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I get slightly different results calculating the cosine of a value. How can I check that this difference is within machine precision?

import math
math.cos(60.0/180.0*math.pi)
-> 0.5000000000000001

import numpy
numpy.cos(60.0/180.0*numpy.pi)
-> 0.50000000000000011
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up vote 10 down vote accepted

The difference seems to be caused by the formatting routines only:

>>> '%.30f' % math.cos(60./180.*math.pi)
'0.500000000000000111022302462516'
>>> '%.30f' % np.cos(60./180.*np.pi)
'0.500000000000000111022302462516'

Note that np.cos returns np.float64 rather than float, and apparently that type is printed differently by default. On common hardware, they're both implemented as 64-bit double, so there's no actual difference in precision.

share|improve this answer
    
np.float64 and float will be backed by the same IEEE-754 double precision data type – David Heffernan Oct 19 '11 at 17:44
1  
@DavidHeffernan: yep, just not the same __repr__, apparently. – Fred Foo Oct 19 '11 at 17:45
    
Of course what you point out in your answer is useful I think it's also useful to have a feel for how much precision you have in a double value. You can actually answer all of this question without running any code and instead just counting digits. – David Heffernan Oct 19 '11 at 17:48
    
Insightful... thanks. – crippledlambda Oct 20 '11 at 6:37

Double precision arithmetic gives you precision of 15-16 decimal significant figures. These two values agree to that precision. Nothing worry about here.

Note that I say decimal to contrast with the 53 binary bits used for the significand in the binary representation of a double precision value.

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Yes, I knew it was there at the cusp of double-precision accuracy! – crippledlambda Oct 20 '11 at 6:37
    
That's odd because that was exactly the question you asked, "How can I check that this difference is within machine precision?" which is what I tried to answer. – David Heffernan Oct 20 '11 at 6:51

Eventhough your numbers turned out to be equal, it is still useful to know how to examine them at full precision. Here are a couple of ways to do it:

>>> a = 1.1 + 2.2
>>> b = 3.3
>>> a == b
False
>>> from decimal import Decimal
>>> Decimal.from_float(a)
Decimal('3.300000000000000266453525910037569701671600341796875')
>>> Decimal.from_float(b)
Decimal('3.29999999999999982236431605997495353221893310546875')
>>> a.hex()
'0x1.a666666666667p+1'
>>> b.hex()
'0x1.a666666666666p+1'
>>> a.as_integer_ratio()
(7430939385161319, 2251799813685248)
>>> b.as_integer_ratio()
(3715469692580659, 1125899906842624)
share|improve this answer
    
Great, this is a good way to check. In R there is a variable called .Machine$double.eps and .Machine$double.neg.eps which can be used to set tolerances, but these tests are also helpful... – crippledlambda Oct 20 '11 at 6:36
    
Or even just Decimal(a); no need for the from_float method. – Mark Dickinson Oct 20 '11 at 6:57

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