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The language of mathematics or mathematical language is an extension of the natural language (for example English) that is used in mathematics and in science for expressing results (scientific laws, theorems, proofs, logical deductions, etc.) with concision, precision and unambiguity.
Features
The main features of the mathematical language are the following.
- Use of common words with a derived meaning, generally more specific and more precise. For example, "or" means "one, the other or both", while, in common language, "both" is sometimes included and sometimes not. Also, a "line" is straight and has zero width.
- Use of common words with a meaning that is completely different from their common meaning. For example, a mathematical ring is not related to any other meaning of "ring". Real numbers and imaginary numbers are two sorts of numbers, none being more real or more imaginary than the others.
- Use of neologisms. For example polynomial, homomorphism.
- Use of symbols as words or phrases. For example,
![image]()
and ![image]()
are respectively read as "![image]()
equals ![image]()
" and "for all ![image]()
". - Use of formulas as part of sentences. For example: "
![image]()
represents quantitatively the mass–energy equivalence." A formula that is not included in a sentence is generally meaningless, since the meaning of the symbols may depend on the context: in " ![image]()
", this is the context that specifies that E is the energy of a physical body, m is its mass, and c is the speed of light. - Use of mathematical jargon that consists of phrases that are used for informal explanations or shorthands. For example, "killing" is often used in place of "replacing with zero", and this led to the use of assassinator and annihilator as technical words.
Understanding mathematical text
The consequence of these features is that a mathematical text is generally not understandable without some prerequisite knowledge. For example, the sentence "a free module is a module that has a basis" is perfectly correct, although it appears only as a grammatically correct nonsense, when one does not know the definitions of basis, module, and free module.
H. B. Williams, an electrophysiologist, wrote in 1927:
Now mathematics is both a body of truth and a special language, a language more carefully defined and more highly abstracted than our ordinary medium of thought and expression. Also it differs from ordinary languages in this important particular: it is subject to rules of manipulation. Once a statement is cast into mathematical form it may be manipulated in accordance with these rules and every configuration of the symbols will represent facts in harmony with and dependent on those contained in the original statement. Now this comes very close to what we conceive the action of the brain structures to be in performing intellectual acts with the symbols of ordinary language. In a sense, therefore, the mathematician has been able to perfect a device through which a part of the labor of logical thought is carried on outside the central nervous system with only that supervision which is requisite to manipulate the symbols in accordance with the rules.: 291
See also
- Formulario mathematico
- Formal language
- History of mathematical notation
- Mathematical notation
- List of mathematical jargon
References
- Horatio Burt Williams (1927) Mathematics and the Biological Sciences, Bulletin of the American Mathematical Society 33(3): 273–94 via Project Euclid
Further reading
Linguistic point of view
- Keith Devlin (2000) The Language of Mathematics: Making the Invisible Visible, Holt Publishing.
- Kay O'Halloran (2004) Mathematical Discourse: Language, Symbolism and Visual Images, Continuum.
- R. L. E. Schwarzenberger (2000), "The Language of Geometry", in A Mathematical Spectrum Miscellany, Applied Probability Trust.
In education
- Lawrence. A. Chang (1983) Handbook for spoken mathematics The regents of the University of California, [1]
- F. Bruun, J. M. Diaz, & V. J. Dykes (2015) The Language of Mathematics. Teaching Children Mathematics, 21(9), 530–536.
- J. O. Bullock (1994) Literacy in the Language of Mathematics. The American Mathematical Monthly, 101(8), 735–743.
- L. Buschman (1995) Communicating in the Language of Mathematics. Teaching Children Mathematics, 1(6), 324–329.
- B. R. Jones, P. F. Hopper, D. P. Franz, L. Knott, & T. A. Evitts (2008) Mathematics: A Second Language. The Mathematics Teacher, 102(4), 307–312. JSTOR.
- C. Morgan (1996) “The Language of Mathematics”: Towards a Critical Analysis of Mathematics Texts. For the Learning of Mathematics, 16(3), 2–10.
- J. K. Moulton (1946) The Language of Mathematics. The Mathematics Teacher, 39(3), 131–133.
This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Language of mathematics news newspapers books scholar JSTOR June 2022 Learn how and when to remove this message The language of mathematics or mathematical language is an extension of the natural language for example English that is used in mathematics and in science for expressing results scientific laws theorems proofs logical deductions etc with concision precision and unambiguity FeaturesThe main features of the mathematical language are the following Use of common words with a derived meaning generally more specific and more precise For example or means one the other or both while in common language both is sometimes included and sometimes not Also a line is straight and has zero width Use of common words with a meaning that is completely different from their common meaning For example a mathematical ring is not related to any other meaning of ring Real numbers and imaginary numbers are two sorts of numbers none being more real or more imaginary than the others Use of neologisms For example polynomial homomorphism Use of symbols as words or phrases For example A B displaystyle A B and x displaystyle forall x are respectively read as A displaystyle A equals B displaystyle B and for all x displaystyle x Use of formulas as part of sentences For example E mc2 displaystyle E mc 2 represents quantitatively the mass energy equivalence A formula that is not included in a sentence is generally meaningless since the meaning of the symbols may depend on the context in E mc2 displaystyle E mc 2 this is the context that specifies that E is the energy of a physical body m is its mass and c is the speed of light Use of mathematical jargon that consists of phrases that are used for informal explanations or shorthands For example killing is often used in place of replacing with zero and this led to the use of assassinator and annihilator as technical words Understanding mathematical textThe consequence of these features is that a mathematical text is generally not understandable without some prerequisite knowledge For example the sentence a free module is a module that has a basis is perfectly correct although it appears only as a grammatically correct nonsense when one does not know the definitions of basis module and free module H B Williams an electrophysiologist wrote in 1927 Now mathematics is both a body of truth and a special language a language more carefully defined and more highly abstracted than our ordinary medium of thought and expression Also it differs from ordinary languages in this important particular it is subject to rules of manipulation Once a statement is cast into mathematical form it may be manipulated in accordance with these rules and every configuration of the symbols will represent facts in harmony with and dependent on those contained in the original statement Now this comes very close to what we conceive the action of the brain structures to be in performing intellectual acts with the symbols of ordinary language In a sense therefore the mathematician has been able to perfect a device through which a part of the labor of logical thought is carried on outside the central nervous system with only that supervision which is requisite to manipulate the symbols in accordance with the rules 291 See alsoFormulario mathematico Formal language History of mathematical notation Mathematical notation List of mathematical jargonReferencesHoratio Burt Williams 1927 Mathematics and the Biological Sciences Bulletin of the American Mathematical Society 33 3 273 94 via Project EuclidFurther readingLinguistic point of view Keith Devlin 2000 The Language of Mathematics Making the Invisible Visible Holt Publishing Kay O Halloran 2004 Mathematical Discourse Language Symbolism and Visual Images Continuum R L E Schwarzenberger 2000 The Language of Geometry in A Mathematical Spectrum Miscellany Applied Probability Trust In education Lawrence A Chang 1983 Handbook for spoken mathematics The regents of the University of California 1 F Bruun J M Diaz amp V J Dykes 2015 The Language of Mathematics Teaching Children Mathematics 21 9 530 536 J O Bullock 1994 Literacy in the Language of Mathematics The American Mathematical Monthly 101 8 735 743 L Buschman 1995 Communicating in the Language of Mathematics Teaching Children Mathematics 1 6 324 329 B R Jones P F Hopper D P Franz L Knott amp T A Evitts 2008 Mathematics A Second Language The Mathematics Teacher 102 4 307 312 JSTOR C Morgan 1996 The Language of Mathematics Towards a Critical Analysis of Mathematics Texts For the Learning of Mathematics 16 3 2 10 J K Moulton 1946 The Language of Mathematics The Mathematics Teacher 39 3 131 133
