Consider a self driving car. Call the human utility function $U$. Call the space of all possible worlds $W$. In the normal operation of a self driving car, the car has only makes decisions over the restricted space $W^{\prime }$ . Say $W^{\prime }=\{\text{Crash into lampost + Rest of universe},\text{Don't crash + Rest of universe}\}$ In practice $W^{\prime }$ will contain a whole bunch of things the car could do. Suppose that the programmers only know $U^{\prime }$ the restriction of $U$ to $W^{\prime }$. This is enough to make a self driving car that behaves correctly in the crash or don't crash dilemma.

However, suppose that a self driving car is faced with an off distribution situation from $W\setminus W^{\prime }$ . Three things it could do include:

1) Recognise the problem and shut down.

2) Fail to coherently optimise at all

3) Coherently optimise some extrapolation of $U^{\prime }$

The behavior we want is to optimise $U$, but the info about what $U$ is just isn't there.

Options (1) and (2) makes the system brittle, tending to fail the moment anything goes slightly differently.

Option (3) leads to reasoning like, "I know not to crash into x, y and z, so maybe I shouldn't crash into anything", In other words, the extrapolation is often quite good when slightly off distribution. However when far off distribution, you can get traffic light maximizer behavior.

In short, the paradox of robustness exists because, when you don't know what to optimize for, you can fail to optimize, or you can guess at something and optimize that.

I think that there are some abstractions that aren't predictively useful, but are still useful in deciding your actions.

Suppose I and my friend both have the goal of maximising the number of DNA strings whose MD5 hash is prime.

I call sequences with this property "ana" and those without this property "kata". Saying that "the DNA over there is ana" does tell me something about the world, there is an experiment that I can do to determine if this is true or false, namely sequencing it and taking the hash. The concept of "ana" isn't useful in a world where no agents care about it and no detectors have been built. If your utility function cares about the difference, it is a useful concept. If someone has connected an ana detector to the trigger of something important, then its a useful concept. If your a crime scene investigator, and all you know about the perpetrators DNA is that its ana, then finding out if Joe Blogs has ana DNA could be important. The concept of ana is useful. If you know the perpitrators entire genome, the concept stops being useful.

A general abstraction is consistent with several, but not all universe states. There are many different universe states in which the gas has a pressure of 37Pa, but also many where it isn't. So all abstractions are subsets of possible universe states. Usually, we use subsets that are suitable for reasoning about in some way.

Suppose you were literally omniscient, knowing every detail of the universe, but you had to give humans a 1Tb summary. Unable to include all the info you might want, you can only include a summery of the important points, you are now engaged in lossy compression.

Sensor data is also an abstraction, for instance you might have temperature and pressure sensors. Cameras record roughly how many photons hit them without tracking every one. So real world agents are translating one lossy approximation of the world into another without ever being able to express the whole thing explicitly.

How you do lossy compression depends on what you want. Music is compressed in a way that is specific to defects in human ears. Abstractions are much the same.

The r vs r' problem can be reduced if you can find a way to sample points of high uncertainty.

Imagine sitting outside the universe, and being given an exact description of everything that happened within the universe. From this perspective you can see who signed what.

You can also see whether your thoughts are happening in biology or silicon or whatever.

My point isn't "you can't tell whether or not your in a simulation so there is no difference", my point is that there is no sharp cut off point between simulation and not simulation. We have a "know it when you see it" definition with ambiguous edge cases. Decision theory can't have different rules for dealing with dogs and not dogs because some things are on the ambiguous edge of dogginess. Likewise decision theory can't have different rules for you, copies of you and simulations of you as there is no sharp cut off. If you want to propose a continuous "simulatedness" parameter, and explain where that gets added to decision theory, go ahead. (Or propose some sharp cutoff)

in fact, it could be an anti-rational agent with the opposite utility function.

These two people might look the same, the might be identical on a quantum level, but one of them is a largely rational agent, and the other is an anti-rational agent with the opposite utility function.

I think that calling something an anti-rational agent with the opposite utility function is a wierd description that doesn't cut reality at its joints. The is a simple notion of a perfect sphere. There is also a simple notion of a perfect optimizer. Real world objects aren't perfect spheres, but some are pretty close. Thus "sphere" is a useful approximation, and "sphere + error term" is a useful description. Real agents aren't perfect optimisers, (ignoring contived goals like "1 for doing whatever you were going to do anyway, 0 else") but some are pretty close, hence "utility function + biases" is a useful description. This makes the notion of an anti-rational agent with opposite utility function like an inside out sphere with its surface offset inwards by twice the radius. Its a cack handed description of a simple object in terms of a totally different simple object and a huge error term.

This is one of those circumstances where it is important to differentiate between you being in a situation and a simulation of you being in a situation.

I actually don't think that there is a general procedure to tell what is you, and what is a simulation of you. Standard argument about slowly replacing neurons with nanomachines, slowly porting it to software, slowly abstracting and proving theorems about it rather than running it directly.

It is an entirely meaningful utility function to only care about copies of your algorithm that are running on certain kinds of hardware. That makes you a "biochemical brains running this algorithm" mazimizer. The paperclip maximizer doesn't care about any copy of its algorithm. Humans worrying about whether the predictors simulation is detailed enough to really suffer is due to specific features of human morality. From the perspective of the paperclip maximizer doing decision theory, what we care about is logical correlation.