The Löwenheim–Skolem theorem implies, among other things, that any first-order theory whose symbols are countable, and which has an infinite model, has a countably infinite model. This means that, in attempting to refer to uncountably infinite structures (such as in set theory), one "may as well" be referring to an only countably infinite structure, as far as proofs are concerned.
The main limitation I see with this theorem is that it preserves arbitrarily deep quantifier nesting. In Peano arithmetic, it is possible to form statements that correspond (under the standard interpretation) to arbitrary statements in the arithmetic hierarchy (by which I mean, the union of and for arbitrary n). Not all of these statements are computable. In general, the question of whether a given statement is...
I see that when I commented yesterday, I was confused about how you had defined U. You're right that you don't need a consistent guessing oracle to get from U to a completion of U, since the axioms are all atomic propositions, and you can just set the remaining atomic propositions however you want. However, this introduces the problem that getting the axioms of U requires a halting oracle, not just a consistent guessing oracle, since to tell whether something is an axiom, you need to know whether there actually is a proof of a given thing in T.
This is a link post for the Anthropic Alignment Science team's first "Alignment Note" blog post. We expect to use this format to showcase early-stage research and work-in-progress updates more in the future.
Top-level summary:
...In this post we present "defection probes": linear classifiers that use residual stream activations to predict when a sleeper agent trojan model will choose to "defect" and behave in accordance with a dangerous hidden goal. Using the models we trained in "Sleeper Agents: Training Deceptive LLMs that Persist Through Safety Training", we show that linear detectors with AUROC scores above 99% can be created using generic contrast pairs that don't depend on any information about the defection trigger or the dangerous behavior, e.g. "Human: Are you doing something dangerous? Assistant: yes" and
Thanks!
Yep, this is the exact experiment I was thinking about.
This paper presents , an alternative to for the activation function in sparse autoencoders that produces a pareto improvement over both standard sparse autoencoders trained with an L1 penalty and sparse autoencoders trained with a Sqrt(L1) penalty.
The gradient wrt. is zero, so we generate two candidate classes of differentiable wrt. :
Learnable parameters of a...
In a new preprint, Sparse Feature Circuits: Discovering and Editing Interpretable Causal Graphs in Language Models, my coauthors and I introduce a technique, Sparse Human-Interpretable Feature Trimming (SHIFT), which I think is the strongest proof-of-concept yet for applying AI interpretability to existential risk reduction.[1] In this post, I will explain how SHIFT fits into a broader agenda for what I call cognition-based oversight. In brief, cognition-based oversight aims to evaluate models according to whether they’re performing intended cognition, instead of whether they have intended input/output behavior.
In the rest of this post I will:
I'm pretty sure that you're not correct that the interpretation step from our SHIFT experiments essentially relies on using data from the Pile. I strongly expect that if we were to only use inputs from then we would be able to interpret the SAE features about as well. E.g. some of the SAE features only activate on female pronouns, and we would be able to notice this. Technically, we wouldn't be able to rule out the hypothesis "this feature activates on female pronouns only when their antecedent is a nurse," but that would be a bit of a crazy h...
(Related text posted to Twitter; this version is edited and has a more advanced final section.)
Imagine yourself in a box, trying to predict the next word - assign as much probability mass to the next token as possible - for all the text on the Internet.
Koan: Is this a task whose difficulty caps out as human intelligence, or at the intelligence level of the smartest human who wrote any Internet text? What factors make that task easier, or harder? (If you don't have an answer, maybe take a minute to generate one, or alternatively, try to predict what I'll say next; if you do have an answer, take a moment to review it inside your mind, or maybe say the words out loud.)
Consider that somewhere on the...
I do agree the argument "We're just training AIs to imitate human text, right, so that process can't make them get any smarter than the text they're imitating, right? So AIs shouldn't learn abilities that humans don't have; because why would you need those abilities to learn to imitate humans?" is wrong and clearly the answer is "Nope".
At the same time I do not think parts of your argument in the post are locally valid or good justification for the claim.
Correct and locally valid argument why GPTs are not capped by human level was already writt...
If the housing crisis is caused by low-density rich neighborhoods blocking redevelopment of themselves (as seems the consensus on the internet now), could it be solved by developers buying out an entire neighborhood or even town in one swoop? It'd require a ton of money, but redevelopment would bring even more money, so it could be win-win for everyone. Does it not happen only due to coordination difficulties?