public void LearnTest()
{
double[][] inputs =
{
new double[] { -1, -1 },
new double[] { -1, 1 },
new double[] { 1, -1 },
new double[] { 1, 1 }
};
int[] xor =
{
-1,
1,
1,
-1
};
// Create Kernel Support Vector Machine with a Polynomial Kernel of 2nd degree
KernelSupportVectorMachine machine = new KernelSupportVectorMachine(new Polynomial(2), inputs[0].Length);
// Create the sequential minimal optimization teacher
SequentialMinimalOptimization learn = new SequentialMinimalOptimization(machine, inputs, xor);
// Run the learning algorithm
learn.Run();
int[] output = inputs.Apply(p => Math.Sign(machine.Compute(p)));
for (int i = 0; i < output.Length; i++)
Assert.AreEqual(System.Math.Sign(xor[i]), System.Math.Sign(output[i]));
}
//public SupportVectorMachine SVM
//{
// get { return svm; }
// private set { svm = value; }
//}
public override void TrainningModel(TrainningData trainningData)
{
ContinuousDataTableAdapter continuousDataTableAdapter = new ContinuousDataTableAdapter();
DataTable continuousDataTable = continuousDataTableAdapter.GetData();
DataTable dataTable = continuousDataTable.DefaultView.ToTable(false, TableMetaData.TestingAttributes);
string[] columnNames;
double[][] inputs = dataTable.ToArray(out columnNames);
int[] outputs = (int[])trainningData.ClassificationAttribute.Clone();
// Create output for SVM (-1 or 1)
for (int index = 0; index < outputs.Length; index++)
{
if (outputs[index] == 0)
{
outputs[index] = -1;
}
}
// Create a Support Vector Machine for the given inputs
//this.svm = new SupportVectorMachine(inputs[0].Length);
//// Create a Kernel Support Vector Machine for the given inputs
this.svm = new KernelSupportVectorMachine(new Gaussian(0.1), inputs[0].Length);
// Instantiate a new learning algorithm for SVMs
SequentialMinimalOptimization smo = new SequentialMinimalOptimization(svm, inputs, outputs);
// Set up the learning algorithm
smo.Complexity = 1.0;
// Run the learning algorithm
double error = smo.Run();
}
public double v3_0_1()
{
var ksvm = new KernelSupportVectorMachine(new Polynomial(2), 2);
var smo = new SequentialMinimalOptimization(ksvm, inputs, outputs);
return smo.Run(computeError: false);
}
static KernelSupportVectorMachine LearnSVM(HSL[] positives, HSL[] negatives,
double throwExceptionWhenErrorGreaterThan)
{
int[] classes = new int[positives.Length + negatives.Length];
double[][] vectors = new double[classes.Length][];
int index = 0;
for (int c = 0; c < positives.Length; c++, index++)
{
classes[index] = 1;
vectors[index] = HSLToDouble(positives[c]);
}
for (int c = 0; c < negatives.Length; c++, index++)
{
classes[index] = -1;
vectors[index] = HSLToDouble(negatives[c]);
}
KernelSupportVectorMachine svm = new KernelSupportVectorMachine(new Gaussian(.1), vectors[0].Length);
SequentialMinimalOptimization smo = new SequentialMinimalOptimization(svm, vectors.ToArray(), classes);
//smo.Complexity = 1.0;
double error = smo.Run();
if (error > throwExceptionWhenErrorGreaterThan)
{
throw new Exception("Failed to get reasonable error value.");
}
return svm;
}
public void Run()
{
// Example AND problem
double[][] inputs =
{
new double[] { 0, 0 }, // 0 and 0: 0 (label -1)
new double[] { 0, 1 }, // 0 and 1: 0 (label -1)
new double[] { 1, 0 }, // 1 and 0: 0 (label -1)
new double[] { 1, 1 } // 1 and 1: 1 (label +1)
};
// Dichotomy SVM outputs should be given as [-1;+1]
int[] labels =
{
// 0, 0, 0, 1
-1, -1, -1, 1
};
// Create a Support Vector Machine for the given inputs
SupportVectorMachine machine = new SupportVectorMachine(inputs[0].Length);
// Instantiate a new learning algorithm for SVMs
SequentialMinimalOptimization smo = new SequentialMinimalOptimization(machine, inputs, labels);
// Set up the learning algorithm
smo.Complexity = 1.0;
// Run the learning algorithm
double error = smo.Run();
// Compute the decision output for one of the input vectors
int decision = System.Math.Sign(machine.Compute(inputs[0]));
}
public override Func<double[], double> Learn(LearningData learningData) {
var svm = new KernelSupportVectorMachine(_kernel, learningData.Variables.Count);
var smo = new SequentialMinimalOptimization(
svm, learningData.Inputs, learningData.Outputs);
smo.Run();
return svm.Compute;
}
public void Setup()
{
ksvm = new SupportVectorMachine<Polynomial>(inputs: 2, kernel: new Polynomial(2));
smo = new SequentialMinimalOptimization<Polynomial>()
{
Model = ksvm
};
}
public SupportVectorMachine<Polynomial> v3_1_0()
{
ksvm = new SupportVectorMachine<Polynomial>(inputs: 2, kernel: new Polynomial(2));
smo = new SequentialMinimalOptimization<Polynomial>()
{
Model = ksvm
};
smo.Learn(inputs, outputs);
return ksvm;
}
//// Do training for all existing trained Data
public SVM(string TrainedDataInputFile)
{
_engine = new TesseractEngine(@"./tessdata3", "eng", EngineMode.TesseractAndCube);
_engine.SetVariable("tessedit_char_whitelist", "abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ");
_engine.SetVariable("tessedit_char_blacklist", "¢§+~»~`!@#$%^&*()_+-={}[]|\\:\";\'<>?,./");
string[] TrainedData = Directory.GetFiles(TrainedDataInputFile, "*.png");
double[][] inputs = new double[TrainedData.Length][]; ///
double[] InputArray = new double[784];
int[] Outputs = new int[TrainedData.Length];
for (int i = 0; i < TrainedData.Length; i++)
{
string filename = Path.GetFileNameWithoutExtension(TrainedData[i]);
Bitmap TrainingImage = new Bitmap(TrainedData[i]);
string[] split = filename.Split('.');
for (int j = 0; j < 28; j++)
{
for (int k = 0; k < 28; k++)
{
if ((!TrainingImage.GetPixel(j, k).Name.Equals("ffffffff")))
InputArray[j * 28 + k] = 1;
else
InputArray[j * 28 + k] = 0;
}
}
inputs[i] = InputArray;
Outputs[i] = Convert.ToInt32(split[0]);
InputArray = new double[784];
}
IKernel kernel;
kernel = new Polynomial(2, 0);
ksvm = new MulticlassSupportVectorMachine(784, kernel, 2);
MulticlassSupportVectorLearning ml = new MulticlassSupportVectorLearning(ksvm, inputs, Outputs);
double complexity = 1; ///// set these three parameters Carefuly later
double epsilon = 0.001;
double tolerance = 0.2;
ml.Algorithm = (svm, classInputs, classOutputs, i, j) =>
{
var smo = new SequentialMinimalOptimization(svm, classInputs, classOutputs);
smo.Complexity = complexity; /// Cost parameter for SVM
smo.Epsilon = epsilon;
smo.Tolerance = tolerance;
return smo;
};
// Train the machines. It should take a while.
double error = ml.Run();
}
public void ComputeTest()
{
// Example AND problem
double[][] inputs =
{
new double[] { 0, 0 }, // 0 and 0: 0 (label -1)
new double[] { 0, 1 }, // 0 and 1: 0 (label -1)
new double[] { 1, 0 }, // 1 and 0: 0 (label -1)
new double[] { 1, 1 } // 1 and 1: 1 (label +1)
};
// Dichotomy SVM outputs should be given as [-1;+1]
int[] labels =
{
// 0, 0, 0, 1
-1, -1, -1, 1
};
// Create a Support Vector Machine for the given inputs
KernelSupportVectorMachine machine = new KernelSupportVectorMachine(new Gaussian(0.1), inputs[0].Length);
// Instantiate a new learning algorithm for SVMs
SequentialMinimalOptimization smo = new SequentialMinimalOptimization(machine, inputs, labels);
// Set up the learning algorithm
smo.Complexity = 1.0;
// Run
double error = smo.Run();
Assert.AreEqual(-1, Math.Sign(machine.Compute(inputs[0])));
Assert.AreEqual(-1, Math.Sign(machine.Compute(inputs[1])));
Assert.AreEqual(-1, Math.Sign(machine.Compute(inputs[2])));
Assert.AreEqual(+1, Math.Sign(machine.Compute(inputs[3])));
Assert.AreEqual(error, 0);
Assert.AreEqual(-0.6640625, machine.Threshold);
Assert.AreEqual(1, machine.Weights[0]);
Assert.AreEqual(-0.34375, machine.Weights[1]);
Assert.AreEqual(-0.328125, machine.Weights[2]);
Assert.AreEqual(-0.328125, machine.Weights[3]);
}
public void TransformTest()
{
var inputs = yinyang.Submatrix(null, 0, 1).ToArray();
var labels = yinyang.GetColumn(2).ToInt32();
ConfusionMatrix actual, expected;
SequentialMinimalOptimization a, b;
var kernel = new Polynomial(2, 0);
{
var machine = new KernelSupportVectorMachine(kernel, inputs[0].Length);
a = new SequentialMinimalOptimization(machine, inputs, labels);
a.UseComplexityHeuristic = true;
a.Run();
int[] values = new int[labels.Length];
for (int i = 0; i < values.Length; i++)
values[i] = Math.Sign(machine.Compute(inputs[i]));
expected = new ConfusionMatrix(values, labels);
}
{
var projection = inputs.Apply(kernel.Transform);
var machine = new SupportVectorMachine(projection[0].Length);
b = new SequentialMinimalOptimization(machine, projection, labels);
b.UseComplexityHeuristic = true;
b.Run();
int[] values = new int[labels.Length];
for (int i = 0; i < values.Length; i++)
values[i] = Math.Sign(machine.Compute(projection[i]));
actual = new ConfusionMatrix(values, labels);
}
Assert.AreEqual(a.Complexity, b.Complexity, 1e-15);
Assert.AreEqual(expected.TrueNegatives, actual.TrueNegatives);
Assert.AreEqual(expected.TruePositives, actual.TruePositives);
Assert.AreEqual(expected.FalseNegatives, actual.FalseNegatives);
Assert.AreEqual(expected.FalsePositives, actual.FalsePositives);
}
public void FixedWeightsTest()
{
var dataset = KernelSupportVectorMachineTest.training;
var inputs = dataset.Submatrix(null, 0, 3);
var labels = Tools.Scale(0, 1, -1, 1, dataset.GetColumn(4)).ToInt32();
KernelSupportVectorMachine machine = new KernelSupportVectorMachine(
Gaussian.Estimate(inputs), inputs[0].Length);
var smo = new SequentialMinimalOptimization(machine, inputs, labels);
smo.Complexity = 10;
double error = smo.Run();
Assert.AreEqual(0.19047619047619047, error);
Assert.AreEqual(265.78327637381551, (machine.Kernel as Gaussian).Sigma);
Assert.AreEqual(29, machine.SupportVectors.Length);
double[] expectedWeights =
{
1.65717694716503, 1.20005456611466, -5.70824245415995, 10,
10, -2.38755497916487, 10, -8.15723436363058, 10, -10, 10,
10, -0.188634936781317, -5.4354281009458, -8.48341139483265,
-5.91105702760141, -5.71489190049223, 10, -2.37289205235858,
-3.33031262413522, -1.97545116517677, 10, -10, -9.563186799279,
-3.917941544845, -0.532584110773336, 4.81951847548326, 0.343668292727091,
-4.34159482731336
};
Assert.IsTrue(expectedWeights.IsEqual(machine.Weights, 1e-6));
int[] actual = new int[labels.Length];
for (int i = 0; i < actual.Length; i++)
actual[i] = Math.Sign(machine.Compute(inputs[i]));
ConfusionMatrix matrix = new ConfusionMatrix(actual, labels);
Assert.AreEqual(8, matrix.FalseNegatives);
Assert.AreEqual(0, matrix.FalsePositives);
Assert.AreEqual(4, matrix.TruePositives);
Assert.AreEqual(30, matrix.TrueNegatives);
Assert.AreEqual(1 / 3.0, matrix.Sensitivity);
Assert.AreEqual(1, matrix.Specificity);
Assert.AreEqual(0.5, matrix.FScore);
Assert.AreEqual(0.5129891760425771, matrix.MatthewsCorrelationCoefficient);
}
public void DynamicalTimeWarpingConstructorTest()
{
double[][] sequences =
{
new double[] // -1
{
0, 0, 0,
1, 1, 1,
2, 2, 2,
},
new double[] // -1
{
0, 1, 0,
0, 2, 0,
0, 3, 0
},
new double[] // +1
{
1, 1, 0,
1, 2, 0,
2, 1, 0,
},
new double[] // +1
{
0, 0, 1,
0, 0, 2,
0, 1, 3,
},
};
int[] outputs = { -1, -1, +1, +1 };
// Set the parameters of the kernel
double alpha = 0.85;
int innerVectorLength = 3;
// Create the kernel. Note that the input vector will be given out automatically
DynamicTimeWarping target = new DynamicTimeWarping(innerVectorLength, alpha);
// When using variable-length kernels, specify 0 as the input length.
KernelSupportVectorMachine svm = new KernelSupportVectorMachine(target, 0);
// Create the Sequential Minimal Optimization as usual
SequentialMinimalOptimization smo = new SequentialMinimalOptimization(svm, sequences, outputs);
smo.Complexity = 1.5;
double error = smo.Run();
// Computing the training values
var a0 = svm.Compute(sequences[0]);
var a1 = svm.Compute(sequences[1]);
var a2 = svm.Compute(sequences[2]);
var a3 = svm.Compute(sequences[3]);
Assert.AreEqual(-1, System.Math.Sign(a0));
Assert.AreEqual(-1, System.Math.Sign(a1));
Assert.AreEqual(+1, System.Math.Sign(a2));
Assert.AreEqual(+1, System.Math.Sign(a3));
// Computing a new testing value
double[] test =
{
1, 0, 1,
0, 0, 2,
0, 1, 3,
};
var a4 = svm.Compute(test);
}
public void LearnTest5()
{
double[][] inputs =
{
new double[] { -1, -1 },
new double[] { -1, 1 },
new double[] { 1, -1 },
new double[] { 1, 1 }
};
int[] positives =
{
1,
1,
1,
1
};
// Create Kernel Support Vector Machine with a Polynomial Kernel of 2nd degree
SupportVectorMachine machine = new SupportVectorMachine(inputs[0].Length);
// Create the sequential minimal optimization teacher
SequentialMinimalOptimization learn = new SequentialMinimalOptimization(machine, inputs, positives);
learn.Complexity = 1;
// Run the learning algorithm
double error = learn.Run();
Assert.AreEqual(0, error);
int[] output = inputs.Apply(p => (int)machine.Compute(p));
for (int i = 0; i < output.Length; i++)
{
bool sor = positives[i] >= 0;
bool sou = output[i] >= 0;
Assert.AreEqual(sor, sou);
}
}
public void ComputeTest()
{
// Example AND problem
double[][] inputs =
{
new double[] { 0, 0 }, // 0 and 0: 0 (label -1)
new double[] { 0, 1 }, // 0 and 1: 0 (label -1)
new double[] { 1, 0 }, // 1 and 0: 0 (label -1)
new double[] { 1, 1 } // 1 and 1: 1 (label +1)
};
// Dichotomy SVM outputs should be given as [-1;+1]
int[] labels =
{
// 0, 0, 0, 1
-1, -1, -1, 1
};
// Create a Support Vector Machine for the given inputs
KernelSupportVectorMachine machine = new KernelSupportVectorMachine(new Linear(0), inputs[0].Length);
// Instantiate a new learning algorithm for SVMs
SequentialMinimalOptimization smo = new SequentialMinimalOptimization(machine, inputs, labels);
// Set up the learning algorithm
smo.Complexity = 100.0;
// Run
double error = smo.Run();
Assert.AreEqual(0, error);
Assert.AreEqual(-1, Math.Sign(machine.Compute(inputs[0])));
Assert.AreEqual(-1, Math.Sign(machine.Compute(inputs[1])));
Assert.AreEqual(-1, Math.Sign(machine.Compute(inputs[2])));
Assert.AreEqual(+1, Math.Sign(machine.Compute(inputs[3])));
// At this point we have the weighted support vectors
// w sv b
// (+4) * (1,1) -3
// (-2) * (1,0)
// (-2) * (0,1)
//
// However, it can be seen that the last SV can be written
// as a linear combination of the two first vectors:
//
// (0,1) = (1,1) - (1,0)
//
// Since we have a linear space (we are using a linear kernel)
// this vector could be removed from the support vector set.
//
// f(x) = sum(alpha_i * x * x_i) + b
// = 4*(1,1)*x - 2*(1,0)*x - 2*(0,1)*x - 3
// = 4*(1,1)*x - 2*(1,0)*x - 2*((1,1) - (1,0))*x - 3
// = 4*(1,1)*x - 2*(1,0)*x - 2*(1,1)*x + 2*(1,0)*x - 3
// = 4*(1,1)*x - 2*(1,0)*x - 2*(1,1)*x + 2*(1,0)*x - 3
// = 2*(1,1)*x - 3
// = 2*x1 + 2*x2 - 3
//
SupportVectorReduction svr = new SupportVectorReduction(machine);
double error2 = svr.Run();
Assert.AreEqual(-1, Math.Sign(machine.Compute(inputs[0])));
Assert.AreEqual(-1, Math.Sign(machine.Compute(inputs[1])));
Assert.AreEqual(-1, Math.Sign(machine.Compute(inputs[2])));
Assert.AreEqual(+1, Math.Sign(machine.Compute(inputs[3])));
}
private static void testWeights(double[][] inputs, int[] labels, IKernel kernel)
{
{
var machine = new KernelSupportVectorMachine(kernel, inputs[0].Length);
var smo = new SequentialMinimalOptimization(machine, inputs, labels);
smo.PositiveWeight = 100;
smo.NegativeWeight = 1;
double error = smo.Run();
int[] actual = new int[labels.Length];
for (int i = 0; i < actual.Length; i++)
actual[i] = Math.Sign(machine.Compute(inputs[i]));
ConfusionMatrix matrix = new ConfusionMatrix(actual, labels);
Assert.AreEqual(50, matrix.TruePositives); // has more importance
Assert.AreEqual(0, matrix.FalseNegatives); // has more importance
}
{
var machine = new KernelSupportVectorMachine(kernel, inputs[0].Length);
var smo = new SequentialMinimalOptimization(machine, inputs, labels);
smo.PositiveWeight = 1;
smo.NegativeWeight = 100;
double error = smo.Run();
int[] actual = new int[labels.Length];
for (int i = 0; i < actual.Length; i++)
actual[i] = Math.Sign(machine.Compute(inputs[i]));
var matrix = new ConfusionMatrix(actual, labels);
Assert.AreEqual(50, matrix.TrueNegatives); // has more importance
Assert.AreEqual(0, matrix.FalsePositives); // has more importance
}
}
public void WeightsTest1()
{
var dataset = yinyang;
double[][] inputs = dataset.Submatrix(null, 0, 1).ToArray();
int[] labels = dataset.GetColumn(2).ToInt32();
Accord.Math.Tools.SetupGenerator(0);
var kernel = new Linear(1);
{
var machine = new KernelSupportVectorMachine(kernel, inputs[0].Length);
var smo = new SequentialMinimalOptimization(machine, inputs, labels);
smo.Complexity = 1.0;
smo.PositiveWeight = 1;
smo.NegativeWeight = 1;
smo.Tolerance = 0.001;
double error = smo.Run();
int[] actual = new int[labels.Length];
for (int i = 0; i < actual.Length; i++)
actual[i] = Math.Sign(machine.Compute(inputs[i]));
ConfusionMatrix matrix = new ConfusionMatrix(actual, labels);
Assert.AreEqual(43, matrix.TruePositives); // both classes are
Assert.AreEqual(43, matrix.TrueNegatives); // well equilibrated
Assert.AreEqual(7, matrix.FalseNegatives);
Assert.AreEqual(7, matrix.FalsePositives);
Assert.AreEqual(1.0, smo.Complexity);
Assert.AreEqual(1.0, smo.WeightRatio);
Assert.AreEqual(1.0, smo.NegativeWeight);
Assert.AreEqual(1.0, smo.PositiveWeight);
Assert.AreEqual(0.14, error);
Assert.AreEqual(0.001, smo.Tolerance);
Assert.AreEqual(31, machine.SupportVectors.Length);
}
{
var machine = new KernelSupportVectorMachine(kernel, inputs[0].Length);
var smo = new SequentialMinimalOptimization(machine, inputs, labels);
smo.Complexity = 1;
smo.PositiveWeight = 100;
smo.NegativeWeight = 1;
smo.Tolerance = 0.001;
double error = smo.Run();
int[] actual = new int[labels.Length];
for (int i = 0; i < actual.Length; i++)
actual[i] = Math.Sign(machine.Compute(inputs[i]));
ConfusionMatrix matrix = new ConfusionMatrix(actual, labels);
Assert.AreEqual(50, matrix.TruePositives); // has more importance
Assert.AreEqual(23, matrix.TrueNegatives);
Assert.AreEqual(0, matrix.FalseNegatives); // has more importance
Assert.AreEqual(27, matrix.FalsePositives);
Assert.AreEqual(1.0, smo.Complexity);
Assert.AreEqual(100, smo.WeightRatio);
Assert.AreEqual(1.0, smo.NegativeWeight);
Assert.AreEqual(100, smo.PositiveWeight);
Assert.AreEqual(0.001, smo.Tolerance);
Assert.AreEqual(0.27, error);
Assert.AreEqual(41, machine.SupportVectors.Length);
}
{
var machine = new KernelSupportVectorMachine(kernel, inputs[0].Length);
var smo = new SequentialMinimalOptimization(machine, inputs, labels);
smo.Complexity = 1;
smo.PositiveWeight = 1;
smo.NegativeWeight = 100;
smo.Tolerance = 0.001;
double error = smo.Run();
int[] actual = new int[labels.Length];
for (int i = 0; i < actual.Length; i++)
actual[i] = Math.Sign(machine.Compute(inputs[i]));
var matrix = new ConfusionMatrix(actual, labels);
Assert.AreEqual(25, matrix.TruePositives);
Assert.AreEqual(50, matrix.TrueNegatives); // has more importance
Assert.AreEqual(25, matrix.FalseNegatives);
Assert.AreEqual(0, matrix.FalsePositives); // has more importance
Assert.AreEqual(1.0, smo.Complexity);
Assert.AreEqual(0.01, smo.WeightRatio);
Assert.AreEqual(100, smo.NegativeWeight);
Assert.AreEqual(1.0, smo.PositiveWeight);
Assert.AreEqual(0.25, error);
Assert.AreEqual(0.001, smo.Tolerance);
Assert.AreEqual(40, machine.SupportVectors.Length);
}
}
public void TrainTest2()
{
double[][] inputs =
{
new double[] { -1, -1 },
new double[] { -1, 1 },
new double[] { 1, -1 },
new double[] { 1, 1 }
};
int[] or =
{
-1,
-1,
-1,
+1
};
// Create Kernel Support Vector Machine with a Polynomial Kernel of 2nd degree
SupportVectorMachine machine = new SupportVectorMachine(inputs[0].Length);
// Create the sequential minimal optimization teacher
SequentialMinimalOptimization learn = new SequentialMinimalOptimization(machine, inputs, or);
learn.Complexity = 1;
// Run the learning algorithm
learn.Run();
double[] output = machine.Compute(inputs);
for (int i = 0; i < output.Length; i++)
{
bool sor = or[i] >= 0;
bool sou = output[i] >= 0;
Assert.AreEqual(sor, sou);
}
}
/// <summary>
/// Creates a Support Vector Machine and teaches it to recognize
/// the previously loaded dataset using the current UI settings.
/// </summary>
///
private void btnCreate_Click(object sender, EventArgs e)
{
if (dgvLearningSource.DataSource == null)
{
MessageBox.Show("Please load some data first.");
return;
}
// Finishes and save any pending changes to the given data
dgvLearningSource.EndEdit();
// Creates a matrix from the entire source data table
double[,] table = (dgvLearningSource.DataSource as DataTable).ToMatrix(out columnNames);
// Get only the input vector values (first two columns)
double[][] inputs = table.GetColumns(0, 1).ToJagged();
// Get only the output labels (last column)
int[] outputs = table.GetColumn(2).ToInt32();
// Creates a new instance of the SMO learning algorithm
var smo = new SequentialMinimalOptimization<IKernel>()
{
// Set learning parameters
Complexity = (double)numC.Value,
Tolerance = (double)numT.Value,
PositiveWeight = (double)numPositiveWeight.Value,
NegativeWeight = (double)numNegativeWeight.Value,
Kernel = createKernel()
};
try
{
// Run
svm = smo.Learn(inputs, outputs);
lbStatus.Text = "Training complete!";
}
catch (ConvergenceException)
{
lbStatus.Text = "Convergence could not be attained. "+
"The learned machine might still be usable.";
}
createSurface(table);
// Check if we got support vectors
if (svm.SupportVectors == null || svm.SupportVectors.Length == 0)
{
dgvSupportVectors.DataSource = null;
graphSupportVectors.GraphPane.CurveList.Clear();
return;
}
// Show support vectors on the Support Vectors tab page
double[][] supportVectorsWeights = svm.SupportVectors.InsertColumn(svm.Weights);
string[] supportVectorNames = columnNames.RemoveAt(columnNames.Length - 1).Concatenate("Weight");
dgvSupportVectors.DataSource = new ArrayDataView(supportVectorsWeights, supportVectorNames);
// Show the support vector labels on the scatter plot
double[] supportVectorLabels = new double[svm.SupportVectors.Length];
for (int i = 0; i < supportVectorLabels.Length; i++)
{
int j = inputs.Find(sv => sv == svm.SupportVectors[i])[0];
supportVectorLabels[i] = outputs[j];
}
double[][] graph = svm.SupportVectors.InsertColumn(supportVectorLabels);
CreateScatterplot(graphSupportVectors, graph.ToMatrix());
}
public void CompactTest()
{
double[][] inputs =
{
new double[] { -1, -1 },
new double[] { -1, 1 },
new double[] { 1, -1 },
new double[] { 1, 1 }
};
int[] xor =
{
-1,
1,
1,
-1
};
{
var machine = new KernelSupportVectorMachine(new Polynomial(2), inputs[0].Length);
var learn = new SequentialMinimalOptimization(machine, inputs, xor);
learn.Compact = false;
double error = learn.Run();
Assert.AreEqual(0, error);
}
{
var machine = new KernelSupportVectorMachine(new Polynomial(2), inputs[0].Length);
var learn = new SequentialMinimalOptimization(machine, inputs, xor);
bool thrown = false;
try { learn.Compact = true; }
catch { thrown = true; }
Assert.IsTrue(thrown);
}
{
var machine = new KernelSupportVectorMachine(new Linear(), inputs[0].Length);
var learn = new SequentialMinimalOptimization(machine, inputs, xor);
learn.Compact = false;
double error = learn.Run();
Assert.AreEqual(0.5, error);
}
{
var machine = new KernelSupportVectorMachine(new Linear(), inputs[0].Length);
var learn = new SequentialMinimalOptimization(machine, inputs, xor);
learn.Compact = false;
double error = learn.Run();
Assert.AreEqual(0.5, error);
}
}
public void BootstrapConstructorTest3()
{
Accord.Math.Tools.SetupGenerator(0);
// This is a sample code on how to use 0.632 Bootstrap
// to assess the performance of Support Vector Machines.
// Consider the example binary data. We will be trying
// to learn a XOR problem and see how well does SVMs
// perform on this data.
double[][] data =
{
new double[] { -1, -1 }, new double[] { 1, -1 },
new double[] { -1, 1 }, new double[] { 1, 1 },
new double[] { -1, -1 }, new double[] { 1, -1 },
new double[] { -1, 1 }, new double[] { 1, 1 },
new double[] { -1, -1 }, new double[] { 1, -1 },
new double[] { -1, 1 }, new double[] { 1, 1 },
new double[] { -1, -1 }, new double[] { 1, -1 },
new double[] { -1, 1 }, new double[] { 1, 1 },
};
int[] xor = // result of xor for the sample input data
{
-1, 1,
1, -1,
-1, 1,
1, -1,
-1, 1,
1, -1,
-1, 1,
1, -1,
};
// Create a new Bootstrap algorithm passing the set size and the number of resamplings
var bootstrap = new Bootstrap(size: data.Length, subsamples: 50);
// Define a fitting function using Support Vector Machines. The objective of this
// function is to learn a SVM in the subset of the data indicated by the bootstrap.
bootstrap.Fitting = delegate(int[] indicesTrain, int[] indicesValidation)
{
// The fitting function is passing the indices of the original set which
// should be considered training data and the indices of the original set
// which should be considered validation data.
// Lets now grab the training data:
var trainingInputs = data.Submatrix(indicesTrain);
var trainingOutputs = xor.Submatrix(indicesTrain);
// And now the validation data:
var validationInputs = data.Submatrix(indicesValidation);
var validationOutputs = xor.Submatrix(indicesValidation);
// Create a Kernel Support Vector Machine to operate on the set
var svm = new KernelSupportVectorMachine(new Polynomial(2), 2);
// Create a training algorithm and learn the training data
var smo = new SequentialMinimalOptimization(svm, trainingInputs, trainingOutputs);
double trainingError = smo.Run();
// Now we can compute the validation error on the validation data:
double validationError = smo.ComputeError(validationInputs, validationOutputs);
// Return a new information structure containing the model and the errors achieved.
return new BootstrapValues(trainingError, validationError);
};
// Compute the bootstrap estimate
var result = bootstrap.Compute();
// Finally, access the measured performance.
double trainingErrors = result.Training.Mean;
double validationErrors = result.Validation.Mean;
// And compute the 0.632 estimate
double estimate = result.Estimate;
Assert.AreEqual(50, bootstrap.B);
Assert.AreEqual(0, trainingErrors);
Assert.AreEqual(0.021428571428571429, validationErrors);
Assert.AreEqual(50, bootstrap.Subsamples.Length);
Assert.AreEqual(0.013542857142857143, estimate);
}
public void SequentialMinimalOptimizationConstructorTest()
{
double[][] inputs =
{
new double[] { -1, -1 },
new double[] { -1, 1 },
new double[] { 1, -1 },
new double[] { 1, 1 }
};
int[] or =
{
0,
0,
0,
+1
};
// Create Kernel Support Vector Machine with a Polynomial Kernel of 2nd degree
SupportVectorMachine machine = new SupportVectorMachine(inputs[0].Length);
bool thrown = false;
try
{
SequentialMinimalOptimization learn = new SequentialMinimalOptimization(machine, inputs, or);
}
catch (ArgumentOutOfRangeException)
{
thrown = true;
}
Assert.IsTrue(thrown);
}
public void LargeLearningTest1()
{
// Create large input vectors
int rows = 1000;
int dimension = 10000;
double[][] inputs = new double[rows][];
int[] outputs = new int[rows];
Random rnd = new Random();
for (int i = 0; i < inputs.Length; i++)
{
inputs[i] = new double[dimension];
if (i > rows / 2)
{
for (int j = 0; j < dimension; j++)
inputs[i][j] = rnd.NextDouble();
outputs[i] = -1;
}
else
{
for (int j = 0; j < dimension; j++)
inputs[i][j] = rnd.NextDouble() * 4.21 + 5;
outputs[i] = +1;
}
}
KernelSupportVectorMachine svm = new KernelSupportVectorMachine(new Polynomial(2), dimension);
SequentialMinimalOptimization smo = new SequentialMinimalOptimization(svm, inputs, outputs)
{
UseComplexityHeuristic = true
};
double error = smo.Run();
Assert.AreEqual(0, error);
}
public void ComputeTest2()
{
double[][] input =
{
new double[] { 1, 4, 2, 0, 1 },
new double[] { 1, 3, 2, 0, 1 },
new double[] { 3, 0, 1, 1, 1 },
new double[] { 3, 0, 1, 0, 1 },
new double[] { 0, 5, 5, 5, 5 },
new double[] { 1, 5, 5, 5, 5 },
new double[] { 1, 0, 0, 0, 0 },
new double[] { 1, 0, 0, 0, 0 },
};
int[] output =
{
0, 0,
1, 1,
2, 2,
3, 3,
};
IKernel kernel = new Polynomial(2);
int classes = 4;
int inputs = 5;
// Create the Multi-class Support Vector Machine using the selected Kernel
var msvm = new MulticlassSupportVectorMachine(inputs, kernel, classes);
// Create the learning algorithm using the machine and the training data
var ml = new MulticlassSupportVectorLearning(msvm, input, output);
// Configure the learning algorithm
ml.Algorithm = (svm, classInputs, classOutputs, i, j) =>
{
var smo = new SequentialMinimalOptimization(svm, classInputs, classOutputs)
{
Complexity = 1
};
return smo;
};
Assert.AreEqual(0, msvm.GetLastKernelEvaluations());
// Executes the training algorithm
double error = ml.Run();
Assert.AreEqual(6, msvm.GetLastKernelEvaluations());
int[] evals = new int[input.Length];
int[] evalexp = { 8, 8, 7, 7, 7, 7, 6, 6 };
#if NET35
AForge.Parallel.For(0, input.Length, i =>
#else
Parallel.For(0, input.Length, i =>
#endif
{
double[] data = input[i];
double[] responses;
int num = msvm.Compute(data, MulticlassComputeMethod.Elimination, out responses);
Assert.AreEqual(output[i], num);
evals[i] = msvm.GetLastKernelEvaluations();
});
for (int i = 0; i < evals.Length; i++)
Assert.AreEqual(evals[i], evalexp[i]);
#if NET35
AForge.Parallel.For(0, input.Length, i =>
#else
Parallel.For(0, input.Length, i =>
#endif
{
double[] data = input[i];
double[] responses;
int num = msvm.Compute(data, MulticlassComputeMethod.Voting, out responses);
Assert.AreEqual(output[i], num);
evals[i] = msvm.GetLastKernelEvaluations();
});
for (int i = 0; i < evals.Length; i++)
Assert.AreEqual(msvm.SupportVectorUniqueCount, evals[i]);
}
public void ComputeTest5()
{
var dataset = yinyang;
double[][] inputs = dataset.Submatrix(null, 0, 1).ToArray();
int[] labels = dataset.GetColumn(2).ToInt32();
{
Linear kernel = new Linear();
var machine = new KernelSupportVectorMachine(kernel, inputs[0].Length);
var smo = new SequentialMinimalOptimization(machine, inputs, labels);
smo.Complexity = 1.0;
double error = smo.Run();
Assert.AreEqual(1.0, smo.Complexity);
Assert.AreEqual(1.0, smo.WeightRatio);
Assert.AreEqual(1.0, smo.NegativeWeight);
Assert.AreEqual(1.0, smo.PositiveWeight);
Assert.AreEqual(0.14, error);
Assert.AreEqual(30, machine.SupportVectors.Length);
double[] actualWeights = machine.Weights;
double[] expectedWeights = { -1, -1, 1, -1, -1, 1, 1, -1, 1, -1, 1, 1, -1, 0.337065120144639, -1, 1, -0.337065120144639, -1, 1, 1, -1, 1, 1, -1, -1, 1, 1, -1, -1, 1 };
Assert.IsTrue(expectedWeights.IsEqual(actualWeights, 1e-10));
int[] actual = new int[labels.Length];
for (int i = 0; i < actual.Length; i++)
actual[i] = Math.Sign(machine.Compute(inputs[i]));
ConfusionMatrix matrix = new ConfusionMatrix(actual, labels);
Assert.AreEqual(7, matrix.FalseNegatives);
Assert.AreEqual(7, matrix.FalsePositives);
Assert.AreEqual(43, matrix.TruePositives);
Assert.AreEqual(43, matrix.TrueNegatives);
}
{
Linear kernel = new Linear();
var machine = new KernelSupportVectorMachine(kernel, inputs[0].Length);
var smo = new SequentialMinimalOptimization(machine, inputs, labels);
smo.Complexity = 1.0;
smo.PositiveWeight = 0.3;
smo.NegativeWeight = 1.0;
double error = smo.Run();
Assert.AreEqual(1.0, smo.Complexity);
Assert.AreEqual(0.3 / 1.0, smo.WeightRatio);
Assert.AreEqual(1.0, smo.NegativeWeight);
Assert.AreEqual(0.3, smo.PositiveWeight);
Assert.AreEqual(0.21, error);
Assert.AreEqual(24, machine.SupportVectors.Length);
double[] actualWeights = machine.Weights;
//string str = actualWeights.ToString(Accord.Math.Formats.CSharpArrayFormatProvider.InvariantCulture);
double[] expectedWeights = { -0.771026323762095, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -0.928973676237905, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, -1 };
Assert.IsTrue(expectedWeights.IsEqual(actualWeights, 1e-10));
int[] actual = new int[labels.Length];
for (int i = 0; i < actual.Length; i++)
actual[i] = (int)machine.Compute(inputs[i]);
ConfusionMatrix matrix = new ConfusionMatrix(actual, labels);
Assert.AreEqual(50, matrix.FalseNegatives);
Assert.AreEqual(0, matrix.FalsePositives);
Assert.AreEqual(0, matrix.TruePositives);
Assert.AreEqual(50, matrix.TrueNegatives);
}
{
Linear kernel = new Linear();
var machine = new KernelSupportVectorMachine(kernel, inputs[0].Length);
var smo = new SequentialMinimalOptimization(machine, inputs, labels);
smo.Complexity = 1.0;
smo.PositiveWeight = 1.0;
smo.NegativeWeight = 0.3;
double error = smo.Run();
Assert.AreEqual(1.0, smo.Complexity);
Assert.AreEqual(1.0 / 0.3, smo.WeightRatio);
Assert.AreEqual(0.3, smo.NegativeWeight);
Assert.AreEqual(1.0, smo.PositiveWeight);
Assert.AreEqual(0.15, error);
Assert.AreEqual(19, machine.SupportVectors.Length);
double[] actualWeights = machine.Weights;
double[] expectedWeights = new double[] { 1, 1, -0.3, 1, -0.3, 1, 1, -0.3, 1, 1, 1, 1, 1, 1, 1, 1, 0.129080057278249, 1, 0.737797469918795 };
Assert.IsTrue(expectedWeights.IsEqual(actualWeights, 1e-10));
int[] actual = new int[labels.Length];
for (int i = 0; i < actual.Length; i++)
actual[i] = Math.Sign(machine.Compute(inputs[i]));
ConfusionMatrix matrix = new ConfusionMatrix(actual, labels);
Assert.AreEqual(0, matrix.FalseNegatives);
Assert.AreEqual(50, matrix.FalsePositives);
Assert.AreEqual(50, matrix.TruePositives);
Assert.AreEqual(0, matrix.TrueNegatives);
}
}
public void ComplexityHeuristicTest()
{
var dataset = yinyang;
double[][] inputs = dataset.Submatrix(null, 0, 1).ToArray();
int[] labels = dataset.GetColumn(2).ToInt32();
var linear = new SupportVectorMachine(inputs[0].Length);
Linear kernel = new Linear(0);
var machine = new KernelSupportVectorMachine(kernel, inputs[0].Length);
var smo1 = new SequentialMinimalOptimization(machine, inputs, labels);
smo1.UseClassProportions = true;
smo1.UseComplexityHeuristic = true;
double e1 = smo1.Run();
var smo2 = new SequentialMinimalOptimization(linear, inputs, labels);
smo2.UseClassProportions = true;
smo2.UseComplexityHeuristic = true;
double e2 = smo2.Run();
Assert.AreEqual(smo1.Complexity, smo2.Complexity);
Assert.AreEqual(e1, e2);
}
public void DynamicalTimeWarpingConstructorTest2()
{
// Declare some testing data
double[][] inputs =
{
// Class -1
new double[] { 0,1,1,0 },
new double[] { 0,0,1,0 },
new double[] { 0,1,1,1,0 },
new double[] { 0,1,0 },
// Class +1
new double[] { 1,0,0,1 },
new double[] { 1,1,0,1 },
new double[] { 1,0,0,0,1 },
new double[] { 1,0,1 },
new double[] { 1,0,0,0,1,1 }
};
int[] outputs =
{
-1,-1,-1,-1, // First four sequences are of class -1
1, 1, 1, 1, 1 // Last five sequences are of class +1
};
// Set the parameters of the kernel
double alpha = 1.0;
int degree = 1;
int innerVectorLength = 1;
// Create the kernel. Note that the input vector will be given out automatically
DynamicTimeWarping target = new DynamicTimeWarping(innerVectorLength, alpha, degree);
// When using variable-length kernels, specify 0 as the input length.
KernelSupportVectorMachine svm = new KernelSupportVectorMachine(target, 0);
// Create the Sequential Minimal Optimization as usual
SequentialMinimalOptimization smo = new SequentialMinimalOptimization(svm, inputs, outputs);
smo.Complexity = 1.5;
double error = smo.Run();
// Check if the model has learnt the sequences correctly.
for (int i = 0; i < inputs.Length; i++)
{
int expected = outputs[i];
int actual = System.Math.Sign(svm.Compute(inputs[i]));
Assert.AreEqual(expected, actual);
}
// Testing new sequences
Assert.AreEqual(-1,System.Math.Sign(svm.Compute(new double[] { 0, 1, 1, 0, 0 })));
Assert.AreEqual(+1,System.Math.Sign(svm.Compute(new double[] { 1, 1, 0, 0, 1, 1 })));
}
public void UseClassProportionsTest()
{
var dataset = KernelSupportVectorMachineTest.training;
var inputs = dataset.Submatrix(null, 0, 3);
var labels = Tools.Scale(0, 1, -1, 1, dataset.GetColumn(4)).ToInt32();
Gaussian kernel = Gaussian.Estimate(inputs);
var machine = new KernelSupportVectorMachine(kernel, inputs[0].Length);
var smo = new SequentialMinimalOptimization(machine, inputs, labels);
smo.Complexity = 1.0;
smo.UseClassProportions = true;
double error = smo.Run();
Assert.AreEqual(1, smo.Complexity);
Assert.AreEqual(0.4, smo.PositiveWeight);
Assert.AreEqual(1.0, smo.NegativeWeight);
Assert.AreEqual(0.4, smo.WeightRatio, 1e-10);
Assert.AreEqual(0.2857142857142857, error);
Assert.AreEqual(265.78327637381551, (machine.Kernel as Gaussian).Sigma);
Assert.AreEqual(26, machine.SupportVectors.Length);
int[] actual = new int[labels.Length];
for (int i = 0; i < actual.Length; i++)
actual[i] = Math.Sign(machine.Compute(inputs[i]));
ConfusionMatrix matrix = new ConfusionMatrix(actual, labels);
Assert.AreEqual(12, matrix.FalseNegatives);
Assert.AreEqual(0, matrix.FalsePositives);
Assert.AreEqual(0, matrix.TruePositives);
Assert.AreEqual(30, matrix.TrueNegatives);
}
private void button3_Click(object sender, EventArgs e)
{
string[] Second = File.ReadAllLines(textBox14.Text);
string[] First = File.ReadAllLines(textBox13.Text);
List<double[]> F = new List<double[]>();
List<double[]> S = new List<double[]>();
double Alpha1Thresh = int.MaxValue; //2000;// int.MaxValue;//
double Alpha2Thresh = int.MaxValue; //2000; //
for (int i=0;i<First.Length;i++)
{
string[] s1 = First[i].Split(' ');
if ((double.Parse(s1[2]) < Alpha1Thresh) && (double.Parse(s1[3]) < Alpha2Thresh))
{
double[] ar = new double[VectorSize];
double sum = 0;
for (int j = 0; j < VectorSize; j++)
{
ar[j] = double.Parse(s1[j]);
if ((j < VectorSize - 2) && (2<=j ))
sum += ar[j];
}
for (int j = 2; j < VectorSize-2; j++)
ar[j] = ar[j] / 1000;
if (ar[0] > 2000)
{
ar[0] = 2000;
}
if (ar[1] > 2000)
{
ar[1] = 2000;
}
ar[0] = ar[0] / 2000;
ar[1] = ar[1] / 2000;
ar[VectorSize - 2] = ar[VectorSize - 2] / 100;
ar[VectorSize - 1] = ar[VectorSize - 1] / 100;
F.Add(ar);
}
}
for (int i = 0; i < Second.Length; i++)
{
string[] s1 = Second[i].Split(' ');
if ((double.Parse(s1[2]) < Alpha1Thresh) && (double.Parse(s1[3]) < Alpha2Thresh))
{
double[] ar = new double[VectorSize];
double sum = 0;
for (int j = 0; j < VectorSize; j++)
{
ar[j] = double.Parse(s1[j]);
if ((j < VectorSize - 2) && (2 <= j))
sum += ar[j];
}
for (int j = 2; j < VectorSize - 2; j++)
ar[j] = ar[j] / 1000;
if (ar[0]>2000)
{
ar[0] = 2000;
}
if (ar[1] > 2000)
{
ar[1] = 2000;
}
ar[0] = ar[0] / 2000;
ar[1] = ar[1] / 2000;
ar[VectorSize - 2] = ar[VectorSize - 2] / 100;
ar[VectorSize - 1] = ar[VectorSize - 1] / 100;
S.Add(ar);
}
}
int min = Math.Min(F.Count, S.Count);
double[][] inputs = new double[2*min][];
int[] outputs = new int[2*min];
int VS = VectorSize; //ТУТ
for (int j=0;j<min;j++)
{
inputs[j] = new double[VS];
inputs[j + min] = new double[VS];
for (int i = 0; i < VS; i++)
// for (int i = VectorSize - 2; i < VectorSize; i++)//ТУТ
{
inputs[j][i] = F[j][i];//ТУТ
inputs[j + min][i] = S[j][i];//ТУТ
// inputs[j][i - VectorSize + 2] = F[j][i];//ТУТ
// inputs[j + min][i - VectorSize + 2] = S[j][i];//ТУТ
}
outputs[j] = -1;
outputs[j + min] = 1;
}
// Get only the output labels (last column)
// Create the specified Kernel
IKernel kernel = new Gaussian((double)0.560);
// IKernel kernel = new Polynomial(5, 500.0);
// Creates the Support Vector Machine for 2 input variables
svm = new KernelSupportVectorMachine(kernel, inputs: VS);
// Creates a new instance of the SMO learning algorithm
var smo = new SequentialMinimalOptimization(svm, inputs, outputs)
{
// Set learning parameters
Complexity = (double)1.50,
Tolerance = (double)0.001,
PositiveWeight = (double)1.00,
NegativeWeight = (double)1.00,
};
try
{
// Run
double error = smo.Run();
}
catch (ConvergenceException)
{
}
// double d = svm.Compute(inputs[10]);
points.Clear();
Points = 0;
points_mid.Clear();
timer3.Enabled = true;
}
public void WeightRatioTest()
{
var dataset = KernelSupportVectorMachineTest.training;
var inputs = dataset.Submatrix(null, 0, 3);
var labels = Tools.Scale(0, 1, -1, 1, dataset.GetColumn(4)).ToInt32();
Gaussian kernel = Gaussian.Estimate(inputs);
{
var machine = new KernelSupportVectorMachine(kernel, inputs[0].Length);
var smo = new SequentialMinimalOptimization(machine, inputs, labels);
smo.Complexity = 1.0;
smo.WeightRatio = 10;
double error = smo.Run();
Assert.AreEqual(1.0, smo.PositiveWeight);
Assert.AreEqual(0.1, smo.NegativeWeight);
Assert.AreEqual(0.7142857142857143, error);
Assert.AreEqual(265.78327637381551, (machine.Kernel as Gaussian).Sigma);
Assert.AreEqual(39, machine.SupportVectors.Length);
int[] actual = new int[labels.Length];
for (int i = 0; i < actual.Length; i++)
actual[i] = Math.Sign(machine.Compute(inputs[i]));
ConfusionMatrix matrix = new ConfusionMatrix(actual, labels);
Assert.AreEqual(12, matrix.TruePositives); // has more importance
Assert.AreEqual(0, matrix.FalseNegatives); // has more importance
Assert.AreEqual(30, matrix.FalsePositives);
Assert.AreEqual(0, matrix.TrueNegatives);
Assert.AreEqual(1.0, matrix.Sensitivity);
Assert.AreEqual(0.0, matrix.Specificity);
Assert.AreEqual(0.44444444444444448, matrix.FScore);
Assert.AreEqual(0.0, matrix.MatthewsCorrelationCoefficient);
}
{
var machine = new KernelSupportVectorMachine(kernel, inputs[0].Length);
var smo = new SequentialMinimalOptimization(machine, inputs, labels);
smo.Complexity = 1.0;
smo.WeightRatio = 0.1;
double error = smo.Run();
Assert.AreEqual(0.1, smo.PositiveWeight);
Assert.AreEqual(1.0, smo.NegativeWeight);
Assert.AreEqual(0.21428571428571427, error);
Assert.AreEqual(265.78327637381551, (machine.Kernel as Gaussian).Sigma);
Assert.AreEqual(18, machine.SupportVectors.Length);
int[] actual = new int[labels.Length];
for (int i = 0; i < actual.Length; i++)
actual[i] = Math.Sign(machine.Compute(inputs[i]));
ConfusionMatrix matrix = new ConfusionMatrix(actual, labels);
Assert.AreEqual(8, matrix.FalseNegatives);
Assert.AreEqual(1, matrix.FalsePositives); // has more importance
Assert.AreEqual(4, matrix.TruePositives);
Assert.AreEqual(29, matrix.TrueNegatives); // has more importance
Assert.AreEqual(0.33333333333333331, matrix.Sensitivity);
Assert.AreEqual(0.96666666666666667, matrix.Specificity);
Assert.AreEqual(0.47058823529411764, matrix.FScore);
Assert.AreEqual(0.41849149947774944, matrix.MatthewsCorrelationCoefficient);
}
}