COPEX high rate compression quality metrics
Project description
COPEX High Rate Compression Quality Metrics
This package provides quality metrics for high rate compression.
Installation
pip install COPEX_high_rate_compression_quality_metrics
Library usage
Comparison of Two Multiband TIFF Images via LRSP (L:LPIPS, R:RMSE, S:SSIM, P:PSNR)
the following shows concrete example of use of the library
Steps:
- Import necessary libraries
- Initialize the model and specify the file paths
- Define preprocessing functions
- Load the TIFF files
- Calculate the metrics individually
- Json Builder
1 Library install / import
use "pip install COPEX-high-rate-compression-quality-metrics" to install the library
# Array handler
import numpy as np
# to have a json formated output
import json
import math
# File handler
from skimage import io
# File path handler
import os
# Metrics and utils
import COPEX_high_rate_compression_quality_metrics.metrics as COPEX_metrics
import COPEX_high_rate_compression_quality_metrics.utils as COPEX_utils
2 LPIPS initialization
# LPIPS initialization
loss_fn = COPEX_metrics.initialize_LPIPS()
3 File path definition
# Specify file paths here
file_path1 = os.path.join('T28PGV_20160318T111102_B04_20m.tif')
file_path2 = os.path.join('T28PGV_20160318T111102_B04_20m_ter.tif')
4 File loading
#load images and show shapes
image1 = io.imread(file_path1)
print(file_path1," [shape =",image1.shape,", min =",np.min(image1), ", max =",np.max(image1), ", dtype = ",image1.dtype,"]")
image2 = io.imread(file_path2)
print(file_path2," [shape =",image2.shape,", min =",np.min(image2), ", max =",np.max(image2), ", dtype = ",image2.dtype,"]")
# checking if images have the same shape
if image1.shape != image2.shape:
raise ValueError("Les deux images doivent avoir les mêmes dimensions.")
print("images loaded with success.")
File visualization (optional)
COPEX_utils.display_multiband_tiffs(image1, image2)
5 metrics calculation
# Calculate all metrics
lpips_values,lpips_value = COPEX_metrics.calculate_lpips_multiband(image1, image2,loss_fn)
mean_ssim = COPEX_metrics.calculate_ssim_multiband(image1, image2)
psnr_value = COPEX_metrics.calculate_psnr(image1, image2)
rmse_value = COPEX_metrics.calculate_rmse(image1, image2)
Results interpretation
see VT-P382-SLD-003-E-01-00_COPEX_DCC_PM3_20230630.pdf for more informations about metrics weeknesses
LPIPS : (identical images) 0 <==========> 1 (completely different images) lower is better [very good LPIPS do not mean that images are not totaly different pixel wise]
RMSE : (identical images) 0 <==========> +inf (completely different images) lower is better [different kind of degradations can give the same score, do not capture blurring]
SSIM : (completely different images) -1 <==========> 1 (identical images) higher is better [sensible to little local distorions, sensible to noise differences]
PSNR : (completely different images) 0 <==========> +inf (identical images) higher is better [sensible to Big local differences]
data = {
"files paths":{
"file1":file_path1,
"file2":file_path2
},
"metrics":{
"LPIPS":lpips_value,
"RMSE":rmse_value,
"SSIM":mean_ssim,
"PSNR":str(psnr_value) if math.isinf(psnr_value) else psnr_value
}
}
json_data = json.dumps(data, indent=4)
print(json_data)
{
"files paths": {
"file1": "T28PGV_20160318T111102_B04_20m.tif",
"file2": "T28PGV_20160318T111102_B04_20m_ter.tif"
},
"metrics": {
"LPIPS": 0.038381848484277725,
"RMSE": 192.01308995822703,
"SSIM": 0.9817911582274915,
"PSNR": 26.491058156522357
}
}
Json builder
auto_update the bensh algo json file automaticly
1 import library
import COPEX_high_rate_compression_quality_metrics.json_builder as json_builder
import COPEX_high_rate_compression_quality_metrics.metrics as metrics
2 define pathparameters
root_directory = "data"
dataset_name = "RANDOM"
test_case_number = 4
nnvvppp_algoname = "01-01-002_JPEG2000"
3 calculate generics/thematics in any order you want
#json_builder.initialize_json(root_directory=root_directory, dataset_name=dataset_name,test_case_number=test_case_number,nnvvppp_algoname=nnvvppp_algoname)
json_builder.make_generic(root_directory = root_directory,
dataset_name = dataset_name,
test_case_number = test_case_number,
nnvvppp_algoname = nnvvppp_algoname)
json_builder.make_thematic(root_directory,
dataset_name,
test_case_number,
nnvvppp_algoname,
thematic.compute_kmeans_score_for_multiband,
original_folder_path,
decompressed_folder_path,
satellite_type)
4 look at results
{
"original_size": 525312,
"compressed_size": 48637,
"compression_factor": 10.8,
"compression_time": 253,
"decompression_time": 432,
"compression_algorithm": "01-01-002_JPEG2000",
"algorithm_version": "01",
"compression_parameter": "002",
"metrics": {
"LPIPS": {
"library": "scikit-image",
"version": "0.24.0",
"date": "2024-08-19 16:53:07",
"results": {
"4c_256_256_random_band_1.tif": 0.15013514459133148,
"4c_256_256_random_band_2.tif": 0.1589806228876114,
"4c_256_256_random_band_3.tif": 0.1509121209383011,
"4c_256_256_random_band_4.tif": 0.1467234492301941
},
"average": 0.152,
"stdev": 0.004
},
"SSIM": {
"library": "scikit-image",
"version": "0.24.0",
"date": "2024-08-19 16:53:07",
"results": {
"4c_256_256_random_band_1.tif": 0.01048029893613139,
"4c_256_256_random_band_2.tif": -0.0020971790915714186,
"4c_256_256_random_band_3.tif": 0.007405245569149331,
"4c_256_256_random_band_4.tif": 0.005087706587301147
},
"average": 0.005,
"stdev": 0.005
},
"PSNR": {
"library": "scikit-image",
"version": "0.24.0",
"date": "2024-08-19 16:53:07",
"results": {
"4c_256_256_random_band_1.tif": 7.801028498092282,
"4c_256_256_random_band_2.tif": 7.75118324229439,
"4c_256_256_random_band_3.tif": 7.785848197523122,
"4c_256_256_random_band_4.tif": 7.762412297083275
},
"average": 7.775,
"stdev": 0.019
},
"RMSE": {
"library": "scikit-image",
"version": "0.24.0",
"date": "2024-08-19 16:53:07",
"results": {
"4c_256_256_random_band_1.tif": 26694.50541651717,
"4c_256_256_random_band_2.tif": 26847.72648228625,
"4c_256_256_random_band_3.tif": 26740.79206290665,
"4c_256_256_random_band_4.tif": 26813.04036306841
},
"average": 26774.016,
"stdev": 59.962
}
},
"kmeans++S2-10-10-42": {
"library": "scikit-learn",
"version": "1.5.1",
"date": "2024-09-11 17:18:17",
"original bands": [
"02",
"03",
"04",
"05",
"06",
"07",
"08",
"11",
"12"
],
"resampled bands": [
"05",
"06",
"07",
"11",
"12"
],
"resampled_bands_factor": 2,
"metrics": {
"overall_accuracy": {
"results": {
"S2A_MSIL1C_20200111T105421_N0208_R051_T29NNJ_20200111T123505.kmeans++-10-10-42.tif": 0.6520533690996381
},
"average": 0.652,
"stdev": 0.0
},
"kappa_coefficient": {
"results": {
"S2A_MSIL1C_20200111T105421_N0208_R051_T29NNJ_20200111T123505.kmeans++-10-10-42.tif": 0.5610928393084549
},
"average": 0.561,
"stdev": 0.0
}
}
}
}
Release history Release notifications | RSS feed
Download files
Download the file for your platform. If you're not sure which to choose, learn more about installing packages.
Source Distribution
Built Distribution
File details
Details for the file COPEX_high_rate_compression_quality_metrics-0.4.4.tar.gz.
File metadata
- Download URL: COPEX_high_rate_compression_quality_metrics-0.4.4.tar.gz
- Upload date:
- Size: 36.8 kB
- Tags: Source
- Uploaded using Trusted Publishing? No
- Uploaded via: twine/5.1.1 CPython/3.11.3
File hashes
| Algorithm | Hash digest | |
|---|---|---|
| SHA256 | 6e2032485b0e9e2c32724dc8b81bd0ed9b32745f09ec6868572b955e782298fb |
|
| MD5 | c5c5639a5bb4af02a6c84e60c63c2390 |
|
| BLAKE2b-256 | f02e2ad1a236c162a50053e7209f516b1d40e629d935169b6c30374c95156170 |
Provenance
File details
Details for the file COPEX_high_rate_compression_quality_metrics-0.4.4-py3-none-any.whl.
File metadata
- Download URL: COPEX_high_rate_compression_quality_metrics-0.4.4-py3-none-any.whl
- Upload date:
- Size: 35.2 kB
- Tags: Python 3
- Uploaded using Trusted Publishing? No
- Uploaded via: twine/5.1.1 CPython/3.11.3
File hashes
| Algorithm | Hash digest | |
|---|---|---|
| SHA256 | cd722d80103a4fd812a11615c5cd990d3e22aedb0a4f9d28249b8057aea58b90 |
|
| MD5 | 10bbb8c164887855601119b264c979d0 |
|
| BLAKE2b-256 | c0a79e14d985b1fc8e50d9076706b90942786383700feeb2e2e0b639448cfd08 |
