Read Online Harnessed: How Language and Music Mimicked Nature and Transformed Ape to Man by Mark Changizi - Free Book Online
Authors: Mark Changizi
Tags: Non-Fiction
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involved—either our own motion or that of the objects involved in events—we get Doppler shifts, a phenomenon we are all familiar with, as when a car approaching you sounds higher-pitched than when it is moving away. (See also the later section of this chapter titled “Unresolved Questions” for more about the Doppler effect and its stamp upon speech. And see the following chapters on music, where the Doppler effect will be discussed in detail.)
Rings can therefore change over time, both in timbre and in pitch. That is, a single ring can often be intrinsically dynamic. What about hits and slides?
Hits are nearly instantaneous, and for this simple reason they cannot change over time, at least not in the sense of continuously varying from one kind of hit to another. Hits can, of course, happen in quick succession, such as when you drop a pen and one end hits an instant before the other. But such a pen event would be two physical interactions, not one. Unlike a single ring, which can wiggle, a single hit has no wiggle room.
How about slides? Slides can occur for a lot longer than an instant, and so they can, in principle, dynamically vary over their occurrence. Although slides can be long—for example, a single snowy hill run on a sled may be one continuous slide—they are much more commonly short (though not instantaneous) in duration, because they quickly dissipate the energy of an event, sometimes ending it. Do the sounds of slides ever, in fact, dynamically vary over time? Before answering this, let’s be clear on what we mean by the sound of a slide. A slide can cause a ring, as we have discussed, but that is not what we’re interested in at the moment. We are, instead, interested in the sound made by the physical interaction of the two sliding surfaces—the noisy friction sound itself, caused by the coarseness of the objects involved. Therefore, to produce a wiggly slide, the coarseness of the surface being slid upon would have to vary, so that one friction sound would change gradually to another friction sound. Although coarseness varies randomly on lots of materials, few objects vary in a systematic, graded fashion, and thus slides will tend to have a rather nonvarying sound.
Rings, then, can be wiggly. But not hits, and not slides. If language has culturally evolved to sound like nature, then we would expect that sonorant phonemes (language’s rings) would sometimes be dynamically varying, but not plosives (language’s hits) or fricatives (language’s slides).
Languages do, indeed, often have sonorants that vary during their utterance. Although vowels like those in “sit” and in “set” are nonvarying, some vowels do vary, like those in “skate” and “dive.” When one says “skate,” for example, notice how the vowel sound requires your mouth to vary its shape, thereby dynamically modulating its timbre (in particular, modulating something called the formant structure , where formants are the bands of frequencies emanating from a sonorant). Vowel sounds like these are called diphthongs. Furthermore, sonorant consonants like l , r , y , w , and m demand ring changes. For example, when you say “yet,” notice how during the “y” your mouth dynamically varies its shape. These sonorants incorporate timbre changes. Recall that rings in nature also can change in pitch due to the Doppler effect. Do we find something like the Doppler shift in sonorant phonemes? Yes, in fact, in the many tonal languages of the world (such as Chinese), where vowels may be distinguished from one another only by virtue of how they dynamically vary their pitch during their utterance.
Whereas sonorants are commonly wiggly, effectively making more than one ringing sound during their utterance, no language possesses phonemes having in them more than one hit sound. It is possible in principle to have a single phoneme that sounds like two hits in very quick succession—for example, the “ct” in “ectoplasm”—but
Rings can therefore change over time, both in timbre and in pitch. That is, a single ring can often be intrinsically dynamic. What about hits and slides?
Hits are nearly instantaneous, and for this simple reason they cannot change over time, at least not in the sense of continuously varying from one kind of hit to another. Hits can, of course, happen in quick succession, such as when you drop a pen and one end hits an instant before the other. But such a pen event would be two physical interactions, not one. Unlike a single ring, which can wiggle, a single hit has no wiggle room.
How about slides? Slides can occur for a lot longer than an instant, and so they can, in principle, dynamically vary over their occurrence. Although slides can be long—for example, a single snowy hill run on a sled may be one continuous slide—they are much more commonly short (though not instantaneous) in duration, because they quickly dissipate the energy of an event, sometimes ending it. Do the sounds of slides ever, in fact, dynamically vary over time? Before answering this, let’s be clear on what we mean by the sound of a slide. A slide can cause a ring, as we have discussed, but that is not what we’re interested in at the moment. We are, instead, interested in the sound made by the physical interaction of the two sliding surfaces—the noisy friction sound itself, caused by the coarseness of the objects involved. Therefore, to produce a wiggly slide, the coarseness of the surface being slid upon would have to vary, so that one friction sound would change gradually to another friction sound. Although coarseness varies randomly on lots of materials, few objects vary in a systematic, graded fashion, and thus slides will tend to have a rather nonvarying sound.
Rings, then, can be wiggly. But not hits, and not slides. If language has culturally evolved to sound like nature, then we would expect that sonorant phonemes (language’s rings) would sometimes be dynamically varying, but not plosives (language’s hits) or fricatives (language’s slides).
Languages do, indeed, often have sonorants that vary during their utterance. Although vowels like those in “sit” and in “set” are nonvarying, some vowels do vary, like those in “skate” and “dive.” When one says “skate,” for example, notice how the vowel sound requires your mouth to vary its shape, thereby dynamically modulating its timbre (in particular, modulating something called the formant structure , where formants are the bands of frequencies emanating from a sonorant). Vowel sounds like these are called diphthongs. Furthermore, sonorant consonants like l , r , y , w , and m demand ring changes. For example, when you say “yet,” notice how during the “y” your mouth dynamically varies its shape. These sonorants incorporate timbre changes. Recall that rings in nature also can change in pitch due to the Doppler effect. Do we find something like the Doppler shift in sonorant phonemes? Yes, in fact, in the many tonal languages of the world (such as Chinese), where vowels may be distinguished from one another only by virtue of how they dynamically vary their pitch during their utterance.
Whereas sonorants are commonly wiggly, effectively making more than one ringing sound during their utterance, no language possesses phonemes having in them more than one hit sound. It is possible in principle to have a single phoneme that sounds like two hits in very quick succession—for example, the “ct” in “ectoplasm”—but
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