# Form feature vectors for training data
trainingInputData, trainingOutputData = util.formFeatureVectors(trainingData)
actualOutputData = minMax.inverse_transform(testingData)[:, 0]
# Initial seed
initialSeedForValidation = trainingData[-1]
networkSize = 500
populationSize = 10
noOfBest = int(populationSize / 2)
noOfGenerations = 10
predictedOutputData, bestPopulation = utilityGA.tuneTrainPredictConnectivityGA(
trainingInputData=trainingInputData,
trainingOutputData=trainingOutputData,
validationOutputData=validationData,
initialInputSeedForValidation=initialSeedForValidation,
horizon=nTesting,
noOfBest=noOfBest,
resTopology=utilityGA.Topology.ErdosRenyi,
size=networkSize,
popSize=populationSize,
maxGeneration=noOfGenerations,
)
predictedOutputData = minMax.inverse_transform(predictedOutputData)
# Plotting of the prediction output and error
outputFolderName = "Outputs/Erdos_Renyi_Outputs" + datetime.now().strftime("%Y_%m_%d_%H_%M_%S")
os.mkdir(outputFolderName)
outplot = outputPlot.OutputPlot(
outputFolderName + "/Prediction.html",
"Mackey-Glass Time Series - GA Optimization)",
"Prediction on Testing data",
from reservoir import GAUtility as utilityGA
from plotting import ScatterPlot as plot
import numpy as np
import os
from datetime import datetime
# File name for
folderName = "Outputs/GAResults_Small_World_Graphs_" + datetime.now().strftime(
"%Y_%m_%d_%H_%M_%S")
os.mkdir(folderName)
# Load the best population from the file
bestPopulation = utilityGA.loadBestPopulation("population.pkl")
# Iterate over all the elements and get the network properties
networkSize = 500
meanDegreeList = []
betaList = []
errorList = []
averageDegreeList = []
averagePathLengthList = []
averageDiameterList = []
averageClusteringCoefficientList = []
for item in bestPopulation:
# Fitness
meanDegree = item[0][0, 0]
beta = item[0][0, 1]
error = item[1]
# Network properties
averageDegree = item[2]['averageDegree']
averagePathLength = item[2]['averagePathLength']
# Split the data into training, validation and testing
trainingData, validationData, testingData = util.splitData(data, 0.5, 0.25, 0.25)
nValidation = validationData.shape[0]
nTesting = testingData.shape[0]
# Form feature vectors for training data
trainingInputData, trainingOutputData = util.formFeatureVectors(trainingData)
actualOutputData = minMax.inverse_transform(testingData)[:,0]
# Initial seed
initialSeedForValidation = trainingData[-1]
predictedOutputData = utilGA.tuneTrainPredictGA(trainingInputData=trainingInputData,
trainingOutputData=trainingOutputData,
validationOutputData=validationData,
initialInputSeedForValidation=initialSeedForValidation,
testingData=actualOutputData
)
predictedOutputData = minMax.inverse_transform(predictedOutputData)
#Plotting of the prediction output and error
outputFolderName = "Outputs/Outputs" + datetime.now().strftime("%Y_%m_%d_%H_%M_%S")
os.mkdir(outputFolderName)
outplot = outputPlot.OutputPlot(outputFolderName + "/Prediction.html", "Mackey-Glass Time Series - GA Optimization", "Predicted vs Actual", "Time", "Output")
outplot.setXSeries(np.arange(1, nTesting + 1))
outplot.setYSeries('Actual Output', actualOutputData)
outplot.setYSeries('Predicted Output', predictedOutputData)
outplot.createOutput()
# Form feature vectors for training data
trainingInputData, trainingOutputData = util.formFeatureVectors(trainingData)
actualOutputData = minMax.inverse_transform(testingData)[:, 0]
# Initial seed
initialSeedForValidation = trainingData[-1]
networkSize = 500
populationSize = 200
noOfBest = int(populationSize / 2)
noOfGenerations = 100
predictedOutputData, bestPopulation = utilityGA.tuneTrainPredictConnectivityGA(
trainingInputData=trainingInputData,
trainingOutputData=trainingOutputData,
validationOutputData=validationData,
initialInputSeedForValidation=initialSeedForValidation,
horizon=nTesting,
noOfBest=noOfBest,
resTopology=utilityGA.Topology.Random,
size=networkSize,
popSize=populationSize,
maxGeneration=noOfGenerations)
predictedOutputData = minMax.inverse_transform(predictedOutputData)
#Plotting of the prediction output and error
outputFolderName = "Outputs/Random_Graph_Outputs" + datetime.now().strftime(
"%Y_%m_%d_%H_%M_%S")
os.mkdir(outputFolderName)
outplot = outputPlot.OutputPlot(outputFolderName + "/Prediction.html",
"Mackey-Glass Time Series - GA Optimization)",
"Prediction on Testing data", "Time", "Output")
# Split the data into training, validation and testing
trainingData, validationData, testingData = util.splitData(
data, 0.5, 0.25, 0.25)
nValidation = validationData.shape[0]
nTesting = testingData.shape[0]
# Form feature vectors for training data
trainingInputData, trainingOutputData = util.formFeatureVectors(trainingData)
actualOutputData = minMax.inverse_transform(testingData)[:, 0]
# Initial seed
initialSeedForValidation = trainingData[-1]
predictedOutputData = utilGA.tuneTrainPredictGA(
trainingInputData=trainingInputData,
trainingOutputData=trainingOutputData,
validationOutputData=validationData,
initialInputSeedForValidation=initialSeedForValidation,
testingData=actualOutputData)
predictedOutputData = minMax.inverse_transform(predictedOutputData)
#Plotting of the prediction output and error
outputFolderName = "Outputs/Outputs" + datetime.now().strftime(
"%Y_%m_%d_%H_%M_%S")
os.mkdir(outputFolderName)
outplot = outputPlot.OutputPlot(outputFolderName + "/Prediction.html",
"Mackey-Glass Time Series - GA Optimization",
"Predicted vs Actual", "Time", "Output")
outplot.setXSeries(np.arange(1, nTesting + 1))
outplot.setYSeries('Actual Output', actualOutputData)
outplot.setYSeries('Predicted Output', predictedOutputData)
from reservoir import GAUtility as utilityGA
from plotting import ScatterPlot as plot
import numpy as np
import os
from datetime import datetime
# File name for
folderName = "Outputs/GAResults_Combined_" + datetime.now().strftime(
"%Y_%m_%d_%H_%M_%S")
os.mkdir(folderName)
# Load the best population from the file
bestPopulationErdos = utilityGA.loadBestPopulation("erdos.pkl")
bestPopulationScaleFree = utilityGA.loadBestPopulation("scalefree.pkl")
bestPopulationSmallWorld = utilityGA.loadBestPopulation("smallworld.pkl")
bestPopulationList = [
bestPopulationErdos, bestPopulationScaleFree, bestPopulationSmallWorld
]
# Iterate over all the elements and get the network properties
networkSize = 500
errorList = []
averageDegreeList = []
averagePathLengthList = []
averageDiameterList = []
averageClusteringCoefficientList = []
for bestPopulation in bestPopulationList:
for item in bestPopulation:
# Fitness
from reservoir import GAUtility as utilityGA
from plotting import ScatterPlot as plot
import numpy as np
import os
from datetime import datetime
# File name for
folderName = "Outputs/GAResults_Random_Graphs_" + datetime.now().strftime(
"%Y_%m_%d_%H_%M_%S")
os.mkdir(folderName)
# Load the best population from the file
bestPopulation = utilityGA.loadBestPopulation("population.pkl")
# Iterate over all the elements and get the network properties
networkSize = 500
connectivityList = []
errorList = []
averageDegreeList = []
averagePathLengthList = []
averageDiameterList = []
averageClusteringCoefficientList = []
for item in bestPopulation:
# Fitness
connectivity = item[0][0, 0]
error = item[1]
# Network properties
averageDegree = item[2]['averageDegree']
averagePathLength = item[2]['averagePathLength']
averageDiameter = item[2]['averageDiameter']
averageClusteringCoefficient = item[2]['averageClusteringCoefficient'] * 500
# Form feature vectors for training data
trainingInputData, trainingOutputData = util.formFeatureVectors(trainingData)
actualOutputData = minMax.inverse_transform(testingData)[:, 0]
# Initial seed
initialSeedForValidation = trainingData[-1]
networkSize = 500
populationSize = 10
noOfBest = int(populationSize / 2)
noOfGenerations = 10
predictedOutputData, bestPopulation = utilityGA.tuneTrainPredictConnectivityGA(
trainingInputData=trainingInputData,
trainingOutputData=trainingOutputData,
validationOutputData=validationData,
initialInputSeedForValidation=initialSeedForValidation,
horizon=nTesting,
noOfBest=noOfBest,
resTopology=utilityGA.Topology.SmallWorldGraphs,
size=networkSize,
popSize=populationSize,
maxGeneration=noOfGenerations)
predictedOutputData = minMax.inverse_transform(predictedOutputData)
#Plotting of the prediction output and error
outputFolderName = "Outputs/Small_World_Graphs" + datetime.now().strftime(
"%Y_%m_%d_%H_%M_%S")
os.mkdir(outputFolderName)
outplot = outputPlot.OutputPlot(outputFolderName + "/Prediction.html",
"Mackey-Glass Time Series - GA Optimization)",
"Prediction on Testing data", "Time", "Output")
from reservoir import GAUtility as utilityGA
from plotting import ScatterPlot as plot
import numpy as np
import os
from datetime import datetime
# File name for
folderName = "Outputs/GAResults_Small_World_Graphs_" + datetime.now().strftime("%Y_%m_%d_%H_%M_%S")
os.mkdir(folderName)
# Load the best population from the file
bestPopulation = utilityGA.loadBestPopulation("population.pkl")
# Iterate over all the elements and get the network properties
networkSize = 500
meanDegreeList = []
betaList = []
errorList = []
averageDegreeList = []
averagePathLengthList = []
averageDiameterList = []
averageClusteringCoefficientList = []
for item in bestPopulation:
# Fitness
meanDegree = item[0][0,0]
beta = item[0][0,1]
error = item[1]
# Network properties
averageDegree = item[2]['averageDegree']
from reservoir import GAUtility as utilityGA
from plotting import ScatterPlot as plot
import numpy as np
import os
from datetime import datetime
# File name for
folderName = "Outputs/GAResults_Combined_" + datetime.now().strftime("%Y_%m_%d_%H_%M_%S")
os.mkdir(folderName)
# Load the best population from the file
bestPopulationErdos = utilityGA.loadBestPopulation("erdos.pkl")
bestPopulationScaleFree = utilityGA.loadBestPopulation("scalefree.pkl")
bestPopulationSmallWorld = utilityGA.loadBestPopulation("smallworld.pkl")
bestPopulationList = [bestPopulationErdos, bestPopulationScaleFree, bestPopulationSmallWorld]
# Iterate over all the elements and get the network properties
networkSize = 500
errorList = []
averageDegreeList = []
averagePathLengthList = []
averageDiameterList = []
averageClusteringCoefficientList = []
for bestPopulation in bestPopulationList:
for item in bestPopulation:
# Fitness
attachment = item[0][0,0]/networkSize
