Optimized Color Classified Colorization with Segment Anything Model (SAM)

The proposed method can be adapted for real-time applications by optimizing the model architecture and training process to ensure efficient and fast colorization of images. This can involve reducing computational complexity, optimizing memory usage, and implementing parallel processing techniques to speed up inference time. Additionally, utilizing hardware acceleration such as GPUs or TPUs can significantly improve the speed of colorization tasks in real-time applications.

While weighted functions can help address class imbalance issues in colorization tasks, there are some potential limitations and drawbacks to consider. One limitation is that determining appropriate weights for each class may require manual tuning or hyperparameter optimization, which can be time-consuming and resource-intensive. Additionally, if not properly implemented, weighted functions may introduce bias towards certain classes or lead to overfitting on rare classes. Moreover, adjusting weights dynamically during training may add complexity to the model optimization process.

Addressing feature imbalance in colorization is crucial for improving overall image quality. By ensuring a balanced representation of different colors and features in the training data through techniques like weighted functions and class re-weighting formulas, the model can learn to predict colors more accurately across various objects and backgrounds. This leads to more realistic and visually appealing colorized images with better saturation levels, reduced desaturation biases, and improved fidelity compared to ground truth references.