GSoc/2022/StatusReports/PhuocKhanhLe: Difference between revisions

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The main idea of IQS in digiKam is to determine the quality of an image and convert it into a score. This score is based on four factors sabotaging image: blur, noise, exposure, and compression. The current approach helps determine whether images are distorted for one of these reasons. However, the current algorithm also presents some drawbacks: It demands lots of fine-tuning from the user’s side and cannot work on the aesthetic image. So, I propose the solution of the deep learning algorithm. While the dataset and the paper for aesthetic image quality assessment are free to use, we are capable of constructing a mathematical model that can learn the pattern of a dataset, hence, predicting the score of quality. As deep learning is an end-to-end solution, it doesn’t require the setting for the hyperparameter. Therefore, we can reduce most of the fine-tuning parts to make this feature easier to use
The main idea of IQS in digiKam is to determine the quality of an image and convert it into a score. This score is based on four factors sabotaging image: blur, noise, exposure, and compression. The current approach helps determine whether images are distorted for one of these reasons. However, the current algorithm also presents some drawbacks: It demands lots of fine-tuning from the user’s side and cannot work on the aesthetic image. So, I propose the solution of the deep learning algorithm. While the dataset and the paper for aesthetic image quality assessment are free to use, we are capable of constructing a mathematical model that can learn the pattern of a dataset, hence, predicting the score of quality. As deep learning is an end-to-end solution, it doesn’t require the setting for the hyperparameter. Therefore, we can reduce most of the fine-tuning parts to make this feature easier to use
== Work report ==
25/07/2022:
Conclusion of first model for Aesthetic Image Quality Assessment.
07/08/2022 :
Feature Aesthetic Detection to classify aesthetic image in digiKam using deep learning model.
30/08/2022 :
Improvement of the model for Aesthetic Image Quality Assessment.
== Links to Blogs and other writing ==
Main merge request:
* https://invent.kde.org/graphics/digikam/-/merge_requests/181
My blog for GSoC :
* https://phuockhanhle.github.io/jekyll/update/2022/06/19/gsoc-2022.html
Research repository for aesthetic image quality assessment:
* https://github.com/phuockhanhle/iqs-digikam

Latest revision as of 23:17, 4 September 2022

DigiKam Image Quality Sorter Algorithms Improvement

The main idea of IQS in digiKam is to determine the quality of an image and convert it into a score. This score is based on four factors sabotaging image: blur, noise, exposure, and compression. The current approach helps determine whether images are distorted for one of these reasons. However, the current algorithm also presents some drawbacks: It demands lots of fine-tuning from the user’s side and cannot work on the aesthetic image. So, I propose the solution of the deep learning algorithm. While the dataset and the paper for aesthetic image quality assessment are free to use, we are capable of constructing a mathematical model that can learn the pattern of a dataset, hence, predicting the score of quality. As deep learning is an end-to-end solution, it doesn’t require the setting for the hyperparameter. Therefore, we can reduce most of the fine-tuning parts to make this feature easier to use

Work report

25/07/2022: Conclusion of first model for Aesthetic Image Quality Assessment.

07/08/2022 : Feature Aesthetic Detection to classify aesthetic image in digiKam using deep learning model.

30/08/2022 : Improvement of the model for Aesthetic Image Quality Assessment.

Links to Blogs and other writing

Main merge request:

My blog for GSoC :

Research repository for aesthetic image quality assessment: