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[5]: 71 This analysis was developed in a 1962 grammar by Barbara M. H. Strang [5]: 73 and in 1972 by Randolph Quirk and colleagues. [5]: 74 In 1985, A Comprehensive Grammar of the English Language appears to have been the first work to explicitly conceive of determiner as a distinct lexical category. [5]: 74
The personal pronouns of Modern English retain morphological case more strongly than any other word class (a remnant of the more extensive case system of Old English). For other pronouns, and all nouns, adjectives, and articles, grammatical function is indicated only by word order , by prepositions , and by the " Saxon genitive " ( -'s ).
(Note: the case in Slavic languages termed the "locative case" in English is actually a prepositional case.) Pergressive case: vicinity: in the vicinity of the house Kamu: Pertingent case: contacting: touching the house Tlingit | Archi: Postessive case: posterior: after the house Lezgian | Agul: Subessive case: under: under/below the house Tsez ...
wife wò 2SG. POSS âka that nà the ani wò âka nà wife 2SG.POSS that the ´that wife of yours´ There are also languages in which demonstratives and articles do not normally occur together, but must be placed on opposite sides of the noun. For instance, in Urak Lawoi, a language of Thailand, the demonstrative follows the noun: rumah house besal big itu that rumah besal itu house big that ...
In mathematics, the distributive property of binary operations is a generalization of the distributive law, which asserts that the equality (+) = + is always true in elementary algebra. For example, in elementary arithmetic , one has 2 ⋅ ( 1 + 3 ) = ( 2 ⋅ 1 ) + ( 2 ⋅ 3 ) . {\displaystyle 2\cdot (1+3)=(2\cdot 1)+(2\cdot 3).}
The following proposition says that for any set , the power set of , ordered by inclusion, is a bounded lattice, and hence together with the distributive and complement laws above, show that it is a Boolean algebra.
a; a few; a little; all; an; another; any; anybody; anyone; anything; anywhere; both; certain (also adjective) each; either; enough; every; everybody; everyone ...
Mathematically, the ability to break up a multiplication in this way is known as the distributive law, which can be expressed in algebra as the property that a(b+c) = ab + ac. The grid method uses the distributive property twice to expand the product, once for the horizontal factor, and once for the vertical factor.