**TL;DR** use the matrices its easier to understand and takes advantage of optimized CPU instructions.

In computer science parlance, the efficiency (scalability) of algorithms is reasoned about using Big O cost. A score can be given to both the time and space complexity.

Using Big O notation lets compare the two approaches:

## Array Approach

**time complexity**:

Array index access is `O(1)`

time, no matter how large an array becomes, it is just as computationally easy to access an element given its index.

As you've created a function to compute the index of the `k-th`

weight, this adds some small complexity but would probably run in constant `O(1)`

time as it is a mathematical expression, so negligible.

**space complexity**:
`O(N)`

where `N`

is the number of weights across all layers.

## Matrices Approach

**time complexity**:

A matrix is essentially a 2d array with `O(1)`

access

**space complexity**

`O(N + M)`

, where `N`

is number of neurons and `M`

is number of weights.

Conceptually, we can see that the two approaches have an equivalent time and space complexity score.

However there are the other trade-offs involved (and as a good SO-er must inform you of those)

When it comes to working with the data in the array vs matrices approach, the array approach is less efficient as it circumvents the opportunity for MISD operations. As @liborm alluded to there are vectorised (MISD) operations handled by lower level system libraries like `LAPACK/BLAS`

, which "batch" CPU instructions for some matrix operations (less overhead cost to transfer and compute data at CPU compared to sending a new instruction every time)

Instead of having one matrix per layer, I thought of a way ... to store all of my weights in a single array

It's hard to see why you would opt-ed for the latter as it requires you to create a bespoke indexing function. Maybe its nicer to think about all your weights being in one long array place? However I would argue the mental load required to maintain the array mapping is higher than having multiple matrices dedicated to a layer.

A hash-table like structure of matrices would be much easier to reason about

```
layers <- list(layer1 = [[...]], layer2 = [[...]], layerN = [[...]])
```

## Further reading

http://www.noamross.net/blog/2014/4/16/vectorization-in-r--why.html