Probability and Statistics

How long does it take to find large primes?

Posted on by John

Descriptions of cryptography algorithms often start with something like “Let p be a large prime” or maybe more specifically “Let p be a 256 bit prime.” How hard is it to find large prime numbers?

Let’s look at the question in base b, so we can address binary and base 10 at the same time. The prime number theorem says that for large n, the number of primes less than bn is approximately

bn / n log b

and so the probability that an n-digit number base b is prime is roughly 1 / n log b. If you select an odd b-digit number, you double your chances.

If you generate odd n-digit numbers at random, how long would it be until you find a prime? You might get lucky and find one on your first try. Or you might have extraordinarily bad luck and find a composite every time until you give up.

The number of tries until you find a prime is a geometric random variable with

p = 2 / n log b.

The expected value is 1 / p.

So, for example, if you wanted to find a 256-bit prime, you would need to test on average 256 log(2) / 2 = 89 candidates. And if you wanted to find a 100-digit prime, you’d need to test on average 100 log(10) / 2 = 115 candidates.

You could get more accurate bounds by using a refined variation of the prime number theorem. Also, we implicitly looked at the problem of finding a number with at most n digits rather than exactly n digits. Neither of these would make much difference to our final result. To back up this claim, let’s compare our estimate to a simulation that actually looks for primes.

histogram

The histogram above was based on finding 10,000 primes, each with 100 digits, and counting how many candidates were evaluated each time. The plot matches a geometric distribution well. The mean from the simulation was 113.5, close to the 115 estimated above.

For cryptographic applications, you often don’t want just any prime. You might want a safe prime or a prime satisfying some other property, in which case you’ll need to test more primes. But your probability of success will likely still be geometrically distributed.

It’s plausible that for large pp being prime and 2p + 1 being prime are independent events, at least approximately, and a numerical experiment suggests that’s true. I generated 10,000 primes, each 100-digits long, and 48 were safe primes, about what you’d expect from theory.

Related posts

The other butterfly effect

Posted on by John

monarch butterfly

The original butterfly effect

The butterfly effect is the semi-serious claim that a butterfly flapping its wings can cause a tornado half way around the world. It’s a poetic way of saying that some systems show sensitive dependence on initial conditions, that the slightest change now can make an enormous difference later. Often this comes up in the context of nonlinear, chaotic systems but it isn’t limited to that. I give an example here of a linear differential equation whose solutions start out the essentially the same but eventually diverge completely.

Once you think about these things for a while, you start to see nonlinearity and potential butterfly effects everywhere. There are tipping points everywhere waiting to be tipped!

The other butterfly effect

But a butterfly flapping its wings usually has no effect, even in sensitive or chaotic systems. You might even say especially in sensitive or chaotic systems.

Sensitive systems are not always and everywhere sensitive to everything. They are sensitive in particular ways under particular circumstances, and can otherwise be quite resistant to influence. Not only may a system be insensitive to butterflies, it may even be relatively insensitive to raging bulls. The raging bull may have little more long-term effect than a butterfly. This is what I’m calling the other butterfly effect.

Steering complex systems

In some ways chaotic systems are less sensitive to change than other systems. And this can be a good thing. Resistance to control also means resistance to unwanted tampering. Chaotic or stochastic systems can have a sort of self-healing property. They are more stable than more orderly systems, though in a different way.

The lesson that many people draw from their first exposure to complex systems is that there are high leverage points, if only you can find them and manipulate them. They want to insert a butterfly to at just the right time and place to bring about a desired outcome. Instead, we should humbly evaluate to what extent it is possible to steer complex systems at all. We should evaluate what aspects can be steered and how well they can be steered. The most effective intervention may not come from tweaking the inputs but from changing the structure of the system.

Related posts

The cold start problem

Posted on by John

How do you operate a data-driven application before you have any data? This is known as the cold start problem.

We faced this problem all the time when I designed clinical trials at MD Anderson Cancer Center. We uses Bayesian methods to design adaptive clinical trial designs, such as clinical trials for determining chemotherapy dose levels. Each patient’s treatment assignment would be informed by data from all patients treated previously.

But what about the first patient in a trial? You’ve got to treat a first patient, and treat them as well as you know how. They’re struggling with cancer, so it matters a great deal what treatment they are assigned. So you treat them according to expert opinion. What else could you do?

Thanks to the magic of Bayes theorem, you don’t have to have an ad hoc rule that says “Treat the first patient this way, then turn on the Bayesian machine to determine how to treat the next patient.” No, you use Bayes theorem from beginning to end. There’s no need to handle the first patient differently because expert opinion is already there, captured in the form of prior distributions (and the structure of the probability model).

Each patient is treated according to all information available at the time. At first all available information is prior information. After you have data on one patient, most of the information you have is still prior information, but Bayes’ theorem updates this prior information with your lone observation. As more data becomes available, the Bayesian machine incorporates it all, automatically shifting weight away from the prior and toward the data.

The cold start problem for business applications is easier than the cold start problem for clinical trials. First of all, most business applications don’t have the potential to cost people their lives. Second, business applications typically have fewer competing criteria to balance.

What if you’re not sure where to draw your prior information? Bayes can handle that too. You can use Bayesian model selection or Bayesian model averaging to determine which source (or weighting of sources) best fits the new data as it comes in.

Once you’ve decided to use a Bayesian approach, there’s still plenty of work to do, but the Bayesian approach provides scaffolding for that work, a framework for moving forward.

Distribution of eigenvalues for symmetric Gaussian matrix

Posted on by John

Symmetric Gaussian matrices

The previous post looked at the distribution of eigenvalues for very general random matrices. In this post we will look at the eigenvalues of matrices with more structure. Fill an n by n matrix A with values drawn from a standard normal distribution and let M be the average of A and its transpose, i.e. M = ½(A + AT).  The eigenvalues will all be real because M is symmetric.

This is called a “Gaussian Orthogonal Ensemble” or GOE. The term is standard but a little misleading because such matrices may not be orthogonal.

Eigenvalue distribution

The joint probability distribution for the eigenvalues of M has three terms: a constant term that we will ignore, an exponential term, and a product term. (Source)

p(x_1, x_2, \ldots, x_n) \propto \exp\left(-\frac{1}{2} \sum_{j=1}^nx_j^2 \right ) \prod_{j < k} |x_j - x_k|

The exponential term is the same as in a multivariate normal distribution. This says the probability density drops of quickly as you go away from the origin, i.e. it’s rare for eigenvalues to be too big. The product term multiplies the distances between each pair of eigenvalues. This says it’s also rare for eigenvalues to be very close together.

(The missing constant to turn the expression above from a proportionality to an equation is whatever it has to be for the right side to integrate to 1. When trying to qualitatively understand a probability density, it usually helps to ignore proportionality constants. They are determined by the rest of the density expression, and they’re often complicated.)

If eigenvalues are neither tightly clumped together, nor too far apart, we’d expect that the distance between them has a distribution with a hump away from zero, and a tail that decays quickly. We will demonstrate this with a simulation, then give an exact distribution.

Python simulation

The following Python code simulates 2 by 2 Gaussian matrices.

    import matplotlib.pyplot as plt
    import numpy as np
    
    n = 2
    reps = 1000
    
    diffs = np.zeros(reps)
    for r in range(reps):
        A = np.random.normal(scale=n**-0.5, size=(n,n)) 
        M = 0.5*(A + A.T)
        w = np.linalg.eigvalsh(M)
        diffs[r] = abs(w[1] - w[0])
    
    plt.hist(diffs, bins=int(reps**0.5))
    plt.show()

This produced the following histogram:

The exact probability distribution is p(s) = s exp(-s²/4)/2. This result is known as “Wigner’s surmise.”

Biased random number generation

Posted on by John

Melissa O’Neill has a new post on generating random numbers from a given range. She gives the example of wanting to pick a card from a deck of 52 by first generating a 32-bit random integer, then taking the remainder when dividing by 52. There’s a slight bias because 232 is not a multiple of 52.

Since 232 = 82595524*52 + 48, there are 82595525 ways to generate the numbers 0 through 47, but only 82595524 ways to generate the numbers 48 through 51. As Melissa points out in her post, the bias here is small, but the bias increases linearly with the size of our “deck.” To clarify, it is the relative bias that increases, not the absolute bias.

Suppose you want to generate a number between 0 and M, where M is less than 232 and not a power of 2. There will be 1 + ⌊232/M⌋ ways to generate a 0, but ⌊232/M⌋ ways to generate M-1. The difference in the probability of generating 0 vs generating M-1 is 1/232, independent of M. However, the ratio of the two probabilities is 1 + 1/⌊232/M⌋ or approximately 1 + M/232.

As M increases, both the favored and unfavored outcomes become increasingly rare, but ratio of their respective probabilities approaches 2.

Whether this makes any practical difference depends on your context. In general, the need for random number generator quality increases with the volume of random numbers needed.

Under conventional assumptions, the sample size necessary to detect a difference between two very small probabilities p1 and p2 is approximately

8(p1 + p2)/(p1p2

and so in the card example, we would have to deal roughly 6 × 1018 cards to detect the bias between one of the more likely cards and one of the less likely cards.

***

Need help with randomization?

Attribution based on tail probabilities

Posted on by John

If all you know about a person is that he or she is around 5′ 7″, it’s a toss-up whether this person is male or female. If you know someone is over 6′ tall, they’re probably male. If you hear they are over 7″ tall, they’re almost certainly male. This is a consequence of heights having a thin-tailed probability distribution. Thin, medium, and thick tails all behave differently for the attribution problem as we will show below.

Thin tails: normal

Suppose you have an observation that either came from X or Y, and a priori you believe that both are equally probable. Assume X and Y are both normally distributed with standard deviation 1, but that the mean of X is 0 and the mean of Y is 1. The probability you assign to X and Y after seeing data will change, depending on what you see. The larger the value you observe, the more sure you can be that it came from Y.

Posterior probability of Y with normal distributions

This plot shows the posterior probability that an observation came from Y, given that we know the observation is greater than the value on the horizontal axis.

Suppose I’ve seen the exact value, and it’s 4. All I tell you is that it’s bigger than 2. Then you would say it probably came from Y. When I go back and tell you that in fact it’s bigger than 3. You would be more sure it came from Y. The more information I give you, the more convinced you are. This isn’t the case with other probability distributions.

Thick tails: Cauchy

Now let’s suppose X and Y have a Cauchy distribution with unit scale, with X having mode 0 and Y having mode 1. The plot below shows how likely is it that our observation came from Y given a lower bound on the observation.

Posterior distribution of Y assuming Cauchy distributions

We are most confident that our data came from Y when we know that our data is greater than 1. But the larger our lower bound is, the further we look out in the tails, the less confident we are! If we know, for example, that our data is at least 5, then we still think that it’s more likely that it came from Y than from X, but we’re not as sure.

As above, suppose I’ve seen the data value but only tell you lower bounds on its value.  Suppose I see a value of 4, but only tell you it’s positive. When I come back and tell you that the value is bigger than 1, your confidence goes up that the sample came from Y. But as I give you more information, telling you that the sample is bigger than 2, then bigger than 3, your confidence that it came from Y goes down, just the opposite of the normal case.

Explanation

What accounts for the very different behavior?

In the normal example, seeing a value of 5 or more from Y is unlikely, but seeing a value so large from X is very unlikely. Both tails are getting smaller as you move to the right, but in relative terms, the tail of X is getting thinner much faster than the tail of Y.

In the Cauchy example, the value of both tails gets smaller as you move to the right, but the relative difference between the two tails is decreasing. Seeing a value greater than 10, say, from Y is unlikely, but it would only be slightly less likely from X.

Medium tails

In between thin tails and thick tails are medium tails. The tails of the Laplace (double exponential) distribution decay exponentially. Exponential tails are a often considered the boundary between thin tails and thick tails, or super-exponential and sub-exponential tails.

Suppose you have two Laplace random variables with the same scale, with X centered at 0 and Y centered at 1. What is the posterior probability that a sample came from Y rather than X, given that it’s at least some value Z > 1? It’s constant! Specifically, it’s e/(1 + e).

In the normal and Cauchy examples, it didn’t really matter that one distribution was centered at 0 and the other at 1. We’d get the same qualitative behavior no matter what the shift between the two distributions. The limit would tend to 1 for the normal distribution and 1/2 for the Cauchy. The constant value of the posterior probability with the Laplace example depends on the size of the shift between the two.

We’ve assumed that X and Y are equally likely a priori. The limiting value in the normal case does not depend on the prior probabilities of X and Y as long as they’re both positive. The prior probabilities will effect the limiting values for the Cauchy and Laplace case.

Technical details

For anyone who wants a more precise formulation of the examples above, let B be a non-degenerate Bernoulli random variable and define ZBX + (1-B)Y. We’re computing the conditional probability Pr(B = 0 | Z > z) using Bayes’ theorem.  If X and Y are normally distributed, the limit of Pr(B = 0 | Z > z) as z goes to infinity is 1. If X and Y are Cauchy distributed, the limit is the unconditional probability Pr(B = 0).

In the normal case, as z goes to infinity, the distribution of B carries no useful information.

In the Cauchy case, as z goes to infinity, the observation z carries no useful information.

How far is xy from yx on average for quaternions?

Posted on by John

Given two quaternions x and y, the product xy might equal the product yx, but in general the two results are different.

How different are xy and yx on average? That is, if you selected quaternions x and y at random, how big would you expect the difference xy – yx to be? Since this difference would increase proportionately if you increased the length of x or y, we can just consider quaternions of norm 1. In other words, we’re looking at the size of xy – yx relative to the size of xy.

Here’s simulation code to explore our question.

    import numpy as np
    
    def random_unit_quaternion():
        x = np.random.normal(size=4)
        return x / np.linalg.norm(x)
    
    def mult(x, y):
        return np.array([
            x[0]*y[0] - x[1]*y[1] - x[2]*y[2] - x[3]*y[3],
            x[0]*y[1] + x[1]*y[0] + x[2]*y[3] - x[3]*y[2],
            x[0]*y[2] - x[1]*y[3] + x[2]*y[0] + x[3]*y[1],
            x[0]*y[3] + x[1]*y[2] - x[2]*y[1] + x[3]*y[0]
        ])
    
    
    N = 10000
    s = 0
    for _ in range(N):
        x = random_unit_quaternion()
        y = random_unit_quaternion()
        s += np.linalg.norm(mult(x, y) - mult(y, x))
    
    print(s/N)

In this code x and y have unit length, and so xy and yx also have unit length. Geometrically, x, y, xy, and yx are points on the unit sphere in four dimensions.

When I ran the simulation above, I got a result of 1.13, meaning that on average xy and yx are further from each other than they are from the origin.

To see more than the average, here’s a histogram of ||xyyx|| with N above increased to 100,000.

histogram

I imagine you could work out the distribution exactly, though it was quicker and easier to write a simulation. We know the distribution lives on the interval [0, 2] because xy and yx are points on the unit sphere. Looks like the distribution is skewed toward its maximum value, and so xy and yz are more likely to be nearly antipodal than nearly equal.

Update: Greg Egan worked out the exact mean and distribution.

Relative error in the central limit theorem

Posted on by John

If you average a large number independent versions of the same random variable, the central limit theorem says the average will be approximately normal. That is the absolute error in approximating the density of the average by the density of a normal random variable will be small. (Terms and conditions apply. See notes here.)

But the central limit theorem says nothing about relative error. Relative error can diverge to infinity while absolute error converges to zero. We’ll illustrate this with an example.

The average of N independent exponential(1) random variables has a gamma distribution with shape N and scale 1/N.

As N increases, the average becomes more like a normal in distribution. That is, the absolute error in approximating the distribution function of gamma random variable with that of a normal random variable decreases. (Note that we’re talking about distribution functions (CDFs) and not densities (PDFs). The previous post discussed a surprise with density functions in this example.)

The following plot shows that the difference between the distributions functions get smaller as N increases.

But when we look at the ratio of the tail probabilities, that is Pr(X > t) / Pr(Y  > t) where X is the average of N exponential r.v.s and Y is the corresponding normal approximation from the central limit theorem, we see that the ratios diverge, and they diverge faster as N increases.

To make it clear what’s being plotted, here is the Python code used to draw the graphs above.

import matplotlib.pyplot as plt
from scipy.stats import gamma, norm
from scipy import linspace, sqrt

def tail_ratio(ns):

    x = linspace(0, 4, 400)
    
    for n in ns:
        gcdf = gamma.sf(x, n, scale = 1/n)
        ncdf = norm.sf(x, loc=1, scale=sqrt(1/n))
        plt.plot(x, gcdf/ncdf

    plt.yscale("log")        
    plt.legend(["n = {}".format(n) for n in ns])
    plt.savefig("gamma_normal_tail_ratios.svg")

def cdf_error(ns):

    x = linspace(0, 6, 400)
    
    for n in ns:
        gtail = gamma.cdf(x, n, scale = 1/n)
        ntail = norm.cdf(x, loc=1, scale=sqrt(1/n))
        plt.plot(x, gtail-ntail)

    plt.legend(["n = {}".format(n) for n in ns])
    plt.savefig("gamma_normal_cdf_diff.svg")
    
ns = [1, 4, 16]
tail_ratio([ns)
cdf_error(ns)

Central limit theorem and Runge phenomena

Posted on by John

I was playing around with something this afternoon and stumbled on something like Gibbs phenomena or Runge phenomena for the Central Limit Theorem.

The first place most people encounter Gibbs phenomena is in Fourier series for a step function. The Fourier series develops “bat ears” near the discontinuity. Here’s an example I blogged about before not with Fourier series but with analogous Chebyshev series.

Gibbs phenomena for Chebyshev interpolation

The series converges rapidly in the middle of the flat parts, but under-shoots and over-shoots near the jumps in the step function.

Runge phenomena is similar, where interpolating functions under- and over-shoot the function they’re approximating.

Runge example

Both plots above come from this post.

Here’s the example I ran across with the central limit theorem. The distribution of the average of a set of exponential random variables converges to the distribution of a normal random variable. The nice thing about the exponential distribution is that the averages have a familiar distribution: a gamma distribution. If each exponential has mean 1, the average has a gamma distribution with shape N and scale 1/N. The central limit theorem says this is converging in distribution to a normal distribution with the same mean and variance.

The plot below shows the difference between the density function of the average of N exponential random variables and the density function for its normal approximation, for N = 10 and for N = 400.

Notice that the orange line, corresponding to N = 400, is very flat, most of the time. That is, the normal approximation fits very well. But there’s this spike in the middle, something reminiscent of Gibbs phenomena or Runge phenomena. Going from 10 to 400 samples the average error decreases quite a bit, but the maximum error doesn’t go down much at all.

If you go back and look at the Central Limit Theorem, or its more quantitative counterpart the Berry-Esseen theorem, you’ll notice that it applies to the distribution function, not the density, or in other words, the CDF, not the PDF. I think the density functions do converge in this case because the exponential function has a smooth density, but the rate of convergence depends on the norm. It looks like the convergence is fast in square (L²) norm, but slow in sup norm. A little experiment shows that this is indeed the case.

Maybe the max norm doesn’t converge at all, i.e. the densities don’t converge pointwise. It looks like the max norm may be headed toward a horizontal asymptote, just like Gibbs phenomena.

Update: It seems we do not have uniform convergence. If we let N = 1,000,000, the sup norm of the error 0.1836. It appears the sup norm of the error is approaching a lower bound of approximately this value.

Related posts

Computing extreme normal tail probabilities

Posted on by John

Let me say up front that relying on the normal distribution as an accurate model of extreme events is foolish under most circumstances. The main reason to calculate the probability of, say, a 40 sigma event is to show how absurd it is to talk about 40 sigma events. See my previous post on six-sigma events for an explanation.

For this post I’ll be looking at two-tailed events, the probability that a normal random variable is either less than –kσ or greater than kσ. If you’re only interested in one of these two probabilities, divide by 2. Also, since the results are independent of σ, let’s assume σ = 1 for convenience.

The following Python code will print a table of k-sigma event probabilities.

    from scipy.stats import norm

    for k in range(1, 40):
        print(k, 2*norm.cdf(-k))

This shows, for example, that a “25 sigma event,” something I’ve heard people talk about with a straight face, has a probability of 6 × 10-138.

The code above reports that a 38 or 39 sigma event has probability 0, exactly 0. That’s because the actual value, while not zero, is so close to zero that floating point precision can’t tell the difference. This happens around 10-308.

What if, despite all the signs warning hic sunt dracones you want to compute even smaller probabilities? Then for one thing you’ll need to switch over to log scale in order for the results to be representable as floating point numbers.

Exactly computing these extreme probabilities is challenging, but there are convenient upper and lower bounds on the probabilities that can be derived from Abramowitz and Stegun, equation 7.1.13 with a change of variables. See notes here.

We can use these bounds to compute upper and lower bounds on the base 10 logs of the tail probabilities.

    from scipy import log, sqrt, pi

    def core(t, c):
        x = 2*sqrt(2/pi)/(t + sqrt(t**2 + c))
        ln_p = -0.5*t**2 + log(x)
        return ln_p/log(10)

    def log10_upper(t):
        return core(t, 8/pi)

    def log10_lower(t):
        return core(t, 4)

This tells us that the log base 10 of the probability of a normal random variable being more than 38 standard deviations away from its mean is between -315.53968 and -315.53979. The upper and lower bounds agree to about seven significant figures, and the accuracy only improves as k gets larger. So for large arguments, we can use either the upper or lower bound as an accurate approximation.

The code above was used to compute this table of tail probabilities for k = 1 to 100 standard deviations.

Six sigma events

Posted on by John

I saw on Twitter this afternoon a paraphrase of a quote from Nassim Taleb to the effect that if you see a six-sigma event, that’s evidence that it wasn’t really a six-sigma event.

What does that mean? Six sigma means six standard deviations away from the mean of a probability distribution, sigma (σ) being the common notation for a standard deviation. Moreover, the underlying distribution is implicitly a normal (Gaussian) distribution; people don’t commonly talk about “six sigma” in the context of other distributions [1]. Here’s a table to indicate the odds against a k-sigma event for various k.

        |-------+-----------------|
        | Sigma | Odds            |
        |-------+-----------------|
        |     1 | 2 : 1           |
        |     2 | 21 : 1          |
        |     3 | 370 : 1         |
        |     4 | 16,000 : 1      |
        |     5 | 1,700,000 : 1   |
        |     6 | 500,000,000 : 1 |
        |-------+-----------------|

If you see something that according to your assumptions should happen twice in a billion tries, maybe you’ve seen something extraordinarily rare, or maybe your assumptions were wrong. Taleb’s comment suggests the latter is more likely.

Bayes rule and Bayes factors

You could formalize this with Bayes rule. For example, suppose you’re 99% sure the thing you’re looking at has a normal distribution with variance 1, but you’re willing to concede there’s a 1% chance that what you’re looking at has a fat-tailed distribution, say a Student t distribution with 10 degrees of freedom, rescaled to also have variance 1.

normal distribution vs t with 10 dof

It’s hard to tell the two distributions apart, especially in the tails. But although both are small in the tails, the normal is relatively much smaller.

Now suppose you’ve seen an observation greater than 6. The Bayes factor in favor of the t distribution hypothesis is 272. This means that even though before seeing any data you thought the odds were 99 to 1 in favor of the data coming from a normal distribution, after seeing such a large observation you would put the odds at 272 to 1 in favor of the t distribution.

If you allow a small possibility that your assumption of a normal distribution is wrong (see Cromwell’s rule) then seeing an extreme event will radically change your mind. You don’t have to think the fat-tailed distribution is equally likely, just a possibility. If you did think a priori that both possibilities were equally likely, the posterior odds for the t distribution would be 27,000 to 1.

In this example we’re comparing the normal distribution to a very specific and somewhat arbitrary alternative. Our alternative was just an example. You could have picked a wide variety of alternatives that would have given a qualitatively similar result, reversing your a priori confidence in a normal model.

By the way, a t distribution with 10 degrees of freedom is not a very fat-tailed distribution. It has fatter tails than a normal for sure, but not nearly as fat as a Cauchy, which corresponds to a t with only one degree of freedom. If we had used a distribution with a heavier tail, the posterior odds in favor of that distribution would have been higher.

***

[1] A six-sigma event isn’t that rare unless your probability distribution is normal. By Markov’s inequality, the probability is less than 1/36 for any distribution. The rarity of six-sigma events comes from the assumption of a normal distribution more than from the number of sigmas per se.

Robustness and tests for equal variance

Posted on by John

The two-sample t-test is a way to test whether two data sets come from distributions with the same mean. I wrote a few days ago about how the test performs under ideal circumstances, as well as less than ideal circumstances.

This is an analogous post for testing whether two data sets come from distributions with the same variance. Statistics texts books often present the F-test for this task, then warn in a footnote that the test is highly dependent on the assumption that both data sets come from normal distributions.

Sensitivity and robustness

Statistics texts give too little attention to robustness in my opinion. Modeling assumptions never hold exactly, so it’s important to know how procedures perform when assumptions don’t hold exactly. Since the F-test is one of the rare instances where textbooks warn about a lack of robustness, I expected the F-test to perform terribly under simulation, relative to its recommended alternatives Bartlett’s test and Levene’s test. That’s not exactly what I found.

Simulation design

For my simulations I selected 35 samples from each of two distributions. I selected significance levels for the F-test, Bartlett’s test, and Levene’s test so that each would have roughly a 5% error rate under a null scenario, both sets of data coming from the same distribution, and a 20% error rate under an alternative scenario.

I chose my initial null and alternative scenarios to use normal (Gaussian) distributions, i.e. to satisfy the assumptions of the F-test. Then I used the same designs for data coming from a fat-tailed distribution to see how well each of the tests performed.

For the normal null scenario, both data sets were drawn from a normal distribution with mean 0 and standard deviation 15. For the normal alternative scenario I used normal distributions with standard deviations 15 and 25.

Normal distribution calibration

Here are the results from the normal distribution simulations.

|----------+-------+--------+---------|
| Test     | Alpha | Type I | Type II |
|----------+-------+--------+---------|
| F        |  0.13 | 0.0390 |  0.1863 |
| Bartlett |  0.04 | 0.0396 |  0.1906 |
| Levene   |  0.06 | 0.0439 |  0.2607 |
|----------+-------+--------+---------|

Here the Type I column is the proportion of times the test incorrectly concluded that identical distributions had unequal variances. The Type II column reports the proportion of times the test failed to conclude that distributions with different variances indeed had unequal variances. Results were based on simulating 10,000 experiments.

The three tests had roughly equal operating characteristics. The only difference that stands out above simulation noise is that the Levene test had larger Type II error than the other tests when calibrated to have the same Type I error.

To calibrate the operating characteristics, I used alpha levels 0.15, 0.04, and 0.05 respectively for the F, Bartlett, and Levene tests.

Fat-tail simulation results

Next I used the design parameters above, i.e. the alpha levels for each test, but drew data from distributions with a heavier tail. For the null scenario, both data sets were drawn from a Student t distribution with 4 degrees of freedom and scale 15. For the alternative scenario, the scale of one of the distributions was increased to 25. Here are the results, again based on 10,000 simulations.

|----------+-------+--------+---------|
| Test     | Alpha | Type I | Type II |
|----------+-------+--------+---------|
| F        |  0.13 | 0.2417 |  0.2852 |
| Bartlett |  0.04 | 0.2165 |  0.2859 |
| Levene   |  0.06 | 0.0448 |  0.4537 |
|----------+-------+--------+---------|

The operating characteristics degraded when drawing samples from a fat-tailed distribution, t with 4 degrees of freedom, but they didn’t degrade uniformly.

Compared to the F-test, the Bartlett test had slightly better Type I error and the same Type II error.

The Levene test, had a much lower Type I error than the other tests, hardly higher than it was when drawing from a normal distribution, but had a higher Type II error.

Conclusion: The F-test is indeed sensitive to departures from the Gaussian assumption, but Bartlett’s test doesn’t seem much better in these particular scenarios. Levene’s test, however, does perform better than the F-test, depending on the relative importance you place on Type I and Type II error.

Related posts

Two-sample t-test and robustness

Posted on by John

A two-sample t-test is intended to determine whether there’s evidence that two samples have come from distributions with different means. The test assumes that both samples come from normal distributions.

Robust to non-normality, not to asymmetry

It is fairly well known that the t-test is robust to departures from a normal distribution, as long as the actual distribution is symmetric. That is, the test works more or less as advertised as long as the distribution is symmetric like a normal distribution, but it may not work as expected if the distribution is asymmetric.

This post will explore the robustness of the t-test via simulation. How far can you be from a normal distribution and still do OK? Can you have any distribution as long as it’s symmetric? Does a little asymmetry ruin everything? If something does go wrong, how does it go wrong?

Experiment design

For the purposes of this post, we’ll compare the null hypothesis that two groups both have mean 100 to the alternative hypothesis that one group has mean 100 and the other has mean 110. We’ll assume both distributions have a standard deviation of 15. There is a variation on the two-sample t-test that does not assume equal variance, but for simplicity we will keep the variance the same in both groups.

We’ll do a typical design, 0.05 significance and 0.80 power. That is, under the null hypothesis, that is if the two groups do come from the same distribution, we expect the test to wrongly conclude that the two distributions are different 5% of the time. And under the alternative hypothesis, when the groups do come from distributions with means 100 and 110, we expect the test to conclude that the two means are indeed different 80% of the time.

Under these assumptions, you’d need a sample of 36 in each group.

Python simulation code

Here’s the code we’ll use for our simulation.

    from scipy.stats import norm, t, gamma, uniform, ttest_ind

    num_per_group = 36

    def simulate_trials(num_trials, group1, group2):
        num_reject = 0
        for _ in range(num_trials):
            a = group1.rvs(num_per_group)
            b = group2.rvs(num_per_group)
            stat, pvalue = ttest_ind(a, b)
            if pvalue < 0.05:
                num_reject += 1
        return(num_reject)

Normal simulation

Normal distributions

Let’s see how the two-sample t-test works under ideal conditions by simulating from the normal distributions that the method assumes.

First we simulate from the null, i.e. we draw the data for both groups from the same distribution

    n1 = norm(100, 15)
    n2 = norm(100, 15)
    print( simulate_trials(1000, n1, n2) )

Out of 1000 experiment simulations, the method rejected the null 54 times, very close to the expected number of 50 based on 0.05 significance.

Next we simulate under the alternative, i.e. we draw data from different distributions.

    n1 = norm(100, 15)
    n2 = norm(110, 15)
    print( simulate_trials(1000, n1, n2) )

This time the method rejected the null 804 times in 1000 simulations, very close to the expected 80% based on the power.

Gamma simulation

Gamma distributions

Next we draw data from a gamma distribution. First we draw both groups from a gamma distribution with mean 100 and standard deviation 15. This requires a shape parameter of 44.44 and a scale of 2.25.

    g1 = gamma(a = 44.44, scale=2.25)
    g2 = gamma(a = 44.44, scale=2.25)
    print( simulate_trials(1000, g1, g2) )

Under the null simulation, we rejected the null 64 times out of 1000 simulations, higher than expected, but not that remarkable.

Under the alternative simulation, we pick the second gamma distribution to have mean 110 and standard deviation 15, which requires shape 53.77 and scale 2.025.

    g1 = gamma(a = 44.44, scale=2.25)
    g2 = gamma(a = 53.77, scale=2.045)
    print( simulate_trials(1000, g1, g2) )

We rejected the null 805 times in 1000 simulations, in line with what you’d expect from the power.

Gamma distributions

When the gamma distribution has such large shape parameters, the distributions are approximately normal, though slightly asymmetric. To increase the asymmetry, we’ll use a couple gamma distributions with smaller mean but shifted over to the right. Under the null, we create two gamma distributions with mean 10 and standard deviation 15, then shift them to the right by 90.

    g1 = gamma(a = 6.67, scale=1.5, loc=90)
    g2 = gamma(a = 6.67, scale=1.5, loc=90)
    print( simulate_trials(1000, g1, g2) )

Under this simulation we reject the null 56 times out of 1000 simulations, in line with what you’d expect.

For the alternative simulation, we pick the second distribution to have a mean of 20 and standard deviation 15, and then shift it to the right by 90 so tht it has mean 110. This distribution has quite a long tail.

    g1 = gamma(a = 6.67, scale=1.5, loc=90)
    g2 = gamma(a = 1.28, scale=11.25, loc=90)
    print( simulate_trials(1000, g1, g2) )

This time we rejected the null 499 times in 1000 simulations. This is a serious departure from what’s expected. Under the alternative hypothesis, we reject the null 50% of the time rather than the 80% we’d expect. If higher mean is better, this means that half the time you’d fail to conclude that the better group really is better.

Uniform distribution simulation

Next we use uniform random samples from the interval [74, 126]. This is a symmetric distribution with mean 100 and standard deviation 15. When we draw both groups from this distribution we rejected the null 48 times, in line with what we’d expect.

    u1 = uniform(loc=74, scale=52)
    u2 = uniform(loc=74, scale=52)
    print( simulate_trials(1000, u1, u2) )

If we move the second distribution over by 10, drawing from [84, 136], we rejected the null 790 times out of 1000, again in line with what you’d get from a normal distribution.

    u1 = uniform(loc=74, scale=52)
    u2 = uniform(loc=84, scale=52)
    print( simulate_trials(1000, u1, u2) )

In this case, we’ve made a big departure from normality and the test still worked as expected. But that’s not always the case, as in the t(3) distribution below.

Student-t simulation (fat tails)

Finally we simulate from a Student-t distribution. This is a symmetric distribution but it has fat tails relative to the normal distribution.

t distributions with 6 dof

First, we simulate from a t distribution with 6 degrees of freedom and scale 12.25, making the standard deviation 15. We shift the location of the distribution by 100 to make the mean 100.

    t1 = t(df=6, loc=100, scale=12.25)
    t2 = t(df=6, loc=100, scale=12.25)
    print( simulate_trials(1000, t1, t2) )

When both groups come from this distribution, we rejected the null 46 times. When we shifted the second distribution to have mean 110, we rejected the null 777 times out of 1000.

    t1 = t(df=6, loc=100, scale=12.25)
    t2 = t(df=6, loc=110, scale=12.25)
    print( simulate_trials(1000, t1, t2) )

In both cases, the results are in line what we’d expect given a 5% significance level and 80% power.

t distributions with 3 dof

A t distribution with 6 degrees of freedom has a heavy tail compared to a normal. Let’s try making the tail even heavier by using 3 degrees of freedom. We make the scale 15 to keep the standard deviation at 15.

    t1 = t(df=3, loc=100, scale=15)
    t2 = t(df=3, loc=100, scale=15)
    print( simulate_trials(1000, t1, t2) )

When we draw both samples from the same distribution, we rejected the null 37 times out of 1000, less than the 50 times we’d expect.

    t1 = t(df=3, loc=100, scale=15)
    t2 = t(df=3, loc=110, scale=15)
    print( simulate_trials(1000, t1, t2) )

When we shift the second distribution over to have mean 110, we rejected the null 463 times out of 1000, far less than the 80% rejection you’d expect if the data were normally distributed.

Just looking at a plot of the PDFs, a t(3) looks much closer to a normal distribution than a uniform distribution does. But the tail behavior is different. The tails of the uniform are as thin as you can get—they’re zero!—while the t(3) has heavy tails.

These two examples show that you can replace the normal distribution with a moderately heavy tailed symmetric distribution, but don’t overdo it. When the data some from a heavy tailed distribution, even one that is symmetric, the two-sample t-test may not have the operating characteristics you’d expect.

Sensitivity of logistic regression prediction on coefficients

Posted on by John

The output of a logistic regression model is a function that predicts the probability of an event as a function of the input parameter. This post will only look at a simple logistic regression model with one predictor, but similar analysis applies to multiple regression with several predictors.

p(x) = \frac{1}{1 + \exp(-a + bx)}

Here’s a plot of such a curve when a = 3 and b = 4.

Flattest part

The curvature of the logistic curve is small at both extremes. As x comes in from negative infinity, the curvature increases, then decreases to zero, then increases again, then decreases as x goes to positive infinity. We quantified this statement in another post where we calculate the curvature. The curvature is zero at the point where the second derivative of p

p''(x) = \frac{b^2 \exp(a + bx)\left(\exp(a +bx) -1\right)}{(1 + \exp(a + bx))^3}

is zero, which occurs when x = –a/b. At that point p = 1/2, so the curve is flattest where the probability crosses 1/2. In the graph above, this happens at x = -0.75.

A little calculation shows that the slope at the flattest part of the logistic curve is simply b.

Sensitivity to parameters

Now how much does the probability prediction p(x) change as the parameter a changes? We now need to consider p as a function of three variables, i.e. we need to consider a and b as additional variables. The marginal change in p in response to a change in a is the partial derivative of p with respect to a.

To know where this is maximized with respect to x, we take the partial derivative of the above expression with respect to x

\frac{\partial^2 p}{\partial x\, \partial a} = \frac{b(\exp(a + bx) - 1) \exp(a + bx)}{(1 + \exp(a + bx))^3}

which is zero when  x = –a/b, the same place where the logistic curve is flattest. And the partial of p with respect to a at that point is simply 1/4, independent of b. So a small change Δa results in a change of approximately Δa/4 at the flattest part of the logistic curve and results in less change elsewhere.

What about the dependence on b? That’s more complicated. The rate of change of p with respect to b is

\frac{\partial p}{\partial b} = \frac{\exp(a + bx) x }{(1 + \exp(a + bx))^2}

and this is maximized where

\frac{\partial^2 p}{\partial x \partial b} = 0

which in turn requires solving a nonlinear equation. This is easy to do numerically in a specific case, but not easy to work with analytically in general.

However, we can easily say how p changes with b near the point x = –a/b. This is not where the partial of p with respect to b is maximized, but it’s a place of interest because it has come up two times above. At that point the derivative of p with respect to b is –a/4b. So if a and b have the same sign, then a small increase in b will result in a small decrease in p and vice versa.

Obesity index: Measuring the fatness of probability distribution tails

Posted on by John

A probability distribution is called “fat tailed” if its probability density goes to zero slowly. Slowly relative to what? That is often implicit and left up to context, but generally speaking the exponential distribution is the dividing line. Probability densities that decay faster than the exponential distribution are called “thin” or “light,” and densities that decay slower are called “thick”, “heavy,” or “fat,” or more technically “subexponential.” The distinction is important because fat-tailed distributions tend to defy our intuition.

One surprising property of heavy-tailed (subexponential) distributions is the single big jump principle. Roughly speaking, most of the contribution to the sum of several heavy-tailed random variables comes from the largest of the samples. To be more specific, let “several” = 4 for reasons that’ll be apparent soon, though the result is true for any n. As x goes to infinity, the probability that

X1 + X2 + X3 + X4

is larger than x is asymptotically equal the probability that

max(X1, X2, X3, X4)

is larger than x.

The idea behind the obesity index [1] is turn the theorem above around, making it an empirical measure of how thick a distribution’s tail is. If you draw four samples from a random variable and sort them, the obesity index is the probability that that the sum of the max and min, X1 + X4, is greater than the sum of the middle samples, X2 + X3.

The obesity index could be defined for any distribution, but it only measures what the name implies for right-tailed distributions. For any symmetric distribution, the obesity index is 1/2. A Cauchy distribution is heavy-tailed, but it has two equally heavy tails, and so its obesity index is the same as the normal distribution, which has two light tails.

Note that location and scale parameters have no effect on the obesity index; shifting and scaling effect all the X values the same, so it doesn’t change the probability that X1 + X4 is greater than X2 + X3.

To get an idea of the obesity index in action, we’ll look at the normal, exponential, and Cauchy distributions, since these are the canonical examples of thin, medium, and thick tailed distributions. But for reasons explained above, we’ll actually look at the folded normal and folded Cauchy distributions, i.e. we’ll take their absolute values to create right-tailed distributions.

To calculate the obesity index exactly you’d need to do analytical calculations with order statistics. We’ll simulate the obesity index because that’s easier. It’s also more in the spirit of calculating the obesity index from data.

    from scipy.stats import norm, expon, cauchy

    def simulate_obesity(dist, N):
        data = abs(dist.rvs(size=(N,4)))
        count = 0
        for row in range(N):
            X = sorted(data[row])
            if X[0] + X[3] > X[1] + X[2]:
                count += 1
        return count/N

    for dist in [norm, expon, cauchy]:
        print( simulate_obesity(dist, 10000) )

When I ran the Python code above, I got

    0.6692
    0.7519
    0.8396

This ranks the three distributions in the anticipated order of tail thickness.

Note that the code above takes the absolute value of the random samples. This lets us pass in ordinary (unfolded) versions of the normal and Cauchy distributions, and its redundant for any distribution like the exponential that’s already positive-valued.

[I found out after writing this blog post that SciPy now has foldnorm and foldcauchy, but they don’t seem to work like I expect.]

Let’s try it on a few more distributions. Lognormal is between exponential and Cauchy in thickness. A Pareto distribution with parameter b goes to zero like x-1-b and so we expect a Pareto distribution to have a smaller obesity index than Cauchy when b is greater than 1, and a larger index when b is less than one. Once again the simulation results are what we’d expect.

The code

    for dist in [lognorm, pareto(2), pareto(0.5)]:
        print( simulate_obesity(dist, 10000) )

returns

    0.7766
    0.8242
    0.9249

By this measure, lognormal is just a little heavier than exponential. Pareto(2) comes in lighter than Cauchy, but not by much, and Pareto(0.5) comes in heavier.

Since the obesity index is a probability, it will always return a value between 0 and 1. Maybe it would be easier to interpret if we did something like take the logit transform of the index to spread the values out more. Then the distinctions between Pareto distributions of different orders, for example, might match intuition better.

[1] Roger M. Cooke et al. Fat-Tailed Distributions: Data, Diagnostics and Dependence. Wiley, 2014.