I've improved the methodology provided by Christian in order to accept a wider range of fractions. The trick was to "pre-normalize" the unit vector by dividing it by the smallest non-zero entry. This works reliably for all fractions of a specified maximum denominator.

```
from fractions import Fraction, gcd
def recover_integer_vector(u, denom=50):
'''
For a given vector u, return the smallest vector with all integer entries.
'''
# make smallest non-zero entry 1
u /= min(abs(x) for x in u if x)
# get the denominators of the fractions
denoms = (Fraction(x).limit_denominator(denom).denominator for x in u)
# multiply the scaled u by LCM(denominators)
lcm = lambda a, b: a * b / gcd(a, b)
return u * reduce(lcm, denoms)
```

## Testing:

The following code was used to ensure that all fractions in the given range work correctly.

```
import numpy as np
from numpy import array
from itertools import combinations_with_replacement
for t in combinations_with_replacement(range(1, 50), 3):
if reduce(gcd, t) != 1: continue
v = array(map(float, t))
u = v / np.linalg.norm(v)
w = recover_integer_vector(u)
assert np.allclose(w, v) or np.allclose(w, -v)
```

As can be seen by the testing time, this code is **not** very quick. It took my computer about 6 seconds to test. I'm not sure whether the timing can be improved.