First, let's review what `epsilon`

really is in the return value of `sys.float_info`

.

Epsilon (or `𝟄`

) is the smallest number such that **0.5 + 𝟄 ≠ 0.5 AND 0.5 - 𝟄 ≠ 0.5**

Python is telling you that the smallest number that will cause `0.5`

to increment or decrement repeatably is `epsilon=2.220446049250313e-16`

-- **but this is only for the value 0.5**. You are attempting to increment `1.0`

by `1.0e-17`

. This is a larger value (1.0 vs 0.5) being incremented by a smaller number than the 𝟄 for 0.5 (1.0e-17 vs 2.2e-16). You are off by an order of magnitude roughly, since the increment value of 1.0e-17 is an order of magnitude smaller than the relative epsilon for 1.0.

You can see this here:

These change the value of `0.5`

```
>>> 0.5+sys.float_info.epsilon
0.5000000000000002
>>> 0.5-sys.float_info.epsilon
0.4999999999999998
```

These values do not:

```
>>> 0.5+sys.float_info.epsilon/10.0
0.5
>>> 0.5-sys.float_info.epsilon/10.0
0.5
>>> 5.0+sys.float_info.epsilon
5.0
>>> 5.0-sys.float_info.epsilon
5.0
```

**Explanation:**

IEEE 754 defines the floating point format in use today on most standard computers (specialty computers or libraries may use a different format.) The 64 bit format of IEEE 754 uses 53 bits of precision to calculate and 52 to store to the mantissa of a floating point value. Since you have a fixed 52/53 bits to work with, the magnitude and accuracy of the mantissa changes for larger / smaller values. So then the 𝟄 changes as the relative magnitude of a floating point number changes. The value of 𝟄 for 0.5 is different that the value for 1.0 and for 100.0.

For a variety of very good and platform-specific reasons (storage and representation, rounding, etc), even though you *could* use a smaller number, epsilon is defined as using 52 bits of precision for the 64 bit float format. Since most Python implementations use a C double float for float, this can be demonstrated:

```
>>> 2**-52==sys.float_info.epsilon
True
```

See how many bits *your* platform will do:

```
>>> 0.5 + 2.0**-53
0.5000000000000001
>>> 0.5 - 2.0**-53
0.4999999999999999
>>> 0.5 + 2.0**-54
0.5 # fail for 0.5 + 54 bits...
>>> 0.5 - 2.0**-54
0.49999999999999994 # OK for minus
>>> 0.5 - 2.0**-55
0.5 # fail for 0.5 minus 55 bits...
```

There are several work arounds for your issue:

- You can use the C99 concept of nextafter to calculate the value appropriate epsilon. For Python, either use numpy or the Decimal class to calculate
`nextafter`

. More on `nextafter`

in my previous answer HERE
- Use integers. A 64 bit integer will clearly handle an epsilon value in the 17th order of magnitude without rounding.
- Use an arbitrary precision math library. Decimal is in the standard Python distribution.

The important concept is that the value of 𝟄 is **relative to value** (and if you are incrementing or decrementing).

This can be seen here:

```
>>> numpy.nextafter(0.0,1.0)-0.0
4.9406564584124654e-324 # a relative epsilon value of 4.94e-324
>>> numpy.nextafter(0.01,1.0)-0.01
1.7347234759768071e-18 # 1e-17 would still work...
>>> numpy.nextafter(0.1,1.0)-0.1
1.3877787807814457e-17 # 1e-17 would >>barely<< work...
>>> numpy.nextafter(0.5,1.0)-0.5
1.1102230246251565e-16 # a relative epsilon value of 1.1e-16
>>> numpy.nextafter(500.0,501.0)-500.0
5.6843418860808015e-14 # relative epsilon of 5.6e-14
>>> numpy.nextafter(1e17,1e18)-1e17
16.0 # the other end of the spectrum...
```

So you can see that 1e-17 will work handily to increment values between 0.0 and 0.1 but not many values greater than that. As you can see above, the relative 𝟄 for 1e17 is 16.