I'm trying to code a digital ringing filter on an AVR microncontroller, and I am having some trouble with the implementation of the state diagram in fixed point arithmetic. Here's a picture of the signal flow I am attempting to write code for:

Edit: (I believe the equation for T_c above should be e^[-1/(F_s*D)] )

Here's what I have so far. I have a routine called smultfix that does a fixed point signed multiply on two 8 bit signed integers and returns a 16 bit signed product. F_c and T_c are 8 bit signed binary fractions. "Output" and the intermediate step at the junction of T_c's input and the delay element, z1, are treated as 16 bit binary fractions. So I have:

(assume F_c and T_c are defined elsewhere)

```
int8_t generateSample()
{
static int16_t z1 = 0x7FFF; //initialize first delay element to max positive value
static int16_t output;
int8_t byteOutput = 0;
int8_t bytez1 = 0;
bytez1 = (z1 & 0xFF00)>>8; //make z1 into an eight bit signed binary fraction for
//multiplication
output = (smultfix(bytez1,F_c)<<1) + output; //calculate output, shift product
//left once to
//remove double sign bit
byteOutput = (output & 0xFF00)>>8; //generate output byte
z1 = (-(smultfix(byteOutput,F_c)<<1)) - \
(smultfix(bytez1,T_c)<<1) //generate intermediate
//product z1
return byteOutput;
}
```

Unfortunately, I seem to have just created a poor random number generator, as this code generates a lot of garbage filling up my output buffer! If someone could point out where I might be going wrong, or if they have an implementation idea that would be better, it would be much appreciated.