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2025-AKO/v1_multifailure.py

v1_multifailure.py 15KB
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  1. # Csar Fdez, UdL, 2025

  2. import pandas as pd

  3. import matplotlib.pyplot as plt

  4. import datetime

  5. import numpy as np

  6. import keras

  7. import os.path

  8. import pickle

  9. from keras import layers

  10. from optparse import OptionParser

  11. 

  12. 

  13. parser = OptionParser()

  14. parser.add_option("-t", "--train", dest="train", help="Trains the models (false)", default=False, action="store_true")

  15. 

  16. (options, args) = parser.parse_args()

  17. 

  18. 

  19. # data files arrays. Index:

  20. # 0.  No failure

  21. # 1.  Blocked evaporator

  22. # 2.   Full Blocked condenser

  23. # 3.   Partial Blocked condenser

  24. # 4   Fan condenser not working

  25. # 5.  Open door

  26. 

  27. 

  28. NumberOfFailures=5

  29. NumberOfFailures=4  # So far, we have only data for the first 4 types of failures

  30. datafiles=[]

  31. for i in range(NumberOfFailures+1):

  32.     datafiles.append([])

  33. 

  34. # Next set of ddata corresponds to Freezer, SP=-26

  35. datafiles[0]=['2024-08-07_5_','2024-08-08_5_'] 

  36. datafiles[1]=['2024-12-11_5_', '2024-12-12_5_','2024-12-13_5_','2024-12-14_5_','2024-12-15_5_'] 

  37. datafiles[2]=['2024-12-18_5_','2024-12-19_5_'] 

  38. datafiles[3]=['2024-12-21_5_','2024-12-22_5_','2024-12-23_5_','2024-12-24_5_','2024-12-25_5_','2024-12-26_5_'] 

  39. datafiles[4]=['2024-12-28_5_','2024-12-29_5_','2024-12-30_5_','2024-12-31_5_','2025-01-01_5_'] 

  40. #datafiles[4]=[] 

  41. 

  42. # Features suggested by Xavier

  43. # Care with 'tc s3' because on datafiles[0] is always nulll

  44. # Seems to be incoropored in new tests

  45. 

  46. features=['r1 s1','r1 s4','r1 s5','pa1 apiii']

  47. features=['r1 s1','r1 s2','r1 s3','r1 s4','r1 s5','r1 s6','r1 s7','r1 s8','r1 s9','r1 s10','r2 s1','r2 s2','r2 s3','r2 s4','r2 s5','r2 s6','r2 s7','r2 s8','r2 s9','pa1 apiii','tc s1','tc s2']

  48. 

  49. #features=['r2 s2', 'tc s1','r1 s10','r1 s6','r2 s8']

  50. 

  51. NumFeatures=len(features)

  52. 

  53. df_list=[]

  54. for i in range(NumberOfFailures+1):

  55.     df_list.append([])

  56. 

  57. for i in range(NumberOfFailures+1):

  58.     dftemp=[]

  59.     for f in datafiles[i]:

  60.         print("                 ", f)

  61.         #df1 = pd.read_csv('./data/'+f+'.csv', parse_dates=['datetime'], dayfirst=True, index_col='datetime')

  62.         df1 = pd.read_csv('./data/'+f+'.csv')

  63.         dftemp.append(df1)

  64.     df_list[i]=pd.concat(dftemp)

  65. 

  66. 

  67. # subsampled to 5'  =  30 * 10"

  68. # We consider smaples every 5' because in production, we will only have data at this frequency

  69. subsamplingrate=30

  70. 

  71. dataframe=[]

  72. for i in range(NumberOfFailures+1):

  73.     dataframe.append([])

  74. 

  75. for i in range(NumberOfFailures+1):

  76.     datalength=df_list[i].shape[0]

  77.     dataframe[i]=df_list[i].iloc[range(0,datalength,subsamplingrate)][features]

  78.     dataframe[i].reset_index(inplace=True,drop=True)

  79.     dataframe[i].dropna(inplace=True)

  80. 

  81. 

  82. # Train data is first 2/3 of data

  83. # Test data is: last 1/3 of data 

  84. dataTrain=[]

  85. dataTest=[]

  86. for i in range(NumberOfFailures+1):

  87.     dataTrain.append(dataframe[i].values[0:int(dataframe[i].shape[0]*2/3),:])

  88.     dataTest.append(dataframe[i].values[int(dataframe[i].shape[0]*2/3):,:])

  89. 

  90. 

  91. def normalize2(train,test):

  92.     # merges train and test

  93.     means=[]

  94.     stdevs=[]

  95.     for i in range(NumFeatures):

  96.         means.append(train[:,i].mean())

  97.         stdevs.append(train[:,i].std())

  98.     return( (train-means)/stdevs, (test-means)/stdevs )

  99. 

  100. dataTrainNorm=[]

  101. dataTestNorm=[]

  102. for i in range(NumberOfFailures+1):

  103.     dataTrainNorm.append([])

  104.     dataTestNorm.append([])

  105. 

  106. for i in range(NumberOfFailures+1):

  107.     (dataTrainNorm[i],dataTestNorm[i])=normalize2(dataTrain[i],dataTest[i])

  108. 

  109. def plotData():    

  110.     fig, axes = plt.subplots(

  111.         nrows=NumberOfFailures+1, ncols=2, figsize=(15, 20), dpi=80, facecolor="w", edgecolor="k",sharex=True

  112.     )

  113.     for i in range(NumberOfFailures+1):

  114.         axes[i][0].plot(np.concatenate((dataTrainNorm[i][:,0],dataTestNorm[i][:,0])),label="Fail "+str(i)+",  feature 0")

  115.         axes[i][1].plot(np.concatenate((dataTrainNorm[i][:,1],dataTestNorm[i][:,1])),label="Fail "+str(i)+",  feature 1")

  116.     #axes[1].legend()

  117.     #axes[0].set_ylabel(features[0])

  118.     #axes[1].set_ylabel(features[1])

  119.     #plt.show()

  120. 

  121. #plotData()

  122. 

  123. NumFilters=64

  124. KernelSize=7

  125. DropOut=0.2

  126. ThresholdFactor=1.7

  127. TIME_STEPS = 48

  128. def create_sequences(values, time_steps=TIME_STEPS):

  129.     output = []

  130.     for i in range(len(values) - time_steps + 1):

  131.         output.append(values[i : (i + time_steps)])

  132.     return np.stack(output)

  133. 

  134. x_train=[]

  135. for i in range(NumberOfFailures+1):

  136.     x_train.append(create_sequences(dataTrainNorm[i]))

  137. 

  138. 

  139. model=[]

  140. modelckpt_callback =[]

  141. es_callback =[]

  142. path_checkpoint=[]

  143. 

  144. for i in range(NumberOfFailures+1):

  145.     model.append([])

  146.     model[i] = keras.Sequential(

  147.         [

  148.             layers.Input(shape=(x_train[i].shape[1], x_train[i].shape[2])),

  149.             layers.Conv1D(

  150.                 filters=NumFilters,

  151.                 kernel_size=KernelSize,

  152.                 padding="same",

  153.                 strides=2,

  154.                 activation="relu",

  155.             ),

  156.             layers.Dropout(rate=DropOut),

  157.             layers.Conv1D(

  158.                 filters=int(NumFilters/2),

  159.                 kernel_size=KernelSize,

  160.                 padding="same",

  161.                 strides=2,

  162.                 activation="relu",

  163.             ),

  164.             layers.Conv1DTranspose(

  165.                 filters=int(NumFilters/2),

  166.                 kernel_size=KernelSize,

  167.                 padding="same",

  168.                 strides=2,

  169.                 activation="relu",

  170.             ),

  171.             layers.Dropout(rate=DropOut),

  172.             layers.Conv1DTranspose(

  173.                 filters=NumFilters,

  174.                 kernel_size=KernelSize,

  175.                 padding="same",

  176.                 strides=2,

  177.                 activation="relu",

  178.             ),

  179.             layers.Conv1DTranspose(filters=x_train[i].shape[2], kernel_size=KernelSize, padding="same"),

  180.         ]

  181.     )

  182.     model[i].compile(optimizer=keras.optimizers.Adam(learning_rate=0.001), loss="mse")

  183.     model[i].summary()

  184.     path_checkpoint.append("model_v1_"+str(i)+"._checkpoint.weights.h5")

  185.     es_callback.append(keras.callbacks.EarlyStopping(monitor="val_loss", min_delta=0, patience=15))

  186.     modelckpt_callback.append(keras.callbacks.ModelCheckpoint( monitor="val_loss", filepath=path_checkpoint[i], verbose=1, save_weights_only=True, save_best_only=True,))

  187. 

  188. 

  189. if options.train:

  190.     history=[]

  191.     for i in range(NumberOfFailures+1):

  192.         history.append(model[i].fit( x_train[i], x_train[i], epochs=400, batch_size=128, validation_split=0.3, callbacks=[  es_callback[i], modelckpt_callback[i]      ],))

  193. 

  194.     fig, axes = plt.subplots(

  195.         nrows=int(np.ceil((NumberOfFailures+1)/2)), ncols=2, figsize=(15, 20), dpi=80, facecolor="w", edgecolor="k",sharex=True

  196.     )

  197.     for i in range(int(np.ceil((NumberOfFailures+1)/2))):

  198.         for j in range(2):

  199.             r=2*i+j

  200.             if r < NumberOfFailures+1:

  201.                 axes[i][j].plot(history[r].history["loss"], label="Training Loss")

  202.                 axes[i][j].plot(history[r].history["val_loss"], label="Val Loss")

  203.                 axes[i][j].legend()

  204.     #plt.show()

  205. else:

  206.     for i in range(NumberOfFailures+1):

  207.         model[i].load_weights(path_checkpoint[i])

  208. 

  209. 

  210. x_train_pred=[]

  211. train_mae_loss=[]

  212. threshold=[]

  213. for i in range(NumberOfFailures+1):

  214.     x_train_pred.append(model[i].predict(x_train[i]))

  215.     train_mae_loss.append(np.mean(np.abs(x_train_pred[i] - x_train[i]), axis=1))

  216.     threshold.append(np.max(train_mae_loss[i],axis=0))

  217. 

  218. print("Threshold : ",threshold)

  219. for i in range(NumberOfFailures+1):

  220.     threshold[i]=threshold[i]*ThresholdFactor

  221. 

  222. # Threshold is enlarged because, otherwise, for subsamples at 5' have many false positives

  223. 

  224. 

  225. #  1st scenario. Detect only anomaly.  Later, we will classiffy it

  226. # Test data=  testnormal + testfail1 + testtail2 + testfail3 + testfail4 + testnormal

  227. d=np.vstack((dataTestNorm[0],dataTestNorm[1],dataTestNorm[2],dataTestNorm[3],dataTestNorm[4],dataTestNorm[0]))

  228. 

  229. x_test = create_sequences(d)

  230. x_test_pred = model[0].predict(x_test)

  231. test_mae_loss = np.mean(np.abs(x_test_pred - x_test), axis=1)

  232. 

  233. 

  234. # Define ranges for plotting in different colors

  235. testRanges=[]

  236. r=dataTestNorm[0].shape[0]

  237. testRanges.append([0,r])

  238. for i in range(1,NumberOfFailures+1):

  239.     rnext=r+dataTestNorm[i].shape[0]

  240.     testRanges.append([r,rnext] )

  241.     r=rnext

  242. testRanges.append([r, x_test.shape[0]+TIME_STEPS  ])

  243. 

  244. 

  245. def AtLeastOneTrue(x):

  246.     for i in range(NumFeatures):

  247.         if x[i]:

  248.             return True

  249.     return False

  250. 

  251. anomalies = test_mae_loss > threshold[0]

  252. anomalous_data_indices = []

  253. for i in range(anomalies.shape[0]):

  254.     if AtLeastOneTrue(anomalies[i]):

  255.     #if anomalies[i][0] or anomalies[i][1] or anomalies[i][2] or anomalies[i][3]:

  256.         anomalous_data_indices.append(i)

  257. 

  258. #print(anomalous_data_indices)

  259. 

  260. 

  261. # Let's plot some features

  262. 

  263. colorline=['violet','lightcoral','cyan','lime','grey']

  264. colordot=['darkviolet','red','blue','green','black']

  265. 

  266. featuresToPlot=['r1 s1','r1 s2','r1 s3','pa1 apiii']

  267. #featuresToPlot=features

  268. 

  269. indexesToPlot=[]

  270. for i in featuresToPlot:

  271.     indexesToPlot.append(features.index(i))

  272. 

  273. def plotData2():

  274.     NumFeaturesToPlot=len(indexesToPlot)

  275.     fig, axes = plt.subplots(

  276.         nrows=NumFeaturesToPlot, ncols=1, figsize=(25, 20), dpi=80, facecolor="w", edgecolor="k",sharex=True

  277.     )

  278.     for i in range(NumFeaturesToPlot):

  279.         init=0

  280.         end=len(x_train[0])

  281.         axes[i].plot(range(init,end),x_train[0][:,0,indexesToPlot[i]],label="normal train")

  282.         init=end

  283.         end+=testRanges[0][1]

  284.         axes[i].plot(range(init,end),x_test[testRanges[0][0]:testRanges[0][1],0,indexesToPlot[i]],label="normal test")

  285.         init=end

  286.         end+=(testRanges[1][1]-testRanges[1][0])

  287.         for j in range(1,NumberOfFailures+1):

  288.             axes[i].plot(range(init,end),x_test[testRanges[j][0]:testRanges[j][1],0,indexesToPlot[i]],label="fail type "+str(j), color=colorline[j-1])

  289.             init=end

  290.             end+=(testRanges[j+1][1]-testRanges[j+1][0])

  291.         # Shift TIME_STEPS because detection is performed at the end of time serie

  292.         trail=np.hstack((x_test[:,0,indexesToPlot[i]], x_test[-1:,1:TIME_STEPS,indexesToPlot[i]].reshape(TIME_STEPS-1)))

  293.         axes[i].plot(len(x_train[0])+np.array(anomalous_data_indices)+TIME_STEPS,trail[np.array(anomalous_data_indices)+TIME_STEPS],color='grey',marker='.',linewidth=0,label="abnormal detection" )

  294.         

  295.         init=end-(testRanges[NumberOfFailures+1][1]-testRanges[NumberOfFailures+1][0])

  296.         end=init+(testRanges[0][1]-testRanges[0][0])

  297.         axes[i].plot(range(init,end),x_test[testRanges[0][0]:testRanges[0][1],0,indexesToPlot[i]],color='orange')

  298. 

  299.         if i==0:

  300.             axes[i].legend(bbox_to_anchor=(1, 0.5))

  301.         axes[i].set_ylabel(features[indexesToPlot[i]])

  302.         axes[i].grid()

  303.     plt.show()

  304. 

  305. 

  306. def anomalyMetric(testList):  # first of list is non failure data

  307.     # FP, TP: false/true positive

  308.     # TN, FN: true/false negative

  309.     # Sensitivity: probab failure detection if data is fail: TP/(TP+FN)

  310.     # Specificity: true negative ratio given  data is OK: TN/(TN+FP)

  311. 

  312.     x_test = create_sequences(testList[0])

  313.     x_test_pred = model[0].predict(x_test)

  314.     test_mae_loss = np.mean(np.abs(x_test_pred - x_test), axis=1)

  315.     anomalies = test_mae_loss > threshold[0]

  316.     count=0

  317.     for i in range(anomalies.shape[0]):

  318.         if AtLeastOneTrue(anomalies[i]):

  319.             count+=1

  320.     FP=count

  321.     TN=anomalies.shape[0]-count

  322.     count=0

  323.     TP=np.zeros((NumberOfFailures))

  324.     FN=np.zeros((NumberOfFailures))

  325.     for i in range(1,len(testList)):

  326.         x_test = create_sequences(testList[i])

  327.         x_test_pred = model[0].predict(x_test)

  328.         test_mae_loss = np.mean(np.abs(x_test_pred - x_test), axis=1)

  329.         anomalies = test_mae_loss > threshold[0]

  330.         count=0

  331.         for j in range(anomalies.shape[0]):

  332.             if AtLeastOneTrue(anomalies[j]):

  333.                 count+=1

  334.         TP[i-1] = count

  335.         FN[i-1] = anomalies.shape[0]-count

  336.     Sensitivity=TP.sum()/(TP.sum()+FN.sum())

  337.     Specifity=TN/(TN+FP)

  338.     print("Sensitivity: ",Sensitivity)

  339.     print("Specifity: ",Specifity)

  340.     print("FP: ",FP)

  341.     return Sensitivity+Specifity

  342. 

  343. 

  344. 

  345. anomalyMetric([dataTestNorm[0],dataTestNorm[1],dataTestNorm[2],dataTestNorm[3],dataTestNorm[4]])

  346. plotData2()

  347. 

  348. exit(0)

  349. #   2nd scenario. Go over anomalies and classify it by less error

  350. '''   

  351. #This code works, but too slow

  352. anomalous_data_type=[]

  353. for i in anomalous_data_indices:

  354.     error=[]

  355.     for m in range(1,NumberOfFailures+1):

  356.         error.append(np.mean(np.mean(np.abs(model[m].predict(x_test[i:i+1,:,:])-x_test[i:i+1,:,:]),axis=1)))

  357.     anomalous_data_type.append(np.argmin(error)+1)

  358. '''

  359. 

  360. anomalous_data_type=[]

  361. x_test_predict=[]

  362. for m in range(NumberOfFailures+1):

  363.     x_test_predict.append(model[m].predict(x_test))

  364. 

  365. 

  366. for i in anomalous_data_indices:

  367.     error=[]

  368.     for m in range(1,NumberOfFailures+1):

  369.         error.append(np.mean(np.mean(np.abs(x_test_predict[m][i:i+1,:,:]-x_test[i:i+1,:,:]),axis=1)))

  370.     anomalous_data_type.append(np.argmin(error)+1)

  371. 

  372. 

  373. # For plotting purposes

  374. 

  375. 

  376. anomalous_data_indices_by_failure=[]

  377. for i in range(NumberOfFailures+1):

  378.     anomalous_data_indices_by_failure.append([])

  379. 

  380. for i in range(len(anomalous_data_indices)):

  381.     print(i," ",anomalous_data_type[i])

  382.     anomalous_data_indices_by_failure[anomalous_data_type[i]].append(anomalous_data_indices[i])  

  383. 

  384. 

  385. def plotData3():

  386.     NumFeaturesToPlot=len(indexesToPlot)

  387.     fig, axes = plt.subplots(

  388.         nrows=NumFeaturesToPlot, ncols=1, figsize=(25, 20), dpi=80, facecolor="w", edgecolor="k",sharex=True

  389.     )

  390.     for i in range(NumFeaturesToPlot):

  391.         init=0

  392.         end=len(x_train[0])

  393.         axes[i].plot(range(init,end),x_train[0][:,0,indexesToPlot[i]],label="normal train")

  394.         #axes.plot(range(len(x_train[0]),len(x_train[0])+len(x_test)),x_test[:,0,0],label="abnormal")

  395.         init=end

  396.         end+=testRanges[0][1]

  397.         axes[i].plot(range(init,end),x_test[testRanges[0][0]:testRanges[0][1],0,indexesToPlot[i]],label="normal test")

  398.         init=end

  399.         end+=(testRanges[1][1]-testRanges[1][0])

  400.         for j in range(1,NumberOfFailures+1):

  401.             axes[i].plot(range(init,end),x_test[testRanges[j][0]:testRanges[j][1],0,indexesToPlot[i]],label="fail type "+str(j), color=colorline[j-1])

  402.             init=end

  403.             end+=(testRanges[j+1][1]-testRanges[j+1][0])

  404. 

  405.             axes[i].plot(len(x_train[0])+np.array(anomalous_data_indices_by_failure[j])+TIME_STEPS,x_test[np.array(anomalous_data_indices_by_failure[j])+TIME_STEPS,0,indexesToPlot[i]],color=colordot[j-1],marker='.',linewidth=0,label="abnormal detection type "+str(j))

  406. 

  407.         init=end-(testRanges[NumberOfFailures+1][1]-testRanges[NumberOfFailures+1][0])

  408.         end=init+(testRanges[0][1]-testRanges[0][0])

  409.         axes[i].plot(range(init,end),x_test[testRanges[0][0]:testRanges[0][1],0,indexesToPlot[i]],color='orange')

  410. 

  411.         if i==0:

  412.             axes[i].legend(bbox_to_anchor=(1, 0.5))

  413.         axes[i].set_ylabel(features[indexesToPlot[i]])

  414.         axes[i].grid()

  415.     plt.show()

  416. 

  417. 

  418. 

  419. anomalyMetric([dataTestNorm[0],dataTestNorm[1],dataTestNorm[2],dataTestNorm[3],dataTestNorm[4]])

  420. plotData3()

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