Imagine that I write a computer program that starts by choosing a random integer W between 0 and 2. It then generates 10^(3W) random simple math problems, numbering each one and placing it in list P. It then chooses a random math problem from P and presents it to me, without telling me what the problem number is for that particular math problem.
In this case, being presented with a single math problem tells me nothing about the state of W - I expect it to do that in any case. Similarly, if I subsequently find out that I was shown P(50), that rules out W=0 and makes W=1 1,000 times more likely than W=2.
Given that W represents which world we're in, each math problem in P represents a unique person, and being presented with a math problem represents experiencing being that person or knowing that that person exists, the self indication assumption says that my model is flawed.
According to the self-indication assumption, my program needs to do an extra step to be a proper representation. After it generates a list of math problems, it needs to then choose a second random number, X, and present me with a math problem only if there's a math problem numbered X. In this case, being presented with a math problem or not does tell me something about W - I have a much higher chance of getting a math problem if W=2 and a much lower chance if W=0 - and finding out that the one math problem I was presented with was P(50) tells me much more about X than it does about W.
I don't see why this is a proper representation, or why my first model is flawed, though I suspect it relates to thinking about the issue in terms of specific people rather than any person in the relevant set, and I tend to get lost in the math of the usual discussions. Help?
That is not how I would describe SIA in terms of your setup. I would model SIA in this way:
The program starts by generating three pairwise-disjoint lists of math problems: a short list of length 10^(3*0), a medium list of length 10^(3*1), and a long list of length 10^(3*2). The program then chooses a problem P at random from the union of these three lists, and then presents the problem to you. Let W be such that P was on the list of length 10^(3*W). Now, whatever P you get, P was more likely to appear on a longer list than on a shorter list. Therefore, being presented with P makes it more likely that W was larger than that W was smaller.
In contrast, under SSA, the program, having generated the three pairwise-disjoint lists, chooses a number W at random from {0,1,2}, and then presents you with a random problem P from the list of length 10^(3*W).
In general, the distinction between SIA and SSA is this:
Under SIA, the program first chooses an individual at random from among all possible individuals. (Distinct worlds contain disjoint sets of individual.) The world containing the chosen individual is "the actual world". Note that this selection process yields a prior probability distribution for the number of individuals in the actual world, and this prior distribution favors larger values. The program then reports the experience of the chosen individual to you. You then use the fact that the program selected an individual with this experience to get a posterior probability distribution for the number of individuals in the actual world. But you are updating a prior distribution that favored larger worlds.
Under SSA, the program first chooses a world at random from among all possible worlds. The chosen world is "the actual world". Note that this selection process shows no favor to larger worlds as such. Then the program chooses an individual at random from among the individuals within the actual world. The program then reports the experience of the chosen individual to you. You then use the fact that the program selected an individual with this experience to get a posterior probability distribution for the number of individuals in the actual world. But you are updating a prior distribution that did not favor larger worlds as such.
Ahh. Okay, that makes sense.
I'm still not clear on why anyone would think that the world works as indicated by SIA, but that seems likely to be a rather less confusing problem.