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import numpy as np |
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from PIL import Image |
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import matplotlib.pyplot as plt |
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import matplotlib.colors as mcolors |
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from scipy.interpolate import interp1d |
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import os |
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import uuid |
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def calculate_intensity(image): |
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""" |
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Calculate the intensity of the image by converting it to grayscale |
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and taking the mean value. |
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""" |
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gray_image = image.convert('L') |
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intensity = np.mean(np.array(gray_image)) |
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return intensity |
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def process_image(image_path): |
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""" |
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Process the image by dividing it into 32x32 grids and calculating normalized intensity. |
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""" |
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image = Image.open(image_path) |
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width, height = image.size |
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grid_width = width // 32 |
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grid_height = height // 32 |
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intensities = [] |
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for y in range(32): |
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row_intensities = [] |
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for x in range(32): |
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left = x * grid_width |
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upper = y * grid_height |
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right = left + grid_width |
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lower = upper + grid_height |
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grid = image.crop((left, upper, right, lower)) |
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intensity = calculate_intensity(grid) |
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row_intensities.append(intensity) |
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intensities.append(row_intensities) |
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intensities = np.array(intensities) |
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min_intensity = intensities.min() |
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max_intensity = intensities.max() |
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normalized_intensities = (intensities - min_intensity) / (max_intensity - min_intensity) |
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return normalized_intensities |
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def intensity_to_oxygen_level(normalized_intensities): |
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""" |
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Map normalized intensity values to oxygen levels using interpolation. |
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""" |
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ksv_values = [0, 0.009303080328, 0.19176, 0.5196879311, 0.6252571452, 0.7115134738, |
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0.8476158622, 0.9531850764, 1.039441405, 1.145010619, 1.175543793, |
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1.231266948, 1.281113007, 1.47293855, 1.609040939] |
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oxygen_levels = [0, 0.68, 1, 2, 2.5, 3, 4, 5, 6, 7.5, 8, 9, 10, 15, 20] |
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min_ksv = min(ksv_values) |
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max_ksv = max(ksv_values) |
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normalized_intensities = (normalized_intensities * (max_ksv - min_ksv)) + min_ksv |
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interp_func = interp1d(ksv_values, oxygen_levels, kind='linear', fill_value='extrapolate') |
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oxygen_levels_mapped = interp_func(normalized_intensities) |
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return oxygen_levels_mapped |
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def generate_heatmap(data, output_path): |
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""" |
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Generate a high-resolution heatmap from data and save it as an image. |
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""" |
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plt.figure(figsize=(10, 8)) |
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plt.imshow(data, cmap='hot', interpolation='nearest', norm=mcolors.Normalize(vmin=0, vmax=20)) |
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plt.colorbar(label='Oxygen Level (%)') |
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plt.savefig(output_path, dpi=300) |
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plt.close() |
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def process_and_generate_heatmap(image): |
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""" |
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Process the image and generate a heatmap, saving the result to a file. |
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""" |
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unique_id = str(uuid.uuid4()) |
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input_dir = 'Gradio_Images' |
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input_image_path = os.path.join(input_dir, f'uploaded_image_{unique_id}.jpg') |
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image.save(input_image_path) |
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normalized_intensities = process_image(input_image_path) |
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oxygen_levels = intensity_to_oxygen_level(normalized_intensities) |
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output_dir = 'Heatmap_Images' |
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output_image_path = os.path.join(output_dir, f'heatmap_{unique_id}.jpg') |
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generate_heatmap(oxygen_levels, output_image_path) |
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return output_image_path |
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