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@ -27,6 +27,30 @@ class Jumpdetector: |
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self.confidence = 1.5 |
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self.confidence = 1.5 |
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self.convolve_max = 120 |
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self.convolve_max = 120 |
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def intersection_segment(self, data, median): |
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cen_ind = [] |
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for i in range(1, len(data)-1): |
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if data[i-1] < median and data[i+1] > median: |
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cen_ind.append(i) |
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del_ind = [] |
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for i in range(1,len(cen_ind)): |
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if cen_ind[i] == cen_ind[i-1]+1: |
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del_ind.append(i - 1) |
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del_ind = del_ind[::-1] |
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for i in del_ind: |
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del cen_ind[i] |
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return cen_ind |
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def logistic_sigmoid(self, x , y, alpha, height): |
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distribution = [] |
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for i in range(x, y): |
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F = 1 * height / (1 + math.exp(-i * alpha)) |
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distribution.append(F) |
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return distribution |
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def alpha_finder(self, data, ): |
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# поиск альфы для логистической сигмоиды |
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def fit(self, dataframe, segments): |
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def fit(self, dataframe, segments): |
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data = dataframe['value'] |
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data = dataframe['value'] |
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confidences = [] |
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confidences = [] |
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@ -37,7 +61,27 @@ class Jumpdetector: |
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segment_min = min(segment_data) |
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segment_min = min(segment_data) |
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segment_max = max(segment_data) |
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segment_max = max(segment_data) |
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confidences.append(0.20 * (segment_max - segment_min)) |
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confidences.append(0.20 * (segment_max - segment_min)) |
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flat_segment = segment_data.rolling(window=5).mean() #сглаживаем сегмент |
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flat_segment = segment_data.rolling(window=4).mean() #сглаживаем сегмент |
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kde_segment = flat_data.dropna().plot.kde() # distribution density |
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ax = flat_data.dropna().plot.kde() |
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ax_list = ax.get_lines()[0].get_xydata() |
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mids = argrelextrema(np.array(ax_list), np.less)[0] |
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maxs = argrelextrema(np.array(ax_list), np.greater)[0] |
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min_peak = maxs[0] |
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max_peak = maxs[1] |
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min_line = ax_list[min_peak, 0] |
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max_line = ax_list[max_peak, 0] |
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sigm_heidht = max_line - min_line |
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pat_sigm = logistic_sigmoid(-120, 120, 1, sigm_heidht) |
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for i in range(0, len(pat_sigm)): |
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pat_sigm[i] = pat_sigm[i] + min_line |
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cen_ind = self.intersection_segment(flat_segment, mids[0]) |
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c = [] |
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for i in range(len(cen_ind)): |
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x = cen_ind[i] |
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cx = scipy.signal.fftconvolve(pat_sigm, flat_data[x-120:x+120]) |
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c.append(cx[240]) |
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# в идеале нужно посмотреть гистограмму сегмента и выбрать среднее значение, |
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# в идеале нужно посмотреть гистограмму сегмента и выбрать среднее значение, |
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# далее от него брать + -120 |
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# далее от него брать + -120 |
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segment_summ = 0 |
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segment_summ = 0 |
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@ -76,7 +120,7 @@ class Jumpdetector: |
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distribution.append(F) |
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distribution.append(F) |
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return distribution |
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return distribution |
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async def predict(self, dataframe): |
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def predict(self, dataframe): |
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data = dataframe['value'] |
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data = dataframe['value'] |
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result = self.__predict(data) |
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result = self.__predict(data) |
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@ -91,7 +135,7 @@ class Jumpdetector: |
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all_max_flatten_data = data.rolling(window=window_size).mean() |
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all_max_flatten_data = data.rolling(window=window_size).mean() |
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extrema_list = [] |
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extrema_list = [] |
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# добавить все пересечения экспоненты со сглаженным графиком |
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# добавить все пересечения экспоненты со сглаженным графиком |
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# |
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for i in exponential_smoothing(data + self.confidence, 0.02): |
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for i in exponential_smoothing(data + self.confidence, 0.02): |
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extrema_list.append(i) |
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extrema_list.append(i) |
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