Related papers: Device-Free Human State Estimation using UWB Multi-Static Radios

Device-Free Human State Estimation using UWB Multi-Static Radios

URL: http://arxiv.org/abs/2401.05410v1
Date: Tue, 26 Dec 2023 05:51:22 GMT
Title: Device-Free Human State Estimation using UWB Multi-Static Radios
Authors: Saria Al Laham, Bobak H. Baghi, Pierre-Yves Lajoie, Amal Feriani, Sachini Herath, Steve Liu, Gregory Dudek
Abstract summary: We present a human state estimation framework that allows us to estimate the location, and even the activities, of people in an indoor environment without the requirement that they carry a specific device with them. To achieve this "device free" localization we use a small number of low-cost Ultra-Wide Band (UWB) sensors distributed across the environment of interest.
Score: 9.097545017048446
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: We present a human state estimation framework that allows us to estimate the location, and even the activities, of people in an indoor environment without the requirement that they carry a specific devices with them. To achieve this "device free" localization we use a small number of low-cost Ultra-Wide Band (UWB) sensors distributed across the environment of interest. To achieve high quality estimation from the UWB signals merely reflected of people in the environment, we exploit a deep network that can learn to make inferences. The hardware setup consists of commercial off-the-shelf (COTS) single antenna UWB modules for sensing, paired with Raspberry PI units for computational processing and data transfer. We make use of the channel impulse response (CIR) measurements from the UWB sensors to estimate the human state - comprised of location and activity - in a given area. Additionally, we can also estimate the number of humans that occupy this region of interest. In our approach, first, we pre-process the CIR data which involves meticulous aggregation of measurements and extraction of key statistics. Afterwards, we leverage a convolutional deep neural network to map the CIRs into precise location estimates with sub-30 cm accuracy. Similarly, we achieve accurate human activity recognition and occupancy counting results. We show that we can quickly fine-tune our model for new out-of-distribution users, a process that requires only a few minutes of data and a few epochs of training. Our results show that UWB is a promising solution for adaptable smart-home localization and activity recognition problems.

Related papers

Physical-Layer Semantic-Aware Network for Zero-Shot Wireless Sensing [74.12670841657038]
Device-free wireless sensing has recently attracted significant interest due to its potential to support a wide range of immersive human-machine interactive applications. Data heterogeneity in wireless signals and data privacy regulation of distributed sensing have been considered as the major challenges that hinder the wide applications of wireless sensing in large area networking systems. We propose a novel zero-shot wireless sensing solution that allows models constructed in one or a limited number of locations to be directly transferred to other locations without any labeled data.
arXiv Detail & Related papers (2023-12-08T13:50:30Z)
UnLoc: A Universal Localization Method for Autonomous Vehicles using LiDAR, Radar and/or Camera Input [51.150605800173366]
UnLoc is a novel unified neural modeling approach for localization with multi-sensor input in all weather conditions. Our method is extensively evaluated on Oxford Radar RobotCar, ApolloSouthBay and Perth-WA datasets.
arXiv Detail & Related papers (2023-07-03T04:10:55Z)
Deep Multi-Emitter Spectrum Occupancy Mapping that is Robust to the Number of Sensors, Noise and Threshold [32.880113150521154]
One of the primary goals in spectrum occupancy mapping is to create a system that is robust to assumptions about the number of sensors, occupancy threshold (in dBm), sensor noise, number of emitters and the propagation environment. We show that such a system may be designed with neural networks using a process of aggregation to allow a variable number of sensors during training and testing.
arXiv Detail & Related papers (2022-11-27T14:08:11Z)
iSDF: Real-Time Neural Signed Distance Fields for Robot Perception [64.80458128766254]
iSDF is a continuous learning system for real-time signed distance field reconstruction. It produces more accurate reconstructions and better approximations of collision costs and gradients.
arXiv Detail & Related papers (2022-04-05T15:48:39Z)
LocUNet: Fast Urban Positioning Using Radio Maps and Deep Learning [59.17191114000146]
LocUNet: A deep learning method for localization, based merely on Received Signal Strength (RSS) from Base Stations (BSs) In the proposed method, the user to be localized reports the RSS from BSs to a Central Processing Unit ( CPU) which may be located in the cloud. Using estimated pathloss radio maps of the BSs, LocUNet can localize users with state-of-the-art accuracy and enjoys high robustness to inaccuracies in the radio maps.
arXiv Detail & Related papers (2022-02-01T20:27:46Z)
Real-time Outdoor Localization Using Radio Maps: A Deep Learning Approach [59.17191114000146]
LocUNet: A convolutional, end-to-end trained neural network (NN) for the localization task. We show that LocUNet can localize users with state-of-the-art accuracy and enjoys high robustness to inaccuracies in the estimations of radio maps.
arXiv Detail & Related papers (2021-06-23T17:27:04Z)
Wireless Localisation in WiFi using Novel Deep Architectures [4.541069830146568]
This paper studies the indoor localisation of WiFi devices based on a commodity chipset and standard channel sounding. We present a novel shallow neural network (SNN) in which features are extracted from the channel state information corresponding to WiFi subcarriers received on different antennas.
arXiv Detail & Related papers (2020-10-16T22:48:29Z)
Denoising IMU Gyroscopes with Deep Learning for Open-Loop Attitude Estimation [0.0]
This paper proposes a learning method for denoising gyroscopes of Inertial Measurement Units (IMUs) using ground truth data. The obtained algorithm outperforms the state-of-the-art on the (unseen) test sequences.
arXiv Detail & Related papers (2020-02-25T08:04:31Z)
Deep Learning based Pedestrian Inertial Navigation: Methods, Dataset and On-Device Inference [49.88536971774444]
Inertial measurements units (IMUs) are small, cheap, energy efficient, and widely employed in smart devices and mobile robots. Exploiting inertial data for accurate and reliable pedestrian navigation supports is a key component for emerging Internet-of-Things applications and services. We present and release the Oxford Inertial Odometry dataset (OxIOD), a first-of-its-kind public dataset for deep learning based inertial navigation research.
arXiv Detail & Related papers (2020-01-13T04:41:54Z)

This list is automatically generated from the titles and abstracts of the papers in this site.

This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.