Enhancing the Synthetic Medical Images in Healthcare Using AI-based Exposed GANs with Data Augmentation.
Authors
Affiliations (6)
Affiliations (6)
- Vishwakarma Institute of Technology, Computer Science and Engineering, Pune, India.
- Department of Computer Science, College of Computer Science, Applied College Tanumah, King Khalid University, Abha, Saudi Arabia.
- Department of Electronics Engineering, Gopal Narayan Singh University, Bihar, Mathura, India.
- Department of Electronics and Communication Engineering, GLA University, Mathura, India.
- Army Institute of Technology, Dighi, Pune, India.
- School of Computer Studies, Sri Balaji University, Pune, India.
Abstract
We aim to enhance the accuracy of healthcare AI by generating realistic synthetic medical images using Exposed GANs. One potential issue with synthetic MIG using exposed GANs is that the generated images may not accurately reflect real medical images, which could lead to incorrect medical AI diagnostic decisions. The primary goal of this research is to examine the capacity of GANs for generating synthetic medical images, which can improve the accuracy of healthcare AI systems. It is preferable to collaborate with medical institutions or utilize publicly available datasets from the Medical Segmentation Decathlon (MSD) to obtain medical images for academic research. One well-known pre-processing method for medical image data is normalizing to ensure all pixel values fall within a certain range. In the meantime, the Exposed GAN architecture has been designed to incorporate adversarial aerial training, aiming to produce more realistic medical images by pitting the generator against the discriminator to enhance output quality while improving the discriminator's ability to distinguish between fake and real images. Customization is a more likely research strategy; one can optimize model input parameters and loss functions (or offset the increased computational task of acquiring conditional GANs) at the architecture level. Data augmentation techniques, including random transformations and domain-specific adjustments, are employed to leverage the integration of synthetic data models and enhance the realism and generalization capabilities of the generated images. To enhance the accuracy of healthcare AI using synthetic MIG with exposed GANs, Python code must be implemented to train the GAN model on medical image datasets. The output performances of the discriminator were as follows: discriminator accuracy was 0.6924 on the real data and 0.78789 on the fake data. The average accuracy rate, MPa, was 96.29%, which serves as an evaluation tool for the success of our single-generator GAN in encouraging fabrication applications. There is intense hope that we will be able to unify synthetic MIG-GAN techniques to promote other health AI algorithms for personal applications.