First of all, I'm fairly new to anything related to DSP so my I might be asking something really weird or stupid.

NOTE: the system won't allow me to post mote then to links because I'm too new. I decided to add a - in front of any links so the system won't recognise them as links and I can post them anyway. unfortunately this means you'll have to copy/past to follow the link, sorry about this..

I am currently writing an application that needs control over the entire audible sound spectrum. I have chosen a frequency sampling filter because after reading some information I thought it to be able to give me this sort of control. My implementation consists of a comb filter that feeds 80 resonators in the 0-PI range with a sampling frequency of 44100Hz.

I'm curently getting the following impulse response: http://img545.imageshack.us/img545/1979/10269409.png

The current frequncy response looks like this: http://img198.imageshack.us/img198/24/freqj.png

I'm sorry about linking the images in this way, but the system won't allow me to post images because I'm too new, I'm also only allowed 2 links so I'll put a link to the code in a comment if I'm allowed to do that

All my filter coeficients have been 1 in this run

My conclusion is that the resonators are partially canceling eachother out where I wanted each peak to the the same height. I can't seem to find a way to correct this, is there anyone who can help me?

EDIT 1: I have put the most important functions here, I should have done that a LOT sooner. I'm happy to clear up anything that might not be clear.

```
//comb filter function
float filter::comb(buffer* x, float z, float input){
//store the new input value in the buffer
x->write(input);
//calculate the output value according to Y[n] = X[n] - z * X[n-160]
return x->read(0)-(z*x->read(160));
}
//resonator function
float filter::resonator(buffer* res, float r, float w, float phi, float amp){
static int odd_even=1;
float result=0;
if(odd_even){
odd_even=0;
//if called odd times calculate result according to Y[n] = 2 * r * cos(phi) * y[n-1] - r^2 * y[n-1] + amp * w
result=(2*r*cos(phi)*res->read(0))-(r*r*res->read(1))+(amp*w);
}
else{
odd_even=1;
//if called odd times calculate result according to Y[n] = 2 * r * cos(phi) * y[n-1] - r^2 * y[n-1] - amp * w
result=(2*r*cos(phi)*res->read(0))-(r*r*res->read(1))-(amp*w);
}
//store result in buffer
res->write(result);
return result/SCALE;
}
//filter execute function
float filter::exec(float value){
float w;
float total=0;
float temp=0;
cout<<value<<"\t";
//calculate the comb output
w=comb(combX,0.886867188,value);
for(int i=0;i<80;i++){
temp=(resonator(&res[i],0.999,w,(((1.125+i*2.25)/180.0)*pi),getCoef(i)));
total+=temp;
}
return total;
}
```

EDIT 2:

1 resonator at 91.125 degrees: -http://img708.imageshack.us/img708/9995/42515591.png

I think this is pretty much the desired result, a strong response at the desired frequency

2 resonators at 68.625 and 113.625 degrees: -http://img717.imageshack.us/img717/6840/3050.png

I think this is close to the desired response too, again strong reactions at the specified frequencies. I think it's a bit odd that the peaks are biger then in the 1 resonator test though.

8 resonators starting at 21.375 and then at 10 degree increments: -http://img269.imageshack.us/img269/8461/8resonators.png

I'm not sure what to make of this one, the last resonator has an extreme response, but the other ones seem reasonably in line with what should happen.

EDIT 3: I did another test with 16 resonators: -http://img810.imageshack.us/img810/8418/68001938.png

This gives pretty much the same result as the 8 resonator test. the major diffrence is that the same efect that is going on near PI is now also starting to get visible near the 0Hz.