# -*- coding: utf-8 -*- # Document info __author__ = 'Andreas Sjölander, Gemini' __version__ = ['1.0'] __version_date__ = '2025-12-01' __maintainer__ = 'Andreas Sjölander' __email__ = 'asjola@kth.se' """ 1b_histogram_plot.py This script reads the segmented masks and plots histograms of the defect size distribution. It generates: 1. Individual plots for all datasets and individual plots for the tunnels TA, TB, TC. 2. A combined subplot figure comparing TA, TB, and TC. The user chose which defect that should be plotted. """ import os import cv2 import numpy as np import matplotlib.pyplot as plt from glob import glob from tqdm import tqdm # ========================================== # CONFIGURATION # ========================================== # 1. SELECT DEFECT TO PLOT # Options: 'Crack', 'Water', 'Leaching' DEFECT_TO_PLOT = 'Crack' # 2. CLASS DEFINITIONS (Pixel Values) CLASS_MAP = { 'Crack': 40, 'Water': 160, 'Leaching': 200 } # ------------------------------------------ # 3. FONT CONFIGURATION (Global) # ------------------------------------------ FONT_PARAMS = { 'suptitle': 18, # Main title for the combined subplot figure 'title': 16, # Title of individual plots 'label': 14, # X and Y axis labels (e.g. "Frequency") 'ticks': 14, # Numbers on the axes 'legend': 14, # Legend text size } # ------------------------------------------ # 4. SETTINGS: INDIVIDUAL PLOTS (One file per tunnel) # ------------------------------------------ INDIV_X_AXIS_MAX = 15000 # Max pixel area on X-axis INDIV_Y_AXIS_MAX = 50 # Max frequency on Y-axis INDIV_BIN_SIZE = 250 # Bin width for single plots # ------------------------------------------ # 5. SETTINGS: SUBPLOT FIGURE (TA, TB, TC combined) # ------------------------------------------ SUBPLOT_X_AXIS_MAX = 15000 # Max pixel area on X-axis SUBPLOT_Y_AXIS_MAX = 70 # Max frequency on Y-axis SUBPLOT_BIN_SIZE = 400 # Bin width for the comparison plot # ========================================== # MAIN SCRIPT # ========================================== def run_histogram_analysis(): # --- 1. Setup Paths --- script_location = os.path.dirname(os.path.abspath(__file__)) root_dir = os.path.dirname(script_location) mask_folder = os.path.join(root_dir, '3_mask') output_dir = os.path.join(root_dir, '2_statistics') # Create output sub-folder for plots to keep it tidy plot_output_dir = os.path.join(output_dir, 'Plots') os.makedirs(plot_output_dir, exist_ok=True) # Get target pixel value if DEFECT_TO_PLOT not in CLASS_MAP: print(f"Error: {DEFECT_TO_PLOT} is not in CLASS_MAP. Choose: {list(CLASS_MAP.keys())}") return target_value = CLASS_MAP[DEFECT_TO_PLOT] print(f"--- Configuration ---") print(f"Target Defect: {DEFECT_TO_PLOT} (Pixel Value: {target_value})") print(f"Source: {mask_folder}") print(f"Output: {plot_output_dir}") print("-" * 30) # --- 2. Data Collection --- data_buckets = { 'Total': [], 'TA': [], 'TB': [], 'TC': [] } # Get files valid_exts = ['*.jpg', '*.jpeg', '*.png', '*.bmp', '*.tiff'] files = [] for ext in valid_exts: files.extend(glob(os.path.join(mask_folder, ext))) if not files: print("No mask files found.") return print("Reading masks and extracting defect sizes...") for filepath in tqdm(files, unit="mask"): # Read image using OpenCV (Grayscale) mask = cv2.imread(filepath, cv2.IMREAD_GRAYSCALE) if mask is None: continue # Count pixels matching the target value defect_pixels = np.sum(mask == target_value) if defect_pixels > 0: filename = os.path.basename(filepath) # Add to Total data_buckets['Total'].append(defect_pixels) # Add to Sub-dataset buckets if filename.startswith('TA'): data_buckets['TA'].append(defect_pixels) elif filename.startswith('TB'): data_buckets['TB'].append(defect_pixels) elif filename.startswith('TC'): data_buckets['TC'].append(defect_pixels) print("-" * 30) # --- 3. Plotting Loop (Individual) --- print("Generating Individual Plots...") for dataset_name, values in data_buckets.items(): if not values: print(f"Skipping {dataset_name}: No defects found.") continue plot_single_histogram( data_values=values, dataset_name=dataset_name, defect_type=DEFECT_TO_PLOT, output_dir=plot_output_dir, x_max=INDIV_X_AXIS_MAX, y_max=INDIV_Y_AXIS_MAX, bin_size=INDIV_BIN_SIZE ) # --- 4. Plotting Subplots (Combined) --- print("Generating Comparison Subplots...") plot_comparison_figure( data_buckets=data_buckets, defect_type=DEFECT_TO_PLOT, output_dir=plot_output_dir, x_max=SUBPLOT_X_AXIS_MAX, y_max=SUBPLOT_Y_AXIS_MAX, bin_size=SUBPLOT_BIN_SIZE ) print("\nProcessing Complete.") def plot_single_histogram(data_values, dataset_name, defect_type, output_dir, x_max, y_max, bin_size): """ Generates and saves a single histogram. """ # Statistics mean_val = np.mean(data_values) median_val = np.median(data_values) max_val = np.max(data_values) plt.figure(figsize=(8, 6)) # --- Bin Calculation --- upper_limit = x_max if x_max else max_val bins = np.arange(0, upper_limit + bin_size, bin_size) # --- Plotting --- plt.hist(data_values, bins=bins, color='#1f77b4', edgecolor='black', alpha=0.7) # Lines for Mean/Median plt.axvline(mean_val, color='red', linestyle='--', linewidth=2, label=f'Mean: {mean_val:.0f}') plt.axvline(median_val, color='orange', linestyle='-', linewidth=2, label=f'Median: {median_val:.0f}') # Labels & Fonts plt.title(f'{defect_type} Size Distribution: {dataset_name}', fontsize=FONT_PARAMS['title'], fontweight='bold') plt.xlabel(f'Defect Area (Pixels)', fontsize=FONT_PARAMS['label']) plt.ylabel('Frequency (Count)', fontsize=FONT_PARAMS['label']) plt.xticks(fontsize=FONT_PARAMS['ticks']) plt.yticks(fontsize=FONT_PARAMS['ticks']) plt.grid(axis='y', alpha=0.5, linestyle='--') plt.legend(fontsize=FONT_PARAMS['legend']) # Axis Limits if x_max: plt.xlim(0, x_max) if y_max: plt.ylim(0, y_max) plt.tight_layout() # --- Save --- filename = f"Hist_{defect_type}_{dataset_name}.png" save_path = os.path.join(output_dir, filename) plt.savefig(save_path, dpi=300, bbox_inches='tight') plt.close() # Save Stats Text txt_filename = f"Stats_{defect_type}_{dataset_name}.txt" with open(os.path.join(output_dir, txt_filename), 'w') as f: f.write(f"Dataset: {dataset_name}\nDefect: {defect_type}\nMean: {mean_val:.2f}\nMedian: {median_val:.2f}\nMax: {max_val}\n") def plot_comparison_figure(data_buckets, defect_type, output_dir, x_max, y_max, bin_size): """ Generates a 1x3 subplot figure comparing TA, TB, and TC. """ tunnels = ['TA', 'TB', 'TC'] # Setup Figure (1 row, 3 columns) fig, axes = plt.subplots(1, 3, figsize=(18, 6), sharey=True) # Use 'suptitle' from FONT_PARAMS fig.suptitle(f'{defect_type} Distribution Comparison (Bin Size: {bin_size}px)', fontsize=FONT_PARAMS['suptitle'], fontweight='bold') for ax, tunnel in zip(axes, tunnels): data = data_buckets.get(tunnel, []) # Handle empty data if not data: ax.text(0.5, 0.5, 'No Data', ha='center', va='center', transform=ax.transAxes, fontsize=FONT_PARAMS['label']) ax.set_title(f"Tunnel {tunnel}", fontsize=FONT_PARAMS['title']) continue # Stats mean_val = np.mean(data) median_val = np.median(data) max_val_local = np.max(data) # Bins upper_limit = x_max if x_max else max_val_local bins = np.arange(0, upper_limit + bin_size, bin_size) # Plot ax.hist(data, bins=bins, color='Steelblue', edgecolor='black', alpha=0.7) # Lines ax.axvline(mean_val, color='red', linestyle='--', linewidth=2, label=f'Mean: {mean_val:.0f}') ax.axvline(median_val, color='orange', linestyle='-', linewidth=2, label=f'Median: {median_val:.0f}') # Formatting with Fonts ax.set_title(f"Tunnel {tunnel} (n={len(data)})", fontsize=FONT_PARAMS['title']) ax.set_xlabel('Defect Area (Pixels)', fontsize=FONT_PARAMS['label']) # Adjust Ticks ax.tick_params(axis='both', which='major', labelsize=FONT_PARAMS['ticks']) ax.grid(axis='y', alpha=0.5, linestyle='--') ax.legend(fontsize=FONT_PARAMS['legend'], loc='upper right') # Axis Limits if x_max: ax.set_xlim(0, x_max) if y_max: ax.set_ylim(0, y_max) # Set Y-label only on the first plot axes[0].set_ylabel('Frequency (Count)', fontsize=FONT_PARAMS['label']) plt.tight_layout(rect=[0, 0.03, 1, 0.95]) # Make space for suptitle # Save filename = f"Hist_Comparison_{defect_type}_TA_TB_TC.png" save_path = os.path.join(output_dir, filename) plt.savefig(save_path, dpi=300, bbox_inches='tight') plt.close() print(f"Comparison plot saved: {filename}") if __name__ == "__main__": run_histogram_analysis()