This account is being kept for the posterity, but it won’t see further activity past February.

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Joined 4 years ago
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Cake day: April 9th, 2021

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  • Let’s go simpler: what if your instance was allowed to copy the fed/defed lists from other instances, and use them (alongside simple Boolean logic plus if/then statements) to automatically decide who you’re going to federate/defederate with? That would enable caracoles and fedifams for admins who so desire, but also enable other organically grown relations.

    For example. Let’s say that you just joined the federation. And there are three instances that you somewhat trust:

    • Alice - it defederates only really problematic instances.
    • Bob and Charlie - both are a bit prone to defederate other instances on a whim, but when both defed the same instance it’s usually problematic.

    Then you could set up your defederation rules like this:

    • if Alice defed it, then defed it too.
    • else, if (Bob defed it) and (Charlie defed it), then defed it too.
    • else, federate with it.

    Of course, that would require distinguishing between manual and automatic fed/defed. You’d be able to use the manual fed/defed from other instances to create your automatic rules, to avoid deadlocks like “Alice is blocking it because Bob is blocking it, and Bob is blocking it because Alice is doing it”.



  • The source that I’ve linked mentions semantic embedding; so does further literature on the internet. However, the operations are still being performed with the vectors resulting from the tokens themselves, with said embedding playing a secondary role.

    This is evident for example through excerpts like

    The token embeddings map a token ID to a fixed-size vector with some semantic meaning of the tokens. These brings some interesting properties: similar tokens will have a similar embedding (in other words, calculating the cosine similarity between two embeddings will give us a good idea of how similar the tokens are).

    Emphasis mine. A similar conclusion (that the LLM is still handling the tokens, not their meaning) can be reached by analysing the hallucinations that your typical LLM bot outputs, and asking why that hallu is there.

    What I’m proposing is deeper than that. It’s to use the input tokens (i.e. morphemes) only to retrieve the sememes (units of meaning; further info here) that they’re conveying, then discard the tokens themselves, and perform the operations solely on the sememes. Then for the output you translate the sememes obtained by the transformer into morphemes=tokens again.

    I believe that this would have two big benefits:

    1. The amount of data necessary to “train” the LLM will decrease. Perhaps by orders of magnitude.
    2. A major type of hallucination will go away: self-contradiction (for example: states that A exists, then that A doesn’t exist).

    And it might be an additional layer, but the whole approach is considerably simpler than what’s being done currently - pretending that the tokens themselves have some intrinsic value, then playing whack-a-mole with situations where the token and the contextually assigned value (by the human using the LLM) differ.

    [This could even go deeper, handling a pragmatic layer beyond the tokens/morphemes and the units of meaning/sememes. It would be closer to what @njordomir@lemmy.world understood from my other comment, as it would then deal with the intent of the utterance.]


  • Not quite. I’m focusing on chatbots like Bard, ChatGPT and the likes, and their technology (LLM, or large language model).

    At the core those LLMs work like this: they pick words, split them into “tokens”, and then perform a few operations on those tokens, across multiple layers. But at the end of the day they still work with the words themselves, not with the meaning being encoded by those words.

    What I want is an LLM that assigns multiple meanings for those words, and performs the operations above on the meaning itself. In other words the LLM would actually understand you, not just chain words.


  • Complexity does not mean sophistication when it comes to AI and never has and to treat it as such is just a forceful way to make your ideas come true without putting in the real effort.

    It’s a bit off-topic, but what I really want is a language model that assigns semantic values to the tokens, and handles those values instead of directly working with the tokens themselves. That would be probably far less complex than current state-of-art LLMs, but way more sophisticated, and require far less data for “training”.