基于传感器融合的步长估计

2020 IEEE International Conference on Flexible and Printable Sensors and Systems (FLEPS) Pub Date : 2020-08-16 DOI:10.1109/FLEPS49123.2020.9239441

Hasbi Sevinc, Ugur Ayvaz, Kadir Ozlem, Hend Elmoughni, A. Atalay, O. Atalay, G. Ince

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引用次数: 1

摘要

导航系统面临的主要挑战之一是无法在室内空间进行定向和定位精度不足。在某些情况下，导航系统需要在室内以高精度运行。其中一个例子是在室内安全地引导视障人士从一个地方到另一个地方。在本研究中，为了提高室内定位性能，提出了一种使用机器学习模型估计视障人士步长的新方法。因此，一旦知道了这个人的初始位置，就可以通过测量他们的步幅来预测他们的新位置。步长估计系统使用来自三个独立设备的数据进行训练;电容式弯曲传感器、智能手机和WeWALK——一种帮助视障人士的智能手杖。在使用的各种机器学习模型中，使用K最近邻模型获得的结果最好，得分为0.945 R^{2}$。这些结果支持了通过步长估计实现室内导航的可行性。

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Step Length Estimation Using Sensor Fusion

One of the main challenges of navigation systems is the inability of orientation and insufficient localization accuracy in indoor spaces. There are situations where navigation is required to function indoors with high accuracy. One such example is the task of safely guiding visually impaired people from one place to another indoors. In this study, to increase localization performance indoors, a novel method was proposed that estimates the step length of the visually impaired person using machine learning models. Thereby, once the initial position of the person is known, it is possible to predict their new position by measuring the length of their steps. The step length estimation system was trained using the data from three separate devices; capacitive bend sensors, a smart phone, and WeWALK, a smartcane developed to assist visually impaired people. Out of the various machine learning models used, the best result obtained using the K Nearest Neighbor model, with a score of $0.945 R^{2}$. These results support that indoor navigation will be possible through step length estimation.

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2020 IEEE International Conference on Flexible and Printable Sensors and Systems (FLEPS)

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