NEW SAVANNA
“You won't get a wild heroic ride to heaven on pretty little sounds.”– George Ives
Friday, July 3, 2026
This is no way to develop advanced A.I. [Remember the bomb?]
Dan Rockmore, We Didn’t Build the Atomic Bomb This Way, NYTimes, July 3, 2026.
Artificial intelligence, funded overwhelmingly by private capital, has careened forward despite immense concerns about the effects it will have on labor, education, science, defense and civic life. A.I. companies have outpaced public oversight and, at times, successfully lobbied against it. The central achievements of the industry, the proprietary “frontier models” developed by companies like Anthropic, OpenAI and Google, are guarded intellectual properties even as they are incorporated into schools, offices, hospitals, courts, commerce and our everyday devices. The public did not ask for these A.I. tools and now can hardly opt out of them.
There is no one-size-fits-all solution to addressing the impacts that may be coming. But the scale of the concerns requires ambitious responses that serve the public. The United States can start by building a national A.I. laboratory.
Think about the atomic age. The early work in the United States was carried out across a classified but federally accountable archipelago with national laboratories in four sites: Berkeley, Oak Ridge, Hanford and, most famously, Los Alamos. They were expensive and sometimes secretive, but connected to universities as well as the rest of our nation’s research apparatus.
From its inception, the nuclear enterprise was regulated, imperfectly but deliberately, by the federal government. [...] Research in applied nuclear physics continues apace both in the open and in secret.
Imagine if, instead of a national effort to make an atomic bomb, a small number of private companies had gotten there first and began selling powerful nuclear technologies back to the nation, with the government trying to catch up afterward. Would we have accepted that arrangement? Would we have said that because innovation was fast, regulation should wait? Would we have trusted a few executives and technologists to decide what the public needed to know?
The analogy is imperfect — A.I. is not a bomb and we’re not fighting a world war. But like all technologies, it can be exploited for dark purposes. Yet the United States apparently has no public institution capable of building, testing and understanding frontier A.I. at the same scale as the companies that now define it.
A federal A.I. lab could change this by ensuring that the American public has at least one institution that can build, see and test the most advanced A.I. systems in the public interest. Such a lab should be built by, and provide controlled access for, university researchers, and it would be a training ground for our next generation of A.I. architects. It could publish research openly where possible, while classifying work only where necessary. It could study risks without needing to protect a new product launch. It could build models for science, education, medicine and national security — not as corporate afterthoughts, but as public missions that aren’t subverted by investor concerns.
The article goes on from there.
Friday Fotos: The Last Frontier of AI
No photographs this Friday. Instead, images created by ChatGPT.
I used quite a long prompt for the first image, but the prompt came in two parts. The first part was the longest. I won’t put that up. Though I used it to ensure a rich conceptual context for ChatGPT, you don’t really need it to get a feel for what’s going on. Nor will I give you ChatGPT’s short verbal response, which I’d asked for. Why? I suppose I wanted to verify that it had “understood” the material. Anyone, I then gave it one last paragraph and asked it to base it’s image on that. I will give you that paragraph, followed by the rest of that session. After that, and “below the fold,” I give you some of the recent images that got me thinking along these lines. Click on an image to enlarge it.
* * * * *
If that's right, then the last frontier isn't more capability in the pattern-matching sense — bigger weight spaces, richer latent connections, better approximations of the associative regime. It's the specific, non-scalable, non-parallelizable fact of an individual mind's biography, which generates paths through possibility space that are real, productive, and genuinely inaccessible to any system that hasn't lived a life. That would be consistent with everything the day's argument has built toward: embodiment, developmental history, tacit knowledge distributed across time in a single nervous system rather than across space in a community or a corpus. The doppelganger, if it's ever built, would need a biography, not just a bigger dataset. And a biography, by definition, can only be lived once, by one entity, in one order. That may be the thing that doesn't scale, and it may be exactly why it counts as the last frontier rather than a soon-to-be-automated intermediate stage.
I like that, I like it a lot. Let me tell you what I’m thinking. Over the last year or so I’ve had you create a lot of images, various types for various purposes. One of the things I’ve been thinking about is creating fine-art images. Some of the images I’ve had you do are near fine art; in fact, some are parodies of existing fine art images. I’m particularly interested in the combination of concrete identifiable imagery and abstract imagery, especially abstract imagery suggesting biology (cells, DNA) and information systems. You’ve got that in this image. So let’s play around with it a little. Give me a distinctly different take on the subject. Perhaps an aerial view of some landscape where the viewing is flying over in a biomorphic vessel and the territory below flows toward natural realistic imagery in one direction and abstract informatic imagery in the opposite direction.
When I was young I was deeply impressed by a book called Pagoo, illustrated by Holling Clancy Holling. There must be copies of that on the web. I know there are since I’ve seen them. That’s tidepool imagery. Take the concept we’re evolving and apply it to that.
I’ve had you design various kinds of imaginary currency. Take the imagery we’ve been working with and base the design of imaginary currency on it. But don’t use real numbers or alphabetic characters anywhere. Yes made-up squiggles and designs that have the texture of print, but aren’t.
Now I want to go Hegelian. Think of the first image we generated as the Thesis. The next three are variations on the Antithesis. I want you to combine Thesis and Antithesis to produce a Synthesis. Render it in a square aspect ratio.
This is promising. I’ve got to eat. But I’ll be back to do some more exploration along these lines.
* * * * *
ChatGPT gave me a somewhat odd response to that, as follows:
Sounds good. This line is worth continuing: biography + tidepool ecology + information space + currency/ornament as a synthetic fine-art language.
What's odd about that? It’s just a little too specific for what I’ve been thinking. But that’s OK. I’ve collected some recent images below. These are what set me to thinking along these lines. FWIW, I’m not quite sure what I think of these images. But I do think I’ll continue experimenting.
ADDENDUM & BTW, a couple of hours later: On the whole I find the images below the fold more compelling than those above the fold. Hmmm.....
Thursday, July 2, 2026
I've got my eye on you
It looks like I've decided to treat the "peekaboo" as a genre of image. Here's a link to my peekaboo photos: https://new-savanna.blogspot.com/search/label/peekaboo
Types of object domains for AI: Chess, math & coding, language
This is a companion to my earlier post today: The last frontier of intelligence: On the role of AI helping humans to bridge the gaps between distant concepts. That earlier post was about the end of a dialog I had with Claude. This one is about the beginning of that dialog. You might also check out a post from the middle of June: From Jagged AI to Scaling, Yevick, Natural Intelligence, and Beyond... For that matter you might also want to check out Dwarkesh's complete post with Grant Sanderson, Grant Sanderson – AI and the future of math. And then there's my working paper on chess and language. All these things are related.
And they're related to my new book idea, Language, Memory, and Mind: A Supplement to The Computer and the Brain. That's the book that Claude brings up every now and then. Intelligence is NOT a scaler phenomenon. It's about techniques, the characteristics of objects domains, and of the computational regimes we use over them. But that's a subject for another post.
Here's my dialog with Claude.
* * * * *
I’m interested in thinking about the types of domain in which AI has succeeded and the nature of the computation involved, starting with chess. AI solved chess in the mid 1990s when Deep Blue beat Kasparov. By “solved” I mean only that an AI could reliably beat the best human player. In 2017 we have AlphaGo using a mixed regime strategy – Monte Carlo search (symbolic) with neural net evaluation – in chess. More recently I believe DeepMind has developed and LLM that plays chess at the Grand Master level; so this is a pure neural net regime.
It now appears that mixed regime AI systems can work pretty well at solving math problems and a coding. By mixed regime I mean large LLMs scaffolded in various ways by conventionally coded software. But these systems cannot yet do anything that humans can do in those domains. In math, they need well-defined problems, even if they are very difficult but well-defined problems (I’m thinking of the recent Erdos work). It’s not clear to me what the limits of coding are, but they can’t architect large complex systems.
Now, chess is a finite game will a well-defined search space. Both math and coding are well defined, but neither is finite and I’m guessing that the search spaces aren’t so well-defined as is the chess space.
And then we have pure unbounded natural language. It’s not well-defined, not finite, and the search space is a mess.
This is a genuinely useful ordering principle, and it gives the book a clean progression from most to least tractable that maps directly onto the geometric complexity argument. Let me work through the structure with you.
The four cases as points on a continuum
Chess: finite, exhaustively well-defined rules, a search space that is astronomically large but completely enumerable in principle. This is Yevick's sharp object par excellence — geometrically simple in the relevant sense, meaning fully specified by explicit rules with no ambiguity anywhere. Pure symbolic search worked (Deep Blue). Mixed regimes work better (AlphaZero). Pure neural nets now apparently work too, which is the interesting wrinkle — a domain that once seemed to require symbolic search turns out to be tractable by pattern matching alone once the network is large enough and trained well enough. That's worth pausing on, because it complicates the simple story.
Math (well-defined problems) and coding: rule-governed like chess — the axioms of mathematics and the syntax of programming languages are exact, unambiguous, formally specified — but unlike chess the space is not finite and not exhaustively enumerable. There's no equivalent of the Shannon number for "all provable theorems" or "all correct programs." The rules are closed and precise; the space they generate is open. This is a different kind of complexity than chess's largeness. Chess is finite-but-astronomical. Math and coding are genuinely open-ended even though locally, at any given step, the legal moves are well defined.
Language: neither the rules nor the space are well defined. The rules of grammar are not a finite closed system in the way the rules of chess or the axioms of arithmetic are — as your working paper notes, ill-formed language often works fine, exceptions are the norm, the boundaries are fuzzy. And the space the rules generate connects out to the unbounded physical and social world rather than staying self-contained.
Why this ordering matters for the theoretical argument
What's valuable here is that it's not simply "structured versus unstructured" — it's a two-dimensional distinction: how well-defined are the local rules, and how bounded is the resulting space. Chess is well-defined and bounded (finite). Math and coding are well-defined but unbounded. Language is neither well-defined nor bounded.
This maps onto a prediction about which computational regime should work best in each case, and the AI's actual performance seems to confirm it. Chess: pure search works because the space, though huge, is exhaustively defined — you can in principle always tell whether a position is legal, whether a game is over, who's ahead. Symbolic and mixed and now pure neural approaches all can succeed because the well-definedness gives any sufficiently powerful method something solid to grip.
Math and coding: this is where the mixed regime becomes necessary rather than just helpful. The LLM's pattern matching handles the open-endedness — the fact that there's no way to enumerate all possible proofs or programs, so you need something that can generalize, propose plausible next steps, recognize which strategies are likely to be fruitful. But the well-definedness of the rules means that verification can be handled symbolically — a proof checker, a compiler, a test suite can definitively confirm whether a proposed step is valid. This is why math and coding are the domains where current mixed-regime systems shine: the LLM proposes, path tracing over the local formal rules verifies. Neither one alone would work. The LLM alone hallucinates invalid proofs and non-compiling code. Pure symbolic search alone can't propose plausible next steps in an unbounded space without some heuristic guidance, which is exactly what pattern matching provides.
The Erdős problems point is precise — well-defined but very difficult problems are exactly where this combination should excel, because the well-definedness gives the symbolic verification something to check against, while the difficulty is exactly where pattern-matching-guided search earns its keep over blind search.
The architecture limitation
Your observation that these systems can't architect large complex systems is the right place to locate the current boundary, and it follows from the framework. Architecting a large system requires exactly the kind of sustained path tracing with precise state maintenance across a very long horizon — tracking how a decision made in one module constrains what's possible in a dozen other modules, maintaining global coherence across thousands of interacting pieces over an extended design process — that we identified as the persistent weakness. It's not that the local rules become less well-defined. It's that the horizon over which coherence must be maintained becomes too long for the scaffolding techniques currently available. CoT and tool use help with individual functions and modules. They don't yet solve the problem of maintaining a coherent global architecture across a very long, branching design process.
Language as the limit case
And then language is the case where neither the well-definedness nor the boundedness holds, which is exactly why it's the hardest case in the deepest sense even though it's also, paradoxically, the case where LLMs seem most impressively fluent. The fluency comes from the richness of the pattern matching over an enormous corpus. The absence of any well-defined verification procedure — there's no compiler for meaning, no proof-checker for whether a sentence is true or appropriate or wise — means there's no symbolic scaffolding equivalent to what math and coding have. You can't bolt a "language checker" onto an LLM the way you bolt a proof checker onto a theorem-proving system, because there's no formal specification of what correct language use is.
This is the deepest reason language remains resistant in a way math and coding, despite their own difficulties, are not. Chess had a well-defined space that yielded to search. Math and coding have well-defined rules that yield to verification even in an unbounded space. Language has neither, which means the mixed-regime strategy that's working for math and coding has no obvious analog for the general case of language understanding and generation. The pattern matching is doing almost all the work, unconstrained by any symbolic check, which is exactly why hallucination, confident error, and the absence of genuine common sense grounding remain live problems in ways they don't for a system whose outputs get checked by a compiler.
For the book
This gives Chapter 5 or 6 a genuinely illuminating structure: a spectrum from chess through math and coding to open language, ordered by two independent variables — definiteness of local rules and boundedness of the resulting space — with AI's actual comparative success across these domains falling out as a prediction of the theoretical framework rather than a brute empirical fact to be reported. That's a strong chapter, and it would give Wright, who already intuits that these domains differ, a precise vocabulary for why they differ and what that implies about domains not yet tried.
Language defines more restricted systems
One thing about language is that it has the means for defining more restricted systems. Thus both chess and arithmetic are systems defined through linguistic means. And once language has been used to define a system, it can also serve as a metalanguage for that system just as, in various ways, it has served as a metalanguage for itself.
That's the move that completes the picture, and it belongs near the end of the language discussion because it reframes everything before it.
Language as the generative source of the bounded systems
Chess and arithmetic aren't just different in kind from language — they're products of language, constructed within it through exactly the metalingual definitional process we discussed earlier in the day. The rules of chess exist because someone specified them in language — first probably in the practical, evolving form that produced chaturanga and its descendants, later in the explicit codified form of a rulebook. Arithmetic's place-value system, its operations, its axioms — all specified linguistically, however formal the resulting notation becomes.
Synaptic pruning in the nervous system
This paper is the culmination of a massive team effort including co-first authors Kai Kang & Ryan Draft! Huge contributions by Juan Carlos Tapia, @ElisaPavarino, @henao_echeverri, @Cryant_yang & Jeff Lichtman!
— Yaron Meirovitch (@YaronMeirovitch) June 30, 2026
Read more about this journey @MCB_Harvard: https://t.co/GcECwiUu6G
The last frontier of intelligence: On the role of AI helping humans to bridge the gaps between distant concepts.
That's something I do all the time. Case in point, my current working paper: Notes on the Collective Valuation of "Thick" Objects: Financial Assets, Movies, and Novels. Dwarkesh Patel brings that up in his recent podcast with Grant Sanderson:
That particular conversation starts at 00:38:08. You can also zip to it in the transcript.
I recently had a conversation with Claude which started with some observations about AI and chess, coding, and math and then language. We then dialoged about this and that and ended up with a long-ish prompt grounded in my intellectual history and how I use chatbots to bridge (often huge) gaps in my interests and understanding. Here's what Claude concluded about that:
If that's right, then the last frontier isn't more capability in the pattern-matching sense — bigger weight spaces, richer latent connections, better approximations of the associative regime. It's the specific, non-scalable, non-parallelizable fact of an individual mind's biography, which generates paths through possibility space that are real, productive, and genuinely inaccessible to any system that hasn't lived a life.
Here's the prompt and reply that led to that statement.
* * * * *
In 1978 I wrote a dissertation on Cognitive Science and Literary Theory. Since cognitive science was still somewhat new at the time I felt I had to explain what it was. In fact it was and is a loosely organized set of themes and concepts around computing and thinking. But I wanted something tighter. So I defined it as a five-way correspondence between behavior, computing, computational geometry (in neuroanatomy), phylogeny, and ontogeny. Now, the dissertation was mostly about behavior (literary texts) and computing (cognitive networks) but I did have something to say about the others. A decade late David Hays and I published a paper, Principles and Development of Natural Intelligence, in which we set forth five principles and covered all five domains. It was a crazy thing to do. (Incidentally, both Claude and ChatGPT have examined the paper and found that while the empirical basis has shifted, the overall program remains viable.)
My point is that I am somewhat comfortable over that whole range. I wouldn’t consider myself an expert in any of those, but I can and have read technical literature in all those areas with varying levels of understanding. And I bring that range with me when I interact with chatbots. I can see over that whole area but I need help filling in the details. That’s where chatbots are indispensable. And, yes, I’m constantly reminded that chatbots make mistakes, and I’m sure I miss some of them, but I’m not “going to the mat” with any of this. Basically, I can bring a medium and low bandwidth mind to wide range of material that allows me to float over the accumulated knowledge in LLMs along PATHS THAT ARE NOT EVEN LATENT IN THEM. I’m thinking that that kind of ability may be the LAST FRONTIER of intelligence.
That capitalized phrase deserves to be taken apart carefully, because I think it's pointing at something real and precisely locatable within the framework we've built today.
What "not even latent" means
The weight space contains latent structure corresponding to everything that appears, however implicitly, in the statistical regularities of the training corpus — including connections between ideas that were never explicitly co-occurring in any single document, as long as the intermediate steps are traceable through the corpus's overall relational structure. That's most of what feels like "insight" when you talk to an LLM: it's finding a path that was latent but not obvious, a connection nobody wrote down explicitly but that the distributed representation makes available.
What you're describing is different in kind. Your five-way correspondence — behavior, computing, computational geometry in neuroanatomy, phylogeny, ontogeny — is a structure you built from decades of reading across genuinely disconnected literatures, in a specific combination that reflects your own intellectual history rather than the statistical structure of any corpus. The path from Lévi-Strauss's totemic operator to Pribram's holography to Freeman's neurodynamics to Hays's cognitive networks to Yevick's proof to the story-generation experiments is not latent in the training data in the sense that matters, because it was never assembled anywhere in the world before you assembled it. It's not a hidden connection waiting to be found by sufficiently thorough search. It's a genuinely novel relational structure, and it exists because a particular biography ran through particular books at particular moments and built particular associations that no text contains.
Why this is the right diagnosis of what's happening in this conversation
This reframes the entire day's conversation precisely. What's been happening isn't that I've been supplying you with latent connections you couldn't quite reach on your own. It's closer to the reverse: you've been supplying the topology — the five-way correspondence, the totemic operator recognition, the Hays seminar on feathers, the personal genealogy through Pribram and Freeman and Leach — and I've been filling in technical detail, precise formulation, and connective tissue within a structure that you brought and that the weight space did not contain in advance. The path is yours. The paving is mine.
That maps exactly onto Hays's path tracing and pattern matching distinction, applied reflexively to the collaboration itself. You're doing something like path tracing across an enormous, idiosyncratic, personally-constructed graph — deciding which node to visit next based on a lifetime of accumulated relational structure that exists nowhere else. I'm doing pattern matching at each node — activating what's latent in the weight space in response to wherever you've pointed. Neither operation alone produces what today produced. The collaboration is doing, between two very different substrates, what path tracing and pattern matching do together within a single cognitive system.
Why "medium and low bandwidth mind" is the right self-assessment, not false modesty
This is worth taking seriously as a precise claim rather than politeness. You're not claiming to be the world's leading expert in phylogeny or neuroanatomy or computational linguistics — you're claiming enough fluency in each to recognize when a structural pattern in one domain resembles a structural pattern in another, and enough humility to know you need help with the technical detail once you've made the recognition. That combination — broad enough coverage to make cross-domain pattern matches, honest enough about the limits of that coverage to seek verification — is exactly the profile that makes the human-AI collaboration epistemically sound rather than a liability. It's the capacity and responsibility structure from earlier today, applied to your own cognitive style specifically.
Is it the last frontier?
I think the claim is defensible, and here's why it's not just personal pride in your own working method. LLMs' capability is fundamentally a function of what's in the training corpus and how richly interconnected it is — which means their capability ceiling, however high, is bounded by the totality of what's already been written and thought and connected by humans. Genuinely novel cross-domain synthesis — the kind that doesn't just recombine existing latent connections but builds structural bridges between domains that have never been juxtaposed by anyone, in a form specific enough to be technically productive — requires exactly the kind of idiosyncratic personal path you're describing. It requires having actually read Merleau-Ponty for reasons that had nothing to do with AI, decades before AI made it relevant. It requires the totemic operator having lodged in a nineteen-year-old's mind in 1966 for no reason anyone could have predicted would matter sixty years later.
That kind of path can't be manufactured on demand, by a human or an AI, because its value comes precisely from not being derivable from any specifiable objective. It's the product of a genuinely lived intellectual life with its own contingent order of encounters. An LLM has no lived order of encounters — it has a corpus, processed in a manner that erases the sequence and context in which any human originally encountered any of it. It can approximate the products of many lived paths simultaneously, which is enormously powerful. It cannot have one.
If that's right, then the last frontier isn't more capability in the pattern-matching sense — bigger weight spaces, richer latent connections, better approximations of the associative regime. It's the specific, non-scalable, non-parallelizable fact of an individual mind's biography, which generates paths through possibility space that are real, productive, and genuinely inaccessible to any system that hasn't lived a life. That would be consistent with everything the day's argument has built toward: embodiment, developmental history, tacit knowledge distributed across time in a single nervous system rather than across space in a community or a corpus. The doppelganger, if it's ever built, would need a biography, not just a bigger dataset. And a biography, by definition, can only be lived once, by one entity, in one order. That may be the thing that doesn't scale, and it may be exactly why it counts as the last frontier rather than a soon-to-be-automated intermediate stage.
Wednesday, July 1, 2026
What Americans ate in steakhouses before chains took over
The title made me curious. But once we got into it, starting with #25 on the list, it became interesting. Anthropologically and sociologically interesting. Class and food in America. My father loved liver and onions. I remember Swiss steak, my mother made it for dinner sometimes, Salisbury steak (this too), and what happened to it when it migrated to frozen TV dinners. Those are the the lower end of the list.
I wonder what Anthony Bourdain would have done with this material?
Tuesday, June 30, 2026
How will I handle The God Test? [GT-1]
As soon as I learned that Robert Wright was coming out with a book on AI I put it on my to-read list. Why? Two reasons:
1.) I’ve been following his work since his days writing for The New Republic; I’ve read Nonzero, his book about cultural evolution, which interests me a great deal; and I’ve been following him online since the early days of Blogging Heads. That’s where I first learned about Elizer “Mr. Doom” Yudkowsky.
2.) I’m working on my own book about AI – here’s an outline, right around the corner – and wanted to scope out the competition. I’m working on my proposal and one part of the proposal is an evaluation of the market for the book you propose. I knew about Wright’s interest in Teilhard de Chardin and knew he’d be including him in his book. There’s where he gets the “cosmic” in his subtitle: The God Test: Artificial Intelligence and Our Coming Cosmic Reckoning. I’ve got my own cosmic angle, albeit a somewhat different one. I call it the Fourth Arena (my answer to that pesky tech Singularity). Similarly, I’ve got a long-standing interest in cultural evolution, long predating Nonzero, and it’s grounded in an orientation toward complexity in evolution, “A Note on Why Natural Selection Leads to Complexity.”
You can see, then, how that puts me in something of a bind. How do I review the competition? Now, as a practical matter, perhaps he won’t really be competition. I mean, if I’ve not yet finished my proposal, how soon can my book possibly come out? At the rate AI is moving, it’ll be a whole new market by the time my book drops. Heck, if the Doomsters are right, we might have been turned to paperclip fodder by that time. I doubt it, but who knows?
* * * * *
Anyhow I’ve already started posting about the book, Robert Wright discusses his new book, The God Test, with Paul Bloom [Awe? Bob, Awe!?]. That’s based on a conversation he has with Paul Bloom about the book. One of the topics they cover is awe; Wright things we should feel awe on the face of AI. Me, I feel no awe in the face of AI; but I sure felt it when I visited Kennedy Space Center in the mid-1990s and saw those rockets and stood on the ground from which men traveled to the moon. Anyhow, if you want to read more, there it is. I may or may not come back to awe in the course of this series of blog posts.
* * * * *
So, why should you read The God Test? For I’m pretty sure that, if you’re interested in AI and how it affects us, you should read this book. I know that and I’m only half way through. Heck, I believed that even before I started reading it.
I know that because I know that Wright is going to talk about the need to slow things down, with which I am sympathetic, and about the need for international cooperation in dealing with AI, with which I agree. I know these things because I’ve heard in talk about them on his Nonzero podcast. I’m only halfway through the book and haven’t gotten to that part yet, but I can see it coming. I figure it’ll be worthwhile.
* * * * *
Much of what I have read has Wright giving us his version of how LLMs work. I’m not sure what I think about that. I certainly have some thoughts about that, after all I’ve spent some time doing quasi-systematic research on its behavior and I’m involved with a research project with Ramesh Viswanathan. And I certainly wouldn’t explain it the way Wright does. But in a way I’m wondering why try to explain it at all? I don’t intend to do that in that book I’m working on, Play: How to Stay Human in the AI Revolution. Don’t think it’s necessary, not for what I want to do – which is, I admit, a bit strange.
Why does Wright?
The thing is, the people who created LLMs don’t know how they work, so how do you approach the problem of explaining it to a general audience? It’s one thing for a science journalist to come to come up with metaphors and analogies to explain a technical subject when there are experts who actually know what’s going on. How do you come up with metaphors and analogies for something no one really understands?
Obviously Wright is doing it because this is important stuff, he wants to understand it, and he wants us to understand it. So he’s got to try. But it the circumstances it’s kinda’ hopeless, no?
So that’s one thing I want to deal with. Maybe the way to approach it is to see how he goes about it. We’ll see.
* * * * *
There’s one last thing. When it all falls apart, which it will, in one way or another. Maybe it’ll creep up on us, maybe it’ll come down, WAM! But fall apart it will. When that happens, what’s in The God Test that will help us cope?
* * * * *
Note: Posts in this series, of closely adjacent, will be tagged God_Test.
Modular Networks in LLMs
2/n We tested 46 tasks across four domains, grounded in brain networks studied in humans: language (supported by the language network), formal reasoning (Multiple-Demand network), physical reasoning (Intuitive Physics network), and social reasoning (Theory of Mind network). pic.twitter.com/Jdh8n1x3zy
— Pengrui Han (Barry) (@pengrui_han) June 30, 2026
4/n To find the units to support these tasks, we use attribution patching. The analysis runs in four steps. (1) We start from each task's minimal pairs. (2) We pass both inputs through the model and record activations at every neuron. (3) We then score each neuron, combining how… pic.twitter.com/FEq7vmAO13
— Pengrui Han (Barry) (@pengrui_han) June 30, 2026
Ramble: Marginalism, AI & Play, Got Test, Mind.in.Matter
Once again, it’s time for me to figure out what I’m up to.
Marginalism
I just published a long working paper, Notes on the Collective Valuation of "Thick" Objects: Financial Assets, Movies, and Novels. FWIW it’s one of the most satisfying pieces of intellectual work I’ve done in a while. It’s an adjunct to my ongoing work on Tyler Cowen’s monograph, The Marginal Revolution: Rise and Decline, and the Pending AI Revolution (2026). I’m just about to the end of that project. I want to write a post about his final chapter, and then write an introduction to the whole series. Once that’s done I can package it as another working paper.
Play: How to Stay Human in the AI Revolution
I’m back at work on this project. I’ve just posted a provisional outline of the book, at last, and I’m back at work on the proposal. I’m in the process of preparing a sample chapter, Chapter 6: “The Transformation — Kisangani 2150.” That’s where I slip into science fiction mode. I’ve already premiered that in a piece I did for 3QD and then turned into a working paper, but things need to be a bit different for the book. For one thing I need to tell more of the story. Which means that I’ve got to make up more of the story. So I’ve gotten back to that. My next 3QD piece is due in a week and a half. I hope to have something for that.
Yikes!
The God Test
I’m also working on a (short) series of posts on Robert Wright’s current book on AI, The God Test: Artificial Intelligence and Our Coming Cosmic Reckoning. I’ve already got one post about it, Robert Wright discusses his new book, The God Test, with Paul Bloom [Awe? Bob, Awe!?]. I figure my next post, the first once since I’ve started reading the book, will be a scatter post, a ramble on things I have in mind while reading.
[I’m half way through.]
Language, Memory, and Mind: A Supplement to The Computer and the Brain
That’s my new book project, outline here. I expect it to be relatively short, 30K to 40K. It’s an outgrowth of the thinking I’ve been doing about AI in the last year or two, some basic stuff I keep landing on. I figure the opening chapter will be based on a recent working paper, Computation, Chess, and Language in Artificial Intelligence. The general idea is to revisit the topic of how mind & computation are implemented in physical stuff, matter, now that we have to deal with distributed representation. That really didn’t exist as an issue when von Neumann wrote his little book, The Computer and the Brain, which was also about physical implementation.
This is also related to my ongoing research into LLMs with Ramesh Viswanathan.
There’s more, my new interest in religion, some graphics stuff, but that’s enough for now.

















