Datasets:

HowardZhangdqs
/

sign_language_comparison_table_modified

	import cv2
	import numpy as np
	import os
	from pathlib import Path

	def process_image(image_path, output_dir="segmented_images"):
	"""
	Process an image by binarizing it, finding horizontal lines with 80%+ black pixels,
	and segmenting the image at those lines.

	Args:
	image_path (str): Path to the input image
	output_dir (str): Directory to save segmented images
	"""

	# Read the image
	img = cv2.imread(image_path)
	if img is None:
	print(f"Error: Could not read image from {image_path}")
	return

	print(f"Processing image: {image_path}")
	print(f"Original image shape: {img.shape}")

	# Convert to grayscale
	gray = cv2.cvtColor(img, cv2.COLOR_BGR2GRAY)

	# Apply binary thresholding (binarization)
	# Using THRESH_BINARY_INV so that text/lines become white (255) and background becomes black (0)
	_, binary = cv2.threshold(gray, 127, 255, cv2.THRESH_BINARY_INV)

	# Create morphological kernel for dilation (10px)
	kernel = np.ones((10, 10), np.uint8)

	# Apply dilation to expand black regions
	dilated = cv2.dilate(binary, kernel, iterations=1)

	# Create horizontal kernel for connecting broken lines (40px horizontal)
	horizontal_kernel = np.ones((1, 40), np.uint8)

	# Apply horizontal dilation to connect broken line segments
	dilated_horizontal = cv2.dilate(dilated, horizontal_kernel, iterations=1)

	# Display the binary and dilated images
	cv2.imshow('Original', img)
	cv2.imshow('Binary', binary)
	cv2.imshow('Dilated (10px)', dilated)
	cv2.imshow('Dilated Horizontal (40px)', dilated_horizontal)
	cv2.waitKey(0)
	cv2.destroyAllWindows()

	# Get image dimensions
	height, width = dilated_horizontal.shape

	# Find lines where black pixels exceed 70% of width
	cut_lines = []
	threshold = width * 0.8

	for y in range(height):
	# Count black pixels (value > 0 in dilated_horizontal image, since we used THRESH_BINARY_INV)
	black_pixel_count = np.sum(dilated_horizontal[y, :] > 0)

	if black_pixel_count >= threshold:
	cut_lines.append(y)

	print(f"Found {len(cut_lines)} rows with 70%+ black pixels")

	if not cut_lines:
	print("No cut lines found. Saving original image.")
	# Create output directory
	os.makedirs(output_dir, exist_ok=True)
	base_name = Path(image_path).stem
	output_path = os.path.join(output_dir, f"{base_name}_segment_0.png")
	cv2.imwrite(output_path, img)
	return

	# Group consecutive cut lines to find actual separation boundaries
	# Also enforce minimum 600px distance between separation lines
	separation_lines = []
	if cut_lines:
	current_group = [cut_lines[0]]

	for i in range(1, len(cut_lines)):
	if cut_lines[i] - cut_lines[i-1] <= 5: # Lines within 5 pixels are considered same group
	current_group.append(cut_lines[i])
	else:
	# End of current group, add middle line
	middle_line = current_group[len(current_group)//2]
	separation_lines.append(middle_line)
	current_group = [cut_lines[i]]

	# Don't forget the last group
	if current_group:
	middle_line = current_group[len(current_group)//2]
	separation_lines.append(middle_line)

	# Filter separation lines to ensure minimum 600px distance
	filtered_separation_lines = []
	for line_y in separation_lines:
	# Check if this line is at least 600px away from all previously accepted lines
	valid = True
	for prev_line in filtered_separation_lines:
	if abs(line_y - prev_line) < 600:
	valid = False
	break

	if valid:
	filtered_separation_lines.append(line_y)

	separation_lines = filtered_separation_lines

	print(f"Identified {len(separation_lines)} separation lines at rows: {separation_lines}")

	# Create output directory
	os.makedirs(output_dir, exist_ok=True)

	# Segment the image at separation lines
	base_name = Path(image_path).stem

	# Define segment boundaries
	segments = []
	start_y = 0

	for line_y in separation_lines:
	if line_y > start_y + 20: # Minimum segment height of 20 pixels
	segments.append((start_y, line_y))
	start_y = line_y + 1

	# Add the last segment
	if start_y < height - 20:
	segments.append((start_y, height))

	print(f"Creating {len(segments)} segments")

	# Save each segment
	for i, (start_y, end_y) in enumerate(segments):
	segment = img[start_y:end_y, :]
	output_path = os.path.join(output_dir, f"{base_name}_segment_{i}.png")
	cv2.imwrite(output_path, segment)
	print(f"Saved segment {i}: rows {start_y}-{end_y} to {output_path}")

	# Also save the processed binary and dilated images for debugging
	debug_dir = os.path.join(output_dir, "debug")
	os.makedirs(debug_dir, exist_ok=True)

	cv2.imwrite(os.path.join(debug_dir, f"{base_name}_binary.png"), binary)
	cv2.imwrite(os.path.join(debug_dir, f"{base_name}_dilated.png"), dilated)
	cv2.imwrite(os.path.join(debug_dir, f"{base_name}_dilated_horizontal.png"), dilated_horizontal)

	# Create visualization showing cut lines
	visualization = img.copy()
	for line_y in separation_lines:
	cv2.line(visualization, (0, line_y), (width-1, line_y), (0, 0, 255), 2)
	cv2.imwrite(os.path.join(debug_dir, f"{base_name}_with_cutlines.png"), visualization)

	print(f"Processing complete. Segments saved to {output_dir}")
	return segments

	def main():
	# Process the specific image
	image_path = "/data/scientific_research/sign_language/extracted_pages/page_1076.png"

	if not os.path.exists(image_path):
	print(f"Error: Image file {image_path} not found")
	return

	segments = process_image(image_path)

	if segments:
	print(f"\nSummary:")
	print(f"Original image segmented into {len(segments)} parts")
	for i, (start_y, end_y) in enumerate(segments):
	print(f" Segment {i}: rows {start_y}-{end_y} (height: {end_y-start_y}px)")

	if __name__ == "__main__":
	main()