Hi Matthieu,
Thanks
Hi,
A few random thoughts...
I'm not mad keen on the way you're rewriting the objective of the tests into null hypothesis and alternative hypothesis. It's not what the test actually does.
It most certainly is what it does; the Fisher test (an exact test) is based on null hypothesis testing; it’s not a matter of rewriting anything at all but merely stating the basic foundation to which the test itself relates.
For instance you say, for the midpoint analysis, that the null hypothesis is "A deep stops profile is as efficient as, or more efficient than, a shallow stops profile" and the alternative "A deep stops profile is less efficient than a shallow stops profile".
Yes, that is correct.
If the hypotheses are mutually exclusive, the p-value is either 0 or 1. But it's not. In fact, what you're saying is a much (much!) stronger proposition: one of them is correct and the other one is wrong. But a Fisher test can not do that.
I think you’re a bit confused about the premises of null hypothesis testing. The p-value can assume any value between 0 and 1. In null-hypothesis testing, you try and reject the null hypothesis (which states there is no relationship between two given phenomena), and in the process, if you do reject it (by finding a p-value less than an adopted threshold), then you've effectively garnered support for the alternative (which obviously can’t be the same as the null by definition).
While the two-tailed test is required in most cases, there is a class of problems where a one-tailed test is perfectly appropriate:
Sure - and furthermore, note what I said in the article itself (I quote): "Given the context within which the study was carried out, namely the fact that the U.S. Navy would depart from continuing to use shallow-stop profiles ONLY in case of the “finding of significantly lower PDCS [probability of DCS] for the bubble model schedule [deep-stops profiles] than the gas content model schedule [shallow-stops profile]” the choice of a one-sided test is appropriate, as the authors point out. However, one has to keep this context and associated implications in mind when interpreting this study."
So I think you missed the point here.
One, when you reject an alternative hypothesis as "not statistically significant", you in effect assert that there is evidence supporting the null hypothesis at the significance level.
Again, there is some confusion here which seems to point to a misunderstanding of (a) the premises of null hypothesis testing, and (b) what this kind of testing does. We do not set out to “reject an alternative hypothesis”; that’s not at all what we do in such testing. We strive to reject the
null hypothesis, and in rejecting it we build support for the alternative; with a statistical test (such as the Fisher test) we calculate a p-value that we want to be lower than an adopted threshold we’re happy with (e.g. 0.05). All we can say is that we can reject the null hypothesis (and therefore have support for the alternative hypothesis) if the p-value < 0.05. If the p-value is >/=0.05, we do not have a statistically significant result and we cannot reject the null hypothesis. That is
all we can say. Reframing this as a process whereby we try to reject the alternative hypothesis is incorrect, and a fairly common mistake.
In medicine, the default impact of swallowing something is: nothing happens. The standard there is 0.05. In the present case, however, we don't have that, not that I know of.
0.05 is an adopted threshold (which the p-value has to be smaller than). Once you adopt that threshold (as is done here) you simply want your p-value to be smaller than it. The third sentence above is unclear.
I'm not aware of anything supporting the idea that the null hypothesis is a valid default for this experiment at any significance level.
Anything that you do with the type of testing we’re talking about here relates back to the null hypothesis, it's the very backbone.
In fact, and that's point two, we know that the null hypothesis is wrong. We know that the dive profile impacts DCS. At what significance level, I don't know, but the null hypothesis itself is flaky at best. It's used because that's what the Fisher test demands, but it's important to note that it's not, on the face of it, a reasonable explanation. To me this justifies a higher statistical significance level, and I'm happy with 8.7%.
You never know "that the null hypothesis is wrong” before you collect data. If you
did know, then there would be no need for the experiment to begin with. The whole point is to collect data and try to reject the null hypothesis.
Hope that clears up some of the confusion.
Joseph