12

If you run code like:

length(unique(runif(10000000)))
length(unique(rnorm(10000000)))

you'll see that only about 99.8% of runif values are unique, but 100% of rnorm values are. I thought this might be because of the constrained range, but upping the range to (0, 100000) for runif doesn't change the result. Continuous distributions should have probability of repeats =0, and I know in floating-point precision that's not the case, but I'm curious why we don't see fairly close to the same number of repeats between the two.

10
  • 2
    IF your read the op: but upping the range to (0, 100000) for runif doesn't change the result
    – s_baldur
    Jul 19, 2018 at 14:52
  • 1
    Well, one could argue that 99.8% IS fairly close..
    – RLave
    Jul 19, 2018 at 14:56
  • @RLava I would not argue so. Jul 19, 2018 at 15:07
  • kind of a joke..
    – RLave
    Jul 19, 2018 at 15:08
  • 1
    @Ryan I get the same results as op using uniqueN().
    – s_baldur
    Jul 19, 2018 at 15:22

2 Answers 2

3

This is due primarily to the properties of the default PRNG (the fact that runif has a smaller range than rnorm and therefore a smaller number of representable values may also have a similar effect at some point even if the RNG doesn't). It is discussed somewhat obliquely in ?Random:

Do not rely on randomness of low-order bits from RNGs. Most of the supplied uniform generators return 32-bit integer values that are converted to doubles, so they take at most 2^32 distinct values and long runs will return duplicated values (Wichmann-Hill is the exception, and all give at least 30 varying bits.)

With the example:

sum(duplicated(runif(1e6))) # around 110 for default generator
## and we would expect about almost sure duplicates beyond about
qbirthday(1 - 1e-6, classes = 2e9) # 235,000

Changing to the Wichmann-Hill generator indeed reduces the chance of duplicates:

RNGkind("Wich")  
sum(duplicated(runif(1e6)))
[1] 0
sum(duplicated(runif(1e8)))
[1] 0
3
  • It is nice to see confirmation that the phenomenon disappears when you switch to Wichmann-Hill. Jul 19, 2018 at 16:02
  • 1
    I like this answer and it points out some good things, but it doesn't really answer the main question. If I'm not using Wichmann-Hill, shouldn't both methods be using the default? And if I'm using the default shouldn't both methods have approximately the same amount of repeats?
    – jntrcs
    Jul 22, 2018 at 22:30
  • @jntrcs The answer states that runif under the default generators has a limited level of randomness. rnorm isn't documented to have the same limitation .
    – James
    Jul 23, 2018 at 13:27
2

The documentation for random number generations says:

Do not rely on randomness of low-order bits from RNGs. Most of the supplied uniform generators return 32-bit integer values that are converted to doubles, so they take at most 2^32 distinct values and long runs will return duplicated values (Wichmann-Hill is the exception, and all give at least 30 varying bits.)

By the birthday paradox you would expect to see repeated values in a set of more than roughly 2^16 values, and 10000000 > 2^16. I haven't found anything directly in the documentation about how many distinct values rnorm will return, but it is presumably larger than 2^32. It is interesting to note that set.seed has different parameters kind which determines the uniform generator and normal.kind which determines the normal generator, so the latter is not a simple transformation of the former.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.