Objects that have sharp edges generate higher frequency harmonics when agitated, because lower-size features resonate on higher frequencies (like shorter strings ring on higher pitch). Objects that are round resonate on low frequencies only. The "kiki" sound has more high frequency content than the "bouba" sound, and it's no mystery why the brain associates one with the other.
In nature there's few things laying around that resonate particularly well.
I thought the same but they used chicks that just hatched with zero world experience.
That's what I was thinking. But then I was wondering: if it was that obvoius, would there be such research about it?
You do need to research "obvious" things every once in a while. They have this annoying tendency of being proven wrong occasionally.
It's a hypothesis. How would you prove or disprove that it's because of that? (and I would say, a priori, it's not utterly obvious that the brain would relate spacial and temporal frequencies like this)
For each chick they do 24 trials divided into 4 blocks with retraining on the ambiguous shape and actual rewards after each block. During the actual tests they didn't give rewards. In figure 1 they show the data bucketed by trial index. It's a bit surprising it doesn't show any apparent effect vs trial number, e.g. the first trial after retraining being slightly different.<p>I have to admit I'm super skeptical there's not some stupid mistake here. Definitely thought provoking. But I wish they'd kept iteratively removing elements until the correlation stopped happening, so they could nail down causation more precisely.
I wonder if this is a result of a Fourier transform type operation that turns the serial time domain into something that can be processed in parallel?
Is this not reducible to whether a speech sound contains fricatives and stops or not? They produce spiky sounds<p>But I guess it's about why so we associate those with spiky shapes, though surely it's because they represent sharp immediate changes in frequency?<p>I'd be interested on results of shapes imagined when you take the source as musical or other non speech sounds.
> But I guess it's about why so we associate those with spiky shapes, though surely it's because they represent sharp immediate changes in frequency?<p>Sure, but it's a very abstract connection between objects being sharp in vision and frequencies changing sharply in hearing. There's no guarantee any given organism would make the connection.
In the book „the design of everyday things“ it is mentioned that „natural mappings“ exist. Moving the knob of a vertical slider to the upper end universally means „brighter“ or „louder“, not „less bright“ or „more silent“.
maybe the chicks and norman get it, but i'm currently renting an apartment in france that has a bunch of these light switches installed all upside down, with "-" at the top:<p><a href="https://www.legrand.com.gh/en/catalog/products/arteor-push-button-dimmer-universal-2-wire-2-module-white-572239a" rel="nofollow">https://www.legrand.com.gh/en/catalog/products/arteor-push-b...</a>
Which way would a vertical weight slider go?
> Moving the knob of a vertical slider to the upper end universally means „brighter“ or „louder“, not „less bright“ or „more silent“.<p>Except for the organ drawbars?
I don't think it's abstract at all. Rub something sharp (anything from a stick to a phonograph needle) on an object and you'll directly transcribe its spatial frequency spectrum into an audio frequency spectrum.
>But I guess it's about why so we associate those with spiky shapes<p>I think the why just got a lot tricker than we imagined. Because we failed to replicate this experiment on other primates, we couldn't avoid a semantic suspicion about those associations. Now we probably have to set semantics aside or let it get a lot weirder, because we can replicate across ~300My.<p>>surely it's because they represent sharp immediate changes in frequency?<p>Maybe, and I think "multi-sensory signal processing" is the best framing, but the representation could also carry harder to think about things like "harm".<p>It's also super cool because the bouba-kiki effect framing was chosen due to methodological convenience for linguists and cultural anthropologists and their experimental bounds, not neuroscientists or signal processing folks. We could potentially find other experiments quickly, since chicks are a model organism and the mechanism is clear.<p>Things could move fast here.
This is just one micro-instance of a much larger thing. Brain encodes structural similarity across modalities. Corollary: language is far from arbitrary labels for things.
No, language is still pretty close to arbitrary labels. The handful of tenuous common threads like the bouba-kiki effect don't change the overall picture that much. The simple fact that language varies as much as it does is sufficient to prove that it's only loosely bound to anything universal.
<a href="https://en.wikipedia.org/wiki/True_name" rel="nofollow">https://en.wikipedia.org/wiki/True_name</a>
>language is far from arbitrary labels for things<p>I think this is a misunderstanding of the arbitrariness of the sign. Arbitrary doesn't mean "random" or "uniformly sampled." The fact there are systematic tendencies among languages in how things are called doesn't negate the arbitrariness of the sign, they <i>could</i> have been called other things. We can also decide to refer to things by another name and we can use any arbitrary name we like! There is no limits on what names we can use (besides silly physiological constraints like having a word with 50 000 consonants). But, of course, there's much more to language than just labels!<p>For me, the interesting thing in this paper vis-à-vis language is that it shows how much innate structure in cognition must shape our language.
Preprint: <a href="https://www.biorxiv.org/content/10.1101/2024.05.17.594640v1.full.pdf" rel="nofollow">https://www.biorxiv.org/content/10.1101/2024.05.17.594640v1....</a>
I'm not entirely sold by this discovery. For example when you learn to train dogs, you learn about the 3 voices. Encouraging voice, atta boy, negative voice, more stern, and the big "NO!".<p>To some degree these words type sounding language are doing the same thing. Some sounds will irk, some will soothe, and it would affect this 'evidence' found.
I think it’s natural to think of this in terms of frequencies so the kiki shape has a higher visual frequency. As does the word have a higher audio frequencies within in than bouba so that is naturally associated with the lower frequency undulating line of that shape.
I'm very intrigued by this, but I'll be much more interested when this is replicated on non-domesticated animals...!<p>It must take some strange things to survive co-evolution with humans for several thousands years
What's the N value of this study
I don’t know, but it really should be in units of N dozen.
From the preprint linked above:<p>> We tested a total of 42 subjects, 17 of which were females.
baba is keke
All the universal translators in fiction make more sense now lol.
Believe it or not: This is pure and unadulterated advancement of civilization.
Please elaborate.
Okay Gemini