# Subtractive Clustring implementation

My aim is to cluster my data using subtractive clustering and so that further I can extract Fuzzy Rules from that.

suppose I have the following 2 dimensional data:-

``````X[]=[  {0,.16,.24,.42,.48,.66,.83,.24,.42,.48,.66,.66,.16,.24,.42,.42,.48,.48,.48,.66,.66,.66,.66,.66,.66,.66,.83,.83,.83,.66},

{0,0,0,0,0,0,0,.15,.13,.1,.12,.18,.58,.78,.59,.78,.45,.49,.58,.45,.49,.58,.65,.71,.715,.72,.66,.725,.726,.455}
]
``````

please provide me examples on how to implement subtractive clustering in java.

by the way I did some research work and found the following algorithm for that

the algorithm:-

1. normalize the data using Max and Min values from both the dimensions
2. calculate the potentials by using

where m is the dimensions or type of data ( 2 in my case ), n is the number of points.

3 selecting the highest potential value as the first cluster center and Revise the potential of all data points untill

some how I have implemented it using java, code:- (please note that due to some reason I am unable to provide the full running code, so I am attaching the code that is doing the presented algorithm steps)

``````class SClustering {

double[][]data;
double normData[][];
ArrayList Potentials=new ArrayList();
ArrayList sortedPotentials;
ArrayList clusters=new ArrayList();
double rj[];
double squashFactor=1.5;
double acceptRatio=.5;
double rejectFactor=0.3;
double beta=4.0/(Math.pow(rb,2.0));
double max[];
double min[];
int numofdimen=2;    // as according to the input dataset
int numofPoints=29; // as according to the input dataset
ArrayList centersArrayList=new ArrayList();
Potential p=new Potential();
double Pi=0;
boolean noCenter=false;
boolean flag=false;

{
data=new double[2][29];
normData=new double[2][29];
max=new double[2];
min=new double[2];
rj=new double[2];
double[] sigmas=new double[centersArrayList.size()];
rj[0]=100;
rj[1]=50;
int index;
for(int i=0;i<29;i++)
{
for(int j=0;j<2;j++)
{
data[j][i]=data[j][i];
}

}
dataNormalize();
calculatePotential();

int m=0;
while(!flag)
{
sortPotentials();
index=setCenters(Potentials.size()-1);
sigmas=calculateSigmas();
if(index!=-1)
{
new cluster()
//setting the cluster
cluster.setCentroid(getCenterPoint(index));
cluster.setSigmas(sigmas);

RecalculatePotential(index);
}
else
{
flag=true;
}
}
}

public void dataNormalize()

{
//getting the max and min data point
for(int m=0;m<numofdimen;m++)
{
min[m]=data[m][0];

for(int i=0;i<numofPoints;i++)
{
if(min[m]>data[m][i])
{
min[m]=data[m][i];
}

}

}
for(int m=0;m<numofdimen;m++)
{
max[m]=data[m][0];

for(int i=0;i<numofPoints;i++)
{
if(max[m]<data[m][i])
{
max[m]=data[m][i];
}

}

}

//normalizing
for(int m=0;m<numofdimen;m++)
{
for(int i=0;i<numofPoints;i++)
{
normData[m][i]=(data[m][i]-min[m])/(max[m]-min[m]);

}

}
}

public void calculatePotential(){

double distance=0;
double tempPotential=0;

for(int k=0;k<numofPoints;k++)
{
for(int i=0;i<numofPoints;i++)
{
if(k!=i)
{
for(int m=0;m<numofdimen;m++)
{
distance+=normData[m][k]-normData[m][i];

}

tempPotential=(Math.exp(-1* alpha *Math.pow(distance,2)));

if(i!=0)
{

//here p is an object of potential class and here we are getting the previous set potentials
tempPotential+=previousPotentials.getValue();
}
}

}
p.setPotentials(k,tempPotential);
p=new Potential();
}

}

void RecalculatePotential(int index_of_center)
{
double distance=0;
double tempPotential;

for(int k=0;k<numofPoints;k++)
{
if(k!=index_of_center)
{
for(int m=0;m<numofdimen;m++)
{
distance+=normData[m][k]-normData[m][index_of_center];

}
tempPotential=(Math.exp(-1*beta*Math.pow(distance,2)));
tempPotential=((Potentials.get(k))-(((Potentials.get(index_of_center)))*tempPotential);

p =new Potential();
p.setPotentials(k,tempPotential);
Potentials.set(k,p);
p=new Potential();
}
}

}

boolean ifNewCenter(int index_of_center)
{
//if not new return false
//if new return true
}

double getMinDistance(int index_of_center)
{

double vectorDistances[]=new double[numofdimen];
double distances[]=new double[centersArrayList.size()];
double minDistanceistance;
for(int j=0;j<centersArrayList.size();j++)
{
for(int m=0;m<numofdimen;m++)
{
if(index_of_center!=j)
{
vectorDistances[m]=normData[m][index_of_center]-normData[m][((Integer)(centers.get(j))).intValue()];
}
}
distances[j]=calculateVLength(vectorDistances);
}

//sort the distances
return distances[0];
}

public void sortPotentials()
{
//returns the sorted list of potentials
}

public int setCenters(int maxIndex)
{

double minDistance;
double PotentialCenter;
PotentialCenter=((Double)(sortedPotentials.get(maxIndex))).doubleValue();
if(centersArrayList.size()!=0)
{

if(ifNewCenter()) // here we are checking the the center is new or not
{
minDistance=getMinDistance(maxIndex);

if(PotentialCenter>((acceptRatio)*((Potential)Potentials.get(Potentials.size()-1)).getValue()))
else if(clusteringEnd(maxIndex))
flag=true;
{
p=new Potential();
p.setPotentials(maxIndex,0);
Potentials.set(maxIndex,p);

if(maxIndex>0)
{
setCenters(maxIndex-1);
}
else
{
noCenter=true;
return 0;
}
}
else

{
//   System.out.println("flag is true nwo------------------------------------");

}
}
else
{
if(maxIndex>0)
{
setCenters(maxIndex-1);
}
else
{
noCenter=true;
return 0;
}
}
}
else
{
Pi=PotentialCenter;
}
if(!noCenter || !flag)
{
return ((Integer)(centersArrayList.get(centersArrayList.size()-1))).intValue();
}
else
{
return -2;
}
}

public boolean clusteringEnd(int centerindex)
{

//comparing the current potential with the rejectFactor* first largest potential
if((((Potential)(Potentials.get(centerindex))))<(rejectFactor*(((Potential)(Potentials.get(Potentials.size()-1))))))
return true;

return false;
}
public double[] calculateSigmas()
{
double sigmas[]=new double[numofdimen];

for(int m=0;m<numofdimen;m++)
{
sigmas[m]=(rj[m]*(max[m]-min[m]))/(Math.sqrt(8.0));
}
return sigmas;
}
public double calculateVLength(double input[]){
double temp=0;
double length=0;

for(int i=0;i<input.length;i++)
{
temp+=Math.pow(input[i],2);
}
length=Math.sqrt(temp);

return length;
}

public static void main(String[] args) {

double Points[][]={  {0,.16,.24,.42,.48,.66,.83,.24,.42,.48,.66,.66,.16,.24,.42,.42,.48,.48,.48,.66,.66,.66,.66,.66,.66,.66,.83,.83,.83,.66},
{0,0,0,0,0,0,0,.15,.13,.1,.12,.18,.58,.78,.59,.78,.45,.49,.58,.45,.49,.58,.65,.71,.715,.72,.66,.725,.726,.455}
};
SClustering sc;
sc=new SClustering(Points,.4);
}
}
``````

but My problem in the code is :-

when I am running my program I getting only two clusters with centroid1: 0.83,0.725 centroid2:- 0.83,0.726

but when I execute the Matlab 'clusterfind' program on the same above mentioned dataset I am getting 3 clusters with

centroid1: 0.66,0.65 centroid2:- 0.48,0.10 centroid3:- 0.16,0.0

the various parameter values that are shown in the image below is also same in my implementation

so is there any problem in the algorithm that I am implementing, kindly provide me guidance

-
Post your code so we have a better idea of what you're doing? –  Squazic Apr 1 '12 at 6:41
@Squazic I have added the code –  Deepak Apr 1 '12 at 7:35
@Squazic: Can you please provide me any working example of subtractive clustering –  Deepak Apr 1 '12 at 10:40