# Algorithm

Consider a target number `r`

and a set `F`

of fractions `{1/2, 1/4, ... 1/(2^N)}`

. Let the smallest fraction, `1/(2^N)`

, be denoted `P`

.

Then the optimal sum will be equal to:

```
S = P * round(r/P)
```

That is, the optimal sum `S`

will be some **integer** multiple of the smallest fraction available, `P`

. The maximum error, `err = r - S`

, is `± 1/2 * 1/(2^N)`

. No better solution is possible because this would require the use of a number smaller than `1/(2^N)`

, which is the smallest number in the set `F`

.

Since the fractions `F`

are all power-of-two multiples of `P = 1/(2^N)`

, *any* integer multiple of `P`

can be expressed as a sum of the fractions in `F`

. To obtain the list of fractions that should be used, encode the integer `round(r/P)`

in binary and read off `1`

in the `kth`

binary place as "include the `kth`

fraction in the solution".

# Example:

Take `r = 0.3`

and `F`

as `{1/2, 1/4, 1/8, 1/16, 1/32}`

.

Multiply the entire problem by 32.

Take `r = 9.6`

, and `F`

as `{16, 8, 4, 2, 1}`

.

Round `r`

to the nearest integer.

Take `r = 10`

.

Encode `10`

as a binary integer (five places)

```
10 = 0b 0 1 0 1 0 ( 8 + 2 )
^ ^ ^ ^ ^
| | | | |
| | | | 1
| | | 2
| | 4
| 8
16
```

Associate each binary bit with a fraction.

```
= 0b 0 1 0 1 0 ( 1/4 + 1/16 = 0.3125 )
^ ^ ^ ^ ^
| | | | |
| | | | 1/32
| | | 1/16
| | 1/8
| 1/4
1/2
```

# Proof

Consider transforming the problem by multiplying all the numbers involved by `2**N`

so that all the fractions become integers.

The original problem:

Consider a target number `r`

in the range `0 < r < 1`

, and a list of fractions `{1/2, 1/4, .... 1/(2**N)`

. Find the subset of the list of fractions that sums to `S`

such that `error = r - S`

is minimised.

Becomes the following equivalent problem (after multiplying by `2**N`

):

Consider a target number `r`

in the range `0 < r < 2**N`

and a list of **integers** `{2**(N-1), 2**(N-2), ... , 4, 2, 1}`

. Find the subset of the list of integers that sums to `S`

such that `error = r - S`

is minimised.

Choosing powers of two that sum to a given number (with as little error as possible) is simply binary encoding of an integer. This problem therefore reduces to binary encoding of a integer.

- Existence of solution: Any positive floating point number
`r`

, `0 < r < 2**N`

, can be cast to an integer and represented in binary form.
- Optimality: The maximum error in the integer version of the solution is the round-off error of
`±0.5`

. (In the original problem, the maximum error is `±0.5 * 1/2**N`

.)
- Uniqueness: for any positive (floating point) number there is a unique integer representation and therefore a unique binary representation. (Possible exception of
`0.5`

= see below.)

# Implementation (Python)

This function converts the problem to the integer equivalent, rounds off `r`

to an integer, then reads off the binary representation of `r`

as an integer to get the required fractions.

```
def conv_frac (r,N):
# Convert to equivalent integer problem.
R = r * 2**N
S = int(round(R))
# Convert integer S to N-bit binary representation (i.e. a character string
# of 1's and 0's.) Note use of [2:] to trim leading '0b' and zfill() to
# zero-pad to required length.
bin_S = bin(S)[2:].zfill(N)
nums = list()
for index, bit in enumerate(bin_S):
k = index + 1
if bit == '1':
print "%i : 1/%i or %f" % (index, 2**k, 1.0/(2**k))
nums.append(1.0/(2**k))
S = sum(nums)
e = r - S
print """
Original number `r` : %f
Number of fractions `N` : %i (smallest fraction 1/%i)
Sum of fractions `S` : %f
Error `e` : %f
""" % (r,N,2**N,S,e)
```

Sample output:

```
>>> conv_frac(0.3141,10)
1 : 1/4 or 0.250000
3 : 1/16 or 0.062500
8 : 1/512 or 0.001953
Original number `r` : 0.314100
Number of fractions `N` : 10 (smallest fraction 1/1024)
Sum of fractions `S` : 0.314453
Error `e` : -0.000353
>>> conv_frac(0.30,5)
1 : 1/4 or 0.250000
3 : 1/16 or 0.062500
Original number `r` : 0.300000
Number of fractions `N` : 5 (smallest fraction 1/32)
Sum of fractions `S` : 0.312500
Error `e` : -0.012500
```

# Addendum: the `0.5`

problem

If `r * 2**N`

ends in `0.5`

, then it could be rounded up or down. That is, there are two possible representations as a sum-of-fractions.

If, as in the original problem statement, you want the representation that uses fewest fractions (i.e. the least number of `1`

bits in the binary representation), just try both rounding options and pick whichever one is more economical.

`0.6`

as a sum of fractions.){Further note: you may not have intended it, but your remark "It seems like there are some SO'ers who are not in the mood of reading the question completely..." sounds a little abrasive. Correcting misconceptions is fine, but do it politely.}– Li-aung Yip May 7 '12 at 8:23`0.70`

as a sum of the numbers in the set`{0.500, 0.250, 0.125}`

. A greedy algorithm (as in my deleted answer) gives`0.500 + 0.125 = 0.625`

, which has an error of`0.075`

. A better solution is`0.500 + 0.250 = 0.750`

, which has an error of`0.050`

. – Li-aung Yip May 7 '12 at 8:54