For the past year, we at the AI Futures Project have been sinking most of our time into our next big scenario. Now it’s done!
It’s called AI 2040: Plan A.
It’s called Plan A because it’s a recommendation, not a prediction. It’s what we think should happen, not what will happen, though we think it’s plausible enough to aim for.
It’s called AI 2040 because in it, they delay the creation of superintelligence to 2040. It would have happened much sooner (in 2030, to be precise) if not for decisive action on the part of the US and Chinese governments.
As with AI 2027, summaries don’t really do it justice, since the whole point was to be detailed and comprehensive and work things out step by step rather than rely on high-level abstractions like doom or utopia.
Read the scenario at ai-2040.com. You can...
As discussed in Intro to Brain-Like-AGI Safety, I’m working on the technical alignment problem for a hypothetical future “brain-like AGI”, with a particular focus on treating human innate social and moral drives as a possible jumping-off point for our technical alignment approach.
After all, if it’s possible for humans to do stuff that ultimately leads to a good future, then it’s probably also possible for sufficiently human-like AGIs to do stuff that ultimately leads to a good future. Or if it’s not possible for humans to do stuff that ultimately leads to a good future, then we’re screwed no matter what. But assuming it’s possible, the “sufficiently human-like AGIs” would certainly need to have good prosocial motivations. What code do we write that would...
Thanks!
Sorry if you already said this, but are you assuming that everything the AI outputs is reliably checkable by humans? If yes, I’m skeptical about the “strategic constraints” of §6.1. Or if no, I don’t understand how risk-aversion helps.
Let’s say Company A has its brand new risk-averse ASI in a box. The problem to be solved is: maybe some Company B somewhere on Earth will make a long-term-optimizing ruthless out-of-control ASI that then eats the world, in the near future. And my question is: How is Company A (or anyone else) supposed to solve this pro...
(Fictional) Optimist: So you expect future artificial superintelligence (ASI) “by default”, i.e. in the absence of yet-to-be-invented techniques, to be a ruthless sociopath, happy to lie, cheat, and steal, whenever doing so is selfishly beneficial, and with callous indifference to whether anyone (including its own programmers and users) lives or dies?
Me: Yup! (Alas.)
Optimist: …Despite all the evidence right in front of our eyes from humans and LLMs.
Me: Yup!
Optimist: OK, well, I’m here to tell you: that is a very specific and strange thing to expect, especially in the absence of any concrete evidence whatsoever. There’s no reason to expect it. If you think that ruthless sociopathy is the “true core nature of intelligence” or whatever, then you should really look at yourself in a mirror and...
The first one (bootstrapping) has the issue that if the serial thinking is not 100% perfect, then it will sometimes get mistakes, and then you’re SFT’ing on the mistakes, making the model more confident in those mistakes, and then the next round of serial thinking will incorporate and build on those mistakes. Repeat a billion times in a sealed box, and I think it would spiral into nonsense—it would get dumber not smarter.
Thanks, this is helpful and not an argument i've come across before!
One quick clarification: I presume you're here talking about systemat...
We are excited to announce that Resolution (fka Sequent) has a $160M grant from Coefficient Giving (cG) to put rigorous alignment research on a (closer to) even footing with the frontier labs. We will use it to accelerate progress towards higher-confidence alignment, or to find evidence and obstacles showing why alignment is hard.
The grant is structured as a $108M base plus $52M conditional on a combination of hiring success and compute needs. The base includes a small regranting budget, which we plan to use both for high-quality non-Resolution alignment research and to give back to shared community infrastructure that we depend on. Coefficient Giving will be our sole funder to start (thank you!); our goal is to raise larger-scale funds from a mixture of sources once we...
Suppose we have a capable and potentially scheming model, and before we deploy it, we want some evidence that it won’t do anything catastrophically dangerous once we deploy it. A common approach is to use black-box alignment evaluations. However, alignment evaluations are only reassuring to the extent that the model can't reliably[1] distinguish the deployment distribution from the evaluation distribution, as it is otherwise difficult to rule out the possibility of alignment faking.
There are many approaches one could use to try to make evaluations appear more realistic: you can try to create realistic environments (e.g. Petri, WebArena, OSWorld); use data from past deployments (e.g. OpenAI, SAD); and spoof tool-call responses (e.g. ToolEmu).
However, the core difference between an alignment evaluation and a...
Thank you for the flag! Yeah, I do think the posts Deployment Awareness Matters More Than Evaluation Awareness and If This Were a Test, How Much Would It Cost? are relevant here. [1]
To give me two cents on this:
I'd be very excited to see a strong taxonomy of eval/deployment signals, it might help make progress here.
Agreed. Though I would frame this more as "taxonomy of the most important underlying differences between evals and deployments + discussion of when these differences translate into a reliable signal". An attempt to gesture at some...
As various people have written about before, AIs that have long-term memory might pose additional risks (most notably, LLM AGI will have memory, and memory changes alignment by Seth Herd). Even if an AI is aligned or only occasionally scheming at the start of a deployment, the AI might become a consistent and coherent behavioral schemer via updates to its long-term memories.
In this post, I’ll spell out the version of the threat model that I’m most concerned about, including some novel arguments for its plausibility, and describe some promising strategies for mitigating this risk. While I think some plausible mitigations are reasonably cheap and could be effective at reducing the risk from coherent scheming arising via this mechanism, research here will likely be substantially more productive in the future...
if the selection of memories happens in clear rounds where memories are evaluated according to rewards, then I don't see clear structural differences between training and deployment.
Isn't another structural difference that in deployment, this round structure may be happening many times in parallel, leading to increased variance in deployed models and increased chance that one of the models is misaligned?
E.g. say we have some sort of continual learning where deployed models specialize over the timeline of weeks-months to different task distributions. I thi...
Total research transparency feels a bit too galaxy-brained for me. It makes non-robust assumptions that newly discovered techniques won't be usable to enhance already existing open-weights models to dangerous capability levels. I also think the disincentive for research is overstated as it neglects first-mover advantage.