I'm trying to implement a version of the **Fuzzy C-Means algorithm** in Java and I'm trying to do some optimization by computing just once everything that can be computed just once.

This is an iterative algorithm and regarding the updating of a matrix, the *pixels x clusters* membership matrix `U`

(the sum of the values in a row must be 1.0), this is the update rule I want to optimize:

where the x are the element of a matrix `X`

(*pixels x features*) and v belongs to the matrix `V`

(*clusters x features*). And `m`

is a parameter that ranges from `1.1`

to `infinity`

and `c`

is the number of clusters. The distance used is the euclidean norm.

If I had to implement this formula in a banal way I'd do:

```
for(int i = 0; i < X.length; i++)
{
int count = 0;
for(int j = 0; j < V.length; j++)
{
double num = D[i][j];
double sumTerms = 0;
for(int k = 0; k < V.length; k++)
{
double thisDistance = D[i][k];
sumTerms += Math.pow(num / thisDistance, (1.0 / (m - 1.0)));
}
U[i][j] = (float) (1f / sumTerms);
}
}
```

In this way some optimization is already done, I precomputed all the possible squared distances between `X`

and `V`

and stored them in a matrix `D`

but that is not enough, since I'm cycling througn the elements of `V`

two times resulting in two nested loops.
Looking at the formula the numerator of the fraction is independent of the sum so I can compute numerator and denominator independently and the denominator can be computed just once for each pixel.
So I came to a solution like this:

```
int nClusters = V.length;
double exp = (1.0 / (m - 1.0));
for(int i = 0; i < X.length; i++)
{
int count = 0;
for(int j = 0; j < nClusters; j++)
{
double distance = D[i][j];
double denominator = D[i][nClusters];
double numerator = Math.pow(distance, exp);
U[i][j] = (float) (1f / (numerator * denominator));
}
}
```

Where I precomputed the denominator into an additional column of the matrix `D`

while I was computing the distances:

```
for (int i = 0; i < X.length; i++)
{
for (int j = 0; j < V.length; j++)
{
double sum = 0;
for (int k = 0; k < nDims; k++)
{
final double d = X[i][k] - V[j][k];
sum += d * d;
}
D[i][j] = sum;
D[i][B.length] += Math.pow(1 / D[i][j], exp);
}
}
```

By doing so I encounter numerical differences between the 'banal' computation and the second one that leads to different numerical value in `U`

(not in the first iterates but soon enough). I guess that the problem is that exponentiate very small numbers to high values (the elements of `U`

can range from 0.0 to 1.0 and `exp`

, for `m = 1.1`

, is `10`

) leads to very small values, whereas by dividing the numerator and the denominator and **THEN** exponentiating the result seems to be better numerically. The problem is it involves much more operations.

**UPDATE**

Some values I get at ** ITERATION 0**:

This is the first row of the matrix `D`

not optimized:

`384.6632 44482.727 17379.088 1245.4205`

This is the first row of the matrix `D`

the optimized way (note that the last value is the precomputed denominator):

`384.6657 44482.7215 17379.0847 1245.4225 1.4098E-26`

This is the first row of the `U`

not optimized:

`0.99999213 2.3382613E-21 2.8218658E-17 7.900302E-6`

This is the first row of the `U`

optimized:

`0.9999921 2.338395E-21 2.822035E-17 7.900674E-6`

** ITERATION 1**:

This is the first row of the matrix `D`

not optimized:

`414.3861 44469.39 17300.092 1197.7633`

This is the first row of the matrix `D`

the optimized way (note that the last value is the precomputed denominator):

`414.3880 44469.38 17300.090 1197.7657 2.0796E-26`

This is the first row of the `U`

not optimized:

`0.99997544 4.9366603E-21 6.216704E-17 2.4565863E-5`

This is the first row of the `U`

optimized:

`0.3220644 1.5900239E-21 2.0023086E-17 7.912171E-6`

The last set of values shows that they are very different due to a propagated error (I still hope I'm doing some mistake) and even the constraint that the sum of those values must be 1.0 is violated.

Am I doing something wrong? Is there a possible solution to get both the code optimized and numerically stable? Any suggestion or criticism will be appreciated.