That was a scary but also fun read, thanks for sharing and glad you’re doing OK ❤️

(That drawing of the Dunning-Kruger Effect is a popular misconception—there was a post last week on that, see also here.)

I think there’s “if you have a hammer, everything looks like a nail” stuff going on. Economists spend a lot of time thinking about labor automation, so they often treat AGI as if it will be just another form of labor automation. LLM & CS people spend a lot of time thinking about the LLMs of 2025, so they often treat AGI as if it will be just like the LLMs of 2025. Military people spend a lo of time thinking about weapons, so they often treat AGI as if it will be just another weapon. Etc.

So yeah, this post happens to be targeted at economists, but that’s not because economists are uniquely blameworthy, or anything like that.

I noticed that peeing is rewarding? What the hell?! How did enough of my (human) non-ancestors die because peeing wasn't rewarding enough? The answer is they weren't homo sapiens or hominids at all.

I would split it into two questions:

• (1) what’s the evolutionary benefit of peeing promptly?
• (2) In general, if it’s evolutionarily beneficial to do X, why does the brain implement desire-to-X in the form of both “carrots” and “sticks”, as opposed to just one or just the other? Needing to pee is unpleasant (stick) AND peeing is then pleasant (carrot). Being hungry is unpleasant (stick) AND eating is then pleasant (carrot). Etc.

I do think there’s a generic answer to (2) in terms of learning algorithms etc., but no need to get into the details here.

As for (1), you’re wasting energy by carrying around extra weight of urine. Maybe there are other factors too. (Eventually of course you risk incontinence or injury or even death.) Yes I think it’s totally possible that our hominin ancestors had extra counterfactual children by wasting 0.1% less energy or whatever. Energy is important, and every little bit helps.

There are about ~100-200 different neurotransmitters our brains use. I was surprised to find out that I could not find a single neurotransmitter that is not shared between humans and mice (let me know if you can find one, though).

Like you said, truly new neurotransmitters are rare. For example, oxytocin and vasopressin split off from a common ancestor in a gene duplication event 500Mya, and the ancestral form has homologues in octopuses and insects etc. OTOH, even if mice and humans have homologous neurotransmitters, they presumably differ by at least a few mutations; they’re not exactly the same. (Separately, their functional effects are sometimes quite different! For example, eating induces oxytocin release in rodents but vasopressin release in humans.)

Anyway, looking into recent evolutionary changes to neurotransmitters (and especially neuropeptides) is an interesting idea (thanks!). I found this paper comparing endocrine systems of humans and chimps. It claims (among other things) that GNRH2 and UCN2 are protein-coding genes in humans but inactive (“pseudogenes”) in chimps. If true, what does that imply? Beats me. It does not seem to have any straightforward interpretation that I can see. Oh well.

Thanks for the advice. I have now added at least the basic template, for the benefit of readers who don’t already have it memorized. I will leave it to the reader to imagine the curves moving around—I don’t want to add too much length and busy-ness.

Manipulating the physical world is a very different problem from invention, and current LLM-based architectures are not suited for this. … Friction, all the consequence of a lack of knowledge about the problem; friction, all the million little challenges that need to be overcome; friction, that which is smoothed over the second and third and fourth times something done. Friction, that which is inevitably associated with the physical world. Friction--that which only humans can handle. 

This OP is about “AGI”, as defined in my 3rd & 4th paragraph as follows:

By “AGI” I mean here “a bundle of chips, algorithms, electricity, and/or teleoperated robots that can autonomously do the kinds of stuff that ambitious human adults can do—founding and running new companies, R&D, learning new skills, using arbitrary teleoperated robots after very little practice, etc.”

Yes I know, this does not exist yet! (Despite hype to the contrary.) Try asking an LLM to autonomously write a business plan, found a company, then run and grow it for years as CEO. Lol! It will crash and burn! But that’s a limitation of today’s LLMs, not of “all AI forever”. AI that could nail that task, and much more beyond, is obviously possible—human brains and bodies and societies are not powered by some magical sorcery forever beyond the reach of science. I for one expect such AI in my lifetime, for better or worse. (Probably “worse”, see below.)

So…

• “The kinds of stuff that ambitious human adults can do” includes handling what you call “friction”, so “AGI” as defined above would be able to do that too.
• “The kinds of stuff that ambitious human adults can do” includes manipulating the physical world, so “AGI” as defined above would be able to do that too. (As a more concrete example, adult humans, after just a few hours’ practice, can get all sorts of things done in the physical world using even quite inexpensive makeshift teleoperated robots, therefore AGI would be able to do that too.)
• I am >99% confident that “AGI” as defined above is physically possible, and will be invented eventually.
• I am like 90% confident that it will be invented in my lifetime.
• This post is agnostic on the question of whether such AGI will or won’t have anything to do with “current LLM-based architectures”. I’m not sure why you brought that up. But since you asked, I think it won’t; I think it will be a different, yet-to-be-developed, AI paradigm.

As for the rest of your comment, I find it rather confusing, but maybe that’s downstream of what I wrote here.

Spencer Greenberg (@spencerg) & Belen Cobeta at ClearerThinking.org have a more thorough and well-researched discussion at: Study Report: Is the Dunning-Kruger Effect real? (Also, their slightly-shorter blog post summary.)

This OP would mostly correspond to what ClearerThinking calls “noisy test of skill”. But ClearerThinking also goes through various other statistical artifacts impacting Dunning-Kruger studies, plus some of their own data analysis. Here’s (part of) their upshot:

The simulations above are remarkable because they show that when researchers are careful to avoid "fake" Dunning-Kruger effects, the real patterns that emerge in Dunning-Kruger studies, can typically be reproduced with just two assumptions:

1. Closer-To-The-Average Effect: people predict their skill levels to be closer to the mean skill level than they really are. This could be rational (when people simply have limited evidence about their true skill level), or irrational (if people still do this strongly when they have lots of evidence about their skill, then they are not adjusting their predictions enough based on that evidence).
2. Better-Than-Average Effect: on average, people tend to irrationally predict they are above average at skills. While this does not happen on every skill, it is known to happen for a wide range of skills. This bias is not the same thing as the Dunning-Kruger effect, but it shows up in Dunning-Kruger plots.