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from models import Model
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import scipy.signal
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from scipy.fftpack import fft
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from scipy.signal import argrelextrema
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import utils
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import numpy as np
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import pickle
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class StepModel(Model):
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def __init__(self):
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super()
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self.segments = []
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self.idrops = []
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self.state = {
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'confidence': 1.5,
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'convolve_max': 570000
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}
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def fit(self, dataframe, segments):
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self.segments = segments
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#dataframe = dataframe.iloc[::-1]
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d_min = min(dataframe['value'])
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for i in range(0,len(dataframe['value'])):
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dataframe.loc[i, 'value'] = dataframe.loc[i, 'value'] - d_min
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data = dataframe['value']
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new_data = []
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for val in data:
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new_data.append(val)
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confidences = []
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convolve_list = []
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for segment in segments:
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if segment['labeled']:
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segment_data = new_data[segment['start'] : segment['finish'] + 1]
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segment_min = min(segment_data)
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segment_max = max(segment_data)
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confidences.append( 0.4*(segment_max - segment_min))
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flat_segment = segment_data #.rolling(window=5).mean()
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segment_min_index = flat_segment.index(min(flat_segment)) - 5 + segment['start']
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self.idrops.append(segment_min_index)
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labeled_drop = new_data[segment_min_index - 240 : segment_min_index + 240]
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convolve = scipy.signal.fftconvolve(labeled_drop, labeled_drop)
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convolve_list.append(max(convolve))
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if len(confidences) > 0:
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self.state['confidence'] = min(confidences)
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else:
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self.state['confidence'] = 1.5
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if len(convolve_list) > 0:
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self.state['convolve_max'] = max(convolve_list)
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else:
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self.state['convolve_max'] = 570000
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async def predict(self, dataframe):
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#dataframe = dataframe.iloc[::-1]
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d_min = min(dataframe['value'])
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for i in range(0,len(dataframe['value'])):
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dataframe.loc[i, 'value'] = dataframe.loc[i, 'value'] - d_min
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data = dataframe['value']
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result = self.__predict(data)
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result.sort()
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if len(self.segments) > 0:
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result = [segment for segment in result if not utils.is_intersect(segment, self.segments)]
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return result
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def __predict(self, data):
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window_size = 24
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all_max_flatten_data = data.rolling(window=window_size).mean()
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new_flat_data = []
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for val in all_max_flatten_data:
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new_flat_data.append(val)
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all_mins = argrelextrema(np.array(all_max_flatten_data), np.less)[0]
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extrema_list = []
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for i in utils.exponential_smoothing(data - self.state['confidence'], 0.01):
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extrema_list.append(i)
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#extrema_list = extrema_list[::-1]
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segments = []
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for i in all_mins:
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if new_flat_data[i] < extrema_list[i]:
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segments.append(i) #-window_size
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return [(x - 1, x + 1) for x in self.__filter_prediction(segments, new_flat_data)]
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def __filter_prediction(self, segments, new_flat_data):
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delete_list = []
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variance_error = int(0.004 * len(new_flat_data))
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if variance_error > 100:
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variance_error = 100
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for i in range(1, len(segments)):
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if segments[i] < segments[i - 1] + variance_error:
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delete_list.append(segments[i])
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for item in delete_list:
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segments.remove(item)
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delete_list = []
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print(self.idrops[0])
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pattern_data = new_flat_data[self.idrops[0] - 240 : self.idrops[0] + 240]
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print(self.state['convolve_max'])
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for segment in segments:
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if segment > 240:
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convol_data = new_flat_data[segment - 240 : segment + 240]
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conv = scipy.signal.fftconvolve(pattern_data, convol_data)
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if conv[480] > self.state['convolve_max'] * 1.2 or conv[480] < self.state['convolve_max'] * 0.9:
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delete_list.append(segment)
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print(segment, conv[480], 0)
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else:
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print(segment, conv[480], 1)
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else:
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delete_list.append(segment)
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for item in delete_list:
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segments.remove(item)
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return segments
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