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newCAM-Emulation

This is a DNN written with PyTorch to Emulate the gravity wave drag (GWD, both zonal and meridional) in the CAM model. The repository contains the code for a machine learning model that emulates the climatic process of gravity wave drag (GWD, both zonal and meridional). The model is a part of parameterization scheme where smaller and highly dynamical climatic processes are emulated using neural networks.

Gravity waves, also called buyoncy waves are formed due to displacement of air in the atmosphere instigated by differnt physical mechanisms, such as moist convection, orographic lifting, shear unstability etc. These waves can propagate both vertically and horizontally through the lift and drag mechanism respectively. This ML model focuses on the drag component of gravity waves.

The long-term goal of the model is to be coupled with a larger fortran-based numerical weather prediction model called the Mid-top CAM Model (Community Atmospheric Model).
https://www.cesm.ucar.edu/models/cam.

Installing

  1. Change your current working directory to the location where you want to clone the repository
     git clone [email protected]:DataWaveProject/newCAM_emulation.git
    to clone via ssh, or
    git clone https://github.com/DataWaveProject/newCAM_emulation.git
    to clone via https
  2. Then run below command to install the neccessary dependencies:
    pip install .
    
  3. (Optional) Install an additional package pre-commit to ensure consistent code format throughout development. If installed, it automatically runs on codebase before committing changes. Run below commands to install pre-commit and it's hooks:
    pip install pre-commit
    pre-commit install
    
    The commands will first install the pre-commit package and then the formatting tools that pre-commit package is using on the code.

Note: It is recommended this is done from inside a virtual environment.

Model Description

Architecture

The machine leaning model is a Feed Forward Neural Network (FFNN) with 10 hidden layers and 500 neurons in each layer. The activation used at each layer is a Sigmoid Linear Unit (SiLU) activation function.

Dataset

The dataset available in the Demodata is a sample output data from CAM. It is 3D global output from the mid-top CAM model, on the original model grid. The demo data here is one very small part of the CAM output and is only for demo purpose.

  • Input variables: pressure levels, latitude, longitude

  • Output variables: zonal drag force, meridional drag force

The data has been split in a ratio of 75:25 into training and validation sets. The input variables have been normalised using mean and standard deviation before feeding them to the model for training. Normalisation allows all the inputs to have similar ranges and distribution, hence preventing variables wiht large numerical scale to dominate the predictions.

Training

The model is trained using the script train.py using the demo data. The optimiser used is an Adam optimiser with a learning rate of 0.001. The data is divided into 128 batches for faster training and effcient memory usage and is run on the model for 100 epochs. The training comprises of an early stopping mechanism that helps prevent overfitting of the model. The loss in making the predictions is quantified in the form of an MSE (mean squared error). The

Repository Layout

The Demodata folder contains the demo data used to train and test the model

The newCAM_emulation folder contains the code that is required to load data, train the model and make predictions which is structured as following:

train.py - train the model

NN-pred.py - predict the GWD using the trained model

loaddata.py - load the data and reshape it to the NN input

model.py - define the NN model

Usage Instructions

To use the repository, following steps are required:

  1. For example, to run the train.py script to train the model, run the below command:
    python3 train.py

Reference Paper:

Data Imbalance, Uncertainty Quantification, and Generalization via Transfer Learning in Data-driven Parameterizations: Lessons from the Emulation of Gravity Wave Momentum Transport in WACCM.

Authors: Y. Qiang Sun and Hamid A. Pahlavan and Ashesh Chattopadhyay and Pedram Hassanzadeh and Sandro W. Lubis and M. Joan Alexander and Edwin Gerber and Aditi Sheshadri and Yifei Guan https://arxiv.org/pdf/2311.17078.pdf

License:

The repository is licensed under MIT License - see the LICENSE file for details.

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emulator for coupling between Python and CAM

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