Some of the previous answers use methods that are of time or space complexity O(n), where n is the largest “small number” that will be accepted. By contrast, the following method is O(sqrt(n)) in time, and O(1) in space.

Suppose that positive real number `r = x + y`

, where `x=floor(r)`

and `0 ≤ y < 1`

. We want to approximate `r`

by a number of the form `a + √b`

. If `x+y ≈ a+√b`

then `x+y-a ≈ √b`

, so `√b ≈ h+y`

for some integer offset `h`

, and `b ≈ (h+y)^2`

. To make b an integer, we want to minimize the fractional part of `(h+y)^2`

over all eligible `h`

. There are at most `√n`

eligible values of `h`

. See following python code and sample output.

```
import math, random
def findb(y, rhi):
bestb = loerror = 1;
for r in range(2,rhi):
v = (r+y)**2
u = round(v)
err = abs(v-u)
if round(math.sqrt(u))**2 == u: continue
if err < loerror:
bestb, loerror = u, err
return bestb
#random.seed(123456) # set a seed if testing repetitively
f = [math.pi-3] + sorted([random.random() for i in range(24)])
print (' frac sqrt(b) error b')
for frac in f:
b = findb(frac, 12)
r = math.sqrt(b)
t = math.modf(r)[0] # Get fractional part of sqrt(b)
print ('{:9.5f} {:9.5f} {:11.7f} {:5.0f}'.format(frac, r, t-frac, b))
```

(Note 1: This code is in demo form; the parameters to `findb()`

are `y`

, the fractional part of `r`

, and `rhi`

, the square root of the largest small number. You may wish to change usage of parameters. Note 2: The

`if round(math.sqrt(u))**2 == u: continue`

line of code prevents `findb()`

from returning perfect-square values of `b`

, except for the value b=1, because no perfect square can improve upon the accuracy offered by b=1.)

Sample output follows. About a dozen lines have been elided in the middle. The first output line shows that this procedure yields `b=51`

to represent the fractional part of `pi`

, which is the same value reported in some other answers.

```
frac sqrt(b) error b
0.14159 7.14143 -0.0001642 51
0.11975 4.12311 0.0033593 17
0.12230 4.12311 0.0008085 17
0.22150 9.21954 -0.0019586 85
0.22681 11.22497 -0.0018377 126
0.25946 2.23607 -0.0233893 5
0.30024 5.29150 -0.0087362 28
0.36772 8.36660 -0.0011170 70
0.42452 8.42615 0.0016309 71
...
0.93086 6.92820 -0.0026609 48
0.94677 8.94427 -0.0024960 80
0.96549 11.95826 -0.0072333 143
0.97693 11.95826 -0.0186723 143
```

With the following code added at the end of the program, the output shown below also appears. This shows closer approximations for the fractional part of pi.

```
frac, rhi = math.pi-3, 16
print (' frac sqrt(b) error b bMax')
while rhi < 1000:
b = findb(frac, rhi)
r = math.sqrt(b)
t = math.modf(r)[0] # Get fractional part of sqrt(b)
print ('{:11.7f} {:11.7f} {:13.9f} {:7.0f} {:7.0f}'.format(frac, r, t-frac, b,rhi**2))
rhi = 3*rhi/2
frac sqrt(b) error b bMax
0.1415927 7.1414284 -0.000164225 51 256
0.1415927 7.1414284 -0.000164225 51 576
0.1415927 7.1414284 -0.000164225 51 1296
0.1415927 7.1414284 -0.000164225 51 2916
0.1415927 7.1414284 -0.000164225 51 6561
0.1415927 120.1415831 -0.000009511 14434 14641
0.1415927 120.1415831 -0.000009511 14434 32761
0.1415927 233.1415879 -0.000004772 54355 73441
0.1415927 346.1415895 -0.000003127 119814 164836
0.1415927 572.1415909 -0.000001786 327346 370881
0.1415927 911.1415916 -0.000001023 830179 833569
```