Respiration Detection of Ground Injured Human Target Using UWB Radar Mounted on a Hovering UAV
Abstract
:1. Introduction
2. UAV-mounted UWB Radar System
3. Signal Model
4. Signal Processing
4.1. Range Migration Compensation
4.2. Observed Signals Extraction
4.3. Pre-Processing
4.4. Independent Component Analysis
4.4.1. ICA Compliance
4.4.2. Process of ICA
Algorithm 1 FastICA |
1: Input the observed signals. |
2: Centre the data to give . 3: Whiten the data to give . 4: Choose the number of independent components m. 5: For 6: Initialize the weight vector 7: 8: 9: 10: If is not converged, go back to step 7. 11: End for 12: |
4.5. Respiratory Signal Extraction
5. Experiments
5.1. Experimental Setup
5.2. Results and Discussion
5.2.1. Observed Signals Extraction
5.2.2. Respiration Detection in Scenario 1
5.2.3. Respiration Detection in Scenario 2
6. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Parameters | Values |
---|---|
Centre frequency | 7.29 GHz |
Bandwidth | 1.4 GHz |
Detection range | 0.4–5 m |
Range resolution | 0.0514 m |
Frame rate | 17 Hz |
Scenario 1 | RR (Hz) | Accuracy (%) | SNR (dB) | ||||
---|---|---|---|---|---|---|---|
Reference | Our Method | BGR | Our Method | BGR | Our Method | BGR | |
Subject 1 | 0.3418 | 0.3652 | 0.3652 | 93.15 | 93.15 | 15.82 | 10.56 |
Subject 2 | 0.2032 | 0.2153 | 0.2210 | 94.05 | 91.24 | 16.18 | 11.49 |
Subject 3 | 0.2889 | 0.2833 | 0.2833 | 98.05 | 98.05 | 15.27 | 11.35 |
Scenario 2 | RR (Hz) | Accuracy (%) | SNR (dB) | ||||
---|---|---|---|---|---|---|---|
Reference | Our Method | BGR | Our Method | BGR | Our Method | BGR | |
Subject 1 | 0.4329 | 0.4482 | 0.1268 | 96.47 | 29.29 | 6.69 | 5.48 |
Subject 2 | 0.2930 | 0.2988 | 0.3682 | 98.02 | 74.33 | 7.38 | 5.95 |
Subject 3 | 0.2500 | 0.2656 | 0.4016 | 93.76 | 39.36. | 6.74 | 4.92 |
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Jing, Y.; Qi, F.; Yang, F.; Cao, Y.; Zhu, M.; Li, Z.; Lei, T.; Xia, J.; Wang, J.; Lu, G. Respiration Detection of Ground Injured Human Target Using UWB Radar Mounted on a Hovering UAV. Drones 2022, 6, 235. https://doi.org/10.3390/drones6090235
Jing Y, Qi F, Yang F, Cao Y, Zhu M, Li Z, Lei T, Xia J, Wang J, Lu G. Respiration Detection of Ground Injured Human Target Using UWB Radar Mounted on a Hovering UAV. Drones. 2022; 6(9):235. https://doi.org/10.3390/drones6090235
Chicago/Turabian StyleJing, Yu, Fugui Qi, Fang Yang, Yusen Cao, Mingming Zhu, Zhao Li, Tao Lei, Juanjuan Xia, Jianqi Wang, and Guohua Lu. 2022. "Respiration Detection of Ground Injured Human Target Using UWB Radar Mounted on a Hovering UAV" Drones 6, no. 9: 235. https://doi.org/10.3390/drones6090235
APA StyleJing, Y., Qi, F., Yang, F., Cao, Y., Zhu, M., Li, Z., Lei, T., Xia, J., Wang, J., & Lu, G. (2022). Respiration Detection of Ground Injured Human Target Using UWB Radar Mounted on a Hovering UAV. Drones, 6(9), 235. https://doi.org/10.3390/drones6090235