So, if you have some horrible matrix

```
A = RandomReal[0.1, {4, 4}]; (* A horrible matrix *)
```

which we make anti-symmetric (so the solution is oscillatory)

```
A = A - Transpose@A;
```

Define the vector of functions and their initial conditions

```
v[x_] := {v1[x], v2[x], v3[x], v4[x]};
init = v[0] == RandomReal[1, 4]
```

Then the `NDSolve`

command looks like

```
sol = NDSolve[LogicalExpand[v'[x] == A.v[x] && init],
{v1, v2, v3, v4}, {x, 0, 1000}]
```

And the solutions can be plotted with

```
Plot[Evaluate[v[x] /. sol], {x, 0, 1000}]
```

Note that that the above differential equation is a linear, first order equation with constant coefficients, so is simply solved using a matrix exponential.
However, if the matrix `A`

was a function of `x`

, then analytic solutions become hard, but the numerical code stays the same.

For example, try:

```
A = RandomReal[1/10, {4, 4}] - Exp[-RandomReal[1/100, {4, 4}] x^2];
A = A - Transpose@A;
```

Which can produce solutions like