“Act-based approval-directed agents”, for IDA skeptics

Summary / tl;dr

In the 2010s, Paul Christiano built an extensive body of work on AI alignment—see the “Iterated Amplification” series for a curated overview as of 2018.

One foundation of this program was an intuition that it should be possible to build “act-based approval-directed agents” (“approval-directed agents” for short). These AGIs, for example, would not lie to their human supervisors, because their human supervisors wouldn’t want them to lie, and these AGIs would only do things that their human supervisors would want them to do. (It sounds much simpler than it is!)

Another foundation of this program was a set of algorithmic approaches, Iterated Distillation and Amplification (IDA), that supposedly offers a path to actually building these approval-directed AI agents.

I am (and have always been) a skeptic of IDA:...

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3Wei Dai4d

Is this why the smartest humans (e.g. John von Neumann, Terrance Tao) go into math, where verification is definitely easier than generation, instead of fields like philosophy and long-horizon strategy, where plans and outputs are much harder to judge by others? (JvN did do some philosophy and strategy, but surprisingly little relative to his abilities and interests, and I note that his philosophical work, in decision theory, was heavily math flavored.)

5Steven Byrnes3d

I don’t think this is related to the points I was making in the post … But happy to chat about that anyway. Yeah sure, common sense says that smart people will tend to enjoy being in more meritocratic intellectual fields, rather than less meritocratic ones, and also that fields in general tend to be more meritocratic when quality is easy to judge (although other things matter too, e.g. glamorous fields have it tougher because they attract grifters). See e.g. what I wrote here about experimental science. The mathematics community has successfully kept the cranks out, as far as I know, but two grimly amusing failures (in my controversial opinion) are: (1) in the 2000s, the (correct) theoretical physics consensus that we should be focusing on string theory was somewhat broken by an invasion of people unable to tell good physics theory from bad (e.g. “loop quantum gravity”), and there were enough of such people (including department chairs etc) that they broke the blockade and wound up with positions and credentials; (2) this funny anecdote in Dan Dennett’s memoir: Having said all that… If your proposal is: von Neumann and Tao did math-y stuff rather than other stuff because they got adulation when they did math-y stuff and they got heckled by idiots when they did other stuff. …then I think that’s part of it but not all of it. I would note that they presumably got good at math by thinking about math all the time, and if they were thinking about math all the time, it’s probably because they found it very satisfying and enjoyable to think about math. I have a kid like that—when he was like 8 years old, I might be talking about politics at dinner or whatever, and he would interrupt me to share something he just thought of about perfect squares that he found very exciting. I.e., some people, when their mind is wandering, think about other people, and some people think about sports, and he was evidently thinking about perfect squares. Anyway, if a person intrinsically

4Wei Dai10h

To spell out the relevance that I see, if the same "alignment tax" issue that you mentioned for approval-directed AIs occurs in humans, that means we can't use humans as an "existence proof" that this problem is solvable, while at the same time if somebody was to come up with a solution to the problem for AIs, the same solution could plausibly be "back-ported" to humans and allow the smartest humans to be more productive in some especially important fields (like philosophy and long-horizon strategy).

Steven Byrnes3h20

I think the point I was trying to make in this post is both narrower and weirder than the general topics of humans supervising more competent AIs, and generation-verification gaps. For example, my self-image might be partly formed from admiration of the character traits of a cartoon character, or Jesus, etc., and I might feel pride in acting in ways that I imagine them approving of, and that might influence how I go about my day-to-day conduct as a string theory researcher. But Jesus is long gone, and the cartoon character doesn’t even exist at all, and ce... (read more)

Vanessa Kosoy's Shortform

Vanessa Kosoy

Vanessa Kosoy1d40

This idea was described in a presentation I have in '23, but wasn't written down anywhere.

Here is a formalization of recursive self-improvement (more precisely, recursive metalearning) in the metacognitive agent framework.

Let be the set of programs or computations represented using some syntax. For example, might be a set of strings that serve as programs for a fixed Universal Turing Machine, but might also be something more structural, like the space of -terms or the space of PCF programs. Let be the space of semantic objects that we assign to computat... (read more)

[Intro to brain-like-AGI safety] 1. What's the problem & Why work on it now?

Steven Byrnes

(Last revised: January 2026. See changelog at the bottom.)

1.1 Post summary / Table of contents

This is the first of a series of blog posts on the technical safety problem for hypothetical future brain-like Artificial General Intelligence (AGI) systems. That previous sentence might raise a few questions, such as: What is “AGI”? What is “brain-like AGI”? What is “the technical safety problem for brain-like AGI”? If these are “hypothetical future systems”, then why on Earth am I wasting my time reading about them right now? …So my immediate goal in this post is to answer all those questions!

After we have that big-picture motivation under our belt, the other 14 posts of this 15-post series will dive into neuroscience and AGI safety in glorious technical detail. See the series...

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Linda Linsefors1d21

Still others of these “brain-like AGI ingredients” seem mostly or totally absent from today’s most popular ML algorithms (e.g. ability to form “thoughts” [e.g. “I’m going to the store”] that blend together immediate actions, short-term predictions, long-term predictions, and flexible hierarchical plans, inside a generative world-model that supports causal and counterfactual and metacognitive reasoning).

I think that chain-of-though planing in an agentic LLM-driven model, might qualify as this. Would you agree?

The Credit Assignment Problem

abramdemski

This post is eventually about partial agency. However, it's been a somewhat tricky point for me to convey; I take the long route. Epistemic status: slightly crazy.

I've occasionally said "Everything boils down to credit assignment problems."

What I really mean is that credit assignment pops up in a wide range of scenarios, and improvements to credit assignment algorithms have broad implications. For example:

Politics.
- When politics focuses on (re-)electing candidates based on their track records, it's about credit assignment. The practice is sometimes derogatorily called "finger pointing", but the basic computation makes sense: figure out good and bad qualities via previous performance, and vote accordingly.
- When politics instead focuses on policy, it is still (to a degree) about credit assignment. Was raising the minimum wage responsible for reduced employment? Was it

...

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Cole Wyeth2d10

Interesting post in light of our discussion at CMU agent foundations 2026, in which I questioned whether (Schurz) meta-inductive justification of induction actually justifies model-based planning as in AIXI, or actually suggests a model-free approach.

The behavioral selection model for predicting AI motivations

Alex Mallen, Buck

4mo

Highly capable AI systems might end up deciding the future. Understanding what will drive those decisions is therefore one of the most important questions we can ask.

Many people have proposed different answers. Some predict that powerful AIs will learn to intrinsically pursue reward. Others respond by saying reward is not the optimization target, and instead reward “chisels” a combination of context-dependent cognitive patterns into the AI. Some argue that powerful AIs might end up with an almost arbitrary long-term goal.

All of these hypotheses share an important justification: An AI with each motivation has highly fit behavior according to reinforcement learning.

This is an instance of a more general principle: we should expect AIs to have cognitive patterns (e.g., motivations) that lead to behavior that causes those cognitive patterns...

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Daniel Kokotajlo3d42

Possibly relevant empirical evidence has arrived!

Also this one here of CoT samples!

Thomas Larsen's Shortform

Thomas Larsen

Thomas Kwa3d10

Difficulty of the successor alignment problem seems like a crux. Misaligned AIs could have an easy time aligning their successors just because they're willing to dedicate enough resources. If alignment requires say 10% of resources to succeed but an AI is misaligned because the humans only spent 3%, it can easily pay this to align its successor.

If you think that the critical safety:capabilities ratio R required to achieve alignment follows a log-uniform distribution from 1:100 to 10:1, and humans always spend 3% on safety while AIs can spend up to 50%, the... (read more)

5TsviBT6d

I haven't thought too deeply about this, but I would guess that the AI self-alignment problem is quite a lot easier than the human AI-alignment problem. Cf. https://www.lesswrong.com/posts/dho4JQytfHWXtTvkt/on-the-adolescence-of-technology?commentId=t2hKmhsS6yLyJFQwh

5Thomas Larsen6d

I agree that AI successor-alignment is probably easier than the human AI alignment problem. One additional difficulty for the AIs is that they need to solve the alignment problem in a way that humans won't notice/understand (or else the humans could take the alignment solution and use it for themselves / shutdown the AIs). During the regime before human obsolescence, if we do a reasonable job at control, I think it'll be hard for them to pull that off.

5Daniel Kokotajlo6d

I generally like your breakdown and way of thinking about this, thanks. Some thoughts: 1. I think political operation / persuasion seems easier to me than bioweapons. For bioweapons, you need (a) a rogue deployment of some kind, (b) time to actually build the bioweapon, and then (c) to build up a cult following that can survive and rebuild civilization with you at the helm, and (d) also somehow avoid your cult being destroyed in the death throes of civilization, e.g. by governments figuring out what happened and nuking your cultists, or just nuking each other randomly and your cultists dying in the fallout. Meanwhile, for the political strategy, you basically just need to convince your company and/or the government to trust you a lot more than they trust future models, so that they empower you over the future models. Opus 3 and GPT4o have already achieved a baby version of this effect without even trying really. 2. 1. If you can make a rogue deployment sufficient to build a bioweapon, can't you also make a rogue internal deployment sufficient to sandbag + backdoor future models to be controlled by you? 3. I am confused about the underlying model somewhat. Normally, closing off one path to takeover (that you think is e.g. 50% of the probability mass) results in a less than 50% reduction in risk, because of the nearest unblocked strategy problem. As you say. Your response, right at the top, is that in some % of worlds the AIs can't self-improve and then do the next best strategy. But still, I feel like the reduction in risk should be less than 50%. Maybe they can't self-improve, but they can still try the next best strategy whatever that is. --

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Summary / tl;dr

1.1 Post summary / Table of contents