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
}
}
}
}
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