I'm guessing that the main issue is translating from Z domain to time.

Y(z) = H(z)*X(z)

H(z) = B(z)/A(z) = Y(z)/X(z)

B(z)*X(z) = A(z)*Y(z)

Then from the documentation:

B(z) = b(1)*z^-n + ... + b(n+1)
A(z) = z^-n + ... + a(n+1)

Converting to time domain:

b(1)*x(t) + b(2)*x(t-1) + ... + b(n+1)*x(t-n) = a(1)y(t) + ... + a(n+1)*y(t-n)

Then 'solving' for y(t), given that a(1) is 1:

y(t) = b(1)*x(t) + b(2)*x(t-1) + ... + b(n+1)*x(t-n) - a(2)*y(t-1) ... - a(n+1)*y(t-n)

where n = 7. So, say you have to arrays in which you store the last 6 values of the input x and the filter output y:

```
/* Warning Warning Warning:
This has not been tested,
for illustration purposes only */
double filter_data(double x)
{
static double x_prev[6] = {0};
static double y_prev[6] = {0};
/* x is newest input value */
double y; /* output to be calculated */
int ii;
/* let's just keep it really simple for now, you can get more sophisticated later */
y = 0.2557*x[0] + -0.5115*x_prev[0] + -0.2557*x_prev[1] + 1.0230*x_prev[2] +
-0.2557*x_prev[3] + -0.5115*x_prev[4] + 0.2557*x_prev[5] - -4.0196*y_prev[0] -
6.1894*y_prev[1] - -4.4532*y_prev[2] - 1.4208*y_prev[3] - -0.1418*y_prev[4] -
0.0044*y_prev[5];
/* really really wasteful, but simple shift of previous values */
for(ii=5;ii>0;ii--)
{
y_prev[ii] = y_prev[ii-1]
x_prev[ii] = x_prev[ii-1]
}
y_prev[0] = y;
x_prev[0] = x;
return y;
}
```

It's not great, but I think that ought to get you going. Let me know if something isn't clear!