The 1905 thought experiment actually cuts both ways. Did humans "invent" the airplane? We watched birds fly for thousands of years — that's training data. The Wright brothers didn't conjure flight from pure reasoning, they synthesized patterns from nature, prior failed attempts, and physics they'd absorbed. Show me any human invention and I'll show you the training data behind it.
Take the wheel. Even that wasn't invented from nothing — rolling logs, round stones, the shape of the sun. The "invention" was recognizing a pattern already present in the physical world and abstracting it. Still training data, just physical and sensory rather than textual.
And that's actually the most honest critique of current LLMs — not that they're architecturally incapable, but that they're missing a data modality. Humans have embodied training data. You don't just read about gravity, you've felt it your whole life. You don't just know fire is hot, you've been near one. That physical grounding gives human cognition a richness that pure text can't fully capture — yet.
Einstein is the same story. He stood on Faraday, Maxwell, Lorentz, and Riemann. General Relativity was an extraordinary synthesis — not a creation from void. If that's the bar for "real" intelligence, most humans don't clear it either.
The uncomfortable truth is that human cognition and LLMs aren't categorically different. Everything you've ever "thought" comes from what you've seen, heard, and experienced. That's training data. The brain is a pattern-recognition and synthesis machine, and the attention mechanism in transformers is arguably our best computational model of how associative reasoning actually works.
So the question isn't whether LLMs can invent from nothing — nothing does that, not even us.
Are there still gaps? Sure. Data quality, training methods, physical grounding — these are real problems. But they're engineering problems, not fundamental walls. And we're already moving in that direction — robots learning from physical interaction, multimodal models connecting vision and language, reinforcement learning from real-world feedback.
The brain didn't get smart because it has some magic ingredient. It got smart because it had millions of years of rich, embodied, high-stakes training data. We're just earlier in that journey with AI. The foundation is already there — AGI isn't a question of if anymore, it's a question of execution.
The whole point is that LLMs, especially the attention mechanism in transformers, have already paved the road to AGI. The main gap is the training data and its quality. Humans have generations of distilled knowledge — books, language, culture passed down over centuries. And on top of that we have the physical world — we watched birds fly, saw apples drop, touched hot things. Maybe we should train the base model with physical world data first, and then fine tune with the distilled knowledge.
Human life includes a lot of adversarial training (lying relatives) and training in temporal logics, which would seem to be a somewhat different domain than purely linguistic computations (e.g. staying up late, feeling bad; working hard at a task for months, getting better at it; feeling physical skills, even editing Go with emacs, move from the conscious layer into the cerebrellar layer). I think attention is a poor mans "OODA" loop; cognitive science is learning that a primary function of the brain is predicting what will be going on with the body in the immediate future, and prepping for it; that's not a thing that LLMs are architecturally positioned to do. Maybe swarms of agents (although in my mind that's more of a way to deal with LLM poor performance with large context of instructions (as opposed to large context of data) than a way to have contending systems fighting to make a decision for the overall entity), but they still lack both the real-time computational aspect and the continuously tricky problem of other people telling partially correct information.
There's plenty of training data, for a human. The LLM architecture is not as efficient as the brain; perhaps we can overcome that with enough twitter posts from PhDs, and enough YouTubes of people answering "why" to their four year olds and college lectures, but that's kind of an experimental question.
Starting a network out in a contrained body and have it learn how to control that, with a social context of parents and siblings would be an interesting experiment, especially if you could give it an inherent temporality and a good similar-content-addressable persistent memory. Perhaps a bit terrifying experiment, but I guess the protocols for this would be air-gapped, not internet connected with a credit card.
256 is plenty, I only had 256GB on my last work machine and was able to maintain 4 different checkouts of our entire (large) codebase and still tons of space for caches.
I can live off 256GB on a notebook (I run Linux), but 4GB of RAM would be ridiculous and I still see notebooks from various makers being offered with 4GB.
> We left product development teams without anyone focused on production. We undid everything that made DevOps work in the first place.
Very good point, that's the same I have observed for the past couple of years when working on a devops team. Product team engineers nowadays feels like spoiled kids, they had no current how server runs, and asked for things unreasonable. I still remembered someone came to my desk and asked for me to increase the mem request to 10s of GB, he claimed that's the best solution he could think of is to load everything in mem.. and very often people don't even know what status code means 500, 502, 503, 504...
An interface with many methods is already a bad design. limiting it to a handful methods is way easier to maintain. it's fine to return an object has implement many interfaces, but you really don't need to use them all on the input side.
Oh, this brought back a lot of good memory in Yahoo. This thing was originally called YTS, it has a very flexible plugin system, the caching functionality was pretty good and easy to use at the time.
Take the wheel. Even that wasn't invented from nothing — rolling logs, round stones, the shape of the sun. The "invention" was recognizing a pattern already present in the physical world and abstracting it. Still training data, just physical and sensory rather than textual.
And that's actually the most honest critique of current LLMs — not that they're architecturally incapable, but that they're missing a data modality. Humans have embodied training data. You don't just read about gravity, you've felt it your whole life. You don't just know fire is hot, you've been near one. That physical grounding gives human cognition a richness that pure text can't fully capture — yet.
Einstein is the same story. He stood on Faraday, Maxwell, Lorentz, and Riemann. General Relativity was an extraordinary synthesis — not a creation from void. If that's the bar for "real" intelligence, most humans don't clear it either. The uncomfortable truth is that human cognition and LLMs aren't categorically different. Everything you've ever "thought" comes from what you've seen, heard, and experienced. That's training data. The brain is a pattern-recognition and synthesis machine, and the attention mechanism in transformers is arguably our best computational model of how associative reasoning actually works.
So the question isn't whether LLMs can invent from nothing — nothing does that, not even us.
Are there still gaps? Sure. Data quality, training methods, physical grounding — these are real problems. But they're engineering problems, not fundamental walls. And we're already moving in that direction — robots learning from physical interaction, multimodal models connecting vision and language, reinforcement learning from real-world feedback. The brain didn't get smart because it has some magic ingredient. It got smart because it had millions of years of rich, embodied, high-stakes training data. We're just earlier in that journey with AI. The foundation is already there — AGI isn't a question of if anymore, it's a question of execution.