Standard non-recursive radix-2 algorithm. I realise what I have here isn't optimal for performance (like repeated trig calls), I just want to get it right before optimising and porting to VHDL. I'm using the complex.h header.
I get correct results for arrays of length 8, but not for 16 or 32. HOWEVER, for real signals, we still get the correct result of conjugal symmetry, just the values are wrong. This leads me to believe that the sorting is correct, but maybe there's something wrong with the trig calls for smaller values? Can anyone help?
I apologise that my code isn't fantastically commented, but honestly it wouldn't help much for the FFT algorithm.
void FFT(double complex x[], int N){
//bit reverse
int s = log2(N);
for(int i = 0; i < N/2; i++){
int h = bitrev(i, s);
printf("%u ", h);
double complex temp = x[i];
x[i] = x[h];
x[h] = temp;
}
unsigned int Np = 2; //NUM POINTS IN EACH BLOCK. INITIALLY 2
unsigned int Bp = (N/2);
for(int i = 0; i < s; i++){
int NpP = Np>>1; //num butterflies
int BaseT = 0;
for (int j = 0; j < Bp; j++){
int BaseB = BaseT + NpP;
for(int k = 0; k < NpP; k++){
double complex top = x[BaseT + k];
double complex bot = (ccos(2*pi*k/Np) - I*csin(2*pi*k/Np))*x[BaseB + k];
x[BaseT + k] = top+bot;
x[BaseB + k] = top-bot;
}
BaseT = BaseT + Np;
}
Bp = Bp>>1;
Np = Np<<1;
}
}
Output is printed with:
for(int i = 0; i < LENGTH; i++){
printf("%f + %fj\n", creal(x[i]), cimag(x[i]));
}
Here's a length 8 input, and the correct output:
double complex x[LENGTH] = {1.0, -1.0, 1.0, -1.0, 10.0, -1.0, 5.0, -1.0};
Output:
13.000000 + 0.000000j
-9.000000 + 4.000000j
5.000000 + 0.000000j
-9.000000 + -4.000000j
21.000000 + 0.000000j
-9.000000 + 4.000000j
5.000000 + 0.000000j
-9.000000 + -4.000000j
Here's a length 16 input, the incorrect output that I get, and what it should be:
double complex x[SIZE] = {10.0, -1.0, 5.0, -1.0, 4.0, 4.0, 2.0, 6.0, 9.0, 3.0, 8.0, 4.0, 5.0, 4.0, 3.0, 8.0};
Output (incorrect):
73.000000 + 0.000000j
-4.882497 + 10.451032j
12.535534 + 5.020815j
6.975351 + 7.165394j
12.000000 + 7.000000j
-0.732710 + 0.094326j
5.464466 + 19.020815j
2.639856 + 3.379964j
19.000000 + 0.000000j
2.639856 + -3.379964j
5.464466 + -19.020815j
-0.732710 + -0.094326j
12.000000 + -7.000000j
6.975351 + -7.165394j
12.535534 + -5.020815j
-4.882497 + -10.451032j
Correct output:
73.000000 + 0.000000j
-4.175390 + 10.743925j
13.535534 + 4.020815j
6.268244 + 5.458287j
10.000000 + 7.000000j
-1.439817 + 1.801433j
6.464466 + 20.020815j
3.346963 + 3.087071j
19.000000 + 0.000000j
3.346963 + -3.087071j
6.464466 + -20.020815j
-1.439817 + -1.801433j
10.000000 + -7.000000j
6.268244 + -5.458287j
13.535534 + -4.020815j
-4.175390 + -10.743925j
For this length 16 example, it gives the correct output (!?):
double complex x[SIZE] = {30.0, -1.0, 4.0, -6.0, 4.0, 9.0, 2.0, 6.0, 9.0, 3.0, -8.0, 4.0, -5.0, 4.0, 3.0, 8.0};
66.000000 + 0.000000j
22.604378 + -9.862676j
43.535534 + 28.091883j
24.900438 + 4.851685j
37.000000 + -3.000000j
-1.285214 + 2.408035j
36.464466 + 10.091883j
37.780399 + 23.693673j
12.000000 + 0.000000j
37.780399 + -23.693673j
36.464466 + -10.091883j
-1.285214 + -2.408035j
37.000000 + 3.000000j
24.900438 + -4.851685j
43.535534 + -28.091883j
22.604378 + 9.862676j
EDIT: I've realised my problem: my bit reversing loop was completely wrong. I should have thought about that seemingly simple part and tested it more thoroughly. The reason it worked for the last case was because it had repeated values, which coincidentally gave the same vector as the working reversal. Here's the fixed loop:
int s = log2(N);
for(int i = 0; i < N; i++){
int h = bitrev(i, s);
if(i < h){
double complex temp = x[i];
x[i] = x[h];
x[h] = temp;
}
}
