static void Main(string[] args)
{
if (usePca)
{
//Application.EnableVisualStyles();
//Application.Run(new Diagrams());
(List <List <double> > data, _) = ReadDataAsList(dataFile, ';', columnsToIgnore, targetColumns, dataStartLine, dataEndLine);
KNN(data);
var pca = PCA.Compute(data, 5);
//read data from file
(double[][] dataArray, double[][] targetArray) = ReadDataAsArray(dataFile, ';', columnsToIgnore, targetColumns, dataStartLine, dataEndLine);
double[][] pcaData = List2DToArray2D(pca);
//normalize all data values (scale between 0 and 1)
(double[][] normalizedPcaData, _, _) = NormalizeData(pcaData);
(double[][] normalizedTargets, double[] min, double[] max) = NormalizeData(targetArray);
//split data into two sets - training and testing = 80% and 20%
(double[][] trainDataArray, double[][] trainTargetArray, double[][] testDataArray, double[][] testTargetArray) = SplitData(normalizedPcaData, normalizedTargets, dataSplitPercentage);
//var nn2 = new NeuralNetwork2();
//nn2.Run(trainDataArray, trainTargetArray, testDataArray, testTargetArray);
//create network
var nn = new BPNeuralNetwork(normalizedPcaData[0].Length, hiddenNeuronCount, outputNeuronCount, min, max, testDataArray, testTargetArray);
//var nn = new BPNeuralNetwork(normalizedPcaData[0].Length, hiddenNeuronCount, outputNeuronCount, min, max);
//nn.CrossValidation(trainDataArray, trainTargetArray, trainingEpochCount, learningRate, learningMomentum, nn);
//train network
(double[] trainErrors, double[] validationErrors, double[] testErrors) = nn.Train(trainDataArray, trainTargetArray, trainingEpochCount, learningRate, learningMomentum);
PlotValidationChart(trainErrors, validationErrors, testErrors);
//string[] propertyNames = ReadPropertyNames("../../Data/property_names.csv", ',');
//for (int i = 0; i < propertyNames.Length; i++)
// Console.WriteLine(i + " | " + propertyNames[i]);
//Test the network
for (int i = 0; i < testDataArray.Length; i++)
{
nn.ComputeOutputs(testDataArray[i], testTargetArray[i]);
}
}
else
{
//read data from file
(double[][] dataArray, double[][] targetArray) = ReadDataAsArray(dataFile, ';', columnsToIgnore, targetColumns, dataStartLine, dataEndLine);
//normalize all data values (scale between 0 and 1)
(double[][] normalizedData, _, _) = NormalizeData(dataArray);
(double[][] normalizedTargets, double[] min, double[] max) = NormalizeData(targetArray);
//split data into two sets - training and testing = 80% and 20%
(double[][] trainDataArray, double[][] trainTargetArray, double[][] testDataArray, double[][] testTargetArray) = SplitData(normalizedData, normalizedTargets, dataSplitPercentage);
//(double[][] trainDataArray, double[][] trainTargetArray, double[][] testDataArray, double[][] testTargetArray) = SplitData(dataArray, targetArray, 0.8);
//create network
var nn = new BPNeuralNetwork(dataArray[0].Length, hiddenNeuronCount, outputNeuronCount, min, max, testDataArray, testTargetArray);
//train network
(double[] trainErrors, double[] validationErrors, double[] testErrors) = nn.Train(trainDataArray, trainTargetArray, trainingEpochCount, learningRate, learningMomentum);
PlotValidationChart(trainErrors, validationErrors, testErrors);
//string[] propertyNames = ReadPropertyNames("../../Data/property_names.csv", ',');
//for (int i = 0; i < propertyNames.Length; i++)
// Console.WriteLine(i + " | " + propertyNames[i]);
//Test the network
for (int i = 0; i < testDataArray.Length; i++)
{
nn.ComputeOutputs(testDataArray[i], testTargetArray[i]);
}
}
Console.WriteLine();
Console.ReadLine();
}
static void KNN(List <List <double> > data)
{
Console.WriteLine("-------------------------------------");
Console.WriteLine("K-Nearest Neighbour method");
Console.WriteLine("-------------------------------------\n");
var normalized = NormalizeData(data);
var pca = PCA.Compute(normalized, 2);
(double[][] dataArray, double[][] targetArray) = ReadDataAsArray(dataFile, ';', columnsToIgnore, targetColumns, dataStartLine, dataEndLine);
double[][] normalizedPcaData = List2DToArray2D(pca);
(double[][] normalizedTargets, double[] min, double[] max) = NormalizeData(targetArray);
//(var data1, var data2) = CrossValidationSplitData(normalizedPcaData, normalizedTargets, 10);
(double[][] trainDataArray, double[][] trainTargetArray, double[][] testDataArray, double[][] testTargetArray) = SplitData(normalizedPcaData, normalizedTargets, dataSplitPercentage);
//Application.EnableVisualStyles();
//Application.Run(new Diagrams(trainDataArray, trainTargetArray, min[0], max[0]));
ChartValues <ObservablePoint> points1 = new ChartValues <ObservablePoint>();
ChartValues <ObservablePoint> points2 = new ChartValues <ObservablePoint>();
ChartValues <ObservablePoint> points3 = new ChartValues <ObservablePoint>();
ChartValues <ObservablePoint> points1Wrong = new ChartValues <ObservablePoint>();
ChartValues <ObservablePoint> points2Wrong = new ChartValues <ObservablePoint>();
ChartValues <ObservablePoint> points3Wrong = new ChartValues <ObservablePoint>();
int K = 131;
int N = 200;
int correct = 0;
int wrong = 0;
for (int i = 0; i < N; i++)//testDataArray.Length
{
int classIdx = KNearestNeighbor.Classify(testDataArray[i], trainDataArray, trainTargetArray, K, min[0], max[0]);
Console.WriteLine("Classified: {0}", classIdx == 1?"0-50": classIdx == 2 ? "50-150" : ">150");
var actual = testTargetArray[i][0] * (max[0] - min[0]) + min[0];
Console.WriteLine("Actual: {0}\n", actual);
if (classIdx == 1)
{
if (actual < 50)
{
correct++;
points1.Add(new ObservablePoint
{
X = testDataArray[i][0],
Y = testDataArray[i][1]
});
}
else
{
wrong++;
points1Wrong.Add(new ObservablePoint
{
X = testDataArray[i][0],
Y = testDataArray[i][1]
});
}
}
else if (classIdx == 2)
{
if (actual > 150)
{
correct++;
points2.Add(new ObservablePoint
{
X = testDataArray[i][0],
Y = testDataArray[i][1]
});
}
else
{
wrong++;
points2Wrong.Add(new ObservablePoint
{
X = testDataArray[i][0],
Y = testDataArray[i][1]
});
}
}
else
{
if (actual > 50 && actual < 150)
{
correct++;
points3.Add(new ObservablePoint
{
X = testDataArray[i][0],
Y = testDataArray[i][1]
});
}
else
{
wrong++;
points3Wrong.Add(new ObservablePoint
{
X = testDataArray[i][0],
Y = testDataArray[i][1]
});
}
}
}
Console.WriteLine("Accuracy: {0} %", (double)correct / N * 100);
Application.EnableVisualStyles();
Application.Run(new Diagrams(points1, points2, points3, points1Wrong, points2Wrong, points3Wrong));
Console.WriteLine("-------------------------------------\n");
}
