Metadata-Version: 2.4
Name: geospaNN
Version: 0.1.9
Summary: A PyThon implementation of NNGLS
Project-URL: Homepage, https://wentaozhan1998.github.io/geospaNN-doc
Project-URL: Repository, https://github.com/WentaoZhan1998/geospaNN
Project-URL: Issues, https://github.com/WentaoZhan1998/geospaNN/issues
Author-email: Wentao Zhan <wzhan3@jhu.edu>, Abhirup Datta <abhidatta@jhu.edu>
Maintainer-email: Wentao Zhan <wzhan3@jhu.edu>
License-File: LICENSE
Classifier: License :: OSI Approved :: MIT License
Classifier: Natural Language :: English
Classifier: Operating System :: OS Independent
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3.10
Classifier: Programming Language :: Python :: 3.11
Classifier: Programming Language :: Python :: 3.12
Classifier: Topic :: Scientific/Engineering :: Mathematics
Requires-Python: >=3.9
Requires-Dist: matplotlib
Requires-Dist: numpy
Requires-Dist: rpy2
Requires-Dist: scikit-learn
Requires-Dist: scipy
Requires-Dist: seaborn
Requires-Dist: torch-geometric>=2.3.0
Requires-Dist: torch-scatter>=2.1.2
Requires-Dist: torch-sparse>=0.6.18
Requires-Dist: torch>=2.0.0
Description-Content-Type: text/markdown

[![PyPI](https://img.shields.io/pypi/v/geospaNN?logo=PyPI)](https://pypi.org/project/geospaNN)
![PyPI - Python Version](https://img.shields.io/pypi/pyversions/geospaNN)

# GeospaNN - Neural networks for geospatial data
**Authors**: Wentao Zhan (<wzhan3@jhu.edu>), Abhirup Datta (<abhidatta@jhu.edu>)
## A package based on the paper: [Neural networks for geospatial data](https://www.tandfonline.com/doi/abs/10.1080/01621459.2024.2356293?casa_token=UaGsBumw4JAAAAAA:RD4cFpZW7lk3pu8Q5uVdxm5o3_RXWKRLXgxByEgl68qENKJfiNsS_Ci5izQ9WMQkZUKgSXasagyLQw)
**GeospaNN** is a formal implementation of NN-GLS, the Neural Networks for geospatial data proposed in Zhan et.al (2024), 
that explicitly accounts for spatial correlation in the data. The package is developed using [PyTorch](https://pytorch.org/) and 
under the framework of [PyG](https://pytorch-geometric.readthedocs.io/en/latest/) library. 
NN-GLS is a geographically-informed Graph Neural Network (GNN) for analyzing large and irregular geospatial data, 
that combines multi-layer perceptrons, Gaussian processes, and generalized least squares (GLS) loss. 
NN-GLS offers both regression function estimation and spatial prediction, and can scale up to sample sizes of hundreds of thousands. Users are welcome to provide any helpful suggestions and comments.

* The official website (with documentation and running examples) is available at [https://wentaozhan1998.github.io/geospaNN-doc/](https://wentaozhan1998.github.io/geospaNN-doc/).

* A vignette is available at [https://github.com/WentaoZhan1998/geospaNN/blob/main/vignette/vignette.pdf](https://github.com/WentaoZhan1998/geospaNN/blob/main/vignette/vignette.pdf). 

Acknowledgement: This work is supported by National Institute of Environmental Health Sciences grant R01ES033739.

## Overview
The Python package **geospaNN** stands for 'geospatial Neural Networks', where we implement NN-GLS, 
neural networks tailored for analysis of geospatial data that explicitly accounts for spatial dependence (Zhan et.al, 2024). 
Geospatial data naturally exhibits spatial correlation or dependence and traditional geostatistical analysis often relies on 
model-based approaches to handle the spatial dependency, treating the spatial outcome $y(s)$ as a linear regression on covariates $x(s)$ and 
modeling dependency through the spatially correlated errors. 
For example, using Gaussian processes (GP) to model dependent errors, 
simple techniques like kriging can provide powerful prediction performance by properly aggregating the neighboring information. 
On the other hand, artificial Neural Networks (NN), one of the most popular machine learning approaches, could be used to estimate non-linear regression functions. 
However, common neural networks like multi-layer perceptrons (MLP) does not incorporate correlation among data units.

Our package **geospaNN** takes the advantages from both perspectives and provides an efficient tool for geospatial data analysis. 
In NN-GLS, an MLP is used to model the non-linear regression function while a GP is used to model the spatial dependence. 
The resulting loss function then becomes a generalized least squares (GLS) loss informed by the GP covariance matrix, 
thereby explicitly incorporating spatial correlation into the neural network optimization. 
The idea mimics the extension of ordinary least squares (OLS) loss to GLS loss in linear regression for dependent data.

Zhan and Datta, 2024 shows that neural networks with GLS loss can be represented as a graph neural network, 
with the GP covariances guiding the neighborhood aggregation on the output layer. 
Thus NN-GLS is implemented in **geospaNN** with the framework of Graph Neural Networks (GNN), and is highly generalizable. 
(The implementation of geospaNN' uses the 'torch_geom' module.)

**geospaNN** provides an estimate of regression function 𝑓(𝑥) as well as accurate spatial predictions using Gaussian process (kriging), 
and thus constitutes a complete geospatial analysis pipeline. 
To accelerate the training process for the GP, **geospaNN** approximates the working correlation structure using 
Nearest Neighbor Gaussian Process (NNGP) (Datta et al., 2016) which makes it suitable for larger datasets towards a size of 0.5 million.

<div align="center">
<a href="https://www.tandfonline.com/doi/abs/10.1080/01621459.2024.2356293?casa_token=UaGsBumw4JAAAAAA:RD4cFpZW7lk3pu8Q5uVdxm5o3_RXWKRLXgxByEgl68qENKJfiNsS_Ci5izQ9WMQkZUKgSXasagyLQw">
  <img
    src="https://github.com/WentaoZhan1998/geospaNN/blob/main/data/nngls.png?raw=True"
    width="800"
  >
</a>
</div>

## Temporary notes (Updated on Sep 12th 2024)
1. The installation of the package relies on PyTorch and PyG libraries, which for now have to be installed manually.

## Installation
### Create and enter virtual environment (recommended)
1. If you haven't installed anaconda on your machine, refer to this [doc](https://docs.anaconda.com/anaconda/install/), follow the instruction, 
and install the right version.
2. Create the conda virtual environment. Refer to this [doc](https://conda.io/projects/conda/en/latest/user-guide/tasks/manage-environments.html). Example:
```commandline\ 
# bash
conda create -n [name of your environment] python=3.10
```
3. Enter the virtual environment by running:
```commandline\ 
# bash
conda activate [name of your environment]
```
4. In the current version of geospaNN, to use the R-package [BRISC](https://github.com/ArkajyotiSaha/BRISC) 
for spatial parameter estimation (through rpy2), we need R installed in the environment. In order to install R, simply run:
```commandline\ 
# bash
conda install r-base
```
If you already have native R installed, it's also possible to manually initialize R for rpy2. 
See [here](https://rpy2.github.io/doc/latest/html/overview.html#install-installation) for more details.

### Manual dependency installation
(Currently) to install the development version of the package, a pre-installed PyTorch and PyG libraries are needed.
We provide options to install PyG libraries using conda and pip.

#### Option 1: Using Conda
For conda, installation in the following order is recommended. It may take around 10 minutes for conda to solve the environment for pytorch-sparse.
The following chunk has been tested in a python 3.10 environment.
```
#bash
conda install pytorch torchvision -c pytorch
conda install pyg -c pyg        
conda install pytorch-sparse -c pyg 
```

#### Option 2: Using pip
For pip, installation in the following order is recommended to avoid any compilation issue. It may take around 15 minutes to finish the installation.
The following chunk has been tested in a python 3.10 environment.
```
# bash
pip install numpy==1.26 --no-cache-dir
pip install torch==2.0.0 --no-cache-dir
pip install torch-scatter -f https://data.pyg.org/whl/torch-2.0.0.html --no-cache-dir
pip install torch-sparse -f https://data.pyg.org/whl/torch-2.0.0.html --no-cache-dir
pip install torch-cluster -f https://data.pyg.org/whl/torch-2.0.0.html --no-cache-dir
pip install torch_geometric --no-cache-dir
```
<!---
1. To install PyTorch, find and install the binary suitable for your machine [here](https://pytorch.org/).
2. Then to install the PyG library, find and install the proper binary [here](https://pytorch-geometric.readthedocs.io/en/latest/notes/installation.html).
3. Make sure to also install the dependencies including *pyg_lib*, *torch_scatter*, *torch_sparse*, *torch_cluster*, and *torch_spline_conv*.
-->


### Main installation
Once PyTorch and PyG are successfully installed, use the following command in the terminal for the latest version (version 04/2025):
```
pip install https://github.com/WentaoZhan1998/geospaNN/archive/main.zip
```

To install the pypi version, use the following command in the terminal (version 04/2025):
```
pip install geospaNN
```

## An easy running sample (functionality verification):
This is a simple running sample to check the functionality of the package.
First, run python in the terminal:
```commandline\
python
```
import the modules and set up the parameters
1. Define the Friedman's function, and specify the dimension of input covariates.
2. Set the parameters for the spatial process.
3. Set the hyperparameters of the data.
```commandline\
import torch
import geospaNN
import numpy as np

# 1. 
def f5(X): return (10*np.sin(np.pi*X[:,0]*X[:,1]) + 20*(X[:,2]-0.5)**2 + 10*X[:,3] +5*X[:,4])/6

p = 5; funXY = f5

# 2.
sigma = 1
phi = 3/np.sqrt(2)
tau = 0.01
theta = torch.tensor([sigma, phi, tau])

# 3.
n = 1000            # Size of the simulated sample.
nn = 20             # Neighbor size used for NNGP.
batch_size = 50     # Batch size for training the neural networks.
```

Next, simulate and split the data.
1. Simulate the spatially correlated data with spatial coordinates randomly sampled on a [0, 10]^2 squared domain.
2. Order the spatial locations by [max-min ordering](https://projecteuclid.org/journals/statistical-science/volume-36/issue-1/A-General-Framework-for-Vecchia-Approximations-of-Gaussian-Processes/10.1214/19-STS755.full).
3. Build the nearest neighbor graph, as a torch_geometric.data.Data object.
4. Split data into training, validation, testing sets.
```commandline\
# 1.
torch.manual_seed(2024)
X, Y, coord, cov, corerr = geospaNN.Simulation(n, p, nn, funXY, theta, range=[0, 10])

# 2.
X, Y, coord, _ = geospaNN.spatial_order(X, Y, coord, method = 'max-min')

# 3.
data = geospaNN.make_graph(X, Y, coord, nn)

# 4.
data_train, data_val, data_test = geospaNN.split_data(X, Y, coord, neighbor_size=20,
                                                   test_proportion=0.2)
```    

Compose the mlp structure and train easily.
1. Define the mlp structure (torch.nn) to use.
2. Define the NN-GLS corresponding model.
3. Define the NN-GLS training class with learning rate and tolerance.
4. Train the model.
```commandline\
# 1.             
mlp = torch.nn.Sequential(
    torch.nn.Linear(p, 50),
    torch.nn.ReLU(),
    torch.nn.Linear(50, 20),
    torch.nn.ReLU(),
    torch.nn.Linear(20, 10),
    torch.nn.ReLU(),
    torch.nn.Linear(10, 1),
)

# 2.
model = geospaNN.nngls(p=p, neighbor_size=nn, coord_dimensions=2, mlp=mlp, theta=torch.tensor([1.5, 5, 0.1]))

# 3.
nngls_model = geospaNN.nngls_train(model, lr =  0.01, min_delta = 0.001)

# 4.
training_log = nngls_model.train(data_train, data_val, data_test,
                                 Update_init = 10, Update_step = 10)
```

Estimation from the model. The variable is a torch.Tensor object of the same dimension
```commandline\
train_estimate = model.estimate(data_train.x)
```

Kriging prediction from the model. The first variable is supposed to be the data used for training, and the second 
variable a torch_geometric.data.Data object which can be composed by geospaNN.make_graph()'.
```commandline\
test_predict = model.predict(data_train, data_test)
```

## Running examples:
* Python packages time, pandas, seaborn, geopandas, and matplotlib are required to run the following experiments.

* A simulation experiment with a common spatial setting is shown [here](https://github.com/WentaoZhan1998/geospaNN/blob/main/Example_simulation.md).

* For the linear regression case, a performance comparison with the R package [BRISC](https://github.com/ArkajyotiSaha/BRISC) is shown [here](https://github.com/WentaoZhan1998/geospaNN/blob/main/Example_linear.md).

* A real data experiment is shown [here](https://github.com/WentaoZhan1998/geospaNN/blob/main/Example_realdata.md). 

* The PM2.5 data is collected from the [U.S. Environmental Protection Agency](https://www.epa.gov/outdoor-air-quality-data/download-daily-data) datasets for each state are collected and bound together to obtain 'pm25_2022.csv'. daily PM2.5 files are subsets of 'pm25_2022.csv' produced by 'realdata_preprocess.py'. One can skip the preprocessing and use the daily files directory. 

* The meteorological data is collected from the [National Centers for Environmental Prediction’s (NCEP) North American Regional Reanalysis (NARR) product](https://psl.noaa.gov/data/gridded/data.narr.html). The '.nc' (netCDF) files should be downloaded from the website and saved in the root directory to run 'realdata_preprocess.py'. Otherwise, one may skip the preprocessing and use covariate files directly. 

* More running examples are available on the [geospaNN website](https://wentaozhan1998.github.io/geospaNN-doc/Examples/)

## Citation
Please cite the following paper when you use **geospaNN**:

> Zhan, Wentao, and Abhirup Datta. 2024. “Neural Networks for Geospatial Data.” Journal of the American Statistical Association 120 (549): 535–547. https://doi.org/10.1080/01621459.2024.2356293
> 
## References

Datta, Abhirup, Sudipto Banerjee, Andrew O. Finley, and Alan E. Gelfand. 2016. “Hierarchical Nearest-Neighbor Gaussian Process Models for Large Geostatistical Datasets.” Journal of the American Statistical Association 111 (514): 800–812. https://doi.org/10.1080/01621459.2015.1044091.

Zhan, Wentao, and Abhirup Datta. 2024. “Neural Networks for Geospatial Data.” Journal of the American Statistical Association 120 (549): 535–547. https://doi.org/10.1080/01621459.2024.2356293

Katzfuss, Matthias, and Joseph Guinness. 2021. "A General Framework for Vecchia Approximations of Gaussian Processes." Statist. Sci. 36 (1) 124 - 141. https://doi.org/10.1214/19-STS755