This doesn’t depend on A happening chronologically before or after B etc., it’s a true mathematical identity regardless.
This doesn’t depend on these things being uncorrelated. The formula is true even in the extreme case where two or more of these things are 100% perfectly correlated. (…In which case one or more of the factors on the right are going to be 1.0.)
You’re entitled to argue that P(TAI)>P(A&B&C&⋯), and you’re entitled to argue that people are assigning conditional probabilities in a wrong and confused way for whatever reason (e.g. see discussion here), but you can’t argue with the mathematical identity, right?
Apologies, I’m not trying to dispute math identities. And thank you, the link provided helps put words to my gut concern: that this essay’s conclusion relies heavily on a multi-stage fallacy, and arriving at point probability estimates for each event independently is fraught/difficult.
It’s a mathematical identity that
P(A&B&C&D&E)=P(A)P(B|A)P(C|A,B)P(D|A,B,C)P(E|A,B,C,D)
This doesn’t depend on A happening chronologically before or after B etc., it’s a true mathematical identity regardless.
This doesn’t depend on these things being uncorrelated. The formula is true even in the extreme case where two or more of these things are 100% perfectly correlated. (…In which case one or more of the factors on the right are going to be 1.0.)
You’re entitled to argue that P(TAI)>P(A&B&C&⋯), and you’re entitled to argue that people are assigning conditional probabilities in a wrong and confused way for whatever reason (e.g. see discussion here), but you can’t argue with the mathematical identity, right?
Apologies, I’m not trying to dispute math identities. And thank you, the link provided helps put words to my gut concern: that this essay’s conclusion relies heavily on a multi-stage fallacy, and arriving at point probability estimates for each event independently is fraught/difficult.