Your search keyword '"bio-radar"' showing total 42 results

1. Radar Translator: Contactless Eyeblink Detection Assisting Basic Daily Intension Voice for the Paralyzed Aphasia Patient Using Bio-Radar

Author

Qi, Fugui, Li, Jiani, Yu, Haoyang, Han, Haoxin, Huang, Wei, Lu, Guohua, Wang, Jianqi, Magjarević, Ratko, Series Editor, Ładyżyński, Piotr, Associate Editor, Ibrahim, Fatimah, Associate Editor, Lackovic, Igor, Associate Editor, Rock, Emilio Sacristan, Associate Editor, Wang, Guangzhi, editor, Yao, Dezhong, editor, Gu, Zhongze, editor, Peng, Yi, editor, Tong, Shanbao, editor, and Liu, Chengyu, editor

Published

2024

2. Remote Emotion Recognition Using Continuous-Wave Bio-Radar System.

Author

Gouveia, Carolina, Soares, Beatriz, Albuquerque, Daniel, Barros, Filipa, Soares, Sandra C., Pinho, Pedro, Vieira, José, and Brás, Susana

Subjects

*EMOTION recognition, *MACHINE learning, *PATTERN recognition systems, *MEASURING instruments, *VITAL signs, *EMOTICONS & emojis, *CONTINUOUS wave radar

Abstract

The Bio-Radar is herein presented as a non-contact radar system able to capture vital signs remotely without requiring any physical contact with the subject. In this work, the ability to use the proposed system for emotion recognition is verified by comparing its performance on identifying fear, happiness and a neutral condition, with certified measuring equipment. For this purpose, machine learning algorithms were applied to the respiratory and cardiac signals captured simultaneously by the radar and the referenced contact-based system. Following a multiclass identification strategy, one could conclude that both systems present a comparable performance, where the radar might even outperform under specific conditions. Emotion recognition is possible using a radar system, with an accuracy equal to 99.7% and an F1-score of 99.9%. Thus, we demonstrated that it is perfectly possible to use the Bio-Radar system for this purpose, which is able to be operated remotely, avoiding the subject awareness of being monitored and thus providing more authentic reactions. [ABSTRACT FROM AUTHOR]

Published

2024

3. Radar-Based Invisible Biometric Authentication.

Author

Louro da Silva, Maria, Gouveia, Carolina, Albuquerque, Daniel Filipe, and Plácido da Silva, Hugo

Subjects

*BIOMETRIC identification, *EMOTIONAL conditioning, *ERROR rates

Abstract

Bio-Radar (BR) systems have shown great promise for biometric applications. Conventional methods can be forged, or fooled. Even alternative methods intrinsic to the user, such as the Electrocardiogram (ECG), present drawbacks as they require contact with the sensor. Therefore, research has turned towards alternative methods, such as the BR. In this work, a BR dataset with 20 subjects exposed to different emotion-eliciting stimuli (happiness, fearfulness, and neutrality) in different dates was explored. The spectral distributions of the BR signal were studied as the biometric template. Furthermore, this study included the analysis of respiratory and cardiac signals separately, as well as their fusion. The main test devised was authentication, where a system seeks to validate an individual's claimed identity. With this test, it was possible to infer the feasibility of these type of systems, obtaining an Equal Error Rate (EER) of 3.48 % if the training and testing data are from the same day and within the same emotional stimuli. In addition, the time and emotion results dependency is fully analysed. Complementary tests such as sensitivity to the number of users were also performed. Overall, it was possible to achieve an evaluation and consideration of the potential of BR systems for biometrics. [ABSTRACT FROM AUTHOR]

Published

2024

4. 人体睡眠监测设备的研究现状.

Author

薛慧君, 张科强, 章启航, 郭天娇, 刘澜涛, and 吕 昊

Abstract

Copyright of Chinese Medical Equipment Journal is the property of Chinese Medical Equipment Journal Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

5. A Novel Non-Contact Detection and Identification Method for the Post-Disaster Compression State of Injured Individuals Using UWB Bio-Radar.

Author

Shi, Ding, Liang, Fulai, Qiao, Jiahao, Wang, Yaru, Zhu, Yidan, Lv, Hao, Yu, Xiao, Jiao, Teng, Liao, Fuyuan, Yan, Keding, Wang, Jianqi, and Zhang, Yang

Subjects

*ULTRA-wideband radar, *FALSE alarms, *BUILDING failures, *ADULT respiratory distress syndrome, *DISSEMINATED intravascular coagulation, *CONVOLUTIONAL neural networks, *MULTIPLE organ failure

Abstract

Building collapse leads to mechanical injury, which is the main cause of injury and death, with crush syndrome as its most common complication. During the post-disaster search and rescue phase, if rescue personnel hastily remove heavy objects covering the bodies of injured individuals and fail to provide targeted medical care, ischemia-reperfusion injury may be triggered, leading to rhabdomyolysis. This may result in disseminated intravascular coagulation or acute respiratory distress syndrome, further leading to multiple organ failure, which ultimately leads to shock and death. Using bio-radar to detect vital signs and identify compression states can effectively reduce casualties during the search for missing persons behind obstacles. A time-domain ultra-wideband (UWB) bio-radar was applied for the non-contact detection of human vital sign signals behind obstacles. An echo denoising algorithm based on PSO-VMD and permutation entropy was proposed to suppress environmental noise, along with a wounded compression state recognition network based on radar-life signals. Based on training and testing using over 3000 data sets from 10 subjects in different compression states, the proposed multiscale convolutional network achieved a 92.63% identification accuracy. This outperformed SVM and 1D-CNN models by 5.30% and 6.12%, respectively, improving the casualty rescue success and post-disaster precision. [ABSTRACT FROM AUTHOR]

Published

2023

6. Remote Emotion Recognition Using Continuous-Wave Bio-Radar System

Author

Carolina Gouveia, Beatriz Soares, Daniel Albuquerque, Filipa Barros, Sandra C. Soares, Pedro Pinho, José Vieira, and Susana Brás

Subjects

micro-Doppler radar, continuous wave, vital signs, bio-radar, emotional recognition, machine learning, Chemical technology, TP1-1185

Abstract

The Bio-Radar is herein presented as a non-contact radar system able to capture vital signs remotely without requiring any physical contact with the subject. In this work, the ability to use the proposed system for emotion recognition is verified by comparing its performance on identifying fear, happiness and a neutral condition, with certified measuring equipment. For this purpose, machine learning algorithms were applied to the respiratory and cardiac signals captured simultaneously by the radar and the referenced contact-based system. Following a multiclass identification strategy, one could conclude that both systems present a comparable performance, where the radar might even outperform under specific conditions. Emotion recognition is possible using a radar system, with an accuracy equal to 99.7% and an F1-score of 99.9%. Thus, we demonstrated that it is perfectly possible to use the Bio-Radar system for this purpose, which is able to be operated remotely, avoiding the subject awareness of being monitored and thus providing more authentic reactions.

Published

2024

7. Radar-Based Invisible Biometric Authentication

Author

Maria Louro da Silva, Carolina Gouveia, Daniel Filipe Albuquerque, and Hugo Plácido da Silva

Subjects

bio-radar, biometrics, electrocardiogram, support vector machines, Information technology, T58.5-58.64

Abstract

Bio-Radar (BR) systems have shown great promise for biometric applications. Conventional methods can be forged, or fooled. Even alternative methods intrinsic to the user, such as the Electrocardiogram (ECG), present drawbacks as they require contact with the sensor. Therefore, research has turned towards alternative methods, such as the BR. In this work, a BR dataset with 20 subjects exposed to different emotion-eliciting stimuli (happiness, fearfulness, and neutrality) in different dates was explored. The spectral distributions of the BR signal were studied as the biometric template. Furthermore, this study included the analysis of respiratory and cardiac signals separately, as well as their fusion. The main test devised was authentication, where a system seeks to validate an individual’s claimed identity. With this test, it was possible to infer the feasibility of these type of systems, obtaining an Equal Error Rate (EER) of 3.48% if the training and testing data are from the same day and within the same emotional stimuli. In addition, the time and emotion results dependency is fully analysed. Complementary tests such as sensitivity to the number of users were also performed. Overall, it was possible to achieve an evaluation and consideration of the potential of BR systems for biometrics.

Published

2024

8. ESTIMATING THE SPECTRAL DENSITY OF FLICKER NOISE OF LOW-NOISE OSCILLATORS AT INFRA-LOW FREQUENCIES

Author

V. M. Konovalov and K. O. Lukin

Subjects

flicker noise, 1/f noise, color noise, low-noise oscillators, bioactivity, bio-radar, Astronomy, QB1-991

Abstract

Subject and Purpose. Designers of the research radars intended for detecting manifestations of biological activity of living organisms may be interested in the noise characteristics shown by their oscillators at offsets about 10–2 Hz or even 10–3Hz from the carrier frequency. Unfortunately, the producing companies do not practice regular information on noise performance of their products at frequencies below 1 Hz. The present authors have set the goal of deriving an analytical expression for the spectral density of flicker noise which should allow radar engineers estimating the probable noise performance of low-noise oscillators over any frequency range. Methods and Methodology. A great number of writers considering spectral properties of flicker noise tend to support the assertion that its spectral density increases continuously with a decrease in frequency, following the power law 1/f. Meanwhile, the present authors assume availability of a certain frequencyfmbelow which the spectral density should most likely remain unchanged, even to as low as zero frequency. Also, there is a range of frequencies above which the spectral density of flicker noise remains constant and the total spectral density is determined solely by thermal noise. Results.The spectral density of noise follows the power law 1/f throughout the range fromfm and up to the point where thermal noise starts to overbalance the flicker noise. The authors have proposed an approximating function to describe the behavior of the averaged spectral density of noise from the oscillator within the entire frequency range. Conclusions. The results obtained shall allow radio system designers to make estimates of the probable noise performance of low-noise oscillators in any frequency range, using only known reference data provided by the manufacturer.

Published

2022

9. 生物雷达回波信号中的心跳信号分离和特征提取方法 研究综述.

Author

乔嘉豪, 石 丁, 周国军, 闫克丁, 廖福元, 吕 昊, 焦 腾, 王健琪, and 张 杨

Abstract

Copyright of Chinese Medical Equipment Journal is the property of Chinese Medical Equipment Journal Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

10. A comprehensive study about low-cost and limited bandwidth FMCW bio-radar: detailed analyses on vital signs measurements.

Author

Seflek, Ibrahim and Yaldiz, Ercan

Subjects

VITAL signs, CONTINUOUS wave radar, FREQUENCIES of oscillating systems, BANDWIDTHS, ERROR rates

Abstract

In this study, a bio-radar system has been constituted using a frequency modulated continuous wave (FMCW) radar with low cost and limited bandwidth, taking into account of the lack of range the continuous wave (CW) radar. The displacement and vibration frequencies have been determined at a distance of 3.5–5 m for single and multiple targets via the help of the target test mechanism. Then, the detection of vital signs has been achieved with healthy human subject measurements. For a single human subject, respiration rate (RR) errors at 3.5 m and 5 m distances are 4% and 4.42%, respectively, and 13.25% and 15.16% for heartbeat rate (HR). In multiple targets measurements, although targets do not create an obstacle to each other, a slight deterioration has been observed in the signals and the error rates increase. The results show that bio-radar have a promising future to replace contact devices in medical applications. [ABSTRACT FROM AUTHOR]

Published

2022

11. A Novel Non-Contact Detection and Identification Method for the Post-Disaster Compression State of Injured Individuals Using UWB Bio-Radar

Author

Ding Shi, Fulai Liang, Jiahao Qiao, Yaru Wang, Yidan Zhu, Hao Lv, Xiao Yu, Teng Jiao, Fuyuan Liao, Keding Yan, Jianqi Wang, and Yang Zhang

Subjects

bio-radar, crushing injury, ultra-wideband, variational modal decomposition, convolutional neural network, Technology, Biology (General), QH301-705.5

Abstract

Building collapse leads to mechanical injury, which is the main cause of injury and death, with crush syndrome as its most common complication. During the post-disaster search and rescue phase, if rescue personnel hastily remove heavy objects covering the bodies of injured individuals and fail to provide targeted medical care, ischemia-reperfusion injury may be triggered, leading to rhabdomyolysis. This may result in disseminated intravascular coagulation or acute respiratory distress syndrome, further leading to multiple organ failure, which ultimately leads to shock and death. Using bio-radar to detect vital signs and identify compression states can effectively reduce casualties during the search for missing persons behind obstacles. A time-domain ultra-wideband (UWB) bio-radar was applied for the non-contact detection of human vital sign signals behind obstacles. An echo denoising algorithm based on PSO-VMD and permutation entropy was proposed to suppress environmental noise, along with a wounded compression state recognition network based on radar-life signals. Based on training and testing using over 3000 data sets from 10 subjects in different compression states, the proposed multiscale convolutional network achieved a 92.63% identification accuracy. This outperformed SVM and 1D-CNN models by 5.30% and 6.12%, respectively, improving the casualty rescue success and post-disaster precision.

Published

2023

12. Evaluation of a non-contact ultra-wideband bio-radar sleep monitoring device for screening of sleep breathing disease.

Author

Wei, Zhijing, Xu, Jiahuan, Li, WenYang, Wang, Xingjian, Qin, Zheng, Zhou, Jiawei, and Wang, Wei

Abstract

Purpose: Ultra-wideband bio-radar (UWB) is a new non-contact technology that can be used to screen for obstructive sleep apnea (OSA). However, little information is available regarding its reliability. This study aimed to evaluate the effectiveness of UWB and to determine if UWB could provide a novel and reliable method for the primary screening of sleep-related breathing disorders. Method: Subjects with suspected OSA from the sleep center of the First Hospital of the China Medical University were assessed over the period of September 2018 to April 2019 for enrollment in the study. Three detection methods were simultaneously used, including the STOP-Bang questionnaire (SBQ), UWB, and standard polysomnography (PSG). The data were analyzed using a fourfold table, receiver operating characteristic curves, Spearman rank correlation coefficients, Bland–Altman plots, and epoch-by-epoch analysis. Result: Of 67 patients, 56 were men, mean age was 43 ± 11 years, mean body mass index was 27.8 ± 4.8 kg/m2, and mean SBQ score was 4.8 ± 1.6. The apnea–hypopnea index (AHI) (r = 0.82, p < 0.01) and minimum arterial oxygen saturation (r = 0.80, p < 0.01) of the UWB were positively correlated with those obtained from the PSG. UWB performed better than SBQ, as indicated by the larger area under the curve (0.85 vs. 0.632). The sensitivity and specificity of the UWB-AHI were good (100%, 70%, respectively). Conclusions: UWB performs well in the screening of OSA and can provide reliable outcomes for the screening of OSA at the primary level. [ABSTRACT FROM AUTHOR]

Published

2022

13. 基于生物雷达的灾后受挤压伤员生命状态识别方法研究.

Author

石 丁, 乔嘉豪, 李瑞瑶, 焦 腾, 安 强, 廖福元, 闫克丁, and 张 杨

Abstract

Copyright of Chinese Medical Equipment Journal is the property of Chinese Medical Equipment Journal Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

14. Evaluation of Heartbeat Signal Extraction Methods Using a 5.8 GHz Doppler Radar System in a Real Application Scenario.

Author

Gouveia, C., Albuquerque, D., Pinho, P., and Vieira, J.

Abstract

Doppler-based radar systems have been seen as a promising tool to assess vital signs, since they are capable to monitor the respiratory and cardiac signal remotely, by measuring the chest-wall displacement. However, due to the spectral overlap of these signals, their proper separation is a challenging task. In this paper, we demonstrate the effectiveness of using Discrete Wavelet Transform in the cardiac signal extraction, by comparing this method with other approaches widely used in literature, namely a standalone Band-Pass Filtering, the Ensembled Empirical Mode Decomposition, the Continuous Wavelet Transform and the Wavelet Packet Decomposition. The comparison metrics were defined taking into consideration the heart rate computation accuracy, and also the peak detection consistency to further evaluate the Heart Rate Variability. The efficiency of those methods is also tested considering real application scenarios, characterized by non-controlled monitoring environment conditions and the ability to equally assess the vital signs of different subjects, regardless their physical stature. [ABSTRACT FROM AUTHOR]

Published

2022

15. Automatic Air-to-Ground Recognition of Outdoor Injured Human Targets Based on UAV Bimodal Information: The Explore Study.

Author

Qi, Fugui, Zhu, Mingming, Li, Zhao, Lei, Tao, Xia, Juanjuan, Zhang, Linyuan, Yan, Yili, Wang, Jianqi, and Lu, Guohua

Subjects

TRACKING radar, RESCUE work, HUMAN ecology, PUBLIC safety, HUMAN beings, EMERGENCY medicine

Abstract

The rapid air-to-ground search of injured people in the outdoor environment has been a hot spot and a great challenge for public safety and emergency rescue medicine. Its crucial difficulties lie in the fact that small-scale human targets possess a low target-background contrast to the complex outdoor environment background and the human attribute of the target is hard to verify. Therefore, an automatic recognition method based on UAV bimodal information is proposed in this paper. First, suspected targets were accurately detected and separated from the background based on multispectral feature information only. Immediately after, the bio-radar module would be released and would try to detect their corresponding physiological information for accurate re-identification of the human target property. Both the suspected human target detection experiments and human target property re-identification experiments show that our proposed method could effectively realize accurate identification of ground injured in outdoor environments, which is meaningful for the research of rapid search and rescue of injured people in the outdoor environment. [ABSTRACT FROM AUTHOR]

Published

2022

16. 心电图 R 波法与生物雷达法测量脉搏波传导 时间的对比研究.

Author

拜 军, 梁 忠, 张保华, and 黄海涛

Abstract

Copyright of Chinese Medical Equipment Journal is the property of Chinese Medical Equipment Journal Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2021

17. 一种基于生物雷达的隐匿性伤情检测方法研究.

Author

薛慧君, 王鹏飞, 焦 腾, 安 强, 梁福来, 张 杨, 王健琪, and 吕 昊

Abstract

Copyright of Chinese Medical Equipment Journal is the property of Chinese Medical Equipment Journal Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2021

18. Mission Chain Driven Unmanned Aerial Vehicle Swarms Cooperation for the Search and Rescue of Outdoor Injured Human Targets

Author

Yusen Cao, Fugui Qi, Yu Jing, Mingming Zhu, Tao Lei, Zhao Li, Juanjuan Xia, Jianqi Wang, and Guohua Lu

Subjects

cooperative strategy, UAV swarms, deep learning, self-organizing network, bio-radar, Motor vehicles. Aeronautics. Astronautics, TL1-4050

Abstract

A novel cooperative strategy for distributed unmanned aerial vehicle (UAV) swarms with different functions, namely the mission chain-driven unmanned aerial vehicle swarms cooperation method, is proposed to allow the fast search and timely rescue of injured human targets in a wide-area outdoor environment. First, a UAV-camera unit is exploited to detect the suspected human target combined with improved deep learning technology. Then, the target location information is transferred to a self-organizing network. Then, the special bio-radar-UAV unit was released to recheck the survivals through a respiratory characteristic detection algorithm. Finally, driven by the location and vital sign status of the injured, a nearby emergency-UAV unit will perform corresponding medical emergency missions, such as dropping emergency supplies. Experimental results show that this strategy can identify the human targets autonomously from the outdoor environment effectively, and the target detection, target sensing, and medical emergency mission chain is completed successfully relying on the cooperative working mode, which is meaningful for the future search-rescue mission of outdoor injured human targets.

Published

2022

19. [Microwave Heartprint: A novel non-contact human identification technology based on cardiac micro-motion detection using ultra wideband bio-radar].

Author

Huang W, Ren W, Wang K, Li Z, Wang J, Lu G, and Qi F

Subjects

Humans, Algorithms, Heart Rate, Signal Processing, Computer-Assisted, Motion, Biometric Identification methods, Respiration, Heart physiology, Principal Component Analysis

Abstract

The existing one-time identity authentication technology cannot continuously guarantee the legitimacy of user identity during the whole human-computer interaction session, and often requires active cooperation of users, which seriously limits the availability. This study proposes a new non-contact identity recognition technology based on cardiac micro-motion detection using ultra wideband (UWB) bio-radar. After the multi-point micro-motion echoes in the range dimension of the human heart surface area were continuously detected by ultra wideband bio-radar, the two-dimensional principal component analysis (2D-PCA) was exploited to extract the compressed features of the two-dimensional image matrix, namely the distance channel-heart beat sampling point (DC-HBP) matrix, in each accurate segmented heart beat cycle for identity recognition. In the practical measurement experiment, based on the proposed multi-range-bin & 2D-PCA feature scheme along with two conventional reference feature schemes, three typical classifiers were selected as representatives to conduct the heart beat identification under two states of normal breathing and breath holding. The results showed that the multi-range-bin & 2D-PCA feature scheme proposed in this paper showed the best recognition effect. Compared with the optimal range-bin & overall heart beat feature scheme, our proposed scheme held an overall average recognition accuracy of 6.16% higher (normal respiration: 6.84%; breath holding: 5.48%). Compared with the multi-distance unit & whole heart beat feature scheme, the overall average accuracy increase was 27.42% (normal respiration: 28.63%; breath holding: 26.21%) for our proposed scheme. This study is expected to provide a new method of undisturbed, all-weather, non-contact and continuous identification for authentication.

Published

2024

20. Automatic Air-to-Ground Recognition of Outdoor Injured Human Targets Based on UAV Bimodal Information: The Explore Study

Author

Fugui Qi, Mingming Zhu, Zhao Li, Tao Lei, Juanjuan Xia, Linyuan Zhang, Yili Yan, Jianqi Wang, and Guohua Lu

Subjects

air-to-ground search, human target, multispectral imagery, bio-radar, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

The rapid air-to-ground search of injured people in the outdoor environment has been a hot spot and a great challenge for public safety and emergency rescue medicine. Its crucial difficulties lie in the fact that small-scale human targets possess a low target-background contrast to the complex outdoor environment background and the human attribute of the target is hard to verify. Therefore, an automatic recognition method based on UAV bimodal information is proposed in this paper. First, suspected targets were accurately detected and separated from the background based on multispectral feature information only. Immediately after, the bio-radar module would be released and would try to detect their corresponding physiological information for accurate re-identification of the human target property. Both the suspected human target detection experiments and human target property re-identification experiments show that our proposed method could effectively realize accurate identification of ground injured in outdoor environments, which is meaningful for the research of rapid search and rescue of injured people in the outdoor environment.

Published

2022

21. A Multi-Channel Ultrasound System for Non-Contact Heart Rate Monitoring.

Author

Ambrosanio, Michele, Franceschini, Stefano, Grassini, Giuseppe, and Baselice, Fabio

Abstract

The monitoring of vital signs represents an important measure in several fields which also go beyond the clinical environment. Nowadays, different technologies are employed to fulfil this aim, and among them, remote monitoring devices are becoming more and more popular. Following this trend, here we present an in-house, experimental ultrasound system for heartbeat detection which does not require any contact with the subject and allows remote monitoring of heart rate and its variability. The system works by transmitting ultrasound waves and receiving the echoes after the reflection on subject’s pit of the neck. By comparing the phases of transmitted and received waves, it measures distances with high accuracy, and thus it can detect the sub-millimetre movements of the skin due to the pressure waves produced by heart contractions. Conversely from other existing ultrasound systems, the novelty proposed in this paper is in the multi-channel strategy to address the null point issue and selecting the best one per each measure, and in the use of an adaptive heartbeat detection algorithm. Due to the adopted transducers and electronics, the proposed system is characterised by a low cost of production. Performance analyses were carried out both in case of phantoms and volunteers to test the system. The results look promising as it was able to detect the heartbeats with reliability close to standard electrocardiography, achieving good performance also in measuring the heart rate variability. An average mean absolute error (MAE) of 0.02 beats per minute (bpm) is assessed on real data. [ABSTRACT FROM AUTHOR]

Published

2020

22. Dynamic Digital Signal Processing Algorithm for Vital Signs Extraction in Continuous-Wave Radars

Author

Carolina Gouveia, Daniel Albuquerque, José Vieira, and Pedro Pinho

Subjects

arc fitting, bio-radar, continuous-wave, DC offsets, digital signal processing algorithm, vital signs, Science

Abstract

Radar systems have been widely explored as a monitoring tool able to assess the subject’s vital signs remotely. However, their implementation in real application scenarios is not straightforward. Received signals encompass parasitic reflections that occur in the monitoring environment. Generally, those parasitic components, often treated as a complex DC (CDC) offsets, must be removed in order to correctly extract the bio-signals information. Fitting methods can be used, but their implementation were revealed to be challenging when bio-signals are weak or when these parasitic reflections arise from non-static targets, changing the CDC offset properties over time. In this work, we propose a dynamic digital signal processing algorithm to extract the vital signs from radar systems. This algorithm includes a novel arc fitting method to estimate the CDC offsets on the received signal. The method revealed being robust to weaker signals, presenting a success rate of 95%, irrespective of the considered monitoring conditions. Furthermore, the proposed algorithm is able to adapt to slow changes in the propagation environment.

Published

2021

23. DeepActivity: a micro-Doppler spectrogram-based net for human behaviour recognition in bio-radar

Author

Hao Du, Tian Jin, Yongping Song, and Yongpeng Dai

Subjects

feature extraction, image classification, Doppler radar, recurrent neural nets, radar imaging, convolutional neural nets, image coding, image motion analysis, human behaviour recognition, bio-radar, human body, limbs, microDoppler signatures, conventional deep learning approaches, temporally localising activity sequence, human activity classification, activity sequence recognition, DeepActivity, microDoppler spectrogram-based net, convolutional gated recurrent units neural Network, local feature extraction, convolutional layer, CNN-GRU model, Engineering (General). Civil engineering (General), TA1-2040

Abstract

The movements of the human body and limbs result in unique micro-Doppler signatures, which can be exploited for classifying human activities. In this work, the authors propose a Convolutional Gated Recurrent Units Neural Network (CNN-GRU) to classify human activities of varying duration based on micro-Doppler spectrogram. Unlike conventional deep learning approaches which often treat the micro-Doppler spectrogram the same way as natural image, the authors extract local feature of micro-Doppler signatures via convolutional layer and encode temporal information with gated recurrent units. Through this unified framework, the temporal evolution of body motions within a short time can be better utilised. It avoids the resolution limitation caused by the fixed-size time window of input data and identifies human activity of duration shorter than the time window length. The experiment shows that CNN-GRU model is capable of recognising and temporally localising activity sequence contained in the spectrogram.

Published

2019

24. 24 GHz Flexible Antenna for Doppler Radar-Based Human Vital Signs Monitoring

Author

Nitin Kathuria and Boon-Chong Seet

Subjects

flexible antenna, Doppler radar, human vital signs, noncontact monitoring, bio-radar, liquid crystal polymer, Chemical technology, TP1-1185

Abstract

Noncontact monitoring of human vital signs has been an emerging research topic in recent years. A key approach to this monitoring is the use of the Doppler radar concept which enables real-time vital signs detection, resulting in a new class of radar system known as bio-radar. The antennas are a key component of any bio-radar module and their designs should meet the common requirements of bio-radar applications such as high radiation directivity and mechanical flexibility. This paper presents the design of a four-element antenna array on a flexible liquid crystal polymer (LCP) substrate of 100 μm thickness and εr of 3.35. The designed antenna array can be used with a 24 GHz bio-radar for vital signs monitoring in a non-contact manner. It features a relatively compact size of 36.5 × 53 mm2 and measured gain of 5.81 dBi. The two vital signs: breathing rate (BR) and heart rate (HR) of two human subjects are detected with relatively good accuracy using the fabricated antenna array and radio frequency (RF) output power of −3 dBm from a distance of approximately 60 cm. The effect of bending on the antenna performance is also analyzed.

Published

2021

25. DeepActivity: a micro-Doppler spectrogram-based net for human behaviour recognition in bio-radar.

Author

Du, Hao, Jin, Tian, Song, Yongping, and Dai, Yongpeng

Subjects

SPECTROGRAMS, CONVOLUTIONAL neural networks, DEEP learning, RADAR target recognition, HUMAN behavior

Abstract

The movements of the human body and limbs result in unique micro-Doppler signatures, which can be exploited for classifying human activities. In this work, the authors propose a Convolutional Gated Recurrent Units Neural Network (CNN-GRU) to classify human activities of varying duration based on micro-Doppler spectrogram. Unlike conventional deep learning approaches which often treat the micro-Doppler spectrogram the same way as natural image, the authors extract local feature of micro-Doppler signatures via convolutional layer and encode temporal information with gated recurrent units. Through this unified framework, the temporal evolution of body motions within a short time can be better utilised. It avoids the resolution limitation caused by the fixed-size time window of input data and identifies human activity of duration shorter than the time window length. The experiment shows that CNN-GRU model is capable of recognising and temporally localising activity sequence contained in the spectrogram. [ABSTRACT FROM AUTHOR]

Published

2019

26. 非接触战场伤情探测技术现状与应用展望.

Author

张杨, 吕昊, 梁福来, 焦腾, 于霄, 李钊, and 王健琪

Abstract

Copyright of Chinese Medical Equipment Journal is the property of Chinese Medical Equipment Journal Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2019

27. 一种用于生物雷达参考的生命信号同步测量系统研制.

Author

宋慧浩, 张自启, 殷 悦, 祁富贵, 王鹏飞, 王健琪, and 吕 昊

Abstract

Copyright of Chinese Medical Equipment Journal is the property of Chinese Medical Equipment Journal Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2019

28. Adaptive Wavelet Scale Selection-based Method for Separating Respiration and Heartbeat in Bio-radars

Author

Hu Xikun and Jin Tian

Subjects

Bio-radar, Adaptive wavelet selection, Respiration and heartbeat separation, Electricity and magnetism, QC501-766

Abstract

Extracting periodic heartbeat signals based on the traditional Fourier transform using a noncontact bio-radar is difficult because chest displacements caused by the heart are much smaller than those caused by respiration. Normally, they can be separated using the continuous wavelet transform; however, the miniscule difference of wavelet scale selection under different conditions may influence the separation performance to some extent. To solve this problem, this study proposes a method based on signal-to-noise ratio calibration to adaptively select the Morletdyadic wavelet scales and then separate the heartbeat signal from the respiration one using the selected scales, which can be applied to detect vital signs of different conditions. The experimental results have exhibited the accuracy and feasibility of the proposed method.

Published

2016

29. Advancements in Bio-radar Speech Signal Detection Technology

Author

Chen Fuming, Li Sheng, An Qiang, Zhang Ziqi, and Wang Jianqi

Subjects

Bio-radar, Speech detection, Speech signal, Acoustic sensor, Electricity and magnetism, QC501-766

Abstract

Speech signal acquisition is of great significance for human communication. Bio-radar technology has many advantages, such as it is noncontact, noninvasive, safe, highly directional, highly sensitivity, immune to strong acoustical disturbance and penetrable. This technology has important applications in the field of speech detection. In this paper, we first review the developmental history of speech detection technology, and then summarize the status of bio-radar speech detection technology. The basic principles of a bio-radar in detecting speech signals are given, and the performance of three types of bio-radar speech detection systems are compared in this paper. Finally, the potential applications of bio-radar speech signal detection technology are prospected.

Published

2016

30. Dynamic digital signal processing algorithm for vital signs extraction in continuous-wave radars

Author

Pedro Pinho, Carolina Gouveia, Daniel Albuquerque, and José Vieira

Subjects

arc fitting, bio-radar, continuous-wave, DC offsets, digital signal processing algorithm, vital signs, Offset (computer science), Computer science, Science, Real-time computing, Vital signs, Radar systems, Signal, Continuous-wave, Digital signal processing algorithms, Arc fitting, Fitting methods, General Earth and Planetary Sciences, Continuous wave, Extraction (military), Bio-radar, Digital signal processing algorithm

Abstract

Radar systems have been widely explored as a monitoring tool able to assess the subject’s vital signs remotely. However, their implementation in real application scenarios is not straightforward. Received signals encompass parasitic reflections that occur in the monitoring environment. Generally, those parasitic components, often treated as a complex DC (CDC) offsets, must be removed in order to correctly extract the bio-signals information. Fitting methods can be used, but their implementation were revealed to be challenging when bio-signals are weak or when these parasitic reflections arise from non-static targets, changing the CDC offset properties over time. In this work, we propose a dynamic digital signal processing algorithm to extract the vital signs from radar systems. This algorithm includes a novel arc fitting method to estimate the CDC offsets on the received signal. The method revealed being robust to weaker signals, presenting a success rate of 95%, irrespective of the considered monitoring conditions. Furthermore, the proposed algorithm is able to adapt to slow changes in the propagation environment.

Published

2021

31. Cognitive bio-radar: The natural evolution of bio-signals measurement.

Author

Malafaia, Daniel, Oliveira, Beatriz, Ferreira, Pedro, Varum, Tiago, Vieira, José, and Tomé, Ana

Published

2016

32. Contact-Free Detection of Obstructive Sleep Apnea Based on Wavelet Information Entropy Spectrum Using Bio-Radar.

Author

Fugui Qi, Chuantao Li, Shuaijie Wang, Hua Zhang, Jianqi Wang, and Guohua Lu

Subjects

*SLEEP apnea syndromes, *APNEA, *SLEEP disorders, *BRAIN stimulation, *RESPIRATION

Abstract

Judgment and early danger warning of obstructive sleep apnea (OSA) is meaningful to the diagnosis of sleep illness. This paper proposed a novel method based on wavelet information entropy spectrum to make an apnea judgment of the OSA respiratory signal detected by bio-radar in wavelet domain. It makes full use of the features of strong irregularity and disorder of respiratory signal resulting from the brain stimulation by real, low airflow during apnea. The experimental results demonstrated that the proposed method is effective for detecting the occurrence of sleep apnea and is also able to detect some apnea cases that the energy spectrum method cannot. Ultimately, the comprehensive judgment accuracy resulting from 10 groups of OSA data is 93.1%, which is promising for the non-contact aided-diagnosis of the OSA. [ABSTRACT FROM AUTHOR]

Published

2016

33. 24 GHz Flexible Antenna for Doppler Radar-Based Human Vital Signs Monitoring

Author

Boon-Chong Seet and Nitin Kathuria

Subjects

020205 medical informatics, Computer science, Acoustics, Doppler radar, Vital signs, flexible antenna, 02 engineering and technology, TP1-1185, bio-radar, Biochemistry, Radar systems, Directivity, Article, Analytical Chemistry, law.invention, Antenna array, liquid crystal polymer, Respiratory Rate, law, Heart Rate, human vital signs, 0202 electrical engineering, electronic engineering, information engineering, Humans, Electrical and Electronic Engineering, Instrumentation, Radar, Vital Signs, Chemical technology, 020206 networking & telecommunications, Ultrasonography, Doppler, Atomic and Molecular Physics, and Optics, Power (physics), noncontact monitoring, bending analysis, Radio frequency, Antenna (radio)

Abstract

Noncontact monitoring of human vital signs has been an emerging research topic in recent years. A key approach to this monitoring is the use of the Doppler radar concept which enables real-time vital signs detection, resulting in a new class of radar system known as bio-radar. The antennas are a key component of any bio-radar module and their designs should meet the common requirements of bio-radar applications such as high radiation directivity and mechanical flexibility. This paper presents the design of a four-element antenna array on a flexible liquid crystal polymer (LCP) substrate of 100 μm thickness and εr of 3.35. The designed antenna array can be used with a 24 GHz bio-radar for vital signs monitoring in a non-contact manner. It features a relatively compact size of 36.5 × 53 mm2 and measured gain of 5.81 dBi. The two vital signs: breathing rate (BR) and heart rate (HR) of two human subjects are detected with relatively good accuracy using the fabricated antenna array and radio frequency (RF) output power of −3 dBm from a distance of approximately 60 cm. The effect of bending on the antenna performance is also analyzed.

Published

2021

34. Multi-target human sensing via UWB bio-radar based on multiple antennas.

Author

Lv, Hao, Liu, Miao, Jiao, Teng, Zhang, Yang, Yu, Xiao, Li, Sheng, Jing, Xijing, and Wang, Jianqi

Abstract

Being capable of sensing human through obstacles, bio-radar is promising in many applications like healthcare, public securities, emergency rescue and so on. In these applications, the presence of human and the human count are among the most important issues that are concerned by people. At present plenty of studies deal with the former issue but there's no study dealing with the latter one. To this end, a framework of determining the count of human targets using ultra-wideband (UWB) bio-radar was presented in this paper. It was developed based on multiple antennas and correlation processing of sensed respiration among the data channels. In the experiment, the UWB bio-radar could distinguish among the cases of no target, single target, two targets and three targets present behind a brick wall and determine the target count with no priori information. On this basis, multi-target estimation and localization can be further realized. [ABSTRACT FROM PUBLISHER]

Published

2013

35. Textile Antenna for Bio-Radar Embedded in a Car Seat

Author

Caroline Loss, José Vieira, Rita Salvado, Carolina Gouveia, and Pedro Pinho

Subjects

Computer science, dielectric substrate, Vital signs, 02 engineering and technology, Substrate (printing), bio-radar, lcsh:Technology, Automotive engineering, Article, law.invention, vital signs, non-contact measurements, law, 0202 electrical engineering, electronic engineering, information engineering, Textile antenna, General Materials Science, Radar, lcsh:Microscopy, Ground plane, lcsh:QC120-168.85, Dielectric substrate, lcsh:QH201-278.5, lcsh:T, 020208 electrical & electronic engineering, Process (computing), 020206 networking & telecommunications, Car seat, lcsh:TA1-2040, textile antenna, lcsh:Descriptive and experimental mechanics, Radio frequency, lcsh:Electrical engineering. Electronics. Nuclear engineering, Textile (markup language), lcsh:Engineering (General). Civil engineering (General), Bio-radar, lcsh:TK1-9971, Non-contact measurements

Abstract

A bio-radar system is presented for vital signs acquisition, using textile antennas manufactured with a continuous substrate that integrates the ground plane. Textile antennas were selected to be used in the RF (Radio Frequency) front-end, rather than those made of conventional materials, to further integrate the system in a car seat cover and thus streamline the industrial manufacturing process. The development of the novel substrate material is described in detail, as well as its characterization process. Then, the antenna design considerations are presented. The experiments to validate the textile antennas operation by acquiring the respiratory signal of six subjects with different body structures while seated in a car seat are presented. In conclusion, it was possible to prove that bio-radar systems can operate with textile-based antennas, providing accurate results of the extraction of vital signs.

Published

2021

36. Contactless Vital Signs Measurement with Low Cost Continuous Wave Doppler Radar

Author

Şeflek, İ̇̇brahim, Yaldız, Ercan, and Selçuk Üniversitesi

Subjects

Temassız ölçüm, Non-contact measurement, Biyoradar, Doppler radar, Radar signal processing, Radar sinyal işleme, Hayati sinyal tespiti, Bio-radar, Vital signs detection

Abstract

Hayati sinyallerin temassız olarak uzaktan algılanması birçok uygulama açısından önem arz etmektedir. Bu algılamayı gerçekleştiren radarlar biyoradar olarak adlandırılmaktadır. Biyoradar kişinin solunum ve kalp atışından kaynaklanan göğüs duvarı hareketinin değişimiyle Doppler prensibini kullanarak hayati sinyallerin doğru bir şekilde ölçülmesini sağlamaktadır. Bu çalışmada, 24 GHz çalışma frekansına sahip düşük maliyetli sürekli dalga (CW) Doppler radarı kullanılarak insan denekten temassız bir şekilde yaşamsal belirti (solunum, kalp atış hızı) ölçümleri gerçekleştirilmiştir. Ölçümlerden elde edilen sinyallerin işlenmesinde iki farklı yöntem kullanılmıştır. İlk yöntem Hızlı Fourier Dönüşümünü (FFT) esas alırken ikinci yöntemde Dalgacık yöntemine dayalı Çoklu Çözünürlük Analizi (MRA) yöntemi kullanılmaktadır. Solunum hızında birinci ve ikinci yöntem için elde edilen sonuçlar %3.75 ve %0’ hata oranlıdır. Kalp atışı için sırasıyla %9.35 ve %8.45 hata oranlı değerler elde edilmiştir. Bu sonuçlar özellikle radarların tıbbi uygulamalar için başarıyla kullanılabileceğini göstermektedir., Remote sensing of vital signals without contact is important for many applications. Radars that perform this detection are called bio-radar. Bio-radar provides accurate measurement of vital signals using the Doppler principle with the change of chest wall movement caused by a person's breathing and heartbeat. In this study, non-contact vital signs (respiration, heart rate) measurements for human subject were performed using a low cost continuous wave (CW) Doppler radar with a 24 GHz operating frequency. Two different methods have been used to process the signals obtained from the measurements. While the first method is based on the Fast Fourier Transform (FFT), the second method uses the Multi-Resolution Analysis (MRA) method based on the Wavelet method. The results obtained by the first and second methods for respiration are 3.75% and 0% error rates, respectively. These values for heartbeat are 9.35% and 8.45%. These results show that radars can be used successfully for medical applications.

Published

2020

37. DeepActivity: a micro-Doppler spectrogram-based net for human behaviour recognition in bio-radar

Author

Yongpeng Dai, Tian Jin, Yongping Song, and Hao Du

Subjects

Computer science, convolutional layer, Feature extraction, Doppler radar, 0211 other engineering and technologies, Energy Engineering and Power Technology, DeepActivity, 02 engineering and technology, bio-radar, ENCODE, image motion analysis, 01 natural sciences, convolutional neural nets, Radar imaging, recurrent neural nets, human behaviour recognition, image coding, local feature extraction, 021101 geological & geomatics engineering, human activity classification, Contextual image classification, Artificial neural network, business.industry, activity sequence recognition, Deep learning, feature extraction, human body, 010401 analytical chemistry, General Engineering, Pattern recognition, limbs, 0104 chemical sciences, radar imaging, conventional deep learning approaches, temporally localising activity sequence, Feature (computer vision), lcsh:TA1-2040, Spectrogram, microDoppler spectrogram-based net, convolutional gated recurrent units neural Network, Artificial intelligence, business, CNN-GRU model, lcsh:Engineering (General). Civil engineering (General), Software, microDoppler signatures, image classification

Abstract

The movements of the human body and limbs result in unique micro-Doppler signatures, which can be exploited for classifying human activities. In this work, the authors propose a Convolutional Gated Recurrent Units Neural Network (CNN-GRU) to classify human activities of varying duration based on micro-Doppler spectrogram. Unlike conventional deep learning approaches which often treat the micro-Doppler spectrogram the same way as natural image, the authors extract local feature of micro-Doppler signatures via convolutional layer and encode temporal information with gated recurrent units. Through this unified framework, the temporal evolution of body motions within a short time can be better utilised. It avoids the resolution limitation caused by the fixed-size time window of input data and identifies human activity of duration shorter than the time window length. The experiment shows that CNN-GRU model is capable of recognising and temporally localising activity sequence contained in the spectrogram.

Published

2019

38. Dynamic Digital Signal Processing Algorithm for Vital Signs Extraction in Continuous-Wave Radars.

Author

Gouveia, Carolina, Albuquerque, Daniel, Vieira, José, and Pinho, Pedro

Subjects

*DIGITAL signal processing, *VITAL signs, *RADAR, *ALGORITHMS

Abstract

Radar systems have been widely explored as a monitoring tool able to assess the subject's vital signs remotely. However, their implementation in real application scenarios is not straightforward. Received signals encompass parasitic reflections that occur in the monitoring environment. Generally, those parasitic components, often treated as a complex DC (CDC) offsets, must be removed in order to correctly extract the bio-signals information. Fitting methods can be used, but their implementation were revealed to be challenging when bio-signals are weak or when these parasitic reflections arise from non-static targets, changing the CDC offset properties over time. In this work, we propose a dynamic digital signal processing algorithm to extract the vital signs from radar systems. This algorithm includes a novel arc fitting method to estimate the CDC offsets on the received signal. The method revealed being robust to weaker signals, presenting a success rate of 95 % , irrespective of the considered monitoring conditions. Furthermore, the proposed algorithm is able to adapt to slow changes in the propagation environment. [ABSTRACT FROM AUTHOR]

Published

2021

39. 24 GHz Flexible Antenna for Doppler Radar-Based Human Vital Signs Monitoring.

Author

Kathuria, Nitin and Seet, Boon-Chong

Subjects

*POLYMER liquid crystals, *VITAL signs, *DOPPLER radar, *ANTENNAS (Electronics), *RADIO antennas, *MODULAR coordination (Architecture)

Abstract

Noncontact monitoring of human vital signs has been an emerging research topic in recent years. A key approach to this monitoring is the use of the Doppler radar concept which enables real-time vital signs detection, resulting in a new class of radar system known as bio-radar. The antennas are a key component of any bio-radar module and their designs should meet the common requirements of bio-radar applications such as high radiation directivity and mechanical flexibility. This paper presents the design of a four-element antenna array on a flexible liquid crystal polymer (LCP) substrate of 100 μm thickness and εr of 3.35. The designed antenna array can be used with a 24 GHz bio-radar for vital signs monitoring in a non-contact manner. It features a relatively compact size of 36.5 × 53 mm2 and measured gain of 5.81 dBi. The two vital signs: breathing rate (BR) and heart rate (HR) of two human subjects are detected with relatively good accuracy using the fabricated antenna array and radio frequency (RF) output power of −3 dBm from a distance of approximately 60 cm. The effect of bending on the antenna performance is also analyzed. [ABSTRACT FROM AUTHOR]

Published

2021

40. Textile Antenna for Bio-Radar Embedded in a Car Seat.

Author

Loss, Caroline, Gouveia, Carolina, Salvado, Rita, Pinho, Pedro, and Vieira, José

Subjects

*ANTENNA design, *ANTENNAS (Electronics), *ELECTROTEXTILES, *RADIO frequency, *MANUFACTURING processes

Abstract

A bio-radar system is presented for vital signs acquisition, using textile antennas manufactured with a continuous substrate that integrates the ground plane. Textile antennas were selected to be used in the RF (Radio Frequency) front-end, rather than those made of conventional materials, to further integrate the system in a car seat cover and thus streamline the industrial manufacturing process. The development of the novel substrate material is described in detail, as well as its characterization process. Then, the antenna design considerations are presented. The experiments to validate the textile antennas operation by acquiring the respiratory signal of six subjects with different body structures while seated in a car seat are presented. In conclusion, it was possible to prove that bio-radar systems can operate with textile-based antennas, providing accurate results of the extraction of vital signs. [ABSTRACT FROM AUTHOR]

Published

2021

41. 2.4 GHz bio-radar system with improved performance by using phase-locked loop.

Author

Seong-Sik Myoung, Jae-Hyung Park, Jong-Gwan Yook, and Byung-Jun Jang

Subjects

*DOPPLER radar, *ELECTRIC noise, *ELECTRIC oscillators, *DIGITAL signal processing, *ANTENNAS (Electronics)

Abstract

This letter presents a novel bio-radar system with phase-locked loop (PLL) for noncontact measurement of vital sign. As the leakage of the phase noise of local oscillator (LO) through antenna is dominant factor for the distances larger than about 30 cm, the performance of a bio-radar system can be improved with the PLL employment. The proposed bio-radar and PLL are implemented by using conventional commercial components, and the measured result shows that the bio-radar system performance is greatly improved with a PLL without any additional digital signal processing. © 2010 Wiley Periodicals, Inc. Microwave Opt Technol Lett 52: 2074–2076, 2010; Published online in Wiley InterScience (www.interscience.wiley.com). DOI 10.1002/mop.25366 [ABSTRACT FROM AUTHOR]

Published

2010

42. Contact-Free Detection of Obstructive Sleep Apnea Based on Wavelet Information Entropy Spectrum Using Bio-Radar

Author

Guohua Lu, Chuantao Li, Shuaijie Wang, Hua Zhang, Jianqi Wang, and Fugui Qi

Subjects

Computer science, Speech recognition, 0206 medical engineering, General Physics and Astronomy, lcsh:Astrophysics, 02 engineering and technology, bio-radar, Respiratory signal, law.invention, OSA, Wavelet, law, lcsh:QB460-466, 0202 electrical engineering, electronic engineering, information engineering, medicine, Radar, lcsh:Science, wavelet information entropy, respiratory signal, Apnea, Sleep apnea, 020206 networking & telecommunications, medicine.disease, 020601 biomedical engineering, lcsh:QC1-999, respiratory tract diseases, Obstructive sleep apnea, Brain stimulation, lcsh:Q, Sleep (system call), medicine.symptom, lcsh:Physics

Abstract

Judgment and early danger warning of obstructive sleep apnea (OSA) is meaningful to the diagnosis of sleep illness. This paper proposed a novel method based on wavelet information entropy spectrum to make an apnea judgment of the OSA respiratory signal detected by bio-radar in wavelet domain. It makes full use of the features of strong irregularity and disorder of respiratory signal resulting from the brain stimulation by real, low airflow during apnea. The experimental results demonstrated that the proposed method is effective for detecting the occurrence of sleep apnea and is also able to detect some apnea cases that the energy spectrum method cannot. Ultimately, the comprehensive judgment accuracy resulting from 10 groups of OSA data is 93.1%, which is promising for the non-contact aided-diagnosis of the OSA.

Published

2016