Hi friends, I am facing a problem understanding the concept of FDR or False Discovery Rate in Multiple Hypothesis Testing. May be the question is silly, please try to bear with me. Actually, when we are talking about P-Value for a single hypothesis test, a value below 0.05 is considered as 5% result is false positive regarding that particular hypothesis. So far, no problem. But, whenever there is suppose 20,000 tests why there will be 5% of the tests is false positive? The P-value we are talking about is for a single hypothesis, why we are connecting that with 20,000 tests? Here, each of the hypothesis is a separate entity, they are independent of each other. Then 5% of 30,000 will be false positive?

No statistical test is 100% accurate, it's a probability. So let's say you test if two means are significantly different from each other. Your test tells you to reject the null hypothesis with P=0.05. But this test isn't absolute, it also has inherent error. Let's say you are wrong once in ten tests. If you only use this test once, no big deal. The trouble arises when you start using this test many times. Let's say you repeat this test for a hundred different populations. Since your test is wrong 1/10th of the time, with 100 tests you can expect to be wrong 10 times on average.

That's where FDR comes in. Methods like Benjamini-Hochberg or Bonferroni aim to control for these false positives, by adjusting your P-value to the number of tests (and/or the distribution of the P-values of all tests). This allows you to repeat a test many times without suffering from a high false positive rate.

Let's imagine we compare gene expression for 20.000 genes between 2 equal groups. The groups are equal - no genes are differentially expressed. But 1/20 of your tests will give you p-value < 0.05 (0.05 = 1/20).

You will report 1000 genes to be differentially expressed. Not cool. Because the right answer is 0.

FDR and FWER corrections help you to overcome this.