In linguistics, a numeral is a word class (part of speech) of number words, specifically of counting words such as English 'two', 'eleven', and 'seventy-seven'.
In mathematics and writing, the word "numeral" is used for a different concept: the symbols used to write numerals and numbers. (See numeral system.)
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Identifying numerals [link]
Numerals may be attributive, as in two dogs, or pronominal, as in I saw two (of them).
Many words of different parts of speech indicate number or quantity. Quantifiers do not enumerate, or designate a specific number, but give another, often less specific, indication of amount. Examples are words such as every, most, least, some, etc. There are also number words which enumerate but are not a distinct part of speech, such as 'dozen', which is a noun, 'first', which is an adjective, or 'twice', which is an adverb. Numerals enumerate, but in addition have distinct grammatical behavior: when a numeral modifies a noun, it may replace the article: the/some dogs played in the park → twelve dogs played in the park. (Note that *dozen dogs played in the park is not grammatical, so 'dozen' is not a numeral.)
Numerals may be simple, such as 'eleven', or compound, such as 'twenty-three'. They indicate cardinal numbers. Various other number words are derived from numerals, but are not themselves numerals. Examples are ordinal numbers (first, second, third, etc.; from 'third' up, these are also used for fractions) and multiplicative adverbs (once, twice, and thrice).
In other languages, there may be other kinds of words derived from numerals. For example, in Slavic languages there are collective numbers which describe sets, such as pair or dozen in English. (See Polish numerals.) Georgian[1] and Latin have distributive numbers, such as Latin singuli "one-by-one", bini "in pairs, two-by-two"), terni "three each", etc.
Some languages have a very limited set of numerals, and in some cases they arguably do not have any numerals at all, but instead use more generic quantifiers or number words, such as 'pair' or 'many'. However, by now most such languages have borrowed the numeral system or part of the numeral system of a national or colonial language, though in a few cases (such as Guarani), a numeral system has been invented internally rather than borrowed. Other languages had an indigenous system but borrowed a second set of numerals anyway. An example is Japanese, which uses either native or Chinese-derived numerals depending on what is being counted.
In many languages, such as Chinese, numerals require the use of numeral classifiers. Many sign languages, such as ASL, incorporate numerals.
Basis of counting system [link]
| Numeral systems by culture | |
|---|---|
| Hindu-Arabic numerals | |
| Western Arabic (Hindu numerals) Eastern Arabic Indian family Tamil |
Burmese Khmer Lao Mongolian Thai |
| East Asian numerals | |
| Chinese Japanese Suzhou |
Korean Vietnamese Counting rods |
| Alphabetic numerals | |
| Abjad Armenian Āryabhaṭa Cyrillic |
Ge'ez Greek Georgian Hebrew |
| other historical systems | |
| Aegean Attic Babylonian Brahmi Egyptian Etruscan Inuit |
Kharosthi Mayan Quipu Roman |
| Positional systems by base | |
| Decimal (10) | |
| 2, 3, 4, 5, 6, 7, 8, 9, 11, 12, 13, 14, 15, 16, 20, 24, 27, 30, 36, 60, 64 | |
| Balanced ternary | |
| Non-positional system | |
| Unary numeral system (Base 1) | |
| List of numeral systems | |
Not all languages have numeral systems. Specifically, there is not much need for numeral systems among hunter-gatherers who do not engage in commerce. Many languages around the world have no numerals above two to four—or at least did not before contact with the colonial societies—and speakers of these languages may have no tradition of using the numerals they did have for counting. Indeed, several languages from the Amazon have been independently reported to have no specific number words other than 'one'. These include Nadëb, pre-contact Mocoví and Pilagá, Culina and pre-contact Jarawara, Jabutí, Canela-Krahô, Botocudo (Krenák), Chiquitano, the Campa languages, Arabela, and Achuar.[2] Some languages of Australia, such as Warlpiri, do not have words for quantities above two,[3][4] as did many Khoisan languages at the time of European contact. Such languages do not have a word class of 'numeral'.
Most languages with both numerals and counting use base 8, 10, 12, or 20. Base 10 appears to come from counting one's fingers, base 20 from the fingers and toes, base 8 from counting the spaces between the fingers (attested in California), and base 12 from counting the knuckles (3 each for the four fingers).[5]
For very large (and very small) numbers, traditional systems have been superseded by the use of scientific notation and the system of SI prefixes. Traditional systems continue to be used in everyday life.
No base [link]
Many languages of Melanesia have (or once had) counting systems based on parts of the body which do not have a numeric base; there are (or were) no numerals, but rather nouns for relevant parts of the body—or simply pointing to the relevant spots—were used for quantities. For example, 1–4 may be the fingers, 5 'thumb', 6 'wrist', 7 'elbow', 8 'shoulder', etc., across the body and down the other arm, so that the opposite pinkie represents a number between 17 (Torres Islands) to 23 (Eleman). For numbers beyond this, the torso, legs and toes may be used, or one might count back up the other arm and back down the first, depending on the people.
4: quaternary [link]
Some Austronesian and Melanesian ethnic groups, including the Māori, some Sulawesi and some Papua New Guineans count with the base number four, using the term asu and aso (derived from Javanese asu: dog), as the ubiquitous village dog has four legs.[6] This is argued by anthropologists to be also based on early humans noting the human and animal shared body feature of two arms and two legs as well as its ease in simple arithmetic and counting. As an example of the system's ease a realistic scenario could include a farmer returning from the market with fifty asu heads of pig (200), less 30 asu (120) of pig bartered for 10 asu (40) of goats noting his new pig count total as twenty asu: 80 pigs remaining. The system has a correlation to the dozen counting system and is still in common use in these areas as a natural and easy method of simple arithmetic.[6][7]
5: quinary [link]
Quinary systems are based on the number 5. It is almost certain the quinary system developed from counting by fingers (five fingers per hand).[8] An example is Api,[which?] a language of Vanuatu, where 5 is luna 'hand', 10 lua-luna 'two hand', 15 tolu-luna 'three hand', etc. 11 is then lua-luna tai 'two-hand one', and 17 tolu-luna lua 'three-hand two'.
5 is a common auxiliary base, or sub-base, where 6 is 'five and one', 7 'five and two', etc. Aztec was a vigesimal (base-20) system with sub-base 5.
6: senary [link]
Kanum is a rare example of a language with base 6. The Sko languages, however, and base-24 with a subbase of 6.
8: octal [link]
Octal is a counting system based on the number 8. It is used in the Yuki language of California and in the Pamean languages of Mexico, because the Yuki and Pame keep count by using the four spaces between their fingers rather than the fingers themselves.[9]
10: decimal [link]
A majority of traditional number systems are based on the decimal numeral system. Anthropologists hypothesize this may be due to humans having five digits per hand, ten in total.[8][10][11] There are many regional variations including:
- Western system: based on thousands, with variants (see English-language numerals)
- Indian system: crore, lakh (see Indian numbering system. Indian numerals)
- East Asian system: based on ten-thousands (see below)
Historically, its use was first employed by the ancient Egyptians, who invented a wholly decimal system, and later extended by the Babylonians,[8] and also a system of pictorial representation, substituting letters and other reminders with symbols. An English farmer coined the term notch, defined as ten, from the tally sticks of the livestock, a full deep score for every twenty, a half score or notch for ten.[12]
12: duodecimal [link]
Duodecimal systems are based on 12.
These include:
- Chepang language of Nepal,
- Mahl language of Minicoy Island in India
- Nigerian Middle Belt areas such as Janji, Kahugu and the Nimbia dialect of Gwandara.
- Melanesia[citation needed]
- Polynesia[citation needed]
- reconstructed proto-Benue–Congo
Duodecimal numeric systems have some practical advantages over decimal. It is much easier to divide the base digit twelve (which is a highly composite number) by many important divisors in market and trade settings, such as the numbers 2, 3, 4 and 6. It is still common usage and is found in idiom. For example, "A dime a dozen" refers to something so common or numerous as to be of little worth or noteworthiness.
The system of basing counting on the number 12, is widespread, across many cultures. Examples include:
- time divisions (twelve months in a year, the twelve-hour clock)
- measurement imperial system of units (twelve inches to the foot, twelve troy ounces to the troy pound)
- traditional British monetary system (twelve pence to the shilling)
- the ancient Babylonian concept of 360 days in the year (12 months x 30 days) from which we get 360 degrees to a circle
Consequently, languages evolved or loaned terms such dozen, gross and great gross, which allow for rudimentary and arguably immediately comprehensible duodecimal nomenclature (e.g., stating: "two gross and six dozen" instead of "three hundred and sixty"). Ancient Romans used decimal for integers, but switched to duodecimal for fractions, and correspondingly Latin developed a rich vocabulary for duodecimal-based fractions (see Roman numerals). A notable fictional duodecimal system was that of J. R. R. Tolkien's Elvish languages, which used duodecimal as well as decimal.
20: vigesimal [link]
Vigesimal numbers use the number 20 as the base number for counting. Anthropologists are convinced the system originated from digit counting, as did bases five and ten, twenty being the number of human fingers and toes combined[8][10] The system is in widespread use across the world. Some include the classical Mesoamerican cultures, still in use today in the modern indigenous languages of their descendants, namely the Nahuatl and Mayan languages (see Maya numerals). A modern national language which uses a full vigesimal system is Dzongkha in Bhutan.
Partial vigesimal systems are found in some European languages: Basque, Celtic languages, French (from Celtic), Danish, and Georgian. In these languages the systems are vigesimal up to 99, then decimal from 100 up. That is, 140 is 'one hundred two score', not *seven score, and there is no numeral for 400.
The term score originates from tally sticks, where taxmen and farmers would groove a notch for every ten, and a full score for every twenty. The English term score, now rarely used, is a remnant of vigesimal numeration in the word score. It was widely used to learn the pre-decimal British currency in this idiom: "a dozen pence and a score of bob" , referring to the 20 shillings in a pound. For Americans the term is most known from the opening of the Gettysburg Address: "Four score and seven years ago, our forefathers...".
24: quadrivigesimal [link]
The Sko languages have a base-24 system with a subbase of 6.
32: duotrigesimal [link]
Ngiti has base 32.
60: sexagesimal [link]
Ekari has a base-60 system. Sumeria had a base-60 system with a decimal subbase, perhaps a conflation of the decimal and a duodecimal systems of its constituent peoples, which was the origin of the numbering of modern degrees, minutes, and seconds.
80: octogesimal [link]
Supyire is said to have a base-80 system; it counts in twenties (with 5 and 10 as subbases) up to 80, then by eighties up to 400, and then by 400s (great scores).
| kàmpwóò | ŋ̀kwuu | sicyɛɛré | ná | béé-tàànre | ná | kɛ́ | ná | báár-ìcyɛ̀ɛ̀rè |
| fourhundred | eighty | four | and | twenty-three | and | ten | and | five-four |
799 [i.e. 400 + (4 x 80) + (3 x 20) + {10 + (5 + 4)}]’
Larger numerals [link]
English has derived numerals for multiples of its base (fifty, sixty, etc), and some languages have simplex numerals for these, or even for numbers between the multiples of its base. Balinese, for example, currently has a decimal system, with words for 10, 100, and 1000, but has additional simplex numerals for 25 (with a second word for 25 only found in a compound for 75), 35, 45, 50, 150, 175, 200 (with a second found in a compound for 1200), 400, 900, and 1600. In Hindustani, the numerals between 10 and 100 have become conflated to the extent that they need to be learned independently.
In many languages, numerals up to the base are a distinct part of speech, while the words for powers of the base belong to one of the other word classes. In English, these higher words are hundred 10², thousand 10³, million 10⁶, and hiɡher powers of a thousand (short scale) or of a million (long scale—see names of large numbers). These words cannot modify a noun without being preceded by an article or numeral (*hundred dogs played in the park), as so are nouns.
In East Asia, the higher units are hundred, thousand, myriad 10⁴, and powers of myriad. In India, they are hundred, thousand, lakh 10⁵, crore 10⁷, and so on. The Mesoamerican system, still used to some extent in Mayan languages, was based on powers of 20: bak’ 400 (20²), pik 8000 (20³), kalab 160,000 (20⁴), etc.
See also [link]
Numerals in various languages [link]
A database Numeral Systems of the World's Languages compiled by Eugene S.L. Chan of Hong Kong is hosted by the Max Planck Institute for Evolutionary Anthropology in Leipzig, Germany. The database currently contains data for about 4000 languages.
- Proto-Indo-European numerals
- Proto-Semitic numerals
- Japanese numerals
- Korean numerals
- Dzongkha numerals
- Javanese numerals
- Balinese numerals
- Finnish numerals
- Polish numerals
- Yoruba numerals
- Australian Aboriginal enumeration
Related topics [link]
Notes [link]
- ^ Walsinfo.com
- ^ Hammarström (2009, page 197) "Rarities in numeral systems"
- ^ UCL Media Relations, "Aboriginal kids can count without numbers"
- ^ The Science Show, Genetic anomaly could explain severe difficulty with arithmetic, Australian Broadcasting Corporation
- ^ Bernard Comrie, "The Typology of Numeral Systems", p. 3
- ^ a b Ryan, Peter. Encyclopaedia of Papua and New Guinea. Melbourne University Press & University of Papua and New Guinea,:1972 ISBN 0-522-84025-6.: 3 pages pp219.
- ^ Aleksandr Romanovich Luriicac, Lev Semenovich Vygotskiĭ, Evelyn Rossiter. Ape, primitive man, and child: essays in the history of behavior . CRC Press: 1992: ISBN 1-878205-43-9: 171 pages
- ^ a b c d Heath, Thomas, A Manual of Greek Mathematics, Courier Dover: 2003. ISBN 0486432319576 page, p:11
- ^ Ascher, Marcia (1994), Ethnomathematics: A Multicultural View of Mathematical Ideas, Chapman & Hall, ISBN 0-412-98941-7
- ^ a b Georges Ifrah, The Universal History of Numbers: The Modern Number System, Random House, 2000: ISBN 1-86046-791-1: 1262 pages
- ^ Scientific American Munn& Co: 1968, vol 219: 219
- ^ Karl Menninger, Paul Broneer, Number Words and Number Symbols Courier Dover Publications: 1992: ISBN 0-486-27096-3: 480 pages
https://wn.com/Numeral_(linguistics)
Zero (name)
Zero or Zéro is surname, given name or pseudonym of the following people:
Zero is name of the following notable fictional characters:
Zero (Yeah Yeah Yeahs song)
"Zero" is a song by American indie rock band Yeah Yeah Yeahs, released as the lead single from their third studio album, It's Blitz! (2009). The song received critical acclaim from music critics for its production, and was named the best track of 2009 by both NME and Spin magazines.
The single had minor commercial success, peaking at numbers four and eighteen on the Billboard Alternative Songs and Hot Dance Singles Sales charts, as well as number forty-nine on the UK Singles Chart. A music video for the single, which shows lead singer Karen O walking the streets of San Francisco at night, was released in March 2009.
Critical reception
"Zero" received acclaim from music critics. Paula Carino of AllMusic described the song as "an exhilarating and wide-open expanse of pure electro-pop". Mary Bellamy of Drowned in Sound viewed the track as "the call to arms of a band who desperately want to teleport the refugees of fashion-fizzled pop, the hippest of hipsters and the weirdest outsiders to the dancefloor of their sweaty spaceship", stating it is "perhaps one of the band's finest moments ever committed to tape."
Zero (B'z song)
Zero is the eleventh single by B'z, released on October 7, 1992, and the only one from their album Run. This song is one of B'z many number-one singles in Oricon chart, selling over 600,000 copies in its first week, although there was no tie up for the song at that moment. The single was re-released in 2003, and re-entered at #4. It sold over 1,310,000 copies according to Oricon.
Track listing
References
External links
Zero (TV series)
Zero (零楼) is a Singaporean drama which aired on SPH MediaWorks Channel U in November 2004. This series was one of the last broadcast by SPH MediaWorks before it amalgamated with MediaCorp. After the credits of the final episode rolled, a candid photo montage of behind-the-scenes and studio staff and personnel were shown.
Cast
Synopsis
Sam (Bryan Wong) is an ambitious man who stops at nothing to achieve his goals and takes things for granted. A schemer by nature, he has many enemies and was assaulted in a parking lot. He falls into a deep coma and goes to a place called "zero" (零楼) where he is met by "001" (Guo Liang). As Sam's bad deeds and good deeds all cancel out each other, the angels can't decide whether to send him to "basement 1" (hell) or "level 1" (heaven).
2 Zero 0-0
2 Zero 0-0 is a 1999 album by the Junkanoo band Baha Men. Initially released in Japan and then two years later in the US and elsewhere, it was most popular in the Western Bahamas and Southern Africa. The album launched the single "You All Dat", which charted at #94 on the Billboard Hot 100.
