Ejemplo n.º 1
0
 def _localNormalizeData(self,values,names,feat):
   """
     Method to normalize data based on the mean and standard deviation.  If undesired for a particular ROM,
     this method can be overloaded to simply pass (see, e.g., GaussPolynomialRom).
     @ In, values, list, list of feature values (from tdict)
     @ In, names, list, names of features (from tdict)
     @ In, feat, list, list of features (from ROM)
     @ Out, None
   """
   self.muAndSigmaFeatures[feat] = mathUtils.normalizationFactors(values[names.index(feat)])
Ejemplo n.º 2
0
 def _weightAndScaleClusters(self, features, featureGroups, clusterFeatures,
                             weightingStrategy):
     """
   Applies normalization and weighting to cluster training features.
   @ In, features, list(str), ordered list of features
   @ In, featureGroups, dict, hierarchal structure of requested features
   @ In, clusterFeaturs, dict, features mapped to arrays of values (per ROM)
   @ In, weightingStrategy, str, weighting strategy to use in ROM metrics
   @ Out, clusterFeatures, dict, weighted and scaled feature space (destructive on original dict)
 """
     # initialize structure
     weights = np.zeros(len(features))
     for f, feature in enumerate(features):
         # scale the data
         data = np.asarray(clusterFeatures[feature])
         # using Z normalization allows the data that is truly far apart to be streched,
         ## while data that is close together remains clustered.
         ## This does not work well if SMALL relative differences SHOULD make a big difference in clustering,
         ##    or if LARGE relative distances should NOT make a big difference in clustering!
         loc, scale = mathUtils.normalizationFactors(data, mode='z')
         clusterFeatures[feature] = (data - loc) / scale
         # weight the data --> NOTE doesn't really work like we think it does!
         _, metric, ID = feature.split('|', 2)
         if weightingStrategy == 'uniform':
             weight = 1.0
         else:
             # TODO when this gets moved to an input spec, we won't need to check it here.
             ## for now, though, it's the only option.
             self.raiseAnError(
                 RuntimeError,
                 'Unrecognized weighting strategy: "{}"!'.format(
                     weightingStrategy))
         weights[f] = weight
     for f, feature in enumerate(features):
         clusterFeatures[feature] = clusterFeatures[feature] * weights[f]
     return clusterFeatures
Ejemplo n.º 3
0
checkArray('NDInArray %s entry' %str(findSmall),entry,points[1])
found,idx,entry = mathUtils.NDInArray(points,findSmall,tol=1e-3)
checkAnswer('NDInArray %s not found' %str(findSmall),int(found),0)
checkType('NDInArray %s no idx' %str(findSmall),idx,None)
checkType('NDInArray %s no entry' %str(findSmall),entry,None)
found,idx,entry = mathUtils.NDInArray(points,findLarge,tol=1e-8)
checkAnswer('NDInArray %s found' %str(findLarge),int(found),1)
checkAnswer('NDInArray %s idx' %str(findLarge),idx,0)
checkArray('NDInArray %s entry' %str(findLarge),entry,points[0])

### check "normalizationFactors"
zeroList       = [0,0,0,0,0]
fourList       = [4,4,4,4,4]
sequentialList = [0,1,2,3,4]

factors = mathUtils.normalizationFactors(zeroList, mode='z')
checkArray('Z-score normalization zeroList: ', factors, (0,1))
factors = mathUtils.normalizationFactors(zeroList, mode='scale')
checkArray('0-1 scaling zeroList: ', factors, (0,1))
factors = mathUtils.normalizationFactors(zeroList, mode='none')
checkArray('No scaling zeroList: ', factors, (0,1))

factors = mathUtils.normalizationFactors(fourList, mode='z')
checkArray('Z-score normalization fourList: ', factors, (4,4))
factors = mathUtils.normalizationFactors(fourList, mode='scale')
checkArray('0-1 scaling fourList: ', factors, (4,4))
factors = mathUtils.normalizationFactors(fourList, mode='none')
checkArray('No scaling fourList: ', factors, (0,1))

factors = mathUtils.normalizationFactors(sequentialList, mode='z')
checkArray('Z-score normalization sequentialList: ', factors, (2,1.41421356237))