traditional min-max method. The distances between the target and references are automatically measured and compensated. Experiments in real-world scenarios using 2.4 GHz ZigBee/IEEE 802.15.4 wireless networks have been conducted in different indoor environments, including an office room, an electrical machine laboratory, and a second-floor walking corridor. Experimental results show that the proposed method has estimation errors lower than the traditional min-max method: 0.460 m (proposed) and 0.715 m (traditional) for the office room, 0.735 m and 1.503 m for the machine laboratory, and 0.661 m and 1.340 m for the corridor. The proposed method significantly outperforms the min-max method by 35.623%, 51.063%, and 50.627%, respectively. For in mobile target scenarios, the proposed method also provides a more estimated precision of tracking results. Finally, the computational cost analysis of the proposed method in terms of mathematical operations is discussed. The worst-case scenario and the results obtained from the experiments are also reported.

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来源期刊

IEEE Access COMPUTER SCIENCE, INFORMATION SYSTEMSENGIN-ENGINEERING, ELECTRICAL & ELECTRONIC

CiteScore

9.80

自引率

7.70%

发文量

6673

审稿时长

6 weeks

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