I have some questions about the math in the first couple pages, specifically the introduction of k. I'm not totally sure I follow exactly what's going on.
So, my assumption is that we're trying to model AI capacity as a function of investment, and I assume that we're modeling this as the integral of an exponential function of base k such that
=\int{k%5Ei}di=\frac{k%5Ei}{\log(k)})
with k held constant. The integral is necessary I believe to insure that the derivative of C is positive in both the k1 scenarios. This I believe matches the example of the nuclear chain reaction. I note here that C as I've defined it, is only a function of investment and tells us nothing about time or any other variable. I think it's also true that we've defined C as an exponential because we're assuming that the AI is reinvesting it's returns. This seems to conflict with the linear relationship between investment and returns mentioned in the Chalmer's quote
"The key issue is the “proportionality thesis” saying that among systems of certain class, an increase of δ in intelligence will yield an increase of δ in the intelligence of systems that these systems can design."
although perhaps those deltas are not intended to be quantitative and equal.
But even then, I'm a little uncertain that my relation is correct. It is not clear to me that the sequence of logarithms obtained in the k<1 case is a result of this function. Specifically, I thought the notion of reinvestment was the motivation for choosing an exponential/logarithmic function to start with, and so I'm not clear on why reinvestment suddenly changes the behavior to that of nested logarithms. Is the logarithmic nature of our return being double counted?
I was also confused by the statement
Over the last many decades, world economic growth has been roughly exponential—growth has neither collapsed below exponential nor exploded above, implying a metaphorical k roughly equal to 1
But from my model, which I think is the correct one, this isn't true. I feel like I understand the math from the nuclear chain reaction, but I have
so that k=1 implies not exponential growth, but linear growth. Even worse, no value of k in my model is capable of making k "explode above" the exponential. I agree with the assessment that k has been slightly on the positive side, which gave me some hope I still have the correct model, but then I got really discouraged by the fact that for money is on the order of 1.02 while
for the neutrons in the nuclear pile was 1.006. The implication from k values alone is that my bank account is somehow more explosive than a large pile of Uranium. Unfortunately this is not true, and so it seems like my model needs to account not only for C as a function of i, but C as a function of time as well.
This issue really comes into play with the prompt critical AI. One of the ways prompt critical AI is deemed capable of growing exponentially smarter is by stealing access to more hardware. Having this as an option challenges either the definition of investment or seriously challenges the notion of constant k. Even in the limit that solving AI problems is exponentially hard (k1 coupled to a short generation time?
I'm really terrible at LW formatting/writing in tiny comment boxes, so if I screwed this up to the point of being confusing let me know.
Summary: Intelligence Explosion Microeconomics (pdf) is 40,000 words taking some initial steps toward tackling the key quantitative issue in the intelligence explosion, "reinvestable returns on cognitive investments": what kind of returns can you get from an investment in cognition, can you reinvest it to make yourself even smarter, and does this process die out or blow up? This can be thought of as the compact and hopefully more coherent successor to the AI Foom Debate of a few years back.
(Sample idea you haven't heard before: The increase in hominid brain size over evolutionary time should be interpreted as evidence about increasing marginal fitness returns on brain size, presumably due to improved brain wiring algorithms; not as direct evidence about an intelligence scaling factor from brain size.)
I hope that the open problems posed therein inspire further work by economists or economically literate modelers, interested specifically in the intelligence explosion qua cognitive intelligence rather than non-cognitive 'technological acceleration'. MIRI has an intended-to-be-small-and-technical mailing list for such discussion. In case it's not clear from context, I (Yudkowsky) am the author of the paper.
Abstract:
The dedicated mailing list will be small and restricted to technical discussants.
This topic was originally intended to be a sequence in Open Problems in Friendly AI, but further work produced something compacted beyond where it could be easily broken up into subposts.
Outline of contents:
1: Introduces the basic questions and the key quantitative issue of sustained reinvestable returns on cognitive investments.
2: Discusses the basic language for talking about the intelligence explosion, and argues that we should pursue this project by looking for underlying microfoundations, not by pursuing analogies to allegedly similar historical events.
3: Goes into detail on what I see as the main arguments for a fast intelligence explosion, constituting the bulk of the paper with the following subsections:
4: A tentative methodology for formalizing theories of the intelligence explosion - a project of formalizing possible microfoundations and explicitly stating their alleged relation to historical experience, such that some possibilities can allegedly be falsified.
5: Which open sub-questions seem both high-value and possibly answerable.
6: Formally poses the Open Problem and mentions what it would take for MIRI itself to directly fund further work in this field.