# Finding the closest integer fraction to a given random real

Given two ranges of positive integers x: [1 ... n] and y: [1 ... m] and random real R from 0 to 1, I need to find the pair of elements (i,j) from x and y such that xi / yj is closest to R.

What is the most efficient way to find this pair?

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What do you have so far? –  Kobi Dec 8 '10 at 8:47
I'm keeping Xi fixed and getting the closest Yi. I'm finding I'm not close enough. I know I can get closer by stepping Xi up and down and seeing what I get, but that seems gross. –  John Shedletsky Dec 8 '10 at 8:48
It seems easy on first glance, but I think it might be hard. If there is not a perfect solution like 1/2 = .5, there may be multiple correct answers. Actually I guess in that case there are also multiple answers like 2/4. In the case where there are multiple answers, I want the biggest Xi and Yi in the range. –  John Shedletsky Dec 8 '10 at 8:51
See this answer –  Gareth Rees Dec 8 '10 at 12:19
Are x[] and y[] a list/array of numbers or a range of numbers? –  Axn Dec 8 '10 at 19:16

Use Farey sequence.

1. Start with a = 0, b = 1 and A = {the closest of a and b to R}.
2. Let c be the next Farey fraction between a and b, given by c = (num(a) + num(b))/(denom(a) + denom(b)) (make sure to devide num(c) and denom(c) by gcd(num(c), denom(c))).
3. If c's numerator or denominator is out of your input range, output A and stop.
4. If c is closer to R than A, set A to c.
5. If R is in [a, c] set b = c, otherwise set a = c.
6. Go to 2.

This finds the best approximation in O(1) space, O(M) time worst-case, and O(log M) on average.

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-1: Why would you even expect this to work? Remember, the numerator and denominators are restricted. –  Aryabhatta Dec 8 '10 at 9:51
@moron: it actually does work for restricted denominators and for numbers between 0 and 1 (which is the case here). in fact, i'm pretty sure it can be adapted for restricted numerators (which restrict the denominators, given the number). –  lijie Dec 8 '10 at 10:41
I'm not sure about the O(log M) average case though, don't have time to analyze right now. –  ybungalobill Dec 8 '10 at 11:27
@John: x = [5], y = [8], R = 3/5. This outputs 1 and stops (in step 3) which is not even a feasible solution. –  Aryabhatta Dec 8 '10 at 18:57
I accepted because it looked the same as this - johndcook.com/blog/2010/10/20/best-rational-approximation/… –  John Shedletsky Dec 8 '10 at 19:45

The standard approach to approximating reals with rationals is computing the continued fraction series (see [1]). Put a limit on the nominator and denominator while computing parts of the series, and the last value before you break the limits is a fraction very close to your real number.

This will find a very good approximation very fast, but I'm not sure this will always find a closest approximation. It is known that

any convergent [partial value of the continued fraction expansion] is nearer to the continued fraction than any other fraction whose denominator is less than that of the convergent

but there may be approximations with larger denominator (still below your limit) that are better approximations, but are not convergents.

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I may be misunderstanding - I don't want a continued fraction as the answer, I want a single numerator and denominator. Are you saying that if I find the continued fraction then I have some sort of guarantee of optimality on a more simplified fraction? –  John Shedletsky Dec 8 '10 at 9:04
What you probably want are the "Best rational approximations" (on the wikipedia page for the continued fraction), which is either a convergent to the continued fraction or has the final quotient of one of the convergents decreased by one. –  Nabb Dec 8 '10 at 9:23
–  starblue Dec 8 '10 at 21:15

Prolly get flamed, but a lookup might be best where we compute all of the fractional values for each of the possible values.. So a simply indexing a 2d array indexed via the fractional parts with the array element containing the real equivalent. I guess we have discrete X and Y parts so this is finite, it wouldnt be the other way around.... Ahh yeah, the actual searching part....erm reet....

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In my particular application, n and m are around 100,000. This makes pre-computation undesirable. I was hoping for some sort of hillclimb optimization. –  John Shedletsky Dec 8 '10 at 8:55
It was like QI, I just answered the idiot answer lol.... –  brumScouse Dec 8 '10 at 8:56

Rather than a completely brute force search, do a linear search over the shortest of your lists, using round to find the best match for each element. Maybe something like this:

``````best_x,best_y=(1,1)
for x in 1...n:
y=max(1,min(m,round(x/R)))
#optional optimization (if you have a fast gcd)
if gcd(x,y)>1:
continue

if abs(R-x/y)<abs(R-bestx/besty):
best_x,best_y=(x,y)
return (best_x,best_y)
``````

Not at all sure whether the `gcd` "optimization" will ever be faster...

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The Solution: You can do this O(1) space and O(m log(n)) time:

there is no need to create any list to search,

The pseudo code may be is buggy but the idea is this:

``````r: input number to search.
n,m: the ranges.

for (int i=1;i<=m;i++)
{
minVal = min(Search(i,1,n,r), minVal);
}

//x and y are start and end of array:
decimal Search(i,x,y,r)
{
if (i/x > r)
return i/x - r;

decimal middle1 = i/Cill((x+y)/2);
decimal middle2 = i/Roof((x+y)/2);

decimal dist = min(middle1,middle2)

decimal searchResult = 100000;

if( middle > r)
searchResult = Search (i, x, cill((x+y)/2),r)
else
searchResult = Search(i, roof((x+y)/2), y,r)

if  (searchResult < dist)
dist = searchResult;

return dist;
}
``````

finding the index as home work to reader.

Description: I think you can understand what's the idea by code, but let trace one of a for loop: when i=1:

you should search within bellow numbers: 1,1/2,1/3,1/4,....,1/n you check the number with (1,1/cill(n/2)) and (1/floor(n/2), 1/n) and doing similar binary search on it to find the smallest one.

Should do this for loop for all items, so it will be done m time. and in each time it takes O(log(n)). this function can improve by some mathematical rules, but It will be complicated, I skip it.

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Any clever optimizations to do better than O(nm) space and O(nm lg (nm)) time? –  John Shedletsky Dec 8 '10 at 9:01
@John Shedletsky, the @ybungalobill answer is good. –  Saeed Amiri Dec 8 '10 at 9:08
No it is not. Especially not without proof. –  Aryabhatta Dec 8 '10 at 18:42
@Moron, you want proof what? The algorithm as described above run in the specified order, and will get the best answer, for example for binary search you saying the proof, it finds exact match? no because the algorithm describes the trust, about the order, it's easy to proof it, if is there any ambiguity tell to describe it. –  Saeed Amiri Dec 8 '10 at 20:10

Given that R is a real number such that `0 <= R <= 1`, integers `x: [1 ... n]` and integers `y: [1 ... m]`. It is assumed that `n <= m`, since if `n > m` then `x[n]/y[m]` will be greater than `1`, which cannot be the closest approximation to `R`.

Therefore, the best approximation of R with the denominator d will be either `floor(R*d) / d` or `ceil(R*d) / d`.

The problem can be solved in `O(m)` time and `O(1)` space (in Python):

``````from __future__ import division
from random import random
from math import floor

def fractionize(R, n, d):
error = abs(n/d - R)
return (n, d, error)  # (numerator, denominator, absolute difference to R)

def better(a, b):
return a if a[2] < b[2] else b

def approximate(R, n, m):
best = (0, 1, R)
for d in xrange(1, m+1):
n1 = min(n, int(floor(R * d)))
n2 = min(n, n1 + 1) # ceil(R*d)
best = better(best, fractionize(R, n1, d))
best = better(best, fractionize(R, n2, d))
return best

if __name__ == '__main__':
def main():
R = random()
n = 30
m = 100
print R, approximate(R, n, m)
main()
``````
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