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I want to generate random numbers in the range -1, 1 and want each one to have equal probability of being generated. I.e. I don't want the extremes to be less likely to come up. What is the best way of doing this? So far, I have used:

2 * numpy.random.rand() - 1

and also:

2 * numpy.random.random_sample() - 1


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Did you have any problem with the approach you used? –  Sven Marnach Jul 26 '12 at 15:48
@ Sven the problem is that I can't be sure that the extremes are as likely to be chosen as all the other possibilities. –  wot Jul 26 '12 at 15:51

3 Answers 3

up vote 9 down vote accepted

Your approach is fine. An alternative is to use the function numpy.random.uniform():

>>> numpy.random.uniform(-1, 1, size=10)
array([-0.92592953, -0.6045348 , -0.52860837,  0.00321798,  0.16050848,
       -0.50421058,  0.06754615,  0.46329675, -0.40952318,  0.49804386])

Regarding the probability for the extremes: If it would be idealised, continuous random numbers, the probability to get one of the extremes would be 0. Since floating point numbers are a discretisation of the continuous real numbers, in realitiy there is some positive probability to get some of the extremes. This is some form of discretisation error, and it is almost certain that this error will be dwarved by other errors in your simulation. Stop worrying!

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thanks. I will try the alternative! –  wot Jul 26 '12 at 15:53
@wok: Added a comment on the extremes. –  Sven Marnach Jul 26 '12 at 15:59
Thanks Sven. I will try and stop worrying :-) but easily said than done. –  wot Jul 26 '12 at 16:05
Note that in both methods the interval is half-open, so the upper bound will be produced with probability 0. –  ecatmur Jul 26 '12 at 16:34
@ecatmur: For the specific values -1.0 and 1.0 as boundaries, this is true. For other values, the upper boundary might also be produced due to rounding (I know the documentation says something else, but the documentation is wrong). Anyway, the chances of hitting any of the boundary values are negligible, so this only matters in practice if you want to avoid some error state, like a division by zero. –  Sven Marnach Jul 26 '12 at 16:36

From the documentation for numpy.random.random_sample:

Results are from the “continuous uniform” distribution over the stated interval. To sample Unif[A, b), b > a multiply the output of random_sample by (b-a) and add a:

 (b - a) * random_sample() + a

Per Sven Marnach's answer, the documentation probably needs updating to reference numpy.random.uniform.

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yes, that's where I checked first. Thanks. –  wot Jul 26 '12 at 16:14

Note that numpy.random.rand allows to generate multiple samples from a uniform distribution at one call:

>>> np.random.rand(5)
array([ 0.69093485,  0.24590705,  0.02013208,  0.06921124,  0.73329277])

It also allows to generate samples in a given shape:

>>> np.random.rand(3,2)
array([[ 0.14022471,  0.96360618], 
       [ 0.37601032,  0.25528411], 
       [ 0.49313049,  0.94909878]])

As You said, uniformly distributed random numbers between [-1, 1) can be generated with:

>>> 2 * np.random.rand(5) - 1
array([ 0.86704088, -0.65406928, -0.02814943,  0.74080741, -0.14416581])
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