Here I would like to give another heuristic, which is different from btilly's.

The task is to find integers `m`

and `n`

such that `m / n <= j < k <= (m + 1) / n`

, with `n`

as big as possible (but still under `M`

).

Intuitively, it is preferable that the fraction `m / n`

is close to `j`

. This leads to the idea of using continued fractions.

The algorithm that I propose is quite simple:

- calculate all the continued fractions of
`j`

using minus signs (so that the fractions are always approching `j`

from above), until the denominator exceeds `M`

;
- for each such fraction
`m / n`

, find the biggest integer `i >= 0`

such that `k <= (m * i + 1) / (n * i)`

and `n * i <= M`

, and replace the fraction `m / n`

with `(m * i) / (n * i)`

;
- among all the fractions in 2, find the one with biggest denominator.

The algorithm is not symmetric in `j`

and `k`

. Hence there is a similar `k`

-version, which in general should not give the same answer, so that you can choose the bigger one from the two results.

Example: Here I will take btilly's example: `j = 0.6`

and `k = 0.65`

, but I will take `M = 10`

.

I will first go through the `j`

-procedure. To calculate the continued fraction expansion of `j`

, we compute:

```
0.6
= 0 + 0.6
= 0 + 1 / (2 - 0.3333)
= 0 + 1 / (2 - 1 / (3 - 0))
```

Since `0.6`

is a rational number, the expansion terminates in fintely many steps. The corresponding fractions are:

```
0 = 0 / 1
0 + 1 / 2 = 1 / 2
0 + 1 / (2 - 1 / 3) = 3 / 5
```

Computing the corresponding `i`

values in step 2, we replaces the three factions with:

```
0 / 1 = 0 / 1
1 / 2 = 3 / 6
3 / 5 = 6 / 10
```

The biggest denominator is given by `6 / 10`

.

Continue with the example above, the corresponding `k`

-procedure goes as follows:

```
0.65
= 1 - 0.35
= 1 - 1 / (3 - 0.1429)
= 1 - 1 / (3 - 1 / (7 - 0))
```

Hence the corresponding fractions:

```
1 = 1 / 1
1 - 1 / 3 = 2 / 3
1 - 1 / (3 - 1 / 7) = 13 / 20
```

Passing step 2, we get:

```
1 / 1 = 2 / 2
2 / 3 = 6 / 9
13 / 20 = 0 / 0 (this is because 20 is already bigger than M = 10)
```

The biggest denominator is given by `6 / 9`

.

EDIT: experimental results.

To my surprise, the algorithm works better than I thought.

I did the following experiment, with the bound `M`

ignored (equivalently, one can take `M`

big enough).

In every round, I generate a pair `(j, k)`

of uniformly distributed random numbers in the inteval `[0, 1)`

with `j < k`

. If the difference `k - j`

is smaller than `1e-4`

, I discard this pair, making this round ineffective. Otherwise I calculate the true result `trueN`

using naive algorithm, and calculate the heuristic result `heurN`

using my algorithm, and add them to statistic data. This goes for 1e6 rounds.

Here is the result:

```
effective round = 999789
sum of trueN = 14013312
sum of heurN = 13907575
correct percentage = 99.2262 %
average quotient = 0.999415
```

The `correct percentage`

is the percentage of effective rounds such that `trueN`

is equal to `heurN`

, and the `average quotient`

is the average of the quotient `heurN / trueN`

for all effective rounds.

Thus the method gives the correct answer in 99%+ cases.

I also did experiments with smaller `M`

values, and the results are similar.

`M = 80 million`

doesn't seem that large, since every choice of`N`

can be checked in`O(1)`

time. But of course it depends on your actual requirements. – WhatsUp May 2 '16 at 19:28