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33 lines
1.1 KiB
Python
33 lines
1.1 KiB
Python
import numpy as np
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import pandas as pd
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from utils import print_progress
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def find_center(df: pd.DataFrame, center: np.ndarray, initial_radius=1):
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# plt.figure()
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all_particles = df[["X", "Y", "Z"]].to_numpy()
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radius = initial_radius
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center_history = []
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i = 0
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while True:
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center_history.append(center)
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distances = np.linalg.norm(all_particles - center, axis=1)
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in_radius_particles = all_particles[distances < radius]
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num_particles = in_radius_particles.shape[0]
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print_progress(i, "?", f"n={num_particles}, r={radius}, c={center}")
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if num_particles < 10:
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break
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center_of_mass = in_radius_particles.mean(axis=0)
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new_center = (center_of_mass + center) / 2
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shift = np.linalg.norm(center - new_center)
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radius = max(2 * shift, radius * 0.9)
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center = new_center
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i += 1
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center_history = np.array(center_history)
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# print(center_history)
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# plt.scatter(center_history[::, 0], center_history[::, 1], c=range(len(center_history[::, 1])))
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# plt.colorbar(label="step")
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# plt.show()
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print()
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return center
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