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5 Commits
| Author | SHA1 | Date | |
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c12653e1f7 | ||
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8cf81bcb44 | ||
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92a651b6a6 | ||
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6712506862 | ||
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6e49c2c607 |
@@ -19,6 +19,7 @@ import matplotlib.font_manager
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import matplotlib.pyplot as plt
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import matplotlib.ticker
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import numpy as np
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from scipy.stats import pearsonr
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matplotlib.use('Agg')
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@@ -210,8 +211,8 @@ def plot_compare_frequency(
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ax: plt.Axes, signal1: SignalData, signal2: SignalData, signal1_belt: str, signal2_belt: str, max_freq: float
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) -> None:
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# Plot the two belts PSD signals
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ax.plot(signal1.freqs, signal1.psd, label='Belt ' + signal1_belt, color=KLIPPAIN_COLORS['purple'])
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ax.plot(signal2.freqs, signal2.psd, label='Belt ' + signal2_belt, color=KLIPPAIN_COLORS['orange'])
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ax.plot(signal1.freqs, signal1.psd, label='Belt ' + signal1_belt, color=KLIPPAIN_COLORS['orange'])
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ax.plot(signal2.freqs, signal2.psd, label='Belt ' + signal2_belt, color=KLIPPAIN_COLORS['purple'])
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psd_highest_max = max(signal1.psd.max(), signal2.psd.max())
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@@ -343,14 +344,12 @@ def plot_versus_belts(
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common_freqs: np.ndarray,
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signal1: SignalData,
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signal2: SignalData,
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interp_psd1: np.ndarray,
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interp_psd2: np.ndarray,
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signal1_belt: str,
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signal2_belt: str,
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) -> None:
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ax.set_title('Cross-belts comparison plot', fontsize=14, color=KLIPPAIN_COLORS['dark_orange'], weight='bold')
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max_psd = max(np.max(interp_psd1), np.max(interp_psd2))
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max_psd = max(np.max(signal1.psd), np.max(signal2.psd))
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ideal_line = np.linspace(0, max_psd * 1.1, 500)
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green_boundary = ideal_line + (0.35 * max_psd * np.exp(-ideal_line / (0.6 * max_psd)))
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ax.fill_betweenx(ideal_line, ideal_line, green_boundary, color='green', alpha=0.15)
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@@ -364,8 +363,8 @@ def plot_versus_belts(
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linewidth=2,
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)
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ax.plot(interp_psd1, interp_psd2, color='dimgrey', marker='o', markersize=1.5)
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ax.fill_betweenx(interp_psd2, interp_psd1, color=KLIPPAIN_COLORS['red_pink'], alpha=0.1)
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ax.plot(signal1.psd, signal2.psd, color='dimgrey', marker='o', markersize=1.5)
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ax.fill_betweenx(signal2.psd, signal1.psd, color=KLIPPAIN_COLORS['red_pink'], alpha=0.1)
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paired_peak_count = 0
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unpaired_peak_count = 0
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@@ -374,31 +373,27 @@ def plot_versus_belts(
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label = ALPHABET[paired_peak_count]
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freq1 = signal1.freqs[peak1[0]]
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freq2 = signal2.freqs[peak2[0]]
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nearest_idx1 = np.argmin(np.abs(common_freqs - freq1))
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nearest_idx2 = np.argmin(np.abs(common_freqs - freq2))
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if nearest_idx1 == nearest_idx2:
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psd1_peak_value = interp_psd1[nearest_idx1]
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psd2_peak_value = interp_psd2[nearest_idx1]
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ax.plot(psd1_peak_value, psd2_peak_value, marker='o', color='black', markersize=7)
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if abs(freq1 - freq2) < 1:
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ax.plot(signal1.psd[peak1[0]], signal2.psd[peak2[0]], marker='o', color='black', markersize=7)
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ax.annotate(
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f'{label}1/{label}2',
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(psd1_peak_value, psd2_peak_value),
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(signal1.psd[peak1[0]], signal2.psd[peak2[0]]),
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textcoords='offset points',
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xytext=(-7, 7),
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fontsize=13,
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color='black',
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)
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else:
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psd1_peak_value = interp_psd1[nearest_idx1]
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psd1_on_peak = interp_psd1[nearest_idx2]
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psd2_peak_value = interp_psd2[nearest_idx2]
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psd2_on_peak = interp_psd2[nearest_idx1]
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ax.plot(psd1_on_peak, psd2_peak_value, marker='o', color=KLIPPAIN_COLORS['orange'], markersize=7)
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ax.plot(psd1_peak_value, psd2_on_peak, marker='o', color=KLIPPAIN_COLORS['purple'], markersize=7)
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ax.plot(
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signal1.psd[peak2[0]], signal2.psd[peak2[0]], marker='o', color=KLIPPAIN_COLORS['orange'], markersize=7
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)
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ax.plot(
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signal1.psd[peak1[0]], signal2.psd[peak1[0]], marker='o', color=KLIPPAIN_COLORS['purple'], markersize=7
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)
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ax.annotate(
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f'{label}1',
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(psd1_peak_value, psd2_on_peak),
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(signal1.psd[peak1[0]], signal2.psd[peak1[0]]),
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textcoords='offset points',
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xytext=(0, 7),
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fontsize=13,
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@@ -406,7 +401,7 @@ def plot_versus_belts(
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)
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ax.annotate(
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f'{label}2',
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(psd1_on_peak, psd2_peak_value),
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(signal1.psd[peak2[0]], signal2.psd[peak2[0]]),
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textcoords='offset points',
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xytext=(0, 7),
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fontsize=13,
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@@ -415,16 +410,12 @@ def plot_versus_belts(
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paired_peak_count += 1
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for _, peak_index in enumerate(signal1.unpaired_peaks):
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freq1 = signal1.freqs[peak_index]
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freq2 = signal2.freqs[peak_index]
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nearest_idx1 = np.argmin(np.abs(common_freqs - freq1))
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nearest_idx2 = np.argmin(np.abs(common_freqs - freq2))
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psd1_peak_value = interp_psd1[nearest_idx1]
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psd2_peak_value = interp_psd2[nearest_idx1]
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ax.plot(psd1_peak_value, psd2_peak_value, marker='o', color=KLIPPAIN_COLORS['purple'], markersize=7)
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ax.plot(
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signal1.psd[peak_index], signal2.psd[peak_index], marker='o', color=KLIPPAIN_COLORS['purple'], markersize=7
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)
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ax.annotate(
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str(unpaired_peak_count + 1),
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(psd1_peak_value, psd2_peak_value),
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(signal1.psd[peak_index], signal2.psd[peak_index]),
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textcoords='offset points',
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fontsize=13,
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weight='bold',
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@@ -434,16 +425,12 @@ def plot_versus_belts(
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unpaired_peak_count += 1
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for _, peak_index in enumerate(signal2.unpaired_peaks):
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freq1 = signal1.freqs[peak_index]
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freq2 = signal2.freqs[peak_index]
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nearest_idx1 = np.argmin(np.abs(common_freqs - freq1))
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nearest_idx2 = np.argmin(np.abs(common_freqs - freq2))
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psd1_peak_value = interp_psd1[nearest_idx1]
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psd2_peak_value = interp_psd2[nearest_idx1]
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ax.plot(psd1_peak_value, psd2_peak_value, marker='o', color=KLIPPAIN_COLORS['orange'], markersize=7)
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ax.plot(
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signal1.psd[peak_index], signal2.psd[peak_index], marker='o', color=KLIPPAIN_COLORS['orange'], markersize=7
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)
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ax.annotate(
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str(unpaired_peak_count + 1),
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(psd1_peak_value, psd2_peak_value),
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(signal1.psd[peak_index], signal2.psd[peak_index]),
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textcoords='offset points',
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fontsize=13,
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weight='bold',
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@@ -476,16 +463,21 @@ def plot_versus_belts(
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# Original Klipper function to get the PSD data of a raw accelerometer signal
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def compute_signal_data(data: np.ndarray, max_freq: float) -> SignalData:
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def compute_signal_data(data: np.ndarray, common_freqs: np.ndarray, max_freq: float) -> SignalData:
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helper = shaper_calibrate.ShaperCalibrate(printer=None)
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calibration_data = helper.process_accelerometer_data(data)
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freqs = calibration_data.freq_bins[calibration_data.freq_bins <= max_freq]
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psd = calibration_data.get_psd('all')[calibration_data.freq_bins <= max_freq]
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_, peaks, _ = detect_peaks(psd, freqs, PEAKS_DETECTION_THRESHOLD * psd.max())
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# Re-interpolate the PSD signal to a common frequency range to be able to plot them one against the other
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interp_psd = np.interp(common_freqs, freqs, psd)
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return SignalData(freqs=freqs, psd=psd, peaks=peaks)
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_, peaks, _ = detect_peaks(
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interp_psd, common_freqs, PEAKS_DETECTION_THRESHOLD * interp_psd.max(), window_size=20, vicinity=15
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)
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return SignalData(freqs=common_freqs, psd=interp_psd, peaks=peaks)
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######################################################################
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@@ -517,8 +509,9 @@ def belts_calibration(
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signal2_belt += belt_info.get(signal2_belt, '')
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# Compute calibration data for the two datasets with automatic peaks detection
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signal1 = compute_signal_data(datas[0], max_freq)
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signal2 = compute_signal_data(datas[1], max_freq)
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common_freqs = np.linspace(0, max_freq, 500)
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signal1 = compute_signal_data(datas[0], common_freqs, max_freq)
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signal2 = compute_signal_data(datas[1], common_freqs, max_freq)
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del datas
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# Pair the peaks across the two datasets
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@@ -526,18 +519,13 @@ def belts_calibration(
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signal1 = signal1._replace(paired_peaks=pairing_result.paired_peaks, unpaired_peaks=pairing_result.unpaired_peaks1)
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signal2 = signal2._replace(paired_peaks=pairing_result.paired_peaks, unpaired_peaks=pairing_result.unpaired_peaks2)
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# Re-interpolate the PSD signals to a common frequency range to be able to plot them one against the other point by point
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common_freqs = np.linspace(0, max_freq, 500)
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interp_psd1 = np.interp(common_freqs, signal1.freqs, signal1.psd)
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interp_psd2 = np.interp(common_freqs, signal2.freqs, signal2.psd)
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# Calculating R^2 to y=x line to compute the similarity between the two belts
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ss_res = np.sum((interp_psd2 - interp_psd1) ** 2)
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ss_tot = np.sum((interp_psd2 - np.mean(interp_psd2)) ** 2)
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similarity_factor = (1 - (ss_res / ss_tot)) * 100
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# R² proved to be pretty instable to compute the similarity between the two belts
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# So now, we use the Pearson correlation coefficient to compute the similarity
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correlation, _ = pearsonr(signal1.psd, signal2.psd)
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similarity_factor = correlation * 100
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similarity_factor = np.clip(similarity_factor, 0, 100)
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ConsoleOutput.print(f'Belts estimated similarity: {similarity_factor:.1f}%')
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# mhi = compute_mhi(similarity_factor, num_peaks, num_unpaired_peaks)
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mhi = compute_mhi(similarity_factor, signal1, signal2)
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ConsoleOutput.print(f'[experimental] Mechanical health: {mhi}')
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@@ -582,11 +570,11 @@ def belts_calibration(
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# Add the accel_per_hz value to the title
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title_line5 = f'| Accel per Hz used: {accel_per_hz} mm/s²/Hz'
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fig.text(0.55, 0.915, title_line5, ha='left', va='top', fontsize=14, color=KLIPPAIN_COLORS['dark_purple'])
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fig.text(0.551, 0.915, title_line5, ha='left', va='top', fontsize=10, color=KLIPPAIN_COLORS['dark_purple'])
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# Plot the graphs
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plot_compare_frequency(ax1, signal1, signal2, signal1_belt, signal2_belt, max_freq)
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plot_versus_belts(ax3, common_freqs, signal1, signal2, interp_psd1, interp_psd2, signal1_belt, signal2_belt)
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plot_versus_belts(ax3, common_freqs, signal1, signal2, signal1_belt, signal2_belt)
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# Adding a small Klippain logo to the top left corner of the figure
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ax_logo = fig.add_axes([0.001, 0.894, 0.105, 0.105], anchor='NW')
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Block a user