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https://github.com/shaadclt/energy-output-prediction-multiplelinearregressor

This project involves the prediction of energy output in a Combined Cycle Power Plant (CCPP) using Multiple Linear Regression in Jupyter Notebook. The dataset contains features such as temperature, pressure, humidity, and exhaust vacuum, which are used to predict the net hourly electrical energy output.
https://github.com/shaadclt/energy-output-prediction-multiplelinearregressor

multiple-linear-regression

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This project involves the prediction of energy output in a Combined Cycle Power Plant (CCPP) using Multiple Linear Regression in Jupyter Notebook. The dataset contains features such as temperature, pressure, humidity, and exhaust vacuum, which are used to predict the net hourly electrical energy output.

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# Energy Output Prediction of CCPP using Multiple Linear Regression



This project involves the prediction of energy output in a Combined Cycle Power Plant (CCPP) using Multiple Linear Regression in Jupyter Notebook. The dataset contains features such as temperature, pressure, humidity, and exhaust vacuum, which are used to predict the net hourly electrical energy output. Through this analysis, we aim to build a regression model that accurately predicts the energy output based on the given input features.



## Dataset



The CCPP dataset used for this analysis includes various features related to the operation of a Combined Cycle Power Plant, such as temperature, pressure, humidity, exhaust vacuum, and the net hourly electrical energy output.



## Prerequisites



Before running the code, make sure you have the following dependencies installed:



- Python (3.x)

- Jupyter Notebook

- Pandas

- NumPy

- Matplotlib

- scikit-learn



## Getting Started



To get started, follow the steps below:



1. Clone the repository:



```bash

git clone https://github.com/shaadclt/Energy-Output-Prediction-MultipleLinearRegressor.git

```



2. Change into the project directory:



```bash

cd Energy-Output-Prediction-MultipleLinearRegressor

```



3. Install the required dependencies:



4. Run Jupyter Notebook:



```bash

jupyter notebook

```



5. Open the `Energy Output Prediction.ipynb` notebook in Jupyter.



6. Run the notebook cells to load the dataset, perform data preprocessing, train the Multiple Linear Regression model, and evaluate its performance.



## Analysis Overview



The notebook provides a step-by-step guide to predict the energy output of the CCPP using Multiple Linear Regression. The analysis includes the following tasks:



- Loading and understanding the dataset

- Data cleaning and preprocessing

- Feature selection and transformation

- Splitting the dataset into training and testing sets

- Training the Multiple Linear Regression model

- Evaluating the model's performance using metrics such as mean squared error and R-squared score

- Making predictions on new data points



## Results and Insights



After training the model and evaluating its performance, you will gain insights into how well the Multiple Linear Regression model predicts the energy output based on the given input features. The notebook includes performance metrics and visualizations to assess the accuracy of the model. Feel free to refer to the notebook for detailed results and interpretations.



## Customization



You can customize the analysis to suit your specific requirements. For example, you can experiment with different feature engineering techniques, try different regression algorithms, or incorporate additional features from the dataset to improve the model's accuracy.



## License



This project is licensed under the MIT License. See the `LICENSE` file for more information.



## Acknowledgments



- This analysis is inspired by the need to predict energy output in a Combined Cycle Power Plant based on operating conditions, with potential applications in energy optimization and efficiency.



## Contributing



Contributions are welcome! If you find any issues or have suggestions for improvements, please open an issue or submit a pull request.