# Computing E becomes chaotic at limits 10 ** 12 in Python?

I have made a program that computes the base of natural logarithms known as e in mathematics using the following well known formula:

e = (1 + 1.0/n) ** n

the code is:

``````def e_formula(lim):
n = lim
e = (1 + 1.0/n) **n
return e
``````

I set up a test iteration from 10*1 to 10*100

``````if __name__ == "__main__":
for i in range(1,100):
print e_formula(10**i)
``````

so far so good:

However the following results around 10**11 blow up

Actual results from shell:

2.5937424601

2.70481382942

2.71692393224

2.71814592682

2.71826823719

2.7182804691

2.71828169413

2.71828179835

2.71828205201

2.71828205323

2.71828205336

2.71852349604

2.71611003409

2.71611003409

3.03503520655

1.0

Question?

I am looking for a reason for this either to do with the result exceeding the floating point limit in a 32 bit machine or becuase of the way Python itself computes floating point numbers: any ideas? I am not looking for a better solution just the underlying reason that it blows up.

-

This is simply due to the limited precision of floating point numbers. You get about 15 significant digits.

You are taking `(1 + very_small_number)`. Most of the digits of `very_small_number` are truncated at this stage.

The `**n` just multiplies this error

-
I thought this would be the answer, do you know if it is the mantissa or exponent that truncates first? I would guess mantissa as it is an accuracy problem? –  pythonMan May 24 '13 at 11:54
@pythonMan, the mantissa. The exponent can be +/-308 IIRC –  gnibbler May 24 '13 at 11:55
Do you have a link to these standards would be very useful: also what is difference IEE and 11RC. I know the theory but do not have practical experience:) –  pythonMan May 24 '13 at 11:59
@pythonMan IIRC == If I Recall Correctly :) en.wikipedia.org/wiki/Double-precision_floating-point_format –  gnibbler May 24 '13 at 12:00
@pythonMan, 2**52 has 16 decimal digits, so you can only guarantee 15 –  gnibbler May 24 '13 at 12:03