### TL;DR: The question is about multiplication **ACCURACY**

I have to multiply matrices `A`

(100x8000), `B`

(8000x27) and `C`

(27x1).

Since matrices `B`

and `C`

are constant and `A`

is variable, I prefer to calculate it as: `ABC = np.dot(A, np.dot(B, C))`

. However I wonder, that it may be **numerically** worse (in terms of **accuracy**) than `np.dot(np.dot(a, B), C)`

.

What may be important: matrices `A`

and `B`

contain 8000 samples of (respectively) 100 and 27 correlated features.

Is there a **numerically** optimal (in terms of **accuracy**) order of the multiplication? If yes - how may I determine it?

### Special Case

It may be assumed that both `A`

and `B`

matrices are nonnegative.
Moreover:

```
C = np.linalg.solve(cov(B, k), X)
```

where `X`

is a 27x1 matrix of 27 (possibly correlated) random variables of unknown distribution, `cov = lambda X, k: np.dot(X.T, X) + k * np.eye(X.shape[1])`

, and `k`

is a nonnegative constant minimizing the expression:

```
sum((X[i, 0] - np.dot(np.dot(B[:, [i]].T, drop(B, i)),
np.linalg.solve(cov(drop(B, i), k),
np.delete(X, i, axis=0))) **2
for i in range(27))
```

The `drop()`

function is defined as `lambda X, i: np.delete(X, i, axis=1)`

.

### Even More Special Case

It may be assumed that `np.cov(B.T, B)`

is a covariance matrix of `X`

, which follows multivariate Gaussian distribution.

whyyou are worried about accuracy. The answer might be different depending on whether the matrices contain floats or large integers, for instance.`(AB)C`

(which is considered accurate) for performance purposes. Unfortunately, I do not remember any recommendations on matrix multiplication order from my numerical analysis class. For sure I am going to run tests with different precision, but I am looking for more solid, theoretical background here. So far my only idea is to write naive expressions for elements of`ABC`

and estimate the error.6more comments