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0 pointsFlowNote7y ago0 comments

And you haven't addressed the implied global scope your hypothetical neural watchdog requires.

Find a global watchdog behaving in the manner you describe within any neural system for any animal at any period in the history of Earth's biosphere.

Find any "neural system resetting" anywhere, in fact.

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eesmith7y ago· 2 in thread

Shrug That wasn't the point. You said that if computers act like X then why don't humans act like X. I pointed out some cases where humans acted a bit like X.

You then asked why those cases weren't also Y. I pointed out that computers aren't always also Y, so why did you think that humans with X must also be Y?

I am not implying a global watchdog, for the simple reason that distributed computing systems can have local watchdogs which reset a node when the node is not active, even without global intervention.

The mechanisms can be different - animals swim while submarines don't, but both move underwater. My point was that I disagreed with your intuition and conclusion, and since I can find one counter-example to show that X doesn't imply Y, you can't conclude that X must imply Y. Nor can you conclude my counter-example is the only possible mechanism.

You still haven't described the basis for your intuition.

FlowNoteOP7y ago

Distributed systems also deadlock in ways that local watchdogs can't account for. You still imply the global watchdog of the brain of the systems designer to navigate those problems.

All of your examples require a human homunculus to steer a system away from deadlocking.

The brain doesn't have an architectural homunculus to do that for it, and yet, it does not deadlock in any way resembling the deadlocks we see in computer science.

My question is how did the brain do this without a system architect? How can natural selection have a bias that prevents deadlocking in neural compositions?

eesmith7y ago

While you haven't expressed the source of your intuition, based on your answers, you see the architecture of human-designed systems, which are engineered based on economic considerations, as being predictive of what natural systems are like.

This is not, generally speaking, true.

Even when built on standard computing architecture, we see that designs influenced by evolutionary design can result in "bizarre, mysterious, and unconventional" designs. I'm quoting from Thompson and Layzell's "Analysis of Unconventional Evolved Electronics" (1999). In that paper, note that the evolve system had a different response to temperature change than the "brittle failure" of normal digital circuits. System crashes like what you describe are "brittle".

Evolution, by human design senses, is incredibly wasteful. We are not going to build computers or distributed computing systems that way, hence any intuition based on those design principles are likely not applicable.

You asked "How can natural selection have a bias that prevents deadlocking in neural compositions?"

The "how" is easy - organisms with hard crashing deadlocks don't reproduce.

You want to know what that mechanism is, which is a different question.

If you really want to understand this, you'll have to talk to biologists who focus on this sort of topic, not a "hacking news" sites.

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