I think this is a pedagogical Version of Andrew Gelmans shrinkage Triology
The most important paper also has a blog post, The very short version is if you z score the published effects, then then you can derive a prior for the 20.000+ effects from the Cochrane database. A Cauchy distribution fits very well. The Cauchy distribution has very fat tails, so you should regress small effects heavily towards the null and regress very large effects very little.
Here is a fun figure of the effects, Medline is published stuff, so no effects between −2 and 2 as they would be ‘insignificant’, In the Cochrane collaboration they also hunted down unpublished results.
Here you see the Cochrane prior In red, you can imagine drawing a lot of random point from the red and then “adding 1 sigma of random noise”, which “smears out” the effect creating the blue inflated effects we observe.
Notice this only works if you have standardized effects, if you observe that breast feeding makes you 4 time richer with sigma=2, then you have z=2 which is a tiny effect as you need 1.96 to reach significance at the 5% level in frequentest statistics, and you should thus regress it heavily towards the null, where if you observe that breast feeding makes you 1% richer with sigma=0.01% then this is a huge effect and it should be regressed towards the null very little
I think this is a pedagogical Version of Andrew Gelmans shrinkage Triology
The most important paper also has a blog post, The very short version is if you z score the published effects, then then you can derive a prior for the 20.000+ effects from the Cochrane database. A Cauchy distribution fits very well. The Cauchy distribution has very fat tails, so you should regress small effects heavily towards the null and regress very large effects very little.
Here is a fun figure of the effects, Medline is published stuff, so no effects between −2 and 2 as they would be ‘insignificant’, In the Cochrane collaboration they also hunted down unpublished results.
Here you see the Cochrane prior In red, you can imagine drawing a lot of random point from the red and then “adding 1 sigma of random noise”, which “smears out” the effect creating the blue inflated effects we observe.
Notice this only works if you have standardized effects, if you observe that breast feeding makes you 4 time richer with sigma=2, then you have z=2 which is a tiny effect as you need 1.96 to reach significance at the 5% level in frequentest statistics, and you should thus regress it heavily towards the null, where if you observe that breast feeding makes you 1% richer with sigma=0.01% then this is a huge effect and it should be regressed towards the null very little