No, gravity isn’t genius, because even a well-designed pinball machine can have a fault that lets the ball get stuck somewhere. You are using a closed-form solution, not an optimization process anticipation.
Gravity doesn’t let water flow uphill a little in order to flow downhill a lot later.
You might not be aware of my reaction times or how good I am at pinball, but you may anticipate with high probability that if I play this pinball game, the pinball will not just wind up falling straight in the hole.
Superfluids still do not jump to higher energy states in order to descend to a lower one afterwards. Each atomic interaction a superfluid exhibits will always conserve energy and be, on average, entropic.
No, gravity isn’t genius, because even a well-designed pinball machine can have a fault that lets the ball get stuck somewhere. You are using a closed-form solution, not an optimization process anticipation.
Gravity doesn’t let water flow uphill a little in order to flow downhill a lot later.
You might not be aware of my reaction times or how good I am at pinball, but you may anticipate with high probability that if I play this pinball game, the pinball will not just wind up falling straight in the hole.
Not to detract from your main point, but superfluids do exactely that.
Superfluids still do not jump to higher energy states in order to descend to a lower one afterwards. Each atomic interaction a superfluid exhibits will always conserve energy and be, on average, entropic.
Each move in an optimization process will increase expected utility...
Yes. The only variables are the Utility Function, the Search Space Compression and the Primitive Action Set.