Fractions with integers is called **fixed point** math.

Try Googling "fixed point".

Fixed point tips and tricks are out of the scope of SO answer...

Example: 5 tap FIR filter

// C is the filter coefficients using 2.8 fixed precision.
// 2 MSB (of 10) is for integer part and 8 LSB (of 10) is the fraction part.
// Actual fraction precision here is 1/256.

```
int FIR_5(int* in, // input samples
int inPrec, // sample fraction precision
int* c, // filter coefficients
int cPrec) // coefficients fraction precision
{
const int coefHalf = (cPrec > 0) ? 1 << (cPrec - 1) : 0; // value of 0.5 using cPrec
int sum = 0;
for ( int i = 0; i < 5; ++i )
{
sum += in[i] * c[i];
}
// sum's precision is X.N. where N = inPrec + cPrec;
// return to original precision (inPrec)
sum = (sum + coefHalf) >> cPrec; // adding coefHalf for rounding
return sum;
}
int main()
{
const int filterPrec = 8;
int C[5] = { 8, 16, 208, 16, 8 }; // 1.0 == 256 in 2.8 fixed point. Filter value are 8/256, 16/256, 208/256, etc.
int W[5] = { 10, 203, 40, 50, 72}; // A sampling window (example)
int res = FIR_5(W, 0, C, filterPrec);
return 0;
}
```

**Notes:**

In the above example:

- the samples are integers (no fraction)
- the coefs have fractions of 8 bit.
- 8 bit fractions mean that each change of
`1`

is treated as 1/256. `1 << 8 == 256`

.
- Useful notation is Y.Xu or Y.Xs. where Y is how many bits are allocated for the integer part and X for he fraction. u/s denote signed/unsigned.
- when multiplying 2 fixed point numbers, their precision (size of fraction bits) are added to each other.
- Example A is 0.8u, B is 0.2U. C=A*B. C is 0.10u
- when dividing, use a shift operation to lower the result precision. Amount of shifting is up to you. Before lowering precision it's better to add a
`half`

to lower the error.
- Example: A=129 in 0.8u which is a little over 0.5 (129/256). We want the integer part so we right shift it by 8. Before that we want to add a
`half`

which is 128 (1<<7). So A = (A + 128) >> 8 --> 1.
- Without adding a half you'll get a larger error in the final result.

`1`

? Then the real value is just the`unsigned int`

multiplied by a scale factor. Think of it as calculating in cents (0.01) instead of dollars/euros/whatever. – rubenvb Dec 11 '13 at 13:32totalSteps= the increment used to phase 0 to 200 (after checking its polarity +/- in a subroutine). Essentially the phasing has to complete exactly at the given cycle. It's working, but it's skipping at least 2 iterations when thetotalStepsgoes over 300. – Mark Löwe Dec 11 '13 at 13:42