The standard answer to this question is that which Brett presented,
i.e., using `Thread`

.
However, I find that for use in `DSolve`

, `NDSolve`

, etc... the command `LogicalExpand`

is better.

```
eqn = {f'[t], g'[t]} == {{a, b}, {c, d}}.{f[t], g[t]};
LogicalExpand[eqn]
(* f'[t] == a f[t] + b g[t] && g'[t] == c f[t] + d g[t] *)
```

It doesn't convert a vector equation to a list, but it is more useful since it automatically flattens out matrix/tensor equations and combinations of vector equations.
For example, if you wanted to add initial conditions to the above differential equation, you'd use

```
init = {f[0], g[0]} == {f0, g0};
LogicalExpand[eqn && init]
(* f[0] == f0 && g[0] == g0 &&
f'[t] == a f[t] + b g[t] && g'[t] == c f[t] + d g[t] *)
```

An example of a matrix equation is

```
mEqn = Array[a, {2, 2}] == Partition[Range[4], 2];
```

Using `Thread`

here is awkward, you need to apply it multiple times and `Flatten`

the result. Using `LogicalExpand`

is easy

```
LogicalExpand[mEqn]
(* a[1, 1] == 1 && a[1, 2] == 2 && a[2, 1] == 3 && a[2, 2] == 4 *)
```