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🔴 Aim: To develop a machine learning model capable of classifying sugarcane leaves into three categories: Healthy, Red Rot, and Red Rust, utilizing image processing techniques and machine learning algorithms.
🔴 Dataset:
Healthy leaves: 75 Images
Red Rot leaves: 74 Images
Red Rust leaves: 75 Images
Total Images: 224 Images
Exploratory Data Analysis (EDA):
Visualize the distribution of images across different categories.
Display sample images from each category.
Preprocess the images (resizing, sharpening, etc.).
Algorithms to Implement and Compare:
DenseNet201 with SVM-inspired approach:
Use transfer learning with DenseNet201 pre-trained on ImageNet.
Custom classification head with Dense and Dropout layers.
Squared hinge loss function for SVM-inspired classification.
Convolutional Neural Network (CNN):
Build a CNN from scratch.
Use standard layers such as Conv2D, MaxPooling2D, Flatten, Dense, and Dropout.
Random Forest:
Extract features from images using pre-trained models.
Train a Random Forest classifier on the extracted features.
Support Vector Machine (SVM):
Extract features from images using pre-trained models.
Train an SVM classifier on the extracted features.
Model Evaluation:
Compare the models using accuracy scores and other relevant metrics.
Use confusion matrices and classification reports for detailed performance analysis.
Implementation Steps:
Preprocess the dataset (resizing, sharpening).
Perform EDA.
Implement and train the models.
Evaluate and compare the models.
Save the best-performing model.
📍 Follow the Guidelines to Contribute in the Project:
You need to create a separate folder named as the Project Title.
Inside that folder, there will be four main components.
Images - To store the required images.
Dataset - To store the dataset or, information/source about the dataset.
Model - To store the machine learning model you've created using the dataset.
requirements.txt - This file will contain the required packages/libraries to run the project on other machines.
Inside the Model folder, the README.md file must be filled up properly, with proper visualizations and conclusions.
🔴🟡 Points to Note:
The issues will be assigned on a first come first serve basis, 1 Issue == 1 PR.
"Issue Title" and "PR Title should be the same. Include issue number along with it.
Follow Contributing Guidelines & Code of Conduct before starting to contribute.
✅ To be Mentioned while taking the issue:
Full name: Vasudha J
GitHub Profile Link: https://github.com/Vasudha-01
Participant ID (If not, then put NA):
Approach for this Project:
What is your participant role? VSoC, Contributor
Happy Contributing 🚀
All the best. Enjoy your open-source journey ahead. 😎
The text was updated successfully, but these errors were encountered:
Hi @Vasudha-01 thanks for creating the issue but this repository mainly focuses on machine learning models instead of deep learning models. Hence this issue can not be worked on here.
🔴 Project Title: Sugarcane Leaf Disease Detection
🔴 Aim: To develop a machine learning model capable of classifying sugarcane leaves into three categories: Healthy, Red Rot, and Red Rust, utilizing image processing techniques and machine learning algorithms.
🔴 Dataset:
Healthy leaves: 75 Images
Red Rot leaves: 74 Images
Red Rust leaves: 75 Images
Total Images: 224 Images
Exploratory Data Analysis (EDA):
Visualize the distribution of images across different categories.
Display sample images from each category.
Preprocess the images (resizing, sharpening, etc.).
Algorithms to Implement and Compare:
DenseNet201 with SVM-inspired approach:
Use transfer learning with DenseNet201 pre-trained on ImageNet.
Custom classification head with Dense and Dropout layers.
Squared hinge loss function for SVM-inspired classification.
Convolutional Neural Network (CNN):
Build a CNN from scratch.
Use standard layers such as Conv2D, MaxPooling2D, Flatten, Dense, and Dropout.
Random Forest:
Extract features from images using pre-trained models.
Train a Random Forest classifier on the extracted features.
Support Vector Machine (SVM):
Extract features from images using pre-trained models.
Train an SVM classifier on the extracted features.
Model Evaluation:
Compare the models using accuracy scores and other relevant metrics.
Use confusion matrices and classification reports for detailed performance analysis.
Implementation Steps:
Preprocess the dataset (resizing, sharpening).
Perform EDA.
Implement and train the models.
Evaluate and compare the models.
Save the best-performing model.
📍 Follow the Guidelines to Contribute in the Project:
You need to create a separate folder named as the Project Title.
Inside that folder, there will be four main components.
Images - To store the required images.
Dataset - To store the dataset or, information/source about the dataset.
Model - To store the machine learning model you've created using the dataset.
requirements.txt - This file will contain the required packages/libraries to run the project on other machines.
Inside the Model folder, the README.md file must be filled up properly, with proper visualizations and conclusions.
🔴🟡 Points to Note:
The issues will be assigned on a first come first serve basis, 1 Issue == 1 PR.
"Issue Title" and "PR Title should be the same. Include issue number along with it.
Follow Contributing Guidelines & Code of Conduct before starting to contribute.
✅ To be Mentioned while taking the issue:
Full name: Vasudha J
GitHub Profile Link: https://github.com/Vasudha-01
Participant ID (If not, then put NA):
Approach for this Project:
What is your participant role? VSoC, Contributor
Happy Contributing 🚀
All the best. Enjoy your open-source journey ahead. 😎
The text was updated successfully, but these errors were encountered: