Statistics

Hocus pocus! Adopt a magician’s stance, if you want to reveal statistical sleights of hand

Posted on February 7, 2017 by Mayo
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Here’s the follow-up post to the one I reblogged on Feb 3. When they sought to subject Uri Geller to the scrutiny of scientists, magicians had to be brought in because only they were sufficiently trained to spot the subtle sleight of hand shifts by which the magician tricks by misdirection. We, too, have to be magicians to discern the subtle misdirections and shifts of meaning in the discussions of statistical significance tests (and other methods)—even by the same statistical guide. We needn’t suppose anything deliberately devious is going on at all! Often, the statistical guidebook reflects shifts of meaning that grow out of one or another critical argument. These days, they trickle down quickly to statistical guidebooks, thanks to popular articles on the “statistics crisis in science”. The danger is that their own guidebooks contain inconsistencies. To adopt the magician’s stance is to be on the lookout for standard sleights of hand. There aren’t that many.[0]

I don’t know Jim Frost, but he gives statistical guidance at the minitab blog. The purpose of my previous post is to point out that Frost uses the probability of a Type I error in two incompatible ways in his posts on significance tests. I assumed he’d want to clear this up, but so far he has not. His response to a comment I made on his blog is this:

Based on Fisher’s measure of evidence approach, the correct way to interpret a p-value of exactly 0.03 is like this:

Assuming the null hypothesis is true, you’d obtain the observed effect or more in 3% of studies due to random sampling error.

We know that the p-value is not the error rate because:

1) The math behind the p-values is not designed to calculate the probability that the null hypothesis is true (which is actually incalculable based solely on sample statistics). …

But this is also true for a test’s significance level α, so on these grounds α couldn’t be an “error rate” or error probability either. Yet Frost defines α to be a Type I error probability (“An α of 0.05 indicates that you are willing to accept a 5% chance that you are wrong when you reject the null hypothesis“.) [1]

Let’s use the philosopher’s slightly obnoxious but highly clarifying move of subscripts. There is error probability1—the usual frequentist (sampling theory) notion—and error probability2—the posterior probability that the null hypothesis is true conditional on the data, as in Frost’s remark.  (It may also be stated as conditional on the p-value, or on rejecting the null.) Whether a p-value is predesignated or attained (observed), error probabilitity1 ≠ error probability2.[2] Frost, inadvertently I assume, uses the probability of a Type I error in these two incompatible ways in his posts on significance tests.[3]

Interestingly, the simulations to which Frost refers to “show that the actual probability that the null hypothesis is true [i.e., error probability2] tends to be greater than the p-value by a large margin” work with a fixed p-value, or α level, of say .05. So it’s not a matter of predesignated or attained p-values [4]. Their computations also employ predesignated probabilities of type II errors and corresponding power values. The null is rejected based on a single finding that attains .05 p-value. Moreover, the point null (of “no effect”) is give a spiked prior of .5. (The idea comes from a context of diagnostic testing; the prior is often based on an assumed “prevalence” of true nulls from which the current null is a member. Please see my previous post.)

Their simulations are the basis of criticisms of error probability1 because what really matters, or so these critics presuppose, is error probability2 .

Whether this assumption is correct, and whether these simulations are the slightest bit relevant to appraising the warrant for a given hypothesis, are completely distinct issues. I’m just saying that Frost’s own links mix these notions. If you approach statistical guidebooks with the magician’s suspicious eye, however, you can pull back the curtain on these sleights of hand.

Oh, and don’t lose your nerve just because the statistical guides themselves don’t see it or don’t relent. Send it on to me at [email protected].

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[0] They are the focus of a book I am completing: “Statistical Inference As Severe Testing: How to Get Beyond the Statistics Wars (CUP, 2017)

[1]  I admit we need a more careful delineation of the meaning of ‘error probability’.  One doesn’t have an error probability without there being something that could be “in error”. That something is generally understood as an inference or an interpretation of data. A method of statistical inference moves from data to some inference about the source of the data as modeled; some may wish to see the inference as a kind of “act” (using Neyman’s language) or “decision to assert” but nothing turns on this.
Associated error probabilities refer to the probability a method outputs an erroneous interpretation of the data, where the particular error is pinned down. For example, it might be, the test infers μ > 0 when in fact the data have been generated by a process where μ = 0.  The test is defined in terms of a test statistic d(X), and  the error probabilitiesrefer to the probability distribution of d(X), the sampling distribution, under various assumptions about the data generating process. Error probabilities in tests, whether of the Fisherian or N-P varieties, refer to hypothetical relative frequencies of error in applying a method.

[2] Notice that error probability2 involves conditioning on the particular outcome. Say you have observed a 1.96 standard deviation difference, and that’s your fixed cut-off. There’s no consideration of the sampling distribution of d(X), if you’ve conditioned on the actual outcome. Yet probabilities of Type I and Type II errors, as well as p-values, are defined exclusively in terms of the sampling distribution of d(X), under a statistical hypothesis of interest. But all that’s error probability1.

[3] Doubtless, part of the problem is that testers fail to clarify when and why a small significance level (or p-value) provides a warrant for inferring a discrepancy from the null. Firstly, for a p-value to be actual (and not merely nominal):

Pr(P < pobs; H0) = pobs .

Cherry picking and significance seeking can yield a small nominal p-value, while the actual probability of attaining even smaller p-values under the null is high. So this identity fails. Second, A small p- value warrants inferring a discrepancy from the null because, and to the extent that, a larger p-value would very probably have occurred, were the null hypothesis correct. This links error probabilities of a method to an inference in the case at hand.

….Hence pobs is the probability that we would mistakenly declare there to be evidence against H0, were we to regard the data under analysis as being just decisive against H0.” (Cox and Hinkley 1974, p. 66).

[4] The myth that significance levels lose their error probability status once the attained p-value is reported is just that, a myth. I’ve discussed it a lot elsewhere; but the the current point doesn’t turn on this. Still, it’s worth listening to statistician Stephen Senn (2002, p. 2438) on this point.

 I disagree with [Steve Goodman] on two grounds here: (i) it is not necessary to separate p-values from their hypothesis test interpretation; (ii) the replication probability has no direct bearing on inferential meaning. Second he claims that, ‘the replication probability can be used as a frequentist counterpart of Bayesian and likelihood models to show that p-values overstate the evidence against the null-hypothesis’ (p. 875, my italics). I disagree that there is such an overstatement.  In my opinion, whatever philosophical differences there are between significance tests and hypothesis test, they have little to do with the use or otherwise of p-values. For example, Lehmann in Testing Statistical Hypotheses, regarded by many as the most perfect and complete expression of the Neyman–Pearson approach, says

‘In applications, there is usually available a nested family of rejection regions corresponding to different significance levels. It is then good practice to determine not only whether the hypothesis is accepted or rejected at the given significance level, but also to determine the smallest significance level … the significance probability or p-value, at which the hypothesis would be rejected for the given observation’. (Lehmann, Testing Statistical hypotheses (1994, p. 70, original italics). 

Note to subscribers: Please check back to find follow-ups and corrected versions of blogposts, indicated with (ii), (iii) etc.

Some Relevant Posts:

Categories: Statistics, frequentist/Bayesian, P-values, reforming the reformers, S. Senn | Leave a comment

High error rates in discussions of error rates: no end in sight

Posted on February 3, 2017 by Mayo
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waiting for the other shoe to drop…

“Guides for the Perplexed” in statistics become “Guides to Become Perplexed” when “error probabilities” (in relation to statistical hypotheses tests) are confused with posterior probabilities of hypotheses. Moreover, these posteriors are neither frequentist, subjectivist, nor default. Since this doublespeak is becoming more common in some circles, it seems apt to reblog a post from one year ago (you may wish to check the comments).

Do you ever find yourself holding your breath when reading an exposition of significance tests that’s going swimmingly so far? If you’re a frequentist in exile, you know what I mean. I’m sure others feel this way too. When I came across Jim Frost’s posts on The Minitab Blog, I thought I might actually have located a success story. He does a good job explaining P-values (with charts), the duality between P-values and confidence levels, and even rebuts the latest “test ban” (the “Don’t Ask, Don’t Tell” policy). Mere descriptive reports of observed differences that the editors recommend, Frost shows, are uninterpretable without a corresponding P-value or the equivalent. So far, so good. I have only small quibbles, such as the use of “likelihood” when meaning probability, and various and sundry nitpicky things. But watch how in some places significance levels are defined as the usual error probabilities —indeed in the glossary for the site—while in others it is denied they provide error probabilities. In those other places, error probabilities and error rates shift their meaning to posterior probabilities, based on priors representing the “prevalence” of true null hypotheses.

Begin with one of his kosher posts “Understanding Hypothesis Tests: Significance Levels (Alpha) and P values in Statistics” (blue is Frost):

(1) The Significance level is the Type I error probability (3/15)

The significance level, also denoted as alpha or α, is the probability of rejecting the null hypothesis when it is true. For example, a significance level of 0.05 indicates a 5% risk of concluding that a difference exists when there is no actual difference….

Keep in mind that there is no magic significance level that distinguishes between the studies that have a true effect and those that don’t with 100% accuracy. The common alpha values of 0.05 and 0.01 are simply based on tradition. For a significance level of 0.05, expect to obtain sample means in the critical region 5% of the time when the null hypothesis is true. In these cases, you won’t know that the null hypothesis is true but you’ll reject it because the sample mean falls in the critical region. That’s why the significance level is also referred to as an error rate! (My emphasis.)

Note: Frost is using the term “error rate” here, which is why I use it in my title. Error probability would be preferable.

This type of error doesn’t imply that the experimenter did anything wrong or require any other unusual explanation. The graphs show that when the null hypothesis is true, it is possible to obtain these unusual sample means for no reason other than random sampling error. It’s just luck of the draw.

(2) Definition Link: Now we go to the blog’s definition link for this “type of error”

No hypothesis test is 100% certain. Because the test is based on probabilities, there is always a chance of drawing an incorrect conclusion.

Type I error

When the null hypothesis is true and you reject it, you make a type I error. The probability of making a type I error is α, which is the level of significance you set for your hypothesis test. An α of 0.05 indicates that you are willing to accept a 5% chance that you are wrong when you reject the null hypothesis. (My emphasis)

  Null Hypothesis
Decision True False
Fail to reject Correct Decision (probability = 1 – α) Type II Error – fail to reject the null when it is false (probability = β)
Reject Type I Error – rejecting the null when it is true (probability = α) Correct Decision (probability = 1 – β)

 

He gives very useful graphs showing quite clearly that the probability of a Type I error comes from the sampling distribution of the statistic (in the illustrated case, it’s the distribution of sample means).

So it is odd that elsewhere Frost tells us that a significance level (attained or fixed) is not the probability of a Type I error. Note: the issue here isn’t whether the significance level is fixed or attained, the difference to which I’m calling your attention is between an ordinary frequentist error probability and a posterior probability in a null hypothesis, given it is rejected—based on a prior probability for the null vs a probability for a single alternative, which he writes as P(real). We may call it the false finding rate (FFR), and it arises in typical diagnostic screening contexts. I elsewhere take up the allegation, by some, that a significance level is an error probability but a P-value is not (Are P-values error probabilities?). A post is here. Also see note [a] below.]
Here are some examples from Frost’s posts on 4/14 & 5/14:

 (3)  In a different post Frost alleges: A significance level is not the Type I error probability

Incorrect interpretations of P values are very common. The most common mistake is to interpret a P value as the probability of making a mistake by rejecting a true null hypothesis (a Type I error).

Now “making a mistake” may be vague, (and his statement here is a bit wonky) but the parenthetical link makes it clear he intends the Type I error probability. Guess what? The link is to the exact same definition of Type I error as before: the ordinary error probability computed from the sampling distribution. Yet in the blogpost itself, the Type I error probability now refers to a posterior probability of the null, based on an assumed prior probability of .5!

If a P value is not the error rate, what the heck is the error rate?

Sellke et al.* have estimated the error rates associated with different P values. While the precise error rate depends on various assumptions (which I discuss here), the table summarizes them for middle-of-the-road assumptions.

P value Probability of incorrectly rejecting a true null hypothesis
0.05 At least 23% (and typically close to 50%)
0.01 At least 7% (and typically close to 15%)

*Thomas SELLKE, M. J. BAYARRI, and James O. BERGER, Calibration of p Values for Testing Precise Null Hypotheses, The American Statistician, February 2001, Vol. 55, No. 1

We’ve discussed how J. Berger and Sellke (1987) compute these posterior probabilities using spiked priors, generally representing undefined “reference” or conventional priors. (Please see my previous post.) J. Berger claims, at times, that these posterior probabilities (which he computes in lots of different ways) are the error probabilities, and Frost does too, at least in some posts. The allegation that therefore P-values exaggerate the evidence can’t be far behind–or so a reader of this blog surmises–and there it is, right below:

Do the higher error rates in this table surprise you? Unfortunately, the common misinterpretation of P values as the error rate creates the illusion of substantially more evidence against the null hypothesis than is justified. As you can see, if you base a decision on a single study with a P value near 0.05, the difference observed in the sample may not exist at the population level. (Frost 5/14)

Admittedly, Frost is led to his equivocation by the sleights of hands of others, encouraged after around 2003 (in my experience).

(4) J. Berger’s Sleight of Hand: These sleights of hand are familiar to readers of this blog; I wouldn’t have expected them in a set of instructional blogposts about misinterpreting significance levels (at least without a great big warning). But Frost didn’t dream them up, he’s following a practice, traceable to J. Berger, of claiming that a posterior (usually based on conventional priors) gives the real error rate (or the conditional error rate). [The computations come from Edwards, Lindmann, and Savage 1963.) Whether it’s the ‘right’ default prior to use or not, my point is simply that the meaning is changed, and Frost ought to issue a trigger alert! Instead, he includes numerous links to related posts on significance tests, making it appear that blithely assigning a .5 spiked prior to the null is not only kosher, but is part of ordinary significance testing. It’s scarcely a justified move. As Casella and R.Berger (1987) show, this is a highly biased prior to use. See this post, and others by Stephen Senn (3/16/15, 5/9/15). Moreover, many people regard point nulls as always false.

In my comment on J. Berger (2003), I noted my surprise at his redefinition of error probability. (See pp. 19-24 in this paper). In response to me, Berger asks,

“Why should the frequentist school have exclusive right to the term ‘error probability’? It is not difficult to simply add the designation ‘frequentist’ (or Type I or Type II) or ‘Bayesian’ to the term to differentiate between the schools” (J. Berger 2003, p. 30).

That would work splendidly, I’m all in favor of differentiating between the schools. Note that he allows “Type I ” to go with the ordinary frequentist variant. If Berger had emphasized this distinction in his paper, Frost would have been warned of the slipperly slide he’s about to take a trip on. Instead, Berger has increasingly grown accustomed to claiming these are the real frequentist(!) error probabilities. (Others have followed.)

(5) Is Hypothesis testing like Diagnostic Screening? Now Frost (following David Colquhoun) appears to favor (not Berger’s conventionalist prior) a type of frequentist or “prevalence” prior:

It is the proportion of hypothesis tests in which the alternative hypothesis is true at the outset. It can be thought of as the long-term probability, or track record, of similar types of studies. It’s the plausibility of the alternative hypothesis.

Do we know these prevalences? What reference class should a given hypothesis be regarded as having been selected? There would be many different urns to which a particular hypothesis belongs. Such frequentist-Bayesian computations may be appropriate in contexts of high throughput screening, where a hypothesis is viewed as a generic, random selection from an urn of hypotheses. Here, a (behavioristic) concern to control the rates of following up false leads is primary. But that’s very different from evaluating how well tested or corroborated a particular H is. And why should fields with “high crud factors” (as Meehl called them) get the benefit? (having a low prior prevalence of “no effect”).

I’ve discussed all these points elsewhere, and they are beside my current complaint which is simply this: In some places, Frost construes the probability of a Type I error as an ordinary error probability based on the sampling distribution alone; and other places as a Bayesian posterior probability of a hypothesis, conditional on a set of data.

Frost goes further in the post to suggest that “hypotheses tests are journeys from the prior probability to posterior probability”.

Hypothesis tests begin with differing probabilities that the null hypothesis is true depending on the specific hypotheses being tested. [Mayo: They do?] This prior probability influences the probability that the null is true at the conclusion of the test, the posterior probability.

 

Initial Probability of
true null (1 – P(real))		 P value obtained Final Minimum Probability
of true null
0.5 0.05 0.289
0.5 0.01 0.110
0.5 0.001 0.018
0.33 0.05 0.12
0.9 0.05 0.76

The table is based on calculations by Colquhoun and Sellke et al. It shows that the decrease from the initial probability to the final probability of a true null depends on the P value. Power is also a factor but not shown in the table.

It is assumed that there is just a crude dichotomy: the null is true vs the effect is real (never mind magnitudes of discrepancy which I and others insist upon), and further, that you reject on the basis of a single, just statistically significant result. But these moves go against the healthy recommendations for good testing in the other posts on the Minitab blog. I recommend Frost go back and label the places where he has conflated the probability of a Type I error with a posterior probability based on a prior: use Berger’s suggestion of reserving “Type I error probability” for the ordinary frequentist error probability based on a sampling distribution alone, calling the posterior error probability Bayesian. Else contradictory claims will ensue…But I’m not holding my breath.

I may continue this in (ii)….

***********************************************************************

January 21, 2016 Update:

Jim Frost from Minitab responded, not to my post, but to a comment I made on his blog prior to writing the post. Since he hasn’t commented here, let me paste the relevant portion of his reply. I want to separate the issue of predesignating alpha and the observed P-value, because my point now is quite independent of it. Let’s even just talk of a fixed alpha or fixed P-value for rejecting the null. My point’s very simple: Frost sometimes considers the type I error probability to be alpha (in the 2015 posts) based solely on the sampling distribution which he ably depicts– whereas in other places he regards it as the posterior probability of the null hypothesis based on a prior probability (the 2014 posts). He does the same in his reply to me (which I can’t seem to link, but it’s in the discussion here):

From Frost’s reply to me:

Yes, if your study obtains a p-value of 0.03, you can say that 3% of all studies that obtain a p-value less than or equal to 0.03 will have a Type I error. That’s more of a N-P error rate interpretation (except that N-P focused on critical test values rather than p-values). …..

Based on Fisher’s measure of evidence approach, the correct way to interpret a p-value of exactly 0.03 is like this:

Assuming the null hypothesis is true, you’d obtain the observed effect or more in 3% of studies due to random sampling error.

We know that the p-value is not the error rate because:

1) The math behind the p-values is not designed to calculate the probability that the null hypothesis is true (which is actually incalculable based solely on sample statistics). See a graphical representation of the math behind p-values and a post dedicated to how to correctly interpret p-values.

2) We also know this because there have been a number of simulation studies that look at the relationship between p-values and the probability that the null is true. These studies show that the actual probability that the null hypothesis is true tends to be greater than the p-value by a large margin.

3) Empirical studies that look at the replication of significant results also suggest that the actual probability that the null is true is greater than the p-value.

Frost’s points (1)-(3) above would also oust alpha as the type I error probability, for it’s also not designed to give a posterior. Never mind the question of the irrelevance or bias associated with the hefty spiked prior to the null involved in the simulations, all I’m saying is that Frost should make the distinction that even J. Berger agrees to, if he doesn’t want to confuse his readers.

—————————————————————————

[a] A distinct issue as to whether significance levels, but not P-values (the attained significance level) are error probabilities, is discussed here. Here are some of the assertions from Fisherian, Neyman-Pearsonian and Bayesian camps cited in that post. (I make no attempt at uniformity in writing the “P-value”, but retain the quotes as written.

From the Fisherian camp (Cox and Hinkley):

For given observations y we calculate t = tobs = t(y), say, and the level of significance pobs by

pobs = Pr(T > tobs; H0).

….Hence pobs is the probability that we would mistakenly declare there to be evidence against H0, were we to regard the data under analysis as being just decisive against H0.” (Cox and Hinkley 1974, 66).

Thus pobs would be the Type I error probability associated with the test.

From the Neyman-Pearson N-P camp (Lehmann and Romano):

“[I]t is good practice to determine not only whether the hypothesis is accepted or rejected at the given significance level, but also to determine the smallest significance level…at which the hypothesis would be rejected for the given observation. This number, the so-called p-value gives an idea of how strongly the data contradict the hypothesis. It also enables others to reach a verdict based on the significance level of their choice.” (Lehmann and Romano 2005, 63-4) 

Very similar quotations are easily found, and are regarded as uncontroversial—even by Bayesians whose contributions stood at the foot of Berger and Sellke’s argument that P values exaggerate the evidence against the null.

Gibbons and Pratt:

“The P-value can then be interpreted as the smallest level of significance, that is, the ‘borderline level’, since the outcome observed would be judged significant at all levels greater than or equal to the P-value[i] but not significant at any smaller levels. Thus it is sometimes called the ‘level attained’ by the sample….Reporting a P-value, whether exact or within an interval, in effect permits each individual to choose his own level of significance as the maximum tolerable probability of a Type I error.” (Gibbons and Pratt 1975, 21).

 

REFERENCES:

Berger, J. O. and Sellke, T.  (1987). “Testing a point null hypothesis: The irreconcilability of p values and evidence,” (with discussion). J. Amer. Statist. Assoc. 82: 112–139.

Casella G. and Berger, R. (1987). “Reconciling Bayesian and Frequentist Evidence in the One-sided Testing Problem,” (with discussion). J. Amer. Statist. Assoc. 82 106–111, 123–139.

Edwards, A. ., Lindman, H. and Savage, L. 1963. ‘Bayesian Statistical Inference for Psychological Research’, Psychological Review 70(3): 193–242.

Sellke, T., Bayarri, M. J. and Berger, J. O. 2001. Calibration of p Values for Testing Precise Null Hypotheses. The American Statistician, 55(1): 62-71.

  1. Frost blog posts:
  • 4/17/14: How to Correctly Interpret P Values
  • 5/1/14: Not All P Values are Created Equal
  • 3/19/15: Understanding Hypothesis Tests: Significance Levels (Alpha) and P values in Statistics

Some Relevant Errorstatistics Posts:

  •  4/28/12: Comedy Hour at the Bayesian Retreat: P-values versus Posteriors.
  • 9/29/13: Highly probable vs highly probed: Bayesian/ error statistical differences.
  • 7/14/14: “P-values overstate the evidence against the null”: legit or fallacious? (revised)
  • 8/17/14: Are P Values Error Probabilities? or, “It’s the methods, stupid!” (2nd install)
  • 3/5/15: A puzzle about the latest test ban (or ‘don’t ask, don’t tell’)
  • 3/16/15: Stephen Senn: The pathetic P-value (Guest Post)
  • 5/9/15: Stephen Senn: Double Jeopardy?: Judge Jeffreys Upholds the Law (sequel to the pathetic P-value)
Categories: highly probable vs highly probed, J. Berger, reforming the reformers, Statistics | 1 Comment

3 YEARS AGO (JANUARY 2014): MEMORY LANE

Posted on January 28, 2017 by Mayo
3 years ago...

3 years ago…

MONTHLY MEMORY LANE: 3 years ago: January 2014. I mark in red three posts from each month that seem most apt for general background on key issues in this blog, excluding those reblogged recently[1], and in green up to 3 others I’d recommend[2].  Posts that are part of a “unit” or a group count as one. This month, I’m grouping the 3 posts from my seminar with A. Spanos, counting them as 1.

January 2014

  • (1/2) Winner of the December 2013 Palindrome Book Contest (Rejected Post)
  • (1/3) Error Statistics Philosophy: 2013
  • (1/4) Your 2014 wishing well. …
  • (1/7) “Philosophy of Statistical Inference and Modeling” New Course: Spring 2014: Mayo and Spanos: (Virginia Tech)
  • (1/11) Two Severities? (PhilSci and PhilStat)
  • (1/14) Statistical Science meets Philosophy of Science: blog beginnings
  • (1/16) Objective/subjective, dirty hands and all that: Gelman/Wasserman blogolog (ii)
  • (1/18) Sir Harold Jeffreys’ (tail area) one-liner: Sat night comedy [draft ii]
  • (1/22) Phil6334: “Philosophy of Statistical Inference and Modeling” New Course: Spring 2014: Mayo and Spanos (Virginia Tech) UPDATE: JAN 21
  • (1/24) Phil 6334: Slides from Day #1: Four Waves in Philosophy of Statistics
  • (1/25) U-Phil (Phil 6334) How should “prior information” enter in statistical inference?
  • (1/27) Winner of the January 2014 palindrome contest (rejected post)
  • (1/29) BOSTON COLLOQUIUM FOR PHILOSOPHY OF SCIENCE: Revisiting the Foundations of Statistics

    .

  • (1/31) Phil 6334: Day #2 Slides

 

[1] Monthly memory lanes began at the blog’s 3-year anniversary in Sept, 2014.

[2] New Rule, July 30, 2016-very convenient.

 

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Categories: 3-year memory lane, Bayesian/frequentist, Statistics | 1 Comment

The “P-values overstate the evidence against the null” fallacy

Posted on January 19, 2017 by Mayo
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The allegation that P-values overstate the evidence against the null hypothesis continues to be taken as gospel in discussions of significance tests. All such discussions, however, assume a notion of “evidence” that’s at odds with significance tests–generally Bayesian probabilities of the sort used in Jeffrey’s-Lindley disagreement (default or “I’m selecting from an urn of nulls” variety). Szucs and Ioannidis (in a draft of a 2016 paper) claim “it can be shown formally that the definition of the p value does exaggerate the evidence against H0” (p. 15) and they reference the paper I discuss below: Berger and Sellke (1987). It’s not that a single small P-value provides good evidence of a discrepancy (even assuming the model, and no biasing selection effects); Fisher and others warned against over-interpreting an “isolated” small P-value long ago.  But the formulation of the “P-values overstate the evidence” meme introduces brand new misinterpretations into an already confused literature! The following are snippets from some earlier posts–mostly this one–and also includes some additions from my new book (forthcoming). 

1. What you should ask…

When you hear the familiar refrain, “We all know that P-values overstate the evidence against the null hypothesis”, what you should ask is:

“What do you mean by overstating the evidence against a hypothesis?”

One honest answer is: Continue reading

Categories: Bayesian/frequentist, fallacy of rejection, highly probable vs highly probed, P-values, Statistics | 46 Comments

BOSTON COLLOQUIUM FOR PHILOSOPHY OF SCIENCE: Understanding Reproducibility & Error Correction in Science

Posted on January 7, 2017 by Mayo

BOSTON COLLOQUIUM FOR PHILOSOPHY OF SCIENCE

2016–2017
57th Annual Program

Download the 57th Annual Program

The Alfred I. Taub forum:

UNDERSTANDING REPRODUCIBILITY & ERROR CORRECTION IN SCIENCE

Cosponsored by GMS and BU’s BEST at Boston University.
Friday, March 17, 2017
1:00 p.m. – 5:00 p.m.
The Terrace Lounge, George Sherman Union
775 Commonwealth Avenue

  • Reputation, Variation, &, Control: Historical Perspectives
    Jutta Schickore History and Philosophy of Science & Medicine, Indiana University, Bloomington.
  • Crisis in Science: Time for Reform?
    Arturo Casadevall Molecular Microbiology & Immunology, Johns Hopkins
  • Severe Testing: The Key to Error Correction
    Deborah Mayo Philosophy, Virginia Tech
  • Replicate That…. Maintaining a Healthy Failure Rate in Science
    Stuart Firestein Biological Sciences, Columbia

 

boston-mayo-2017

Categories: Announcement, philosophy of science, Philosophy of Statistics, Statistical fraudbusting, Statistics | Leave a comment

Midnight With Birnbaum (Happy New Year 2016)

Posted on December 31, 2016 by Mayo

 Just as in the past 5 years since I’ve been blogging, I revisit that spot in the road at 11p.m., just outside the Elbar Room, get into a strange-looking taxi, and head to “Midnight With Birnbaum”. (The pic on the left is the only blurry image I have of the club I’m taken to.) I wonder if the car will come for me this year, given that my Birnbaum article has been out since 2014… The (Strong) Likelihood Principle–whether or not it is named–remains at the heart of many of the criticisms of Neyman-Pearson (N-P) statistics (and cognate methods). Yet as Birnbaum insisted, the “confidence concept” is the “one rock in a shifting scene” of statistical foundations, insofar as there’s interest in controlling the frequency of erroneous interpretations of data. (See my rejoinder.) Birnbaum bemoaned the lack of an explicit evidential interpretation of N-P methods. Maybe in 2017? Anyway, it’s 6 hrs later here, so I’m about to leave for that spot in the road… If I’m picked up, I’ll add an update at the end.

You know how in that (not-so) recent Woody Allen movie, “Midnight in Paris,” the main character (I forget who plays it, I saw it on a plane) is a writer finishing a novel, and he steps into a cab that mysteriously picks him up at midnight and transports him back in time where he gets to run his work by such famous authors as Hemingway and Virginia Wolf?  He is impressed when his work earns their approval and he comes back each night in the same mysterious cab…Well, imagine an error statistical philosopher is picked up in a mysterious taxi at midnight (New Year’s Eve 2011 2012, 2013, 2014, 2015, 2016) and is taken back fifty years and, lo and behold, finds herself in the company of Allan Birnbaum.[i] There are a couple of brief (12/31/14 & 15) updates at the end.  

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ERROR STATISTICIAN: It’s wonderful to meet you Professor Birnbaum; I’ve always been extremely impressed with the important impact your work has had on philosophical foundations of statistics.  I happen to be writing on your famous argument about the likelihood principle (LP).  (whispers: I can’t believe this!)

BIRNBAUM: Ultimately you know I rejected the LP as failing to control the error probabilities needed for my Confidence concept. Continue reading

Categories: Birnbaum Brakes, Statistics, strong likelihood principle | Tags: , , , | 21 Comments

Szucs & Ioannidis Revive the Limb-Sawing Fallacy

Posted on December 30, 2016 by Mayo

 

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When logical fallacies of statistics go uncorrected, they are repeated again and again…and again. And so it is with the limb-sawing fallacy I first posted in one of my “Overheard at the Comedy Hour” posts.* It now resides as a comic criticism of significance tests in a paper by Szucs and Ioannidis (posted this week),  Here’s their version:

“[P]aradoxically, when we achieve our goal and successfully reject Hwe will actually be left in complete existential vacuum because during the rejection of HNHST ‘saws off its own limb’ (Jaynes, 2003; p. 524): If we manage to reject H0then it follows that pr(data or more extreme data|H0) is useless because H0 is not true” (p.15).

Here’s Jaynes (p. 524):

“Suppose we decide that the effect exists; that is, we reject [null hypothesis] H0. Surely, we must also reject probabilities conditional on H0, but then what was the logical justification for the decision? Orthodox logic saws off its own limb.’ 

Ha! Ha! By this reasoning, no hypothetical testing or falsification could ever occur. As soon as H is falsified, the grounds for falsifying disappear! If H: all swans are white, then if I see a black swan, H is falsified. But according to this criticism, we can no longer assume the deduced prediction from H! What? Continue reading

Categories: Error Statistics, P-values, reforming the reformers, Statistics | 14 Comments

3 YEARS AGO (DECEMBER 2013): MEMORY LANE

Posted on December 26, 2016 by Mayo
3 years ago...

3 years ago…

MONTHLY MEMORY LANE: 3 years ago: December 2013. I mark in red three posts from each month that seem most apt for general background on key issues in this blog, excluding those reblogged recently[1], and in green up to 3 others I’d recommend[2].  Posts that are part of a “unit” or a group count as one. In this post, that makes 12/27-12/28 count as one.

December 2013

  • (12/3) Stephen Senn: Dawid’s Selection Paradox (guest post)
  • (12/7) FDA’s New Pharmacovigilance
  • (12/9) Why ecologists might want to read more philosophy of science (UPDATED)
  • (12/11) Blog Contents for Oct and Nov 2013
  • (12/14) The error statistician has a complex, messy, subtle, ingenious piece-meal approach
  • (12/15) Surprising Facts about Surprising Facts
  • (12/19) A. Spanos lecture on “Frequentist Hypothesis Testing
  • (12/24) U-Phil: Deconstructions [of J. Berger]: Irony & Bad Faith 3
  • (12/25) “Bad Arguments” (a book by Ali Almossawi)
  • (12/26) Mascots of Bayesneon statistics (rejected post)
  • (12/27) Deconstructing Larry Wasserman
  • (12/28) More on deconstructing Larry Wasserman (Aris Spanos)
  • (12/28) Wasserman on Wasserman: Update! December 28, 2013
  • (12/31) Midnight With Birnbaum (Happy New Year)

[1] Monthly memory lanes began at the blog’s 3-year anniversary in Sept, 2014.

[2] New Rule, July 30, 2016-very convenient.

 

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Categories: 3-year memory lane, Bayesian/frequentist, Error Statistics, Statistics | 1 Comment

S. Senn: “Placebos: it’s not only the patients that are fooled” (Guest Post)

Posted on December 19, 2016 by Mayo
Stephen Senn

Stephen Senn

Placebos: it’s not only the patients that are fooled

Stephen Senn
Head of  Competence Center for Methodology and Statistics (CCMS)
Luxembourg Institute of Health

In my opinion a great deal of ink is wasted to little purpose in discussing placebos in clinical trials. Many commentators simply do not understand the nature and purpose of placebos. To start with the latter, their only purpose is to permit blinding of treatments and, to continue to the former, this implies that their nature is that they are specific to the treatment studied.

Consider an example. Suppose that Pannostrum Pharmaceuticals wishes to prove that its new treatment for migraine, Paineaze® (which is in the form of a small red circular pill) is superior to the market-leader offered by Allexir Laboratories, Kalmer® (which is a large purple lozenge). Pannostrum decides to do a head-to head comparison and of course, therefore will require placebos. Every patient will have to take a red pill and a purple lozenge. In the Paineaze arm what is red will be Paineaze and what is purple ‘placebo to Kalmer’. In the Kalmer arm what is red will be ‘placebo to Paineaze’ and what is purple will be Kalmer.

senn-placebo

Continue reading

Categories: PhilPharma, PhilStat/Med, Statistics, Stephen Senn | 6 Comments

“Tests of Statistical Significance Made Sound”: excerpts from B. Haig

Posted on December 11, 2016 by Mayo
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I came across a paper, “Tests of Statistical Significance Made Sound,” by Brian Haig, a psychology professor at the University of Canterbury, New Zealand. It hits most of the high notes regarding statistical significance tests, their history & philosophy and, refreshingly, is in the error statistical spirit! I’m pasting excerpts from his discussion of “The Error-Statistical Perspective”starting on p.7.[1]

The Error-Statistical Perspective

An important part of scientific research involves processes of detecting, correcting, and controlling for error, and mathematical statistics is one branch of methodology that helps scientists do this. In recognition of this fact, the philosopher of statistics and science, Deborah Mayo (e.g., Mayo, 1996), in collaboration with the econometrician, Aris Spanos (e.g., Mayo & Spanos, 2010, 2011), has systematically developed, and argued in favor of, an error-statistical philosophy for understanding experimental reasoning in science. Importantly, this philosophy permits, indeed encourages, the local use of ToSS, among other methods, to manage error. Continue reading

Categories: Bayesian/frequentist, Error Statistics, fallacy of rejection, P-values, Statistics | 12 Comments

Gelman at the PSA: “Confirmationist and Falsificationist Paradigms in Statistical Practice”: Comments & Queries

Posted on December 3, 2016 by Mayo

screen-shot-2016-10-26-at-10-23-07-pmTo resume sharing some notes I scribbled down on the contributions to our Philosophy of Science Association symposium on Philosophy of Statistics (Nov. 4, 2016), I’m up to Gelman. Comments on Gigerenzer and Glymour are here and here. Gelman didn’t use slides but gave a very thoughtful, extemporaneous presentation on his conception of “falsificationist Bayesianism”, its relation to current foundational issues, as well as to error statistical testing. My comments follow his abstract.

Confirmationist and Falsificationist Paradigms in Statistical Practice

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Andrew Gelman

There is a divide in statistics between classical frequentist and Bayesian methods. Classical hypothesis testing is generally taken to follow a falsificationist, Popperian philosophy in which research hypotheses are put to the test and rejected when data do not accord with predictions. Bayesian inference is generally taken to follow a confirmationist philosophy in which data are used to update the probabilities of different hypotheses. We disagree with this conventional Bayesian-frequentist contrast: We argue that classical null hypothesis significance testing is actually used in a confirmationist sense and in fact does not do what it purports to do; and we argue that Bayesian inference cannot in general supply reasonable probabilities of models being true. The standard research paradigm in social psychology (and elsewhere) seems to be that the researcher has a favorite hypothesis A. But, rather than trying to set up hypothesis A for falsification, the researcher picks a null hypothesis B to falsify, which is then taken as evidence in favor of A. Research projects are framed as quests for confirmation of a theory, and once confirmation is achieved, there is a tendency to declare victory and not think too hard about issues of reliability and validity of measurements. Continue reading

Categories: Bayesian/frequentist, Gelman, Shalizi, Statistics | 148 Comments

3 YEARS AGO (NOVEMBER 2013): MEMORY LANE

Posted on November 28, 2016 by Mayo
3 years ago...

3 years ago…

MONTHLY MEMORY LANE: 3 years ago: November 2013. I mark in red three posts from each month that seem most apt for general background on key issues in this blog, excluding those reblogged recently[1], and in green up to 3 others I’d recommend[2].  Posts that are part of a “unit” or a group count as one. Here I’m counting 11/9, 11/13, and 11/16 as one

November 2013

  • (11/2) Oxford Gaol: Statistical Bogeymen
  • (11/4) Forthcoming paper on the strong likelihood principle
  • (11/9) Null Effects and Replication (cartoon pic)
  • (11/9) Beware of questionable front page articles warning you to beware of questionable front page articles (iii)
  • (11/13) T. Kepler: “Trouble with ‘Trouble at the Lab’?” (guest post)
  • (11/16) PhilStock: No-pain bull
  • (11/16) S. Stanley Young: More Trouble with ‘Trouble in the Lab’ (Guest post)
  • (11/18) Lucien Le Cam: “The Bayesians hold the Magic”
  • (11/20) Erich Lehmann: Statistician and Poet
  • (11/23) Probability that it is a statistical fluke [i]
  • (11/27)The probability that it be a statistical fluke” [iia]
  • (11/30) Saturday night comedy at the “Bayesian Boy” diary (rejected post*)

[1] Monthly memory lanes began at the blog’s 3-year anniversary in Sept, 2014.

[2] New Rule, July 30, 2016-very convenient.

 

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Categories: 3-year memory lane, Error Statistics, Statistics | Leave a comment

Gigerenzer at the PSA: “How Fisher, Neyman-Pearson, & Bayes Were Transformed into the Null Ritual”: Comments and Queries (ii)

Posted on November 8, 2016 by Mayo
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Gerd Gigerenzer, Andrew Gelman, Clark Glymour and I took part in a very interesting symposium on Philosophy of Statistics at the Philosophy of Science Association last Friday. I jotted down lots of notes, but I’ll limit myself to brief reflections and queries on a small portion of each presentation in turn, starting with Gigerenzer’s “Surrogate Science: How Fisher, Neyman-Pearson, & Bayes Were Transformed into the Null Ritual.” His complete slides are below my comments. I may write this in stages, this being (i).

SLIDE #19

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  1. Good scientific practice–bold theories, double-blind experiments, minimizing measurement error, replication, etc.–became reduced in the social science to a surrogate: statistical significance.

I agree that “good scientific practice” isn’t some great big mystery, and that “bold theories, double-blind experiments, minimizing measurement error, replication, etc.” are central and interconnected keys to finding things out in error prone inquiry. Do the social sciences really teach that inquiry can be reduced to cookbook statistics? Or is it simply that, in some fields, carrying out surrogate science suffices to be a “success”? Continue reading

Categories: Fisher, frequentist/Bayesian, Gigerenzer, Gigerenzer, P-values, spurious p values, Statistics | 11 Comments

3 YEARS AGO (OCTOBER 2013): MEMORY LANE

Posted on October 15, 2016 by Mayo
3 years ago...

3 years ago…

MONTHLY MEMORY LANE: 3 years ago: October 2013. I mark in red three posts from each month that seem most apt for general background on key issues in this blog, excluding those reblogged recently[1], and in green up to 3 others I’d recommend[2].  Posts that are part of a “unit” or a pair count as one.

October 2013

  • (10/3) Will the Real Junk Science Please Stand Up? (critical thinking)
     
  • (10/5) Was Janina Hosiasson pulling Harold Jeffreys’ leg?
  • (10/9) Bad statistics: crime or free speech (II)? Harkonen update: Phil Stat / Law /Stock
  • (10/12) Sir David Cox: a comment on the post, “Was Hosiasson pulling Jeffreys’ leg?”(10/5 and 10/12 are a pair)
     
  • (10/19) Blog Contents: September 2013
  • (10/19) Bayesian Confirmation Philosophy and the Tacking Paradox (iv)*
  • (10/25) Bayesian confirmation theory: example from last post…(10/19 and 10/25 are a pair)
  • (10/26) Comedy hour at the Bayesian (epistemology) retreat: highly probable vs highly probed (vs what ?)
  • (10/31) WHIPPING BOYS AND WITCH HUNTERS (interesting to see how things have changed and stayed the same over the past few years, share comments)

[1] Monthly memory lanes began at the blog’s 3-year anniversary in Sept, 2014.

[2] New Rule, July 30, 2016-very convenient.

 

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Categories: 3-year memory lane, Error Statistics, Statistics | 22 Comments

For Statistical Transparency: Reveal Multiplicity and/or Just Falsify the Test (Remark on Gelman and Colleagues)

Posted on October 7, 2016 by Mayo
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Gelman and Loken (2014) recognize that even without explicit cherry picking there is often enough leeway in the “forking paths” between data and inference so that by artful choices you may be led to one inference, even though it also could have gone another way. In good sciences, measurement procedures should interlink with well-corroborated theories and offer a triangulation of checks– often missing in the types of experiments Gelman and Loken are on about. Stating a hypothesis in advance, far from protecting from the verification biases, can be the engine that enables data to be “constructed”to reach the desired end [1].

[E]ven in settings where a single analysis has been carried out on the given data, the issue of multiple comparisons emerges because different choices about combining variables, inclusion and exclusion of cases…..and many other steps in the analysis could well have occurred with different data (Gelman and Loken 2014, p. 464).

An idea growing out of this recognition is to imagine the results of applying the same statistical procedure, but with different choices at key discretionary junctures–giving rise to a multiverse analysis, rather than a single data set (Steegen, Tuerlinckx, Gelman, and Vanpaemel 2016). One lists the different choices thought to be plausible at each stage of data processing. The multiverse displays “which constellation of choices corresponds to which statistical results” (p. 797). The result of this exercise can, at times, mimic the delineation of possibilities in multiple testing and multiple modeling strategies. Continue reading

Categories: Bayesian/frequentist, Error Statistics, Gelman, P-values, preregistration, reproducibility, Statistics | 9 Comments

A new front in the statistics wars? Peaceful negotiation in the face of so-called ‘methodological terrorism’

Posted on October 1, 2016 by Mayo

images-30I haven’t been blogging that much lately, as I’m tethered to the task of finishing revisions on a book (on the philosophy of statistical inference!) But I noticed two interesting blogposts, one by Jeff Leek, another by Andrew Gelman, and even a related petition on Twitter, reflecting a newish front in the statistics wars: When it comes to improving scientific integrity, do we need more carrots or more sticks? 

Leek’s post, from yesterday, called “Statistical Vitriol” (29 Sep 2016), calls for de-escalation of the consequences of statistical mistakes:

Over the last few months there has been a lot of vitriol around statistical ideas. First there were data parasites and then there were methodological terrorists. These epithets came from established scientists who have relatively little statistical training. There was the predictable backlash to these folks from their counterparties, typically statisticians or statistically trained folks who care about open source.
Continue reading

Categories: Anil Potti, fraud, Gelman, pseudoscience, Statistics | 15 Comments

G.A. Barnard’s 101st Birthday: The Bayesian “catch-all” factor: probability vs likelihood

Posted on September 23, 2016 by Mayo
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G. A. Barnard: 23 Sept 1915-30 July, 2002

Today is George Barnard’s 101st birthday. In honor of this, I reblog an exchange between Barnard, Savage (and others) on likelihood vs probability. The exchange is from pp 79-84 (of what I call) “The Savage Forum” (Savage, 1962).[i] Six other posts on Barnard are linked below: 2 are guest posts (Senn, Spanos); the other 4 include a play (pertaining to our first meeting), and a letter he wrote to me. 

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BARNARD:…Professor Savage, as I understand him, said earlier that a difference between likelihoods and probabilities was that probabilities would normalize because they integrate to one, whereas likelihoods will not. Now probabilities integrate to one only if all possibilities are taken into account. This requires in its application to the probability of hypotheses that we should be in a position to enumerate all possible hypotheses which might explain a given set of data. Now I think it is just not true that we ever can enumerate all possible hypotheses. … If this is so we ought to allow that in addition to the hypotheses that we really consider we should allow something that we had not thought of yet, and of course as soon as we do this we lose the normalizing factor of the probability, and from that point of view probability has no advantage over likelihood. This is my general point, that I think while I agree with a lot of the technical points, I would prefer that this is talked about in terms of likelihood rather than probability. I should like to ask what Professor Savage thinks about that, whether he thinks that the necessity to enumerate hypotheses exhaustively, is important. Continue reading

Categories: Barnard, highly probable vs highly probed, phil/history of stat, Statistics | 14 Comments

Peircean Induction and the Error-Correcting Thesis (Part I)

Posted on September 10, 2016 by Mayo
C. S. Peirce: 10 Sept, 1839-19 April, 1914

C. S. Peirce: 10 Sept, 1839-19 April, 1914

Today is C.S. Peirce’s birthday. He’s one of my all time heroes. You should read him: he’s a treasure chest on essentially any topic, and he anticipated several major ideas in statistics (e.g., randomization, confidence intervals) as well as in logic. I’ll reblog the first portion of a (2005) paper of mine. Links to Parts 2 and 3 are at the end. It’s written for a very general philosophical audience; the statistical parts are pretty informal. Happy birthday Peirce.

Peircean Induction and the Error-Correcting Thesis
Deborah G. Mayo
Transactions of the Charles S. Peirce Society: A Quarterly Journal in American Philosophy, Volume 41, Number 2, 2005, pp. 299-319

Peirce’s philosophy of inductive inference in science is based on the idea that what permits us to make progress in science, what allows our knowledge to grow, is the fact that science uses methods that are self-correcting or error-correcting:

Induction is the experimental testing of a theory. The justification of it is that, although the conclusion at any stage of the investigation may be more or less erroneous, yet the further application of the same method must correct the error. (5.145)

Continue reading

Categories: Bayesian/frequentist, C.S. Peirce, Error Statistics, Statistics | 18 Comments

All She Wrote (so far): Error Statistics Philosophy: 5 years on

Posted on September 3, 2016 by Mayo
metablog old fashion typewriter

D.G. Mayo with her  blogging typewriter

Error Statistics Philosophy: Blog Contents (5 years) [i]
By: D. G. Mayo

Dear Reader: It’s hard to believe I’ve been blogging for five years (since Sept. 3, 2011)! A big celebration is taking place at the Elbar Room this evening. If you’re in the neighborhood, stop by for some Elba Grease.

Amazingly, this old typewriter not only still works; one of the whiz kids on Elba managed to bluetooth it to go directly from my typewriter onto the blog (I never got used to computer keyboards.) I still must travel to London to get replacement ribbons for this klunker.

Please peruse the offerings below, and take advantage of some of the super contributions and discussions by guest posters and readers! I don’t know how much longer I’ll continue blogging, but at least until the publication of my book on statistical inference. After that I plan to run conferences, workshops, and ashrams on PhilStat and PhilSci, and will invite readers to take part! Keep reading and commenting. Sincerely, D. Mayo

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September 2011

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Categories: blog contents, Metablog, Statistics | 11 Comments

TragiComedy hour: P-values vs posterior probabilities vs diagnostic error rates

Posted on August 28, 2016 by Mayo

imgres-10The consequences of recent criticisms of statistical tests have breathed brand new life into some very old howlers, many of which have been discussed on this blog. What is not funny, though, is how standard notions such as frequentist error probabilities are being redefined in the process, and how we now have arguments built on equivocations. In fact, there are official guidebooks for the statistically perplexed giving inconsistent definitions to the same term (See for just 1 of many examples this post). How much more perplexed will that leave us!  Since it’s near the 5-year anniversary of this blog, let’s listen in to a new comedy hour mixing one from 3 years ago with some add-ons*.

Did you hear the one about the frequentist significance tester when he was shown the nonfrequentist nature of p-values?

Critic: I just simulated a long series of tests on a pool of null hypotheses, and I found that among tests with p-values of .05, at least 22%—and typically over 50%—of the null hypotheses are true!

Frequentist Significance Tester: Scratches head: But rejecting the null with a p-value of .05 ensures erroneous rejection no more than 5% of the time!

Raucous laughter ensues!

(Hah, hah… “So funny, I forgot to laugh! Or, I’m crying and laughing at the same time!) Continue reading

Categories: Bayesian/frequentist, Comedy, significance tests, Statistics | 9 Comments

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