WIP: Jump model v8 (#115)

* new jump model with height

* antipeak

* universal n/w jumps

analytics/models/jump_model.py

@@ -6,61 +6,68 @@ import scipy.signal
 from scipy.fftpack import fft
 from scipy.signal import argrelextrema
 import math
+from scipy.stats import gaussian_kde
+from scipy.stats import norm
 
 
-WINDOW_SIZE = 120
+WINDOW_SIZE = 240
 
 class JumpModel(Model):
 
     def __init__(self):
         super()
+        self.segments = []
+        self.ijumps = []
         self.state = {
             'confidence': 1.5,
-            'convolve_max': WINDOW_SIZE
+            'convolve_max': WINDOW_SIZE,
+            'JUMP_HEIGHT': 1,
+            'JUMP_LENGTH': 1,
         }
     
     def fit(self, dataframe, segments):
         self.segments = segments
-        #self.alpha_finder()
         data = dataframe['value']
         confidences = []
         convolve_list = []
+        jump_height_list = []
+        jump_length_list = []
         for segment in segments:
             if segment['labeled']:
-                segment_data = data[segment['start'] : segment['finish'] + 1]
+                segment_data = data[segment['start'] : segment['finish'] + 1].reset_index(drop=True)
                 segment_min = min(segment_data)
                 segment_max = max(segment_data)
                 confidences.append(0.20 * (segment_max - segment_min))
-                flat_segment = segment_data.rolling(window=4).mean() #сглаживаем сегмент
-                kde_segment = flat_data.dropna().plot.kde() # distribution density
-                ax_list = kde_segment.get_lines()[0].get_xydata() #take coordinates of kde
-                mids = argrelextrema(np.array(ax_list), np.less)[0] 
-                maxs = argrelextrema(np.array(ax_list), np.greater)[0]
-                min_peak = maxs[0]
-                max_peak = maxs[1]
-                min_line = ax_list[min_peak, 0]
-                max_line = ax_list[max_peak, 0]
-                sigm_heidht = max_line - min_line
-                pat_sigm = utils.logistic_sigmoid(-WINDOW_SIZE, WINDOW_SIZE, 1, sigm_heidht)
-                for i in range(0, len(pat_sigm)):
-                    pat_sigm[i] = pat_sigm[i] + min_line 
-                cen_ind = utils.intersection_segment(flat_segment, mids[0]) #finds all interseprions with median
-                c = [] # choose the correct one interseption by convolve
-                jump_center = utils.find_jump_center(cen_ind)
-
-                segment_cent_index = jump_center - 4
+                flat_segment = segment_data.rolling(window=5).mean() 
+                pdf = gaussian_kde(flat_segment.dropna())
+                x = np.linspace(flat_segment.dropna().min() - 1, flat_segment.dropna().max() + 1, len(flat_segment.dropna()))
+                y = pdf(x)
+                ax_list = []
+                for i in range(len(x)):
+                    ax_list.append([x[i], y[i]])
+                ax_list = np.array(ax_list, np.float32)
+                antipeaks_kde = argrelextrema(np.array(ax_list), np.less)[0] 
+                peaks_kde = argrelextrema(np.array(ax_list), np.greater)[0]
+                min_peak_index = peaks_kde[0]
+                max_peak_index = peaks_kde[1]
+                segment_median = ax_list[antipeaks_kde[0], 0]                
+                segment_min_line = ax_list[min_peak_index, 0]
+                segment_max_line = ax_list[max_peak_index, 0]
+                jump_height = 0.9 * (segment_max_line - segment_min_line)
+                jump_height_list.append(jump_height)
+                jump_lenght = utils.find_jump_length(segment_data, segment_min_line, segment_max_line)
+                jump_length_list.append(jump_lenght)
+                cen_ind = utils.intersection_segment(flat_segment, segment_median) #finds all interseprions with median
+                #cen_ind =  utils.find_ind_median(segment_median, flat_segment)
+                jump_center = cen_ind[0]
+                segment_cent_index = jump_center - 5 + segment['start']
+                self.ijumps.append(segment_cent_index)
                 labeled_drop = data[segment_cent_index - WINDOW_SIZE : segment_cent_index + WINDOW_SIZE]
                 labeled_min = min(labeled_drop)
-                for value in labeled_drop: # обрезаем
+                for value in labeled_drop:
                     value = value - labeled_min
-                labeled_max = max(labeled_drop)
-                for value in labeled_drop: # нормируем
-                    value = value / labeled_max
                 convolve = scipy.signal.fftconvolve(labeled_drop, labeled_drop)
-                convolve_list.append(max(convolve)) # сворачиваем паттерн
-                # TODO: add convolve with alpha sigmoid
-                # TODO: add size of jump rize
-
+                convolve_list.append(max(convolve))  
 
         if len(confidences) > 0:
             self.state['confidence'] = min(confidences)
@@ -70,14 +77,23 @@ class JumpModel(Model):
         if len(convolve_list) > 0:
             self.state['convolve_max'] = max(convolve_list)
         else:
-            self.state['convolve_max'] = WINDOW_SIZE # макс метрика свертки равна отступу(WINDOW_SIZE), вау!
+            self.state['convolve_max'] = WINDOW_SIZE
+            
+        if len(jump_height_list) > 0:
+            self.state['JUMP_HEIGHT'] = min(jump_height_list)
+        else:
+            self.state['JUMP_HEIGHT'] = 1
+            
+        if len(jump_length_list) > 0:
+            self.state['JUMP_LENGTH'] = max(jump_length_list)
+        else:
+            self.state['JUMP_LENGTH'] = 1   
     
     def predict(self, dataframe):
         data = dataframe['value']
 
         result = self.__predict(data)
         result.sort()
-
         if len(self.segments) > 0:
             result = [segment for segment in result if not utils.is_intersect(segment, self.segments)]
         return result
@@ -86,50 +102,38 @@ class JumpModel(Model):
         window_size = 24
         all_max_flatten_data = data.rolling(window=window_size).mean()
         all_mins = argrelextrema(np.array(all_max_flatten_data), np.less)[0]        
-        possible_jumps = utils.find_all_jumps(all_max_flatten_data, 50, self.state['confidence'])
        
-        '''
-        for i in utils.exponential_smoothing(data + self.state['confidence'], 0.02):
-            extrema_list.append(i)
-
-        segments = []
-        for i in all_mins:
-            if all_max_flatten_data[i] > extrema_list[i]:
-                segments.append(i - window_size)
-        '''
+        possible_jumps = utils.find_jump(data, self.state['JUMP_HEIGHT'], self.state['JUMP_LENGTH'] + 1)
 
         return [(x - 1, x + 1) for x in self.__filter_prediction(possible_jumps, all_max_flatten_data)]
 
     def __filter_prediction(self, segments, all_max_flatten_data):
         delete_list = []
         variance_error = int(0.004 * len(all_max_flatten_data))
-        if variance_error > 200:
-            variance_error = 200
+        if variance_error > 50:
+            variance_error = 50
         for i in range(1, len(segments)):
             if segments[i] < segments[i - 1] + variance_error:
                 delete_list.append(segments[i])
         for item in delete_list:
             segments.remove(item)
-
-        # изменить секонд делит лист, сделать для свертки с сигмоидой
-        # !!!!!!!!
-        # написать фильтрацию паттернов-джампов! посмотерть каждый сегмент, обрезать его
-        # отнормировать, сравнить с выбранным патерном.
-        # !!!!!!!!
         delete_list = []
-        pattern_data = all_max_flatten_data[segments[0] - WINDOW_SIZE : segments[0] + WINDOW_SIZE]
+        if len(segments) == 0 or len(self.ijumps) == 0 :
+            segments = []
+            return segments
+        pattern_data = all_max_flatten_data[self.ijumps[0] - WINDOW_SIZE : self.ijumps[0] + WINDOW_SIZE]
         for segment in segments:
+            if segment > WINDOW_SIZE:
                 convol_data = all_max_flatten_data[segment - WINDOW_SIZE : segment + WINDOW_SIZE]
                 conv = scipy.signal.fftconvolve(pattern_data, convol_data)
-            if max(conv) > self.state['convolve_max'] * 1.1 or max(conv) < self.state['convolve_max'] * 0.9:
+                if max(conv) > self.state['convolve_max'] * 1.2 or max(conv) < self.state['convolve_max'] * 0.8:
+                    delete_list.append(segment)
+            else:
                 delete_list.append(segment)
         for item in delete_list:
             segments.remove(item)
         
-        return segments
+        for ijump in self.ijumps:
+            segments.append(ijump)
 
-    def alpha_finder(self, data):
-        """
-        поиск альфы для логистической сигмоиды
-        """
-        pass
+        return segments

analytics/models/step_model.py

@@ -10,10 +10,10 @@ import pickle
 
 
 class StepModel(Model):
-
     def __init__(self):
         super()
         self.segments = []
+        self.idrops = []
         self.state = {
             'confidence': 1.5,
             'convolve_max': 570000
@@ -21,19 +21,26 @@ class StepModel(Model):
 
     def fit(self, dataframe, segments):
         self.segments = segments
+        #dataframe = dataframe.iloc[::-1]
+        d_min = min(dataframe['value'])
+        for i in range(0,len(dataframe['value'])):
+            dataframe.loc[i, 'value'] = dataframe.loc[i, 'value'] - d_min 
         data = dataframe['value']       
+        new_data = []
+        for val in data:
+            new_data.append(val)
         confidences = []
         convolve_list = []
         for segment in segments:
             if segment['labeled']:
-                segment_data = data[segment['start'] : segment['finish'] + 1]
+                segment_data = new_data[segment['start'] : segment['finish'] + 1]
                 segment_min = min(segment_data)
                 segment_max = max(segment_data)
-                confidences.append(0.20 * (segment_max - segment_min))
-                flat_segment = segment_data.rolling(window=5).mean()
-                
-                segment_min_index = flat_segment.idxmin() - 5
-                labeled_drop = data[segment_min_index - 120 : segment_min_index + 120]
+                confidences.append( 0.4*(segment_max - segment_min))
+                flat_segment = segment_data #.rolling(window=5).mean()
+                segment_min_index = flat_segment.index(min(flat_segment)) - 5 + segment['start']
+                self.idrops.append(segment_min_index)
+                labeled_drop = new_data[segment_min_index - 240 : segment_min_index + 240]
                 convolve = scipy.signal.fftconvolve(labeled_drop, labeled_drop)
                 convolve_list.append(max(convolve))
 
@@ -47,7 +54,13 @@ class StepModel(Model):
         else:
             self.state['convolve_max'] = 570000
 
-    def predict(self, dataframe):
+
+    async def predict(self, dataframe):
+        #dataframe = dataframe.iloc[::-1]
+        d_min = min(dataframe['value'])
+        for i in range(0,len(dataframe['value'])):
+            dataframe.loc[i, 'value'] = dataframe.loc[i, 'value'] - d_min
+
         data = dataframe['value']
 
         result = self.__predict(data)
@@ -60,24 +73,30 @@ class StepModel(Model):
     def __predict(self, data):
         window_size = 24
         all_max_flatten_data = data.rolling(window=window_size).mean()
+        new_flat_data = []
+        for val in all_max_flatten_data:
+            new_flat_data.append(val)
+            
         all_mins = argrelextrema(np.array(all_max_flatten_data), np.less)[0]
-        extrema_list = []
         
-        for i in utils.exponential_smoothing(data - self.state['confidence'], 0.03):
+        extrema_list = []
+        for i in utils.exponential_smoothing(data - self.state['confidence'], 0.01):
             extrema_list.append(i)
+        #extrema_list = extrema_list[::-1]
 
         segments = []
         for i in all_mins:
-            if all_max_flatten_data[i] < extrema_list[i]:
-                segments.append(i - window_size)
+            if new_flat_data[i] < extrema_list[i]:
+                segments.append(i) #-window_size
+        
 
-        return [(x - 1, x + 1) for x in self.__filter_prediction(segments, all_max_flatten_data)]
+        return [(x - 1, x + 1) for x in self.__filter_prediction(segments, new_flat_data)]
 
-    def __filter_prediction(self, segments, all_max_flatten_data):
+    def __filter_prediction(self, segments, new_flat_data):
         delete_list = []
-        variance_error = int(0.004 * len(all_max_flatten_data))
-        if variance_error > 200:
-            variance_error = 200
+        variance_error = int(0.004 * len(new_flat_data))
+        if variance_error > 100:
+            variance_error = 100
         for i in range(1, len(segments)):
             if segments[i] < segments[i - 1] + variance_error:
                 delete_list.append(segments[i])
@@ -85,11 +104,19 @@ class StepModel(Model):
             segments.remove(item)
 
         delete_list = []
-        pattern_data = all_max_flatten_data[segments[0] - 120 : segments[0] + 120]
+        print(self.idrops[0])
+        pattern_data = new_flat_data[self.idrops[0] - 240 : self.idrops[0] + 240]
+        print(self.state['convolve_max'])
         for segment in segments:
-            convol_data = all_max_flatten_data[segment - 120 : segment + 120]
+            if segment > 240:
+                convol_data = new_flat_data[segment - 240 : segment + 240]
                 conv = scipy.signal.fftconvolve(pattern_data, convol_data)
-            if max(conv) > self.state['convolve_max'] * 1.1 or max(conv) < self.state['convolve_max'] * 0.9:
+                if conv[480] > self.state['convolve_max'] * 1.2 or conv[480] < self.state['convolve_max'] * 0.9:
+                    delete_list.append(segment)
+                    print(segment, conv[480], 0)
+                else:
+                    print(segment, conv[480], 1)
+            else:
                 delete_list.append(segment)
         for item in delete_list:
             segments.remove(item)

analytics/utils/__init__.py

@@ -81,6 +81,13 @@ def logistic_sigmoid_distribution(self, x1, x2, alpha, height):
 def logistic_sigmoid(x, alpha, height):
     return height / (1 + math.exp(-x * alpha))
 
+def MyLogisticSigmoid(interval, alpha, heigh):
+    distribution = []
+    for i in range(-interval, interval):
+        F = height / (1 + math.exp(-i * alpha))
+        distribution.append(F)
+    return distribution
+
 def find_one_jump(data, x, size, height, err):
     l = []
     for i in range(x + 1, x + size):
@@ -108,3 +115,44 @@ def find_jump_center(cen_ind):
         if i > 0 and cx > c[i - 1]:
             jump_center = x
     return jump_center
+
+def find_ind_median(median, segment_data):
+    x = np.arange(0, len(segment_data))
+    f = []
+    for i in range(len(segment_data)):
+        f.append(median)
+    f = np.array(f)
+    g = []    
+    for i in segment_data:
+        g.append(i)
+    g = np.array(g)
+    idx = np.argwhere(np.diff(np.sign(f - g)) != 0).reshape(-1) + 0
+    return idx
+
+def find_jump_length(segment_data, min_line, max_line):
+    x = np.arange(0, len(segment_data))
+    f = []
+    l = []
+    for i in range(len(segment_data)):
+        f.append(min_line)
+        l.append(max_line)
+    f = np.array(f)
+    l = np.array(l)
+    g = []    
+    for i in segment_data:
+        g.append(i)
+    g = np.array(g)
+    idx = np.argwhere(np.diff(np.sign(f - g)) != 0).reshape(-1) + 0
+    idl = np.argwhere(np.diff(np.sign(l - g)) != 0).reshape(-1) + 0
+    if (idl[0] - idx[-1] + 1) > 0:
+        return idl[0] - idx[-1] + 1
+    else:
+        return print("retard alert!")
+    
+def find_jump(data, height, lenght):
+    j_list = []
+    for i in range(len(data)-lenght-1):
+        for x in range(1, lenght):
+            if(data[i+x] > data[i] + height):
+                j_list.append(i)
+    return(j_list)