A Systematic Review of Non-Contact Sensing for Developing a Platform to Contain COVID-19
Abstract
:1. Introduction
- (1)
- Systematically review the non-contact sensing platforms used for human activity and health monitoring.
- (2)
- Propose a non-contact sensing platform for the early diagnosis of COVID-19 symptoms and the monitoring of human activities and health during the isolation or quarantine period.
- (3)
- Highlight the challenges, testing environment, performance and optimal solutions to work on deployment.
2. Literature Review
2.1. Covid-19 Summary
2.2. Human Activity Monitoring
2.3. Symptom Diagnosis and Health Monitoring
3. Proposed Platform
3.1. Data Collection
3.2. Data Extraction
3.3. Preprocessing
3.4. Features
3.5. Classification
4. Experimental Setup
4.1. Commercial Hardware Platform
4.2. Specialized Hardware Platform
- Symptoms data collection
- 2.
- Activities data collection
5. Outcomes
- Wireless signals can pass through the wall and do not require LOS. This feature of non-contact sensing eliminates the need for face-to-face contact and provides improved management to contain COVID-19.
- In case COVID-19 symptoms develop, the data sent by means of cloud computing platforms can enable healthcare authorities to respond quickly.
- It will reduce the physical contact time with a COVID-19 patient as much as possible.
- It will not only monitor COVID-19 symptoms but also continuous health monitoring during quarantine and isolation periods in a non-contact manner.
- Transferring care to home, or treating high-risk elders and children in their own homes.
- This will improve privacy of individuals during quarantine or isolation periods.
- It will also help in early recognition of patients who need aggressive management or hospitalization to prevent them from serious or irreversible sequelae of the disease.
- Reduce life risk of doctors, paramedical staff and caretakers during quarantine and isolation periods.
- Innovative tools to construct useful contactless sensing platforms for health care applications.
- These platforms can be deployed by re-using the existing infrastructure of wireless communication networks.
- Improved access to care, increased quality of care and reduced care costs.
- It can be deployed in any emergency condition at any place to counter health challenges.
6. Challenges
- A.
- Environmental effect
- B.
- Experimental subject
- C.
- Orientation and location
- D.
- Multi-subject sensing
- E.
- Privacy and security
7. Future Recommendations
- It is recommended to perform extensive experiments with different environments and experimental setups to develop an RT model.
- It is recommended to collect experimental data by using multi-subjects with extensive experimentation to develop a model.
- An efficient and possible solution must develop a rigorous theoretical model independent of the user’s location and orientation; the correct mapping of the relationship between WCSI measurements and the human body motions identify the health conditions. It is recommended to conduct experiments with different orientations and locations for the collection of data for developing models.
- It is recommended to extract more prominent features to differentiate human activities and health conditions. Frequency domain features are useful for classifying multi-subjects.
- It is recommended to use SDR-based WCSI sensing to counter the privacy and security using a self-generated signal approach that can switch to different frequency bands.
8. Conclusions
Author Contributions
Funding
Conflicts of Interest
References
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Abbreviation | Description | Abbreviation | Description |
---|---|---|---|
AP | Access point | MIMO | Multiple input multiple output |
BMS | Building management systems | ML | Machine learning |
CA | Cerebellar ataxia | MMP | Mouth motion profile |
CAF | Cross-ambiguity function | MSP | Microwave sensing platform |
CARM | Channel state information-based human activity recognition and monitoring | NIC | Network interface card |
CD | Cerebellar dysfunction | OAR | Occupant activity recognition |
CDC | Centers for Disease Control and Prevention | OFDM | Orthogonal frequency Division multiplexing |
CFES | CSI feature enhancement scheme | PADS | Passive detection of moving humans with dynamic speed |
CFR | Channel frequency response | REM | Rapid eye movement |
CNN | Convolutional neural network | RF | Radio frequency |
COPD | Chronic obstructive pulmonary disease | RFA | Random forest algorithm |
COVID | Corona virus disease | RFIC | Radio frequency integrated circuits |
RNN | Recurrent neural network | ||
CSI | Channel state information | RT | Real time |
DG | Domain gap | SARS-CoV-2 | Severe acute respiratory syndrome coronavirus-2 |
DI | Domain independent | SDAR | Spatial diversity aware non-contact activity recognition |
DL | Deep learning | SDR | Software defined radios |
DTW | Dynamic time warping | SIDS | Sudden infant death syndrome |
EWMA | Exponentially weighted moving average | SP | Shaking palsy |
FDD | Frequency division duplex | SSF | Stable signal fusion |
FDTW | Fast dynamic time warping | SVM | Support vector machine |
FOG | Freezing of gait | TDD | Time division duplex |
FPGA | Field programmable gate array | TTW | Through the walls |
FRTCS | Fast and robust target Component separation | USRP | Universal software radio peripheral |
HAR | Human activity recognition | UWB | Ultra-wide band |
HD | Huntington’s disease | WCSI | Wireless channel state information |
HMM | Hidden Markov model | Wi-AR | Wireless activity recognition |
IoT | Internet of things | Wi-Fi | Wireless fidelity |
IWL | Intel Wi-Fi wireless link | Wi-GeR | Wi-Fi-based gesture recognition |
KNN | K-nearest neighbors | Wi-Hear | Wireless Hear |
LCC | Leaky coaxial cable | Wi-Motion | Wireless Motion |
LOS | Line of sight | Wi-See | Wireless See |
LSTM | Long short term memory | Wi-Vit | Wireless Vitality |
MCP | Medical cyber–physical | WSN | Wireless sensor networks |
Symptoms | COVID-19 | |
---|---|---|
Fever | Most common | |
Cough | Most common | |
Sore throat | Less common | |
Shortness of breath | Less common | |
Fatigue | Most common | |
Aches and pains | Rare | |
Headaches | Most common | |
Runny or stuffy nose | Rare | |
Diarrhea | Rare |
Sr | Technology/Reference | Detection and Monitoring | Classification Method | Accuracy |
---|---|---|---|---|
1 | Wi-Fi sensing [28] | Moving human | SVM | 99% |
2 | SDR [29] | Standing, walking, crawling, lying and empty | KNN | 85% |
3 | Wi-Fi sensing [30] | Walking, running sitting and falling, opening, empty, refrigerator, boxing, pushing one hand, brushing teeth | CSI-speed and CSI-activity model | 96% |
4 | Wi-Fi sensing [31] | Human presence static and dynamic | Naïve Bayes | 99% |
5 | Wi-Fi sensing [32] | Walk, Sit, Stand, Run | SVM and LSTM | 95% |
6 | SDR [33] | Standing up or sitting down | RF | 96.70% |
7 | UWB [34] | Standing, sitting, lying | RF | 95.6% |
8 | Wi-Fi sensing [35] | Gestures | FDTW | 97.28% |
9 | Wi-Fi sensing [36] | Human motion | HMM | 94.2% |
10 | Wi-Fi sensing [37] | Eating | Soft decision-based learning | 95% |
11 | SDR [38] | Gestures | Pattern-matching | 94% |
12 | SDR and Wi-Fi sensing [39] | Hearing | ML | 91% |
13 | Radar sensing [40] | Sit-to-stand, stand-to-sit, walking and jogging | K-mean | 85% |
14 | Wi-Fi sensing [41] | Gestures | CNN | 94.45%, |
15 | Radar sensing [42] | Walking, running, and crawling | KNN | 93% |
16 | Wi-Fi sensing [43] | Whole-body movements and partial-body, seated activities | ML | 94.82% |
17 | Wi-Fi sensing [44] | Upper, Lower and whole body | CNN | 90% |
18 | Wi-Fi sensing [45] | Bend, hand clap, walk, phone call, sit down and squat | SVM | 98.4% |
19 | Wi-Fi sensing [46] | Pick up, walking, jogging and sitting on chair | Deep auto-encoder | 91.1% |
20 | Radar sensing [47] | Kitchen activities | CNN | 92.8% |
21 | Wi-Fi sensing [48] | Standing and stand-up, sitting and sit down | Soft-max regression | 97.5% |
22 | Wi-Fi sensing [49] | Walk, stand, empty and sit down | RNN | 90% |
23 | Wi-Fi sensing [50] | Moving area, path walking | Path matching | 90.83% |
24 | Wi-Fi sensing [51] | Sleep | K-NN | 93.88% |
25 | Wi-Fi sensing [52] | Quantifying running | SSF | 93.18% |
26 | Wi-Fi sensing [53] | Walking | STFT | 96% |
Sr | Technology/Reference | Detection and Monitoring | Classification Method | Accuracy |
---|---|---|---|---|
1 | RF sensing [55] | Asthma attacks | SVM | 90% |
2 | Wi-Fi sensing [56] | Post-surgical fall | SVM | 90% |
3 | Wi-Fi sensing [57] | Huntington’s disease | SVM and RF | 98% |
4 | Microwave spectrum sensing [58] | Parkinsonian gait | SVM | 94% |
5 | Wi-Fi sensing [59] | Dementia | SVM | 90% |
6 | SDR [60] | Breathing rate, tremor and falls | ML | 98% |
7 | Wi-Fi sensing [61] | Eclamptic seizures | SVM | 95% |
8 | Wi-Fi sensing [62] | Danger-pose | SVM | 96.23% |
9 | SDR [63] | Breathing | SVM | 85% |
10 | SDR [64] | REM sleep disorder | SVM | 90% |
11 | Microwave sensing [65] | Cerebellar ataxia | SVM | 99.8% |
12 | Wi-Fi sensing [66] | Paraparesis | 1D-CNN | 99.4% |
13 | Microwave sensing [67] | Neurological disorder | SVM | 99% |
14 | Wi-Fi sensing [68] | Cerebellar dysfunction | SVM | 91% |
15 | Wi-Fi sensing [69] | Parkinson’s disease | SVM | 90% |
16 | Wi-Fi sensing [70] | Tumor | SVM | 90% |
17 | Radar sensing [71] | Gait | SVM | 95% |
18 | Wi-Fi sensing [72] | Breathing and heart rate patterns | DTW | 94% |
19 | Wi-Fi sensing [73] | Vital sign during sleep | SVM and RF | 93% |
20 | Wi-Fi sensing [74] | Parkinson’s disease | CNN | 99.7% |
21 | RF sensing [75] | Epileptic seizures | SVM | 90% |
22 | Wi-Fi sensing [76] | Fall | SVM and RF | 94% |
23 | Wi-Fi sensing [77] | Fall | SVM | 100% |
24 | Wi-Fi sensing [78] | Respiration rate | EWMA | 93.04% |
25 | SDR [79] | Post-surgery ankle fractured | CNN | 98.98% |
26 | SDR [80] | Post-surgery spinal cord | FKNN | 99.6% |
Time Domain Features | Frequency Domain Features | ||||
---|---|---|---|---|---|
Statistics | Expression | Statistics | Expression | Statistics | Expression |
Minimum | Skewness | FFT | |||
Maximum | Kurtosis | Spectral probability | |||
Mean | Histogram | Signal energy | |||
Variance | Interquartile range | Spectrum entropy | |||
RMS | Range | Frequency peak |
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Khan, M.B.; Zhang, Z.; Li, L.; Zhao, W.; Hababi, M.A.M.A.; Yang, X.; Abbasi, Q.H. A Systematic Review of Non-Contact Sensing for Developing a Platform to Contain COVID-19. Micromachines 2020, 11, 912. https://doi.org/10.3390/mi11100912
Khan MB, Zhang Z, Li L, Zhao W, Hababi MAMA, Yang X, Abbasi QH. A Systematic Review of Non-Contact Sensing for Developing a Platform to Contain COVID-19. Micromachines. 2020; 11(10):912. https://doi.org/10.3390/mi11100912
Chicago/Turabian StyleKhan, Muhammad Bilal, Zhiya Zhang, Lin Li, Wei Zhao, Mohammed Ali Mohammed Al Hababi, Xiaodong Yang, and Qammer H. Abbasi. 2020. "A Systematic Review of Non-Contact Sensing for Developing a Platform to Contain COVID-19" Micromachines 11, no. 10: 912. https://doi.org/10.3390/mi11100912
APA StyleKhan, M. B., Zhang, Z., Li, L., Zhao, W., Hababi, M. A. M. A., Yang, X., & Abbasi, Q. H. (2020). A Systematic Review of Non-Contact Sensing for Developing a Platform to Contain COVID-19. Micromachines, 11(10), 912. https://doi.org/10.3390/mi11100912