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Frechet Coefficient

Project description

Frechet Coefficient

Frechet Coefficient is a Python package for calculating various similarity metrics between images, including Frechet Distance, Frechet Coefficient, and Hellinger Distance. It leverages pre-trained models from TensorFlow's Keras applications and Torchvision to extract features from images.

Table of Contents

Installation

To install the package, use the following command:

pip install frechet-coefficient # if you have TensorFlow or PyTorch
pip install frechet-coefficient[tensorflow] # for TensorFlow support
pip install frechet-coefficient[torch] # for PyTorch support

Requirements:

  • Python 3.10-3.12
  • TensorFlow 2.18.* OR PyTorch 2.5.*
  • imageio 2.36.*
  • numpy >= 2.0.0

Usage

You can use the command-line interface (CLI) to calculate similarity metrics between two directories of images.

frechet-coefficient <path_to_directory1> <path_to_directory2> --metric <metric> [options]

Remember to use enough images to get a meaningful result. If your datasets are small, consider using --random_patches argument to calculate metrics on random patches of images.

Positional Arguments

  • dir1: Path to the first directory of images.
  • dir2: Path to the second directory of images.

Options

  • --metric: Metric to calculate (fd, fc, hd).
  • --batch_size: Batch size for processing images.
  • --num_of_images: Number of images to load from each directory.
  • --as_gray: Load images as grayscale.
  • --random_patches: Calculate metrics on random patches of images.
  • --patch_size: Size of the random patches.
  • --num_of_patch: Number of random patches to extract.
  • --model: Pre-trained model to use as feature extractor (inceptionv3, resnet50v2, xception, densenet201, convnexttiny, efficientnetv2s).
  • --verbose: Enable verbose output.

Example CLI Commands

To calculate the Frechet Distance between two sets of images, use the following command:

frechet-coefficient images/set1 images/set2 --metric fd

To calculate the Frechet Coefficient between two sets of images using the InceptionV3 model, use the following command:

frechet-coefficient images/set1 images/set2 --metric fc --model inceptionv3

To calculate the Hellinger Distance between two sets of images using random patches, use the following command:

frechet-coefficient images/set1 images/set2 --metric hd --random_patches --patch_size 128 --num_of_patch 10000

Python Code

You can also use python code to calculate similarity metrics between two sets of images.

import numpy as np
from typing import List
from frechet_coefficient import ImageSimilarityMetrics, load_images

# Initialize the ImageSimilarityMetrics class
ism = ImageSimilarityMetrics(model='inceptionv3', verbose=0)

images_1: List[np.ndarray] = load_images(path=...) # shape: (num_of_images, height, width, channels)
images_2: List[np.ndarray] = load_images(path=...) # shape: (num_of_images, height, width, channels)

# Calculate Frechet Distance
fd = ism.calculate_frechet_distance(images_1, images_2, batch_size=4)
# Calculate Frechet Coefficient
fc = ism.calculate_frechet_coefficient(images_1, images_2, batch_size=4)
# Calculate Hellinger Distance
hd = ism.calculate_hellinger_distance(images_1, images_2, batch_size=4)

# Calculate means vectors and covariance matrices
mean_1, cov_1 = ism.derive_mean_cov(images_1, batch_size=4)
mean_2, cov_2 = ism.derive_mean_cov(images_2, batch_size=4)

# Calculate metrics using mean vectors and covariance matrices
fd = ism.calculate_fd_with_mean_cov(mean_1, cov_1, mean_2, cov_2)
fc = ism.calculate_fc_with_mean_cov(mean_1, cov_1, mean_2, cov_2)
hd = ism.calculate_hd_with_mean_cov(mean_1, cov_1, mean_2, cov_2)

You can also calculate similarity metrics between two sets of images using random patches.

import numpy as np
from typing import List
from frechet_coefficient import ImageSimilarityMetrics, crop_random_patches, load_images

# Initialize the ImageSimilarityMetrics class
ism = ImageSimilarityMetrics(model='inceptionv3', verbose=0)

images_1: List[np.ndarray] = load_images(path=...) # shape: (num_of_images, height, width, channels)
images_2: List[np.ndarray] = load_images(path=...) # shape: (num_of_images, height, width, channels)

# Crop random patches from images
images_1_patches = crop_random_patches(images_1, size=(128, 128), num_of_patch=10000)
images_2_patches = crop_random_patches(images_2, size=(128, 128), num_of_patch=10000)

# Calculate Frechet Distance
fd = ism.calculate_frechet_distance(images_1_patches, images_2_patches, batch_size=4)
# Calculate Frechet Coefficient
fc = ism.calculate_frechet_coefficient(images_1_patches, images_2_patches, batch_size=4)
# Calculate Hellinger Distance
hd = ism.calculate_hellinger_distance(images_1_patches, images_2_patches, batch_size=4)

Metrics

  • fd: Frechet Distance (with InceptionV3 model is equivalent to FID)
  • fc: Frechet Coefficient
  • hd: Hellinger Distance

The Hellinger Distance is numerically unstable for small datasets. The main reason is poorly estimated covariance matrices. To mitigate this issue, you can use the --random_patches argument to calculate metrics on random patches of images with a very high number of patches (e.g., 50000).

Models

Model Input size Output size Parameters Keras Applications Torchvision
InceptionV3 299x299 2048 23.9M inceptionv3 inception
ResNet50v2 224x224 2048 25.6M resnet not available in PyTorch
Xception 224x224 2048 22.9M xception not available in PyTorch
DenseNet201 224x224 1920 20.2M densenet densenet
ConvNeXtTiny 224x224 768 28.6M convnext convnext
EfficientNetV2S 384x384 1280 21.6M efficientnet efficientnetv2

PyTorch

To set PyTorch device, use the following code:

import os
os.environ["FRECHET_COEFFICIENT_DEVICE_TORCH"] = "cuda" # or "cpu"

# import the package after setting the device

Features

  • Calculate Frechet Distance, Frechet Coefficient, and Hellinger Distance between two sets of images.
  • Support for multiple pre-trained models.
  • Option to calculate metrics on random patches of images.

Citation

If you use this package in your research, please consider citing the following paper:

  • not available yet

License

This project is licensed under the MIT License. See the [LICENSE] file for details.

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