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Thanks for the informed opinion. I know way less about animal vision than machine vision but the statement that eyes have a "frame rate" and "send images to the brain a fixed number of times a second" smelled really bad.

A maybe-dumb question about point (3) - I've noticed that when I get a blink/flinch response from something (usually some sand or a bug hitting my face when I'm on the bike), it feels like I blink just a split second before the thing hit me. Given that I'm unlikely to have any kind of precognition, do you think this might be related to the blink reflex being 'hard wired' and so my brain gets the "hey, a thing hit your face" signal after the "hey, your eyes just closed" signal? (Alternately, I read something once about our perception of audio being delayed by ~100ms so that it synchs up with our perception of vision, despite our visual processing being slower than audio - maybe the signal that caused the flinch gets 'buffered'?)

Just to add the distance from a fly's eyes to it's flight muscles is very short which inherently reduces reflex time.

They might not view time faster, but they view and react to events much closer to the present.

How about an analogy to CPU clock speed, bus speed, etc.? I think that's really what the camera analogy is getting at -- the rate at which the signals are getting processed and acted upon. Clock speed / bus speed would similarly determine how high of frequency you could "hear" stuff if we were talking about ears instead of eyes. I know the computer model of the brain is way off in many respects but I find it pretty useful for stuff like this.

On 3), the giant fiber is fast but not faster than other descending fibers. If anything, it is more reliable in its ability to signal.

See: https://www.nature.com/neuro/journal/v17/n7/full/nn.3741.htm...

Short abstract snippet (the "parallel circuits" are other, non-giant descending neurons that also trigger the escape behavior upon a looming stimulus):

"Intracellular recording of the descending giant fiber (GF) interneuron during head-fixed escape revealed that GF spike timing relative to parallel circuits for escape actions determined which of the two behavioral responses was elicited. The process was well described by a simple model in which the GF circuit has a higher activation threshold than the parallel circuits, but can override ongoing behavior to force a short takeoff. Our findings suggest a neural mechanism for action selection in which relative activation timing of parallel circuits creates the appropriate motor output."

If your brain and body spanned the size of the Earth, the signals into and within the brain would as a matter of physics take much longer than with a human. It seems reasonable to suppose this is also true when you compare a tiny fly with a comparatively massive human. That said, I haven't seen specific, explicit evidence to prove this seemingly logical theory.

Regarding point 3, I have no sources at the moment but have read several scientific articles in the past claiming that different organisms really do have a fundamentally faster or slower perception of continuous time, and also that drugs can temporarily influence this perception. Is there no truth to this at all?

Great! Any idea what mechanism adrenaline activates that gives the perception of time slowing down? That is something I've always wondered about having experienced it probably half a dozen times in my life so far.

Still what about non escape reflex sense of "time" ? Say like landing. Don't they perceive the world at a faster (or I should say systemically adequate for them) rate ?

Yes this was my first thought after reading the article: no apparent evidence that these animals experience the passage of time at different rates.