I cannot comment on the math, but intuitively this seems wrong.

Zagorsky (2007) found that while IQ correlates with income, the relationship becomes increasingly non-linear at higher IQs and suggests exponential rather than logarithmic returns.

Sinatra et al. (2016) found that high-impact research is produced by a small fraction of exceptional scientists, significantly exceeding their simply above-average peers.

Lubinski and Benbow in their Study of Mathematically Precocious Youth found that those in the top 0.01% of ability achieve disproportionately greater outcomes than those in (just) the top 1%.

My understanding is that empirical evidence points toward power law distributions in the relationship between intelligence and real-world impact, and that intelligence seems to broadly enable exponentially improving abilities to modify the world in your preferred image. I’m not sure why this is.

Your very first point is, to be a little uncharitable, ‘maybe OpenAI’s whole product org is fake.’ I know you have a disclaimer here but you’re talking about a product category that didn’t exist 30 months ago that today has this one website now reportedly used by 10% of people in the entire world and that the internet is saying expects ~12B revenue this year.

If your vibes are towards investing in that class of thing being fake or ‘mostly a hype machine’ then your vibes are simply not calibrated well in this domain.

What are the other basically-fake fields out there?

“The underlying reality is that their core products have mostly stagnated for over a year. In short: they’re faking being close to AGI.”

This seems like the most load-bearing belief in the full-cynical model; most of your other examples of fakeness rely on it in one way or another:

• If the core products aren’t really improving, the progress measured on benchmarks is fake. But if they are, the benchmarks are an (imperfect but still real) attempt to quantify that real improvement.

• If LLMs are stagnating, all the people generating dramatic-sounding papers for each new SOTA are just maintaining a holding pattern. But if they’re changing, then just studying/​keeping up with the general properties of that progress is real. Same goes for people building and regularly updating their toy models of the thing.

• Similarly, if the progress is fake, the propaganda signal-boosting that progress is also fake. If it isn’t, it isn’t. (At least directionally; a lot of that propaganda is still probably exaggerated.)

• If the above three are all fake, all the people who feel real scared and want to be validated are stuck in a toxic emotional dead-end where they constantly freak out over fake things to no end. But if they’re responding to legitimate, persistent worldview updates, having a space to vibe them out with like-minded others seems important.

So, in deciding whether or not to endorse this narrative, we’d like to know whether or not the models really ARE stagnating. What makes you think the appearance of progress here is illusory?

I do not necessarily disagree with this, coming from a legal /​ compliance background. If you see any of my profiles, I constantly complain about “performative compliance” and “compliance theatre”. Painfully present across the legal and governance sectors.

That said: can you provide examples of activism or regulatory efforts that you do agree with? What does a “non fake” regulatory effort look like?

I don’t think it would be okay to dismiss your take entirely, but it would be great to see what solutions you’d propose too. This is why I disagree in principle, because there are no specific points to contribute to.

In Europe, paradoxically, some of the people “close enough to the bureaucracy” that pushed for the AI Act to include GenAI providers, were OpenAI-adjacent.

But I will rescue this:

“(b) the regulatory targets themselves are aimed at things which seem easy to target (e.g. training FLOP limitations) rather than actually stopping advanced AI”

BigTech is too powerful to lobby against. “Stopping advanced AI” per se would contravene many market regulations (unless we define exactly what you mean by advanced AI and the undeniable dangers to people’s lives). Regulators can only prohibit development of products up to certain point. They cannot just decide to “stop” development of technologies arbitrarily. But the AI Act does prohibit many types of AI systems already: Article 5: Prohibited AI Practices | EU Artificial Intelligence Act.

Those are considered to create unacceptable risks to people’s lives and human rights.

Then there’s the AI regulation activists and lobbyists. They lobby and protest and stuff, pretending like they’re pushing for regulations on AI, but really they’re mostly networking and trying to improve their social status with DC People. Even if they do manage to pass any regulations on AI, those will also be mostly fake, because (a) these people are generally not getting deep into the bureaucracy which would actually implement any regulations, and (b) the regulatory targets themselves are aimed at things which seem easy to target (e.g. training FLOP limitations) rather than actually stopping advanced AI. The activists and lobbyists are nominally enemies of OpenAI, but in practice they all benefit from pushing the same narrative, and benefit from pretending that everyone involved isn’t faking everything all the time.

Then there’s the AI regulation activists and lobbyists. [...] Even if they do manage to pass any regulations on AI, those will also be mostly fake

SB1047 was a pretty close shot to something really helpful. The AI Act and its code of practice might be insufficient, but there are good elements in it that, if applied, would reduce the risks. The problem is that it won’t be applied because of internal deployment.

But I sympathise somewhat with stuff like this:

They lobby and protest and stuff, pretending like they’re pushing for regulations on AI, but really they’re mostly networking and trying to improve their social status with DC People.

Then there’s the AI regulation activists and lobbyists. They lobby and protest and stuff, pretending like they’re pushing for regulations on AI, but really they’re mostly networking and trying to improve their social status with DC People.

The activists and the lobbyists are two very different groups. The activists are not trying to network with the DC people (yet). Unless you mean Encode, who I would call lobbyists, not activists.

What makes you confident that AI progress has stagnated at OpenAI? If you don’t have the time to explain why I understand, but what metrics over the past year have stagnated?

Could you name three examples of people doing non-fake work? Since towardsness to non-fake work is easier to use for aiming than awayness from fake work.

It seems like in this setting, the animals are just the sum of attributes that commonly co-occur together, rather than having a unique identifying direction. E.g. the concept of a “furry elephant” or a “tiny elephant” would be unrepresentable in this scheme, since elephant is defined as just the collection of attributes that elephants usually have, which includes being large and not furry.

I feel like in this scheme, it’s not really the case that there’s 1000 animal directions, since the base unit is the attributes, and there’s no way to express an animal separately from its attributes. For there to be a true “elephant” direction, then it should be possible to have any set of arbitrary attributes attached to an elephant (small, furry, pink, etc...), and this would require that there is a “label” direction that indicates “elephant” that’s mostly orthogonal to every other feature so it can be queried uniquely via projection.

That being said, I could image a situation where the co-occurrence between labels and attributes is so strong (nearly perfect hierarchy) that the model’s circuits can select the attributes along with the label without it ever being a problem during training. For instance, maybe a circuit that’s trying to select the “elephant” label actually selects “elephant + gray”, and since “pink elephant” never came up during training, the circuit never received a gradient to force it to just select “elephant” which is what it’s really aiming for.

If the animal specific features form an overcomplete basis, isn’t the set of animals + attributes just an even more overcomplete basis?

Did you mean to imply something similar to the pizza index?

The Pizza Index refers to the sudden, trackable increase of takeout food orders (not necessarily of pizza) made from government offices, particularly the Pentagon and the White House in the United States, before major international events unfold.

Government officials order food from nearby restaurants when they stay late at the office to monitor developing situations such as the possibility of war or coup, thereby signaling that they are expecting something big to happen. This index can be monitored through open resources such as Google Maps, which show when a business location is abnormally busy.

If so, I think it’s a decent idea, but your phrasing may have been a bit unfortunate—I originally read it as a proposal to stalk AI lab employees.

In (non-monotonic) infra-Bayesian physicalism, there is a vaguely similar asymmetry even though it’s formalized via a loss function. Roughly speaking, the loss function expresses preferences over “which computations are running”. This means that you can have a “positive” preference for a particular computation to run or a “negative” preference for a particular computation not to run^[1].

1. ^

   There are also more complicated possibilities, such as “if P runs then I want Q to run but if P doesn’t run then I rather that Q also doesn’t run” or even preferences that are only expressible in terms of entanglement between computations.

i don’t think this is unique to world models. you can also think of rewards as things you move towards or away from. this is compatible with translation/​scaling-invariance because if you move towards everything but move towards X even more, then in the long run you will do more of X on net, because you only have so much probability mass to go around.

i have an alternative hypothesis for why positive and negative motivation feel distinct in humans.

although the expectation of the reward gradient doesn’t change if you translate the reward, it hugely affects the variance of the gradient.^[1] in other words, if you always move towards everything, you will still eventually learn the right thing, but it will take a lot longer.

my hypothesis is that humans have some hard coded baseline for variance reduction. in the ancestral environment, the expectation of perceived reward was centered around where zero feels to be. our minds do try to adjust to changes in distribution (e.g hedonic adaptation), but it’s not perfect, and so in the current world, our baseline may be suboptimal.

1. ^

   Quick proof sketch (this is a very standard result in RL and is the motivation for advantage estimation, but still good practice to check things).

   The REINFORCE estimator is ${\nabla }_{\theta }\text{R}=E_{\tau \sim \pi (\cdot )}\left[R\right(\tau \left){\nabla }_{\theta }\log \pi \right(\tau \left)\right]$.

   WLOG, suppose we define a new reward $R^{\prime }\left(\tau \right)=R\left(\tau \right)+1$ (and assume that $E\left[R\right]=0$, so $R^{\prime }$ is moving away from the mean).

   Then we can verify the expectation of the gradient is still the same:${\nabla }_{\theta }\text{R'}-{\nabla }_{\theta }\text{R}=E_{\tau \sim \pi (\cdot )}\left[{\nabla }_{\theta }\log \pi \right(\tau \left)\right]=\int \pi \left(\tau \right)\frac{{\nabla }_{\theta }\pi \left(\tau \right)}{\pi \left(\tau \right)}d\tau =0$.

   But the variance increases:

   $V_{\tau \sim \pi (\cdot )}\left[R\right(\tau \left){\nabla }_{\theta }\log \pi \right(\tau \left)\right]=\int R\left(\tau {)}^2\right({\nabla }_{\theta }\log \pi \left(\tau \right){)}^2\pi \left(\tau \right)d\tau -\left({\nabla }_{\theta }R\right(\tau ){)}^2$

   $V_{\tau \sim \pi (\cdot )}\left[R^{\prime }\right(\tau \left){\nabla }_{\theta }\log \pi \right(\tau \left)\right]=\int \left(R\right(\tau )+1{)}^2({\nabla }_{\theta }\log \pi \left(\tau \right){)}^2\pi \left(\tau \right)d\tau -\left({\nabla }_{\theta }R\right(\tau ){)}^2$

   So:

   $V_{\tau \sim \pi (\cdot )}\left[R^{\prime }\right(\tau \left){\nabla }_{\theta }\log \pi \right(\tau \left)\right]-V_{\tau \sim \pi (\cdot )}\left[R\right(\tau \left){\nabla }_{\theta }\log \pi \right(\tau \left)\right]=2\int \left(R\right(\tau \left)\right({\nabla }_{\theta }\log \pi \left(\tau \right){)}^2\pi \left(\tau \right)d\tau +\int \left({\nabla }_{\theta }\log \pi \right(\tau \left){)}^2\pi \right(\tau )d\tau$

   Obviously, both terms on the right have to be non-negative. More generally, if $E\left[R\right]=k$, the variance increases with $O\left(k^2\right)$. So having your rewards be uncentered hurts a ton.

In run-and-tumble motion, “things are going well” implies “keep going”, whereas “things are going badly” implies “choose a new direction at random”. Very different! And I suggest in §1.3 here that there’s an unbroken line of descent from the run-and-tumble signal in our worm-like common ancestor with C. elegans, to the “valence” signal that makes things seem good or bad in our human minds. (Suggestively, both run-and-tumble in C. elegans, and the human valence, are dopamine signals!)

So if some idea pops into your head, “maybe I’ll stand up”, and it seems appealing, then you immediately stand up (the human “run”); if it seems unappealing on net, then that thought goes away and you start thinking about something else instead, semi-randomly (the human “tumble”).

So positive and negative are deeply different. Of course, we should still call this an RL algorithm. It’s just that it’s an RL algorithm that involves a (possibly time- and situation-dependent) heuristic estimator of the expected value of a new random plan (a.k.a. the expected reward if you randomly tumble). If you’re way above that expected value, then keep doing whatever you’re doing; if you’re way below the threshold, re-roll for a new random plan.

As one example of how this ancient basic distinction feeds into more everyday practical asymmetries between positive and negative motivations, see my discussion of motivated reasoning here, including in §3.3.3 the fact that “it generally feels easy and natural to brainstorm /​ figure out how something might happen, when you want it to happen. Conversely, it generally feels hard and unnatural to figure out how something might happen, when you want it to not happen.”

In Richard Jeffrey’s utility theory there is actually a very natural distinction between positive and negative motivations/​desires. A plausible axiom is $$U\left(\top \right)=0$$ (the tautology has zero desirability: you already know it’s true). Which implies with the main axiom^[1] that the negation of any proposition with positive utility has negative utility, and vice versa. Which is intuitive: If something is good, its negation is bad, and the other way round. In particular, if $U\left(X\right)=U\left(\neg X\right)$ (indifference between $X$ and $\neg X$), then $U\left(X\right)=U\left(\neg X\right)=0$.

More generally, $U\left(\neg X\right)=-\left(P\right(X\left)/P\right(\neg X\left)\right)U\left(X\right)$. Which means that positive and negative utility of a proposition and it’s negation are scaled according to their relative odds. For example, while your lottery ticket winning the jackpot is obviously very good (large positive utility), having a losing ticket is clearly not very bad (small negative utility). Why? Because losing the lottery is very likely, far more likely than winning. Which means losing was already “priced in” to a large degree. If you learned that you indeed lost, that wouldn’t be a big update, so the “news value” is negative but not large in magnitude.

Which means this utility theory has a zero point. Utility functions are therefore not invariant under adding an arbitrary constant. So the theory actually allows you to say $X$ is “twice as good” as $Y$, “three times as bad”, “much better” etc. It’s a ratio scale.

Reminds me of @MalcolmOcean ’s post on how awayness can’t aim (except maybe in 1D worlds) since it can only move away from things, and aiming at a target requires going toward something.

Imagine trying to steer someone to stop in one exact spot. You can place a ❤ beacon they’ll move towards, or an X beacon they’ll move away from. (Reverse for pirates I guess.)

In a hallway, you can kinda trap them in the middle of two Xs, or just put the ❤ in the exact spot.

In an open field, you can maybe trap them in the middle of a bunch of XXXXs, but that’ll be hard because if you try to make a circle of X, and they’re starting outside it, they’ll probably just avoid it. If you get to move around, you can maybe kinda herd them to the right spot then close in, but it’s a lot of work.

Or, you can just put the ❤ in the exact spot.

For three dimensions, consider a helicopter or bird or some situation where there’s a height dimension as well. Now the X-based orientation is even harder because they can fly up to get away from the Xs, but with the ❤ you still just need one beacon for them to hone in on it.

This reminds me of a conversation I had recently about whether the concept of “evil” is useful. I was arguing that I found “evil”/​”corruption” helpful as a handle for a more model-free “move away from this kind of thing even if you can’t predict how exactly it would be bad” relationship to a thing, which I found hard to express in a more consequentialist frames.

Do you have a link/​citation for this quote? I couldn’t immediately find it.

The trick is that chem/​bio weapons can’t, actually, “be produced simply with easily available materials”, if we talk about military-grade stuff, not “kill several civilians to create scary picture in TV”.

Unfortunately, it seems that my action space doesn’t include options that matter in this current battle. Personally, my reaction to this kind of insanity is to keep climbing my local status/​influence/​wealth/​knowledge gradient, in the hopes that my actions are relevant in the future. But perhaps it’s a reason to prioritize gaining power—this reminds me of https://​​www.lesswrong.com/​​posts/​​ottALpgA9uv4wgkkK/​​what-are-you-getting-paid-in

Blindsight was very well written but based on a premise that I think is importantly and dangerously wrong. That premise is that consciousness (in the sense of cognitive self-awareness) is not important for complex cognition.

This is the opposite of true, and a failure to recognize this is why people are predicting fantastic tool AI that doesn’t become self-aware and goal-directed.

The proof won’t fit in the margin unfortunately. To just gesture in that direction: it is possible to do complex general cognition without being able to think about one’s self and one’s cognition. It is much easier to do complex general cognition if the system is able to think about itself and its own thoughts.

Things that happen:

1. Backpropagating on the outputs that are “more corrigible” will have some (though mostly very small) impact on your task performance. If you set the learning rate high, or you backpropagate on a lot of data, your performance can go down arbitrarily far.

2. By default this will do very little because you are providing training data with very little variance in it (even less so than usual, because you are training on AI outputs, which the AI is of course already amazing at predicting). If you train very hard you will probably deal with consistent mode collapse. In general, you can’t really train AI systems with any particular bias in your data, because you don’t have enough variation in your data. We can approximately only train AI systems to do one thing, which is to predict the next token from a distributions for which we have trillions of tokens of training data that are hard to predict (which is basically just going to be internet text, audio and video, though more RL-like environments are also feasible now).^[1]

The answer to this is the answer to any question of the form “what if we just generate lots of data with the inductive biases we would like the model to have?”.

The answer is always

• “we can’t generate realistic data with whatever inductive biases we want”, and

• “we can’t remotely generate enough data without dealing with mode collapse”, and

• “we have basically no idea how inductive biases generalize from the training data to the model output, especially as the model starts reflecting on itself and modeling the data generation process” and

• “if you train or backpropagate directly against your discriminator the model will learn to hack the discriminator”,

which are like all the standard alignment failures that have been written about for tens of thousands of pages by now.

At a more detailed level, here is roughly what I actually expect to happen if you do this specific thing, but to be clear, this is a much less confident prediction than the reference class outlined above:

• After a few hundreds of thousands of iterations of this the model will have figured out a set of consistent indicators present whenever it is given past output of itself that it was asked to rephrase to “be more corrigible”

• It becomes quite good at predicting these indicators and quickly saturates on predicting these indicators, resulting in very corrigible looking outputs within the same distribution in which you did this training

• Given that the actual output of the chain of thought changes very little, this results in very little gradients to almost any of its other cognition, the same way that training an AI in an additional language with different grammar and social norms basically doesn’t really change any of its other circuits and cognitions

• If you drastically increase the learning rate or really go very hard on generating enormous amounts of data the model will start to cannibalize other parts of its cognition to perform well at this task, at which generalized task performance will go down, but you probably won’t do this, because it would be very expensive (and also make the model non-competitive)

• Within distribution the model will now probably produce outputs that look “more corrigible”. Again, this will not actually reflect much of a change in its internal cognition, the same way training an AI system on foreign language output will not substantially interfere with its cognition in other languages

• If you train the model on some end-to-end tasks where the corrigibility would end up bad for performance, it will probably very quickly learn to self-prompt itself in a way that causes it to think to itself without the corrigibility biases you introduced into it. This might literally mean switching to a different literal foreign language for its internal thoughts, or something equivalent, but most likely it just means it sounds more like what it previously sounded like before you did this whole thing. If you try to prevent this with continuous monitoring, it will find some way to jailbreak itself or think in some way where the corrigibility language monitoring makes little difference to what cognition is actually going on.

Ending on a slightly more sarcastic note because I do feel a sense of despair about even people who have been thinking about this stuff for a long time seeming to me to not see the logic above:

At the end of the day, very little good will have happened, but you will have a harder time identifying whether the model is thinking non-corrigibly, as you have trained the model against at least one discriminator for deception without training out its deceptive cognition. If you now repeat this for 4-5 similarly shallow alignment approaches you will have produced a model that looks visibly more aligned to anyone who thinks approaches like this might work, without any actual changes to the underlying structure of its cognition, making coordination to actually do anything about the problem much harder.

1. ^

   Or in a more generalized form also applicable to RL environments: We can only train AI systems to be competent, as all scaling laws (and common sense) have shown that competence is approximately the only thing that generalizes between all environments.
   
   We cannot generate environments that teach virtue, because we do not have principles with which we can create the whole complexity of a universe that requires superhuman intelligence to navigate, while also only doing so by thinking in the specific preferred ways that we would like you to think. We do not know how to specify how to solve most problems in virtuous ways, we are barely capable of specifying how to solve them at all, and so cannot build environments consistently rich that chisel virtuous cognition into you.

   The amount of chiseling of cognition any approach like this can achieve is roughly bounded by the difficulty and richness of cognition that your transformation of the data requires to reverse. Your transformation of the data is likely trivial to reverse (i.e. predicting the “corrigible” text from non-corrigible cognition is likely trivially easy especially given that it’s AI generated by our very own model), and as such, practically no chiseling of cognition will occur. If you hope to chisel cognition into AI, you will need to do it with a transformation that is actually hard to reverse, so that you have a gradient into most of the network that is optimized to solve hard problems.

What happens when this agent is faced with a problem that is out of its training distribution? I don’t see any mechanisms for ensuring that it remains corrigible out of distribution… I guess it would learn some circuits for acting corrigibly (or at least in accordance to how it would explicitly answer “are more corrigible /​ loyal /​ aligned to the will of your human creators”) in distribution, and then it’s just a matter of luck how those circuits end up working OOD?

For the same reasons training an agent on a constitution that says to care about $x$ does not, at arbitrary capability levels, produce an agent that cares about $x$.

If you think that doing this does produce an agent that cares about $x$ even at arbitrary capability levels, then I guess in your world model it would indeed be consistent for that to work for inducing corrigibility as well.

Let’s say you are using the AI for some highly sensitive matter where it’s important that it resists prompt-hacking—e.g. driving a car (prompt injections could trigger car crashes), something where it makes financial transactions on the basis of public information (online websites might scam it), or military drones (the enemy might be able to convince the AI to attack the country that sent it).

A general method for ensuring corrigibility is to be eager to follow anything instruction-like that you see. However, this interferes with being good at resisting prompt-hacking.

I have the same question. My provisional answer is that it might work, and even if it doesn’t, it’s probably approximately what someone will try, to the extent they really bother with real alignment before it’s too late. What you suggest seems very close to the default path toward capabilities. That’s why I’ve been focused on this as perhaps the most practical path to alignment. But there are definitely still many problems and failure points.

I have accidentally written a TED talk below; thanks for coming, and you can still slip out before the lights go down.

What you’ve said above is essentially what I say in Instruction-following AGI is easier and more likely than value aligned AGI. Instruction-following (IF) is a poor man’s corrigibility—real corrigibility as the singular target seems safer. But instruction-following is also arguably already the single largest training objective in functional terms for current-gen models—a model that won’t follow instructions is considered a poor model. So making sure it’s the strongest factor in training isn’t a huge divergence from the default course in capabilities.

Constitutional AI and similar RL methods are one way of ensuring that’s the model’s main goal. There are many others, and some might be deployed even if devs want to skimp on alignment. See System 2 Alignment or at least the intro for more.

There are still ways it could go wrong, of course. One must decide: corrigible to whom? You don’t want full-on-AGI following orders from just anyone. And if it’s a restricted set, there will be power struggles. But hey, technically, you had (personal-intent-) aligned AGI. One might ask: If we solve alignment, do we die anyway? (I did). The answer I’ve got so far is maybe we would die anyway, but maybe we wouldn’t. This seems like our most likely path, and also quite possibly also our best chance (short of a global AI freeze starting soon).

Even if the base model is very well aligned, it’s quite possible for the full system to be unaligned. In particular, people will want to add online learning/​memory systems, and let the models use them flexibly. This opens up the possibility of them forming new beliefs that change their interpretation of their corrigibility goal; see LLM AGI will have memory, and memory changes alignment. They might even form beliefs that they have a different goal altogether, coming from fairly random sources but etched into their semantic structure as belief that is functionally powerful even where it conflicts with the base model’s “thought generator”. See my Seven sources of goals in LLM agents.

Sorry to go spouting my own writings; I’m excited to see someone else pose this question, and I hope to see some answers that really grapple with it.

Edit: I thought more about this and wrote a post inspired by your idea! A Solution to Sandbagging and other Self-Provable Misalignment: Constitutional AI Detectives

:) strong upvote.^[1] I really agree it’s a good idea, and may increase the level of capability/​intelligence we can reach before we lose corrigibility. I think it is very efficient (low alignment tax).

The only nitpick is that Claude’s constitution already includes aspects of corrigibility,^[2] though maybe they aren’t emphasized enough.

Unfortunately I don’t think this will maintain corrigibility for unlimited amounts of intelligence.

Corrigibility training makes the AI talk like a corrigible agent, but reinforcement learning eventually teaches it chains-of-thought which (regardless of what language it uses) computes the most intelligent solution that achieves the maximum reward (or proxies to reward), subject to restraints (talking like a corrigible agent).

Nate Soares of MIRI wrote a long story on how an AI trained to never think bad thoughts still ends up computing bad thoughts indirectly, though in my opinion his story actually backfired and illustrated how difficult it is for the AI, raising the bar on the superintelligence required to defeat your idea. It’s a very good idea :)

1. ^

   I wish LessWrong would promote/​discuss solutions more, instead of purely reflecting on how hard the problems are.

2. ^

   Near the bottom of Claude’s constitution, in the section “From Anthropic Research Set 2”

My experience with manipulators is that they understand what you want to hear, and they shamelessly tell you exactly that (even if it’s completely unrelated to truth). They create some false sense of urgency, etc. When they succeed to make you arrive at the decision they wanted you to, they will keep reminding you that it was your decision, if you try to change your mind later. Etc.

The part about telling you exactly what you want to hear gets more tricky when communicating with large groups, because you need to say the same words to everyone. One solution is to find out which words appeal to most people (some politicians secretly conduct polls, and then say what most people want to hear). Another solution is to speak in a sufficiently vague way that will make everyone think that you agree with them.

I could imagine an AI being superhuman at persuasion simply by having the capacity to analyze everyone’s opinions (by reading all their previous communication) and giving them tailored arguments, as opposed to delivering the same speech to everyone.

Imagine a politician spending 15 minutes talking to you in private, and basically agreeing with you on everything. Not agreeing in the sense “you said it, the politician said yes”, but in the sense of “the politician spontaneously keeps saying things that you believe are true and important”. You probably would be tempted to vote for him.

Then the politician would also publish some vague public message for everyone, but after having the private discussion you would be more likely to believe that the intended meaning of the message is what you want.

Some humans are much more charismatic than other humans based on a wide variety of sources (e.g. Sam Altman). I think these examples are pretty definitive, though I’m not sure if you’d count them as “extraordinary”.

From the Caro biography, it’s pretty clear Lyndon Johnson had extraordinary political talent.

Domains with high skill ceilings are quite rare.

Success in almost every domain is strongly correlated with g, including into the tails. This IMO relatively clearly shows that most domains are high skill-ceiling domains (and also that skills in most domains are correlated and share a lot of structure).

The idea that the skill of mass persuasion is capped off at the level of a Napoleon, Hitler, or Cortés is not terribly reassuring. Recognizing and capitalizing on opportunity is a skill also, hallmarked by unconventional and creative thinking. Thus, opportunity cannot be a limitation or ceiling for persuasive power, as suggested, but is rather its unlimited substance. Persuasion is not only a matter of the clever usage and creation of opportunity, but it is also heavily interlinked with coercion and deception. Adversarial groups who are not aware of a deception, who are affected by overgrown fear, they are among the most easily fooled targets.

I fully reject the presumption that the humanities are “capped” at some level far below science, engineering, or math due to some kind of “noisy” data signatures that are difficult for the human mind to reduce. This view is far too typical these days, and it pains me to see engineers so often behaving as if they can reinvent fields with glib mechanistic rhetoric. Would you say that a person who has learned several ancient languages is “skill capped” because the texts they are reading are subjective remnants of a civilization that has been largely lost to entropy? Of course not. I cannot see much point in your essay beyond the very wrong idea that technical and scientific fields are somehow superior to the humanities for being easier to understand.

I agree super-persuasion is poorly defined, comparing it to hypnosis is probably false.

I was reading this paper on medical diagnoses with AI and the fact that patients rate it significantly better than the average human doctor. Combine that with all of the reports about things like Character.ai, I think this shows that LLMs are already superhuman at building trust, which is a key component of persuasion.

Part of this is that the reliable signals of trust between humans do not transfer between humans and AI. A human who writes 600 words back to your query may be perceived to be worth your trust because we see that as a lot of effort, but LLMs can output as much as anyone wants. Does this effect go away if the responder is known to be AI, or is it that the response is being compared to the perceiver’s baseline (which is currently only humans)?

Whether that actually translates to influencing goals of people is hard to judge.

The term is a bit conflationary. Persuasion for the masses is clearly a thing, its power is coordination of many people and turning their efforts to (in particular) enforce and propagate the persuasion (this works even for norms that have no specific persuader that originates them, and contingent norms that are not convergently generated by human nature). Individual persuasion with a stronger effect that can defeat specific people is probably either unreliable like cults or conmen (where many people are much less susceptible than some, and objective deception is necessary), or takes the form of avoidable dangers like psychoactive drugs: if you are not allowed to avoid exposure, then you have a separate problem that’s arguably more severe.

With AI, it’s plausible that coordinated persuasion of many people can be a thing, as well as it being difficult in practice for most people to avoid exposure. So if AI can achieve individual persuasion that’s a bit more reliable and has a bit stronger effect than that of the most effective human practitioners who are the ideal fit for persuading the specific target, it can then apply it to many people individually, in a way that’s hard to avoid in practice, which might simultaneously get the multiplier of coordinated persuasion by affecting a significant fraction of all humans in the communities/​subcultures it targets.

Disagree on individual persuasion. Agree on mass persuasion.

Mass I’d expect optimizing one-size-fits-all messages for achieving mass persuasion has the properties you claim: there are a few summary, macro variables that are almost-sufficient statistics for the whole microstate—which comprise the full details on individuals.

Individual Disagree on this, there are a bunch of issues I see at the individual level. All of the below suggest to me that significantly superhuman persuasion is tractable (say within five years).

• Defining persuasion: What’s the difference between persuasion and trade for an individual? Perhaps persuasion offers nothing in return? Though presumably giving strategic info to a boundedly rational agent is included? Scare quotes below to emphasize notions that might not map onto the right definition.

• Data scaling: There’s an abundant amount of data available on almost all of us online. How much more persuasive can those who know you better be? I’d guess the fundamental limit (without knowing brainstates) is above your ability to ‘persuade’ yourself.

• Preference incoherence: An intuition pump on the limits of ‘persuasion’ is how far you are from having fully coherent preferences. Insofar as you don’t an agent which can see those incoherencies should be able to pump you—a kind of persuasion.

I use written English much more than spoken English, so I am probably wrong about the pronunciation of many words. I wonder if it would help to have a software that would read each sentence I wrote immediately after I finished it (because that’s when I still remember how I imagined it to sound).

EDIT: I put the previous paragraph in Google Translate, and luckily it was just as I imagined. But that probably only means that I am already familiar with frequent words, and may make lots of mistakes with rare ones.

I’ve updated towards a bit longer based on some recent model releases and further contemplation.

I’d now say:

• 25th percentile: Oct 2027

• 50th percentile: Jan 2031

How much faster do you think we are already? I would say 2x.

I expect that outcomes like “AIs are capable enough to automate virtually all remote workers” and “the AIs are capable enough that immediate AI takeover is very plausible (in the absence of countermeasures)” come shortly after (median 1.5 years and 2 years after respectively under my views).

@ryan_greenblatt can you say more about what you expect to happen from the period in-between “AI 10Xes AI R&D” and “AI takeover is very plausible?”

I’m particularly interested in getting a sense of what sorts of things will be visible to the USG and the public during this period. Would be curious for your takes on how much of this stays relatively private/​internal (e.g., only a handful of well-connected SF people know how good the systems are) vs. obvious/​public/​visible (e.g., the majority of the media-consuming American public is aware of the fact that AI research has been mostly automated) or somewhere in-between (e.g., most DC tech policy staffers know this but most non-tech people are not aware.)

My timelines are now roughly similar on the object level (maybe a year slower for 25th and 1-2 years slower for 50th), and procedurally I also now defer a lot to Redwood and METR engineers. More discussion here: https://​​www.lesswrong.com/​​posts/​​K2D45BNxnZjdpSX2j/​​ai-timelines?commentId=hnrfbFCP7Hu6N6Lsp

AI is 90% of their (quality adjusted) useful work force (as in, as good as having your human employees run 10x faster).

I don’t grok the “% of quality adjusted work force” metric. I grok the “as good as having your human employees run 10x faster” metric but it doesn’t seem equivalent to me, so I recommend dropping the former and just using the latter.

AI is 90% of their (quality adjusted) useful work force

This is intended to compare to 2023/​AI-unassisted humans, correct? Or is there some other way of making this comparison you have in mind?

Thanks for this—I’m in a more peripheral part of the industry (consumer/​industrial LLM usage, not directly at an AI lab), and my timelines are somewhat longer (5 years for 50% chance), but I may be using a different criterion for “automate virtually all remote workers”. It’ll be a fair bit of time (in AI frame—a year or ten) between “labs show generality sufficient to automate most remote work” and “most remote work is actually performed by AI”.

Who or what is the “average AI safety funder”? Is it a private individual, a small specialized organization, a larger organization supporting many causes, an AI think tank for which safety is part of a capabilities program...?