You can apply `numden`

to extract the numerator and the denominator polynomical expression:

```
[numexpr, denexpr] = numden(sym(H)) %// 'sym' makes sure that H is symbolic
```

and then you can extract the symbolic coefficients of `S`

by using the `coeffs`

command (remember to apply `expand`

on each expression first to obtain their polynomial forms).

However, note that `coeffs`

returns only the non-zero coefficients. To overcome this issue, I suggest the following:

```
%// Extract numerator coefficients
[numcoef, numpow] = coeffs(expand(numexpr), S);
num = rot90(sym(sym2poly(sum(numpow))), 2);
num(num ~= 0) = coeffs(expand(numexpr), S);
%// Extract denominator coefficients
[dencoef, denpow] = coeffs(expand(denexpr), S);
den = rot90(sym(sym2poly(sum(denpow))), 2);
den(den ~= 0) = coeffs(expand(denexpr), S);
```

P.S: you can also apply `sym2polys`

tool from the MATLAB Exchange on `numexpr`

and `denexpr`

instead.

Also note that it is more common for the last elements in the coefficient vectors to be associated with the highest powers of `S`

, so the result of this solution will be in reverse order to what you have described in your question.

### Example

```
%// Create symbolic function
syms a b S
H = b * S / (a + S^2)
[numexpr, denexpr] = numden(sym(H));
%// Extract numerator coefficients
[numcoef, numpow] = coeffs(expand(numexpr), S);
num = rot90(sym(sym2poly(sum(numpow))), 2);
num(num ~= 0) = coeffs(expand(numexpr), S);
%// Extract denominator coefficients
[dencoef, denpow] = coeffs(expand(denexpr), S);
den = rot90(sym(sym2poly(sum(denpow))), 2);
den(den ~= 0) = coeffs(expand(denexpr), S);
```

The result is:

```
num =
[0, b]
den =
[a, 0, 1]
```