Table 7.
Techniques, attributes, and characteristics of monitoring and tracking-COVID-19 applications
| Authors | The basic objective | Pros | Limitations in study | Security method? | Simulation environments | Dataset and Size of Dataset | Using TL? | Mechanism | Application? |
|---|---|---|---|---|---|---|---|---|---|
| Dong, Qiao [103] | Intending to use the XGBoost and a non-contact monitoring system to assess prospective COVID-19 patients automatically |
Precision = 92.5 percent, recall rate = 96.8%, and AUC = 98.0 percent were achieved.-Stable and robust -Low complexity |
-High energy consumption | No | Not mentioned |
Local dataset (Small dataset) |
No | XGBoost + LR algorithm | Non-contact screening system |
| Jaber, Alameri [104] | Using a CNN model to maximize the illness classification process with the fewest possible deviations |
-98.76 percent accuracy -Low variation rate |
–Low robustness | No | MATLAB |
Open research dataset (Small dataset) |
No | CNN | Monitoring COVID-19 patient health |
| Zhang, Zhu [105] | Proposing body temperature monitoring for COVID-19 prevention regularly based on ML | -High accuracy | -Low flexibility | No | Python |
Total of 31,713 entries dataset ( Large size dataset) |
No | RF | Body temperature monitoring |
| Zhang, Liu [106] | Offering an emotion-aware system that includes discriminative emotion identification utilizing CNN |
-High accuracy -High precision |
-Low robustness | No | Python | eNTERFACE’ 05 datasets, SEED dataset, and DEAP database (Large dataset) | Yes | CNN | Emotion-aware and monitoring |
| Castiglione, Umer [107] | Presenting a technique that gathers data from health centers and saves it to a data warehouse for analysis using ML |
-0.754 precision -0.794 recall -0.810 recall -F-score of 0.802 |
-Low security -Low flexibility |
No | Python using Scikit-learn |
Real-time dataset (Small dataset) |
No | Random forest | Monitoring COVID-19 |