Language notes.docx

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A **phoneme** is *the smallest unit of sound that makes a meaningful
difference in a language*. The word "bit" has three phonemes, /b/, /i/,
and /t/ (in transcription, phonemes are placed between slashes), and the
word "pit" also has three: /p/, /i/, and /t/. In spoken languages,
phonemes are produced by the positions and movements of the vocal tract,
including our lips, teeth, tongue, vocal cords, and throat, whereas in
sign languages phonemes are defined by the shapes and movement of the
hands.

There are hundreds of unique phonemes that can be made by human
speakers, but most languages only use a small subset of the
possibilities. English contains about 45 phonemes, whereas other
languages have as few as 15 and others more than 60. The Hawaiian
language contains only about a dozen phonemes, including five vowels (a,
e, i, o, and u) and seven consonants (h, k, l, m, n, p, and w).

In addition to using a different set of phonemes, because the phoneme is
actually a category of sounds that are treated alike within the
language, speakers of different languages are able to hear the
difference only between some phonemes but not others. This is known as
the *categorical perception of speech sounds*. English speakers can
differentiate the /r/ phoneme from the /l/ phoneme, and thus "rake" and
"lake" are heard as different words. In Japanese, however, /r/ and /l/
are the same phoneme, and thus speakers of that language cannot tell the
difference between the word "rake" and the word "lake." Try saying the
words "cool" and "keep" out loud. Can you hear the difference between
the two /k/ sounds? To English speakers they both sound the same, but to
speakers of Arabic these represent two different phonemes (Figure 10.9,
"Speech Sounds and Adults").

Infants are born able to understand all phonemes, but they lose their
ability to do so as they get older; by 10 months of age a child's
ability to recognize phonemes becomes very similar to that of the adult
speakers of the native language. Phonemes that were initially
differentiated come to be treated as equivalent (Werker & Tees, 2002).

Whereas phonemes are the smallest units of sound in language,
a **morpheme** is *a string of one or more phonemes that makes up the
smallest units of meaning in a language*. Some morphemes, such as
one-letter words like "I" and "a," are also phonemes, but most morphemes
are made up of combinations of phonemes. Some morphemes are prefixes and
suffixes used to modify other words. For example, the syllable "re-" as
in "rewrite" or "repay" means "to do again," and the suffix "-est" as in
"happiest" or "coolest" means "to the maximum."

**Syntax** is *the set of rules of a language by which we construct
sentences*. Each language has a different syntax. The syntax of the
English language requires that each sentence have a noun and a verb,
each of which may be modified by adjectives and adverbs. Some syntaxes
make use of the order in which words appear, while others do not. In
English, "The man bites the dog" is different from "The dog bites the
man." In German, however, only the article endings before the noun
matter. "Der Hund beisst den Mann" means "The dog bites the man" but so
does "Den Mann beisst der Hund."

Words do not possess fixed meanings but change their interpretation as a
function of the context in which they are spoken. We use **contextual
information **--- *the information surrounding language*---to help us
interpret it. Examples of contextual information include the knowledge
that we have and that we know that other people have, and nonverbal
expressions such as facial expressions, postures, gestures, and tone of
voice. Misunderstandings can easily arise if people aren't attentive to
contextual information or if some of it is missing, such as it may be in
newspaper headlines or in text messages.

Nonhuman animals have a wide variety of systems of communication. Some
species communicate using scents; others use visual displays, such as
baring the teeth, puffing up the fur, or flapping the wings; and still
others use vocal sounds. Male songbirds, such as canaries and finches,
sing songs to attract mates and to protect territory, and chimpanzees
use a combination of facial expressions, sounds, and actions, such as
slapping the ground, to convey aggression (de Waal, 1989). Honeybees use
a waggle dance to direct other bees to the location of food sources (von
Frisch, 1956). The language of vervet monkeys is relatively advanced in
the sense that they use specific sounds to communicate specific
meanings. Vervets make different calls to signify that they have seen
either a leopard, a snake, or a hawk (Seyfarth & Cheney, 1997).

Despite their wide abilities to communicate, efforts to teach animals to
use language have had only limited success. One of the early efforts was
made by Catherine and Keith Hayes, who raised a chimpanzee named Viki in
their home along with their own children. But Viki learned little and
could never speak (Hayes & Hayes, 1952). Researchers speculated that
Viki's difficulties might have been in part because she could not create
the words in her vocal cords, and so subsequent attempts were made to
teach primates to speak using sign language or boards on which they can
point to symbols.

Allen and Beatrix Gardner worked for many years to teach a chimpanzee
named Washoe to sign using ASL. Washoe, who lived to be 42 years old,
could label up to 250 different objects and make simple requests and
comments, such as "please tickle" and "me sorry" (Fouts, 1997). Washoe's
adopted daughter Loulis, who was never exposed to human signers, learned
more than 70 signs simply by watching her mother sign.

The most proficient nonhuman language speaker is Kanzi, a bonobo who
lives at the Language Learning Center at Georgia State University
(Savage-Rumbaugh & Lewin, 1994). As you can see in "Video Clip: Language
Recognition in Bonobos," Kanzi has a propensity for language that is in
many ways similar to humans. He learned faster when he was younger than
when he got older, he learns by observation, and he can use symbols to
comment on social interactions, rather than simply for food treats.
Kanzi can also create elementary syntax and understand relatively
complex commands. Kanzi can make tools and can even play the video game
Pac-Man.

And yet even Kanzi does not have a true language in the same way that
humans do. Human babies learn words faster and faster as they get older,
but Kanzi does not. Each new word he learns is almost as difficult as
the one before. Kanzi usually requires many trials to learn a new sign,
whereas human babies can speak words after only one exposure. Kanzi's
language is focused primarily on food and pleasure and only rarely on
social relationships. Although he can combine words, he generates few
new phrases and cannot master syntactic rules beyond the level of about
a two-year-old human child (Greenfield & Savage-Rumbaugh, 1991).

In sum, although many animals communicate, none of them has a true
language. With some exceptions, the information that can be communicated
in nonhuman species is limited primarily to displays of liking or
disliking, and related to basic motivations of aggression and mating.
Humans also use this more primitive type of communication, in the form
of *nonverbal behaviours* such as eye contact, touch, hand signs, and
interpersonal distance, to communicate their like or dislike for others,
but they (unlike animals) also supplant this more primitive
communication with language. Although other animal brains share
similarities to ours, only the human brain is complex enough to create
language. What is perhaps most remarkable is that although language
never appears in nonhumans, language is universal in humans. All humans,
unless they have a profound brain abnormality or are completely isolated
from other humans, learn language.