89 lines
2.9 KiB
Python
89 lines
2.9 KiB
Python
import numpy as np
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import matplotlib.pyplot as plt
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from matplotlib import colors
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import scipy
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def read_file(file: str) -> np.typing.ArrayLike:
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with open(f'{file}.csv', 'r') as file:
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lines = file.read().split('Channel,Energy,Counts')[1].strip().split('\n')
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return np.array([int(line.split(',,')[1]) for line in lines], dtype=np.uint16)
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all_data = {
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'200': read_file('200'),
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'100': read_file('100-1') + read_file('100-2'),
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'40': sum([read_file(f'40-{i}') for i in range(1, 6)])
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}
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fig, axs = plt.subplots(len(all_data), 1, sharex='col')
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i = 0
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for dwell_time in all_data:
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print(f'\n==[{dwell_time}ms]==\n')
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data = all_data[dwell_time]
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N = len(data)
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print(f'Loaded {sum(data)} events across {N} samples')
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mean = np.mean(data)
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print(f'Found sample mean {mean:0.2f}')
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stdev = np.std(data, ddof=1)
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print(f'Found sample standard deviation {stdev:0.2f}')
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sigma = np.sqrt(mean)
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print(f'Found sigma {sigma:0.2f}')
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P = 0.6745 * sigma
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print(f'Found P {P:0.2f}')
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times_dev_more_than_s = (np.abs(data - mean) > sigma).sum()
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print(f'Found {times_dev_more_than_s} / {N} ({times_dev_more_than_s / N * 100:0.2f}%) samples deviating from the mean more than sigma {sigma:0.2f}')
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times_dev_more_than_P = (np.abs(data - mean) > P).sum()
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print(f'Found {times_dev_more_than_P} / {N} ({times_dev_more_than_P / N * 100:0.2f}%) samples deviating from the mean more than P {P:0.2f}')
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ax = axs[i]
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ax.set_xlabel('Run Count')
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ax.set_ylabel('Events Measured')
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ax.set_title('Raw Data')
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ax.scatter(np.arange(1, len(data)+1), data, s=4)
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ax.legend(['\n'.join([
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f'Mean: {mean:0.2f}',
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f'Sample Sd. Dev: {stdev:0.2f}',
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f'P: {P:0.2f}',
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f'Events > sigma: {times_dev_more_than_s} ({times_dev_more_than_s / N * 100:0.2f}%)',
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f'Events > P: {times_dev_more_than_P} ({times_dev_more_than_P / N * 100:0.2f}%)'
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])])
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# ax = axs[i][1]
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# ax.set_visible(False)
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# ax.set_title(f'Cumulative Average ({dwell_time}ms Dwell time)')
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# ax.set_xlabel('After N Runs')
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# ax.set_ylabel('Cumulative Average')
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# sample_num = np.arange(1, N + 1)
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# cumulative_average = np.cumsum(data) / sample_num
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# ax.plot(sample_num, cumulative_average, label=f'Final Value: {cumulative_average[-1]:0.2f}')
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# ax.legend()
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# ax = axs[i]
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# N, bins, patches = ax.hist(data, density=True, bins=32, label='Measured Data')
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# fracs = N / N.max()
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# norm = colors.Normalize(fracs.min(), fracs.max())
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# for thisfrac, thispatch in zip(fracs, patches):
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# color = plt.cm.viridis(norm(thisfrac))
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# thispatch.set_facecolor(color)
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# ax.set_xlabel('Event Count')
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# ax.set_ylabel('Frequency')
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# linspace = np.arange(bins.min(), bins.max())
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# gaussian = scipy.stats.norm.pdf(linspace, mean, stdev)
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# ax.plot(linspace, gaussian, label='Fitted Gaussian')
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# ax.legend()
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i += 1
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plt.show() |