Table 10.
The methods, properties, and features of autoencoders -COVID-19 mechanisms.
| Authors | Main idea | Advantages | Research challenges | Security mechanism? | Dataset | Using TL? | Method | Usage? |
|---|---|---|---|---|---|---|---|---|
| Chen, Zhang [78] | Introducing the autoencoder's hash addressing memory module. | -High robustness | -Need to test on more difficult datasets | No | COVID-19 CT images, X-Ray Images, and reference image database | No | Autoencoder | Detect the anomaly, especially in the case of COVID-19 detection |
| -Low delay | -High complexity | |||||||
| -High accuracy | ||||||||
| Li, Fu [79] | Using autoencoders to extract deeper information from CT images. | -Low response time | -The data set is not very big. | No | COVID-CT dataset includes 275 positive images and 195 negative images. | No | Autoencoder | Detection in chest CT |
| -High accuracy | -Low robustness | |||||||
| Atlam, Torkey [80] | Presenting a Cox regression-based autoencoder technique. | -High accuracy | -High delay | No | There are 1085 patients in this dataset. | No | Autoencode + Cox regression | COVID-19 survival analysis |
| -High scalability | -High energy consumption | |||||||
| Wen, Wang [81] | Using an autoencoder-based anomaly detection technique for COVID-19 surveillance. | -High robustness | -Data is not available because the results of the symptom extraction procedure are considered confidential health information | No | The dataset was compiled from clinical documentation created between January 1st, 2011, and May 1st, 2020. | No | Autoencoder | COVID-19 syndromic surveillance |
| -High accuracy | -Low scalability |