Suppose that you have the following example:

```
n = 4;
rng(0)
A = rand(n,n);
B = A * A';
```

If the matrix `B`

is full rank, you can not exactly cover the original matrix using fewer dimensions. So, you can only *approximate* it. The key idea here is to minimize the reconstruction error.

You can decompose `B`

into its eigenvectors using eigenvalue decomposition. You can use `eig`

in MATLAB, but you need to sort the eigenvalues and corresponding eigenvectors afterwards. Instead, I prefer Singular Value Decomposition and use `svd`

in MATLAB. Note that SVD gives the optimal solution for the reconstruction error in low-rank matrix approximation.

```
[U,S,~] = svd(B);
U = U * sqrt(S);
```

We know that `B = U * U'`

now. See relation between SVD and eigenvalue decomposition here.

As I stated, we need to approximate it. I choose the dimensions covering 99% of the total variance as follows:

```
coverage = cumsum(diag(S.^2));
coverage = coverage ./ norm(S,'fro')^2;
[~, nEig] = max(coverage > 0.99);
U2 = U(:,1:nEig);
```

U2 has 2 columns instead of 4 in this case. If the data is correlated, the gain will be even less. The results are as follows:

```
B
B1 = U*U'
B2 = U2*U2'
B =
2.8966 2.1881 1.1965 2.1551
2.1881 1.9966 0.6827 1.8861
1.1965 0.6827 0.7590 0.5348
2.1551 1.8861 0.5348 2.0955
B1 =
2.8966 2.1881 1.1965 2.1551
2.1881 1.9966 0.6827 1.8861
1.1965 0.6827 0.7590 0.5348
2.1551 1.8861 0.5348 2.0955
B2 =
2.8896 2.2134 1.1966 2.1385
2.2134 1.9018 0.6836 1.9495
1.1966 0.6836 0.7586 0.5339
2.1385 1.9495 0.5339 2.0528
```

That seems to be a good approximation.