subsample_classify.py

import calculateFeatures
import numpy as np
import laspy as lp
import sys
import send_email
import time
from sklearn.ensemble import RandomForestClassifier
from sklearn import svm
from sklearn.model_selection import train_test_split
from sklearn.metrics import classification_report, confusion_matrix, accuracy_score

start_read = time.time()
# Get current current time
def get_time():
    t = time.localtime()
    current_time = time.strftime("%H:%M:%S", t)
    return current_time

# FILE PATHS
#LAS files
print(f'Reading LAS files... {get_time()}')
classified_pointCloudPath = None #change to las path
nonClassified_pointCloudPath = None #change to las path
#create output txt files
outputErrorRF = '../results/error_RF_multi.txt'
outputErrorSVM = '../results/error_SVM_multi.txt'
#create output csv file
output_path_csv = '../results/multiscale_classified_reduced.csv'
output_path_las = '../results/multiscale_classified_reduced.las'
# Read LAS data
classified_pointCloud = lp.read(classified_pointCloudPath)
nonClassified_pointCloud = lp.read(nonClassified_pointCloudPath)
classified_points_array = np.vstack((classified_pointCloud.x,
                               classified_pointCloud.y,
                               classified_pointCloud.z,
                               classified_pointCloud['normal z'],
                               classified_pointCloud.classification,
                               classified_pointCloud.red,
                               classified_pointCloud.green,
                               classified_pointCloud.blue)).transpose()

nonClassified_pointCloud = lp.read(nonClassified_pointCloudPath)
nonClassified_points_array = np.vstack((nonClassified_pointCloud.x,
                               nonClassified_pointCloud.y,
                               nonClassified_pointCloud.z,
                               nonClassified_pointCloud['normal z'],
                               nonClassified_pointCloud.classification,
                               nonClassified_pointCloud.red,
                               nonClassified_pointCloud.green,
                               nonClassified_pointCloud.blue)).transpose()
# Scales and Radii
grid_sizes = [0.1, 0.2, 0.4]
radii = [0.5, 1.0, 2.0]

print(f'Subsampling classified pc... {get_time()}')
# Subsample the data
classified_subsampled_s1 = calculateFeatures.grid_subsampling_with_color(classified_points_array, grid_sizes[0])
classified_subsampled_s2 = calculateFeatures.grid_subsampling_with_color(classified_points_array, grid_sizes[1])
classified_subsampled_s3 = calculateFeatures.grid_subsampling_with_color(classified_points_array, grid_sizes[2])

print(f'Subsampling nonclassified pc... {get_time()}')
nonClassified_subsampled_s1 = calculateFeatures.grid_subsampling_with_color(nonClassified_points_array, grid_sizes[0])
nonClassified_subsampled_s2 = calculateFeatures.grid_subsampling_with_color(nonClassified_points_array, grid_sizes[1])
nonClassified_subsampled_s3 = calculateFeatures.grid_subsampling_with_color(nonClassified_points_array, grid_sizes[2])

print(f'Calculating geometric features for classified pc... {get_time()}')
# Calculate geometric features for both
classified_features_s1 = calculateFeatures.calculateGeometricFeatures(classified_subsampled_s1, radii[0])
classified_features_s2 = calculateFeatures.calculateGeometricFeatures(classified_subsampled_s2, radii[1])
classified_features_s3 = calculateFeatures.calculateGeometricFeatures(classified_subsampled_s3, radii[2])

print(f'Calculating geometric features for nonclassified pc... {get_time()}')
nonClassified_features_s1 = calculateFeatures.calculateGeometricFeatures(nonClassified_subsampled_s1, radii[0])
nonClassified_features_s2 = calculateFeatures.calculateGeometricFeatures(nonClassified_subsampled_s2, radii[1])
nonClassified_features_s3 = calculateFeatures.calculateGeometricFeatures(nonClassified_subsampled_s3, radii[2])

print(f'Concatenating features... {get_time()}')
# Concatenate the features
classified_Z = np.concatenate([classified_features_s1.get('Z'),classified_features_s2.get('Z'),classified_features_s3.get('Z')])
classified_omnivariance = np.concatenate([classified_features_s1.get('omnivariance'),classified_features_s2.get('omnivariance'),classified_features_s3.get('omnivariance')])
classified_eigenentropy = np.concatenate([classified_features_s1.get('eigenentropy'),classified_features_s2.get('eigenentropy'),classified_features_s3.get('eigenentropy')])
classified_anisotropy = np.concatenate([classified_features_s1.get('anisotropy'),classified_features_s2.get('anisotropy'),classified_features_s3.get('anisotropy')])
classified_linearity = np.concatenate([classified_features_s1.get('linearity'),classified_features_s2.get('linearity'),classified_features_s3.get('linearity')])
classified_planarity = np.concatenate([classified_features_s1.get('planarity'),classified_features_s2.get('planarity'),classified_features_s3.get('planarity')])
classified_curvature = np.concatenate([classified_features_s1.get('curvature'),classified_features_s2.get('curvature'),classified_features_s3.get('curvature')])
classified_sphericity = np.concatenate([classified_features_s1.get('sphericity'),classified_features_s2.get('sphericity'),classified_features_s3.get('sphericity')])
classified_verticality = np.concatenate([classified_features_s1.get('verticality'),classified_features_s2.get('verticality'),classified_features_s3.get('verticality')])
classified_height_range = np.concatenate([classified_features_s1.get('height_range'),classified_features_s2.get('height_range'),classified_features_s3.get('height_range')])
classified_height_avg = np.concatenate([classified_features_s1.get('height_avg'),classified_features_s2.get('height_avg'),classified_features_s3.get('height_avg')])
classified_height_below = np.concatenate([classified_features_s1.get('height_below'),classified_features_s2.get('height_below'),classified_features_s3.get('height_below')])
classified_height_above = np.concatenate([classified_features_s1.get('height_above'),classified_features_s2.get('height_above'),classified_features_s3.get('height_above')])
classified_neighbor_H = np.concatenate([classified_features_s1.get('neighbor_H'),classified_features_s2.get('neighbor_H'),classified_features_s3.get('neighbor_H')])
classified_neighbor_S = np.concatenate([classified_features_s1.get('neighbor_S'),classified_features_s2.get('neighbor_S'),classified_features_s3.get('neighbor_S')])
classified_neighbor_V = np.concatenate([classified_features_s1.get('neighbor_V'),classified_features_s2.get('neighbor_V'),classified_features_s3.get('neighbor_V')])
classified_H_values = np.concatenate([classified_features_s1.get('H'),classified_features_s2.get('H'),classified_features_s3.get('H')])
classified_S_values = np.concatenate([classified_features_s1.get('S'),classified_features_s2.get('S'),classified_features_s3.get('S')])
classified_V_values = np.concatenate([classified_features_s1.get('V'),classified_features_s2.get('V'),classified_features_s3.get('V')])

print(f'Concatenating features... {get_time()}')
nonClassified_X = np.concatenate([nonClassified_features_s1.get('X'),nonClassified_features_s2.get('X'),nonClassified_features_s3.get('X')])
nonClassified_Y = np.concatenate([nonClassified_features_s1.get('Y'),nonClassified_features_s2.get('Y'),nonClassified_features_s3.get('Y')])
nonClassified_Z = np.concatenate([nonClassified_features_s1.get('Z'),nonClassified_features_s2.get('Z'),nonClassified_features_s3.get('Z')])
nonClassified_omnivariance = np.concatenate([nonClassified_features_s1.get('omnivariance'),nonClassified_features_s2.get('omnivariance'),nonClassified_features_s3.get('omnivariance')])
nonClassified_eigenentropy = np.concatenate([nonClassified_features_s1.get('eigenentropy'),nonClassified_features_s2.get('eigenentropy'),nonClassified_features_s3.get('eigenentropy')])
nonClassified_anisotropy = np.concatenate([nonClassified_features_s1.get('anisotropy'),nonClassified_features_s2.get('anisotropy'),nonClassified_features_s3.get('anisotropy')])
nonClassified_linearity = np.concatenate([nonClassified_features_s1.get('linearity'),nonClassified_features_s2.get('linearity'),nonClassified_features_s3.get('linearity')])
nonClassified_planarity = np.concatenate([nonClassified_features_s1.get('planarity'),nonClassified_features_s2.get('planarity'),nonClassified_features_s3.get('planarity')])
nonClassified_curvature = np.concatenate([nonClassified_features_s1.get('curvature'),nonClassified_features_s2.get('curvature'),nonClassified_features_s3.get('curvature')])
nonClassified_sphericity = np.concatenate([nonClassified_features_s1.get('sphericity'),nonClassified_features_s2.get('sphericity'),nonClassified_features_s3.get('sphericity')])
nonClassified_verticality = np.concatenate([nonClassified_features_s1.get('verticality'),nonClassified_features_s2.get('verticality'),nonClassified_features_s3.get('verticality')])
nonClassified_height_range = np.concatenate([nonClassified_features_s1.get('height_range'),nonClassified_features_s2.get('height_range'),nonClassified_features_s3.get('height_range')])
nonClassified_height_avg = np.concatenate([nonClassified_features_s1.get('height_avg'),nonClassified_features_s2.get('height_avg'),nonClassified_features_s3.get('height_avg')])
nonClassified_height_below = np.concatenate([nonClassified_features_s1.get('height_below'),nonClassified_features_s2.get('height_below'),nonClassified_features_s3.get('height_below')])
nonClassified_height_above = np.concatenate([nonClassified_features_s1.get('height_above'),nonClassified_features_s2.get('height_above'),nonClassified_features_s3.get('height_above')])
nonClassified_neighbor_H = np.concatenate([nonClassified_features_s1.get('neighbor_H'),nonClassified_features_s2.get('neighbor_H'),nonClassified_features_s3.get('neighbor_H')])
nonClassified_neighbor_S = np.concatenate([nonClassified_features_s1.get('neighbor_S'),nonClassified_features_s2.get('neighbor_S'),nonClassified_features_s3.get('neighbor_S')])
nonClassified_neighbor_V = np.concatenate([nonClassified_features_s1.get('neighbor_V'),nonClassified_features_s2.get('neighbor_V'),nonClassified_features_s3.get('neighbor_V')])
nonClassified_H_values = np.concatenate([nonClassified_features_s1.get('H'),nonClassified_features_s2.get('H'),nonClassified_features_s3.get('H')])
nonClassified_S_values = np.concatenate([nonClassified_features_s1.get('S'),nonClassified_features_s2.get('S'),nonClassified_features_s3.get('S')])
nonClassified_V_values = np.concatenate([nonClassified_features_s1.get('V'),nonClassified_features_s2.get('V'),nonClassified_features_s3.get('V')])

#Stack features for classification
print(f'Stacking features... {get_time()}')
classified_features = np.vstack((classified_omnivariance,
                    classified_eigenentropy,
                    classified_anisotropy,
                    classified_linearity,
                    classified_planarity,
                    classified_curvature,
                    classified_sphericity,
                    classified_verticality,
                    classified_Z,
                    classified_height_range,
                    classified_height_avg,
                    classified_height_below,
                    classified_height_above,
                    classified_neighbor_H,
                    classified_neighbor_S,
                    classified_neighbor_V,
                    classified_H_values,
                    classified_S_values,
                    classified_V_values)).transpose()

nonClassified_features = np.vstack((nonClassified_omnivariance,
                    nonClassified_eigenentropy,
                    nonClassified_anisotropy,
                    nonClassified_linearity,
                    nonClassified_planarity,
                    nonClassified_curvature,
                    nonClassified_sphericity,
                    nonClassified_verticality,
                    nonClassified_Z,
                    nonClassified_height_range,
                    nonClassified_height_avg,
                    nonClassified_height_below,
                    nonClassified_height_above,
                    nonClassified_neighbor_H,
                    nonClassified_neighbor_S,
                    nonClassified_neighbor_V,
                    nonClassified_H_values,
                    nonClassified_S_values,
                    nonClassified_V_values)).transpose()
# Labels
labels = np.concatenate([classified_features_s1.get('classification'),classified_features_s2.get('classification'),classified_features_s3.get('classification')])

# Train a classifier
X_train, X_test, y_train, y_test = train_test_split(classified_features, labels, test_size=0.2, random_state=42)

# Machine learning models
rf_model = RandomForestClassifier(n_estimators=100, random_state=42)
svm_model = svm.SVC()
# Train the models
print(f'Training models... {get_time()}')
rf_model.fit(X_train, y_train)
svm_model.fit(X_train, y_train)
# Evaluate model
print(f'Evaluating models... {get_time()}')
y_pred_rf = rf_model.predict(X_test)
y_pred_svm = svm_model.predict(X_test)
#Predict the non-classified area
print(f'Predicting non-classified pc... {get_time()}')
predictions_RF = rf_model.predict(nonClassified_features)
predictions_SVM = svm_model.predict(nonClassified_features)
# RF model report
print(f'Writing RF classification performance to file... {get_time()}')
report_RF = classification_report(y_test, y_pred_rf)
matrix_RF = confusion_matrix(y_test, y_pred_rf)
accuracy_RF = accuracy_score(y_test, y_pred_rf)

#Get accuracy results and write to file
with open(outputErrorRF, 'w') as f:
    f.write('Classification Report for Random Forests:\n')
    f.write(report_RF)
    f.write('\nConfusion Matrix:\n')
    f.write(str(matrix_RF))
    f.write(f'\nAccuracy: {accuracy_RF * 100:.2f}%')
# SVM model report
print(f'Writing SVM classification performance to file... {get_time()}')
report_svm = classification_report(y_test, y_pred_svm)
matrix_svm = confusion_matrix(y_test, y_pred_svm)
accuracy_svm = accuracy_score(y_test, y_pred_svm)

# Write the results to file
with open(outputErrorSVM, 'w') as f:
    f.write('Classification Report for SVM:\n')
    f.write(report_svm)
    f.write('\nConfusion Matrix:\n')
    f.write(str(matrix_svm))
    f.write(f'\nAccuracy: {accuracy_svm * 100:.2f}%')

result_output_array= np.vstack((nonClassified_X,
                                nonClassified_Y,
                                nonClassified_Z,
                                predictions_RF,
                                predictions_SVM)).T
print(f'Saving CSV file... {get_time()}')
np.savetxt(output_path_csv,result_output_array,delimiter=',',header='X,Y,Z,RF,GBT',comments='')

done_time = time.time()
try:
    print(f'Saving classified points as LAS... {get_time()}')
    calculateFeatures.saveNP_as_LAS(result_output_array,nonClassified_pointCloud,output_path_las,predictions_RF,predictions_SVM)
except Exception as e:
    print(e)
    send_email.sendNotification('Error in saving classified points as LAS')

# Add mailme to CLI and get an email notification sent when scipt is done
try:
    if len(sys.argv) >1:
        if sys.argv[1]=='mailme':
            send_email.sendNotification(f"""Process finished. Classification of data is done.
                                        \nThe whole process elapsed {round((done_time - start_read)/3600,2)} hours""")
except:
    print("mail was not send, due to API key error")