Your search keyword '"Yavari, E."' showing total 4 results

1. Separation of Respiratory Signatures for Multiple Subjects Using Independent Component Analysis with the JADE Algorithm.

Author

Islam SMM, Yavari E, Rahman A, Lubecke VM, and Boric-Lubecke O

Subjects

Humans, Motion, Algorithms, Monitoring, Physiologic methods, Radar, Respiration

Abstract

Respiration monitoring using microwave Doppler radar has attracted significant interest over the last four decades due to its non-invasive and non-contact form of measurement. However, this technology is still not at the level of practical implementations in healthcare due to motion artifacts and interference from multiple subjects within the range of the Doppler radar sensor. Most reported results in literature focus only on single subject measurements because when multiple subjects are present there are interfering respiration signals which are difficult to separate as individual respiration signals. This paper investigates the feasibility of separating respiratory signatures from the multiple subjects. We employed a new approach using Independent Component Analysis (ICA) with the Joint Approximate Diagonalization of Eignematrices (JADE) algorithm to achieve this for closely spaced subjects, and the system is also capable of estimating Direction of Arrival (DOA) for well-spaced subjects. Experimental results demonstrated that the ICA-JADE method can separate respiratory signatures from two subjects one meter apart from each other at a distance from the radar of 2.89 meters. The separated respiratory pattern closely correlates with reference chest belt respiration patterns, and the mean square error is approximately 11.58%. Concisely, this paper clearly demonstrates that by integrating ICA with the JADE algorithm in a Doppler radar physiological monitoring system, multiple subjects can be monitored simultaneously.

Published

2018

2. Synchrosqueezing an effective method for analyzing Doppler radar physiological signals.

Author

Yavari E, Rahman A, Jia Xu, Mandic DP, and Boric-Lubecke O

Subjects

Fourier Analysis, Heart Rate physiology, Humans, Respiration, Time Factors, Doppler Effect, Monitoring, Physiologic methods, Radar, Signal Processing, Computer-Assisted

Abstract

Doppler radar can monitor vital sign wirelessly. Respiratory and heart rate have time-varying behavior. Capturing the rate variability provides crucial physiological information. However, the common time-frequency methods fail to detect key information. We investigate Synchrosqueezing method to extract oscillatory components of the signal with time varying spectrum. Simulation and experimental result shows the potential of the proposed method for analyzing signals with complex time-frequency behavior like physiological signals. Respiration and heart signals and their components are extracted with higher resolution and without any pre-filtering and signal conditioning.

Published

2016

3. Wrist-worn heartbeat monitoring system based on bio-impedance analysis.

Author

Jia Xu, Xiaomeng Gao, Lee A, Yamada S, Yavari E, Lubecke V, and Boric-Lubecke O

Subjects

Electric Impedance, Humans, Heart Rate physiology, Monitoring, Physiologic instrumentation, Monitoring, Physiologic methods, Monitoring, Physiologic standards, Wrist

Abstract

In this paper, a bio-impedance analysis (BIA) based wrist-worn heartbeat monitoring system is proposed. The system is able to estimate heart rate from a subject's wrist with only four electrodes. The design is achieved with a standard BIA device and off-the-shelf components for signal conditioning. The measured heartbeat-related impedance signal is compared with a reference heart rate signal obtained from piezoelectric finger pulse transducer. The BIA results agree with the reference, which validates the feasibility of the proposed system. To the best of our knowledge, this is the first reported BIA heartbeat monitoring system in the wristband configuration.

Published

2016

4. Considerations for integration of a physiological radar monitoring system with gold standard clinical sleep monitoring systems.

Author

Singh A, Baboli M, Gao X, Yavari E, Padasdao B, Soll B, Boric-Lubecke O, and Lubecke V

Subjects

Doppler Effect, Feasibility Studies, Humans, Polysomnography, Signal Processing, Computer-Assisted, Monitoring, Physiologic methods, Monitoring, Physiologic standards, Radar, Sleep physiology

Abstract

A design for a physiological radar monitoring system (PRMS) that can be integrated with clinical sleep monitoring systems is presented. The PRMS uses two radar systems at 2.45 GHz and 24 GHz to achieve both high sensitivity and high resolution. The system can acquire data, perform digital processing and output appropriate conventional analog outputs with a latency of 130 ms, which can be recorded and displayed by a gold standard sleep monitoring system, along with other standard sensor measurements.

Published

2013