This is a reformulaiton of shsmurfy's solution when you a priori choose 3 positive tolerances (e1,e2,e3)

The problem is then to search smallest positive integers (n1,n2,n3) and thus largest root frequency f such that:

```
f1 = n1*f +/- e1
f2 = n2*f +/- e2
f3 = n3*f +/- e3
```

We assume 0 <= f1 <= f2 <= f3

If we fix n1, then we get these relations:

```
f is in interval I1=[(f1-e1)/n1 , (f1+e1)/n1]
n2 is in interval I2=[n1*(f2-e2)/(f1+e1) , n1*(f2+e2)/(f1-e1)]
n3 is in interval I3=[n1*(f3-e3)/(f1+e1) , n1*(f3+e3)/(f1-e1)]
```

We start with n1 = 1, then increment n1 until the interval I2 and I3 contain an integer - that is `floor(I2min) different from floor(I2max)`

same with I3

We then choose smallest integer n2 in interval I2, and smallest integer n3 in interval I3.

Assuming normal distribution of floating point errors, the most probable estimate of root frequency f is the one minimizing

```
J = (f1/n1 - f)^2 + (f2/n2 - f)^2 + (f3/n3 - f)^2
```

That is

```
f = (f1/n1 + f2/n2 + f3/n3)/3
```

If there are several integers n2,n3 in intervals I2,I3 we could also choose the pair that minimize the residue

```
min(J)*3/2=(f1/n1)^2+(f2/n2)^2+(f3/n3)^2-(f1/n1)*(f2/n2)-(f1/n1)*(f3/n3)-(f2/n2)*(f3/n3)
```

Another variant could be to continue iteration and try to minimize another criterium like min(J(n1))*n1, until f falls below a certain frequency (n1 reaches an upper limit)...