Law (mathematics) explained

In mathematics, a law is a formula that is always true within a given context.^[1] Laws describe a relationship, between two or more terms or exprssions (which may contain variables), usually using equality or inequality,^[2] or between formulas themselves, for instace, in mathematical logic. For example, the formula

a²\geq0

is true for all real-numbers , and is therefor a law. Laws over an equality are called indentities.^[3] For example,

(a+b)²=a²+2ab+b²

and

\cos^2\theta+\sin^2\theta=1

are identities.^[4] Mathematical laws are distinguished from scientific laws which are based on observations, and try to describe or predict a range of natural phenomena. The more significant laws are often called theorems.

Notable Examples

Geometric laws

Triange inequality: If , , and are the lengths of the sides of a triangle then the triangle inequality states that

c\leqa+b,

with equality only in the degenerate case of a triangle with zero area. In Euclidean geometry and some other geometries, the triangle inequality is a theorem about vectors and vector lengths (norms):

\|u+v\|\leq\|u\|+\|v\|,

where the length of the third side has been replaced by the length of the vector sum . When and are real numbers, they can be viewed as vectors in

\R¹

, and the triangle inequality expresses a relationship between absolute values.

Pythagorean theorem: It states that the area of the square whose side is the hypotenuse (the side opposite the right angle) is equal to the sum of the areas of the squares on the other two sides. The theorem can be written as an equation relating the lengths of the sides a, b and the hypotenuse c, sometimes called the Pythagorean equation:^[5]

a²+b²=c².

Trigonometric identities

See main article: List of trigonometric identities.

Geometrically, trigonometric identities are identities involving certain functions of one or more angles.^[6] They are distinct from triangle identities, which are identities involving both angles and side lengths of a triangle. Only the former are covered in this article.

These identities are useful whenever expressions involving trigonometric functions need to be simplified. Another important application is the integration of non-trigonometric functions: a common technique which involves first using the substitution rule with a trigonometric function, and then simplifying the resulting integral with a trigonometric identity.

One of the most prominent examples of trigonometric identities involves the equation

\sin²\theta+\cos²\theta=1,

which is true for all real values of

\theta

. On the other hand, the equation

\cos\theta=1

is only true for certain values of

\theta

, not all. For example, this equation is true when

\theta=0,

but false when

\theta=2

Another group of trigonometric identities concerns the so-called addition/subtraction formulas (e.g. the double-angle identity

\sin(2\theta)=2\sin\theta\cos\theta

, the addition formula for

\tan(x+y)

), which can be used to break down expressions of larger angles into those with smaller constituents.

Algebraic laws

Cauchy–Schwarz inequality

An upper bound on the inner product between two vectors in an inner product space in terms of the product of the vector norms. It is considered one of the most important and widely used inequalities in mathematics.^[7]

The Cauchy–Schwarz inequality states that for all vectors

and

of an inner product space

\left\vert\langle\boldu,\boldv\rangle\right\vert\leq\langle\boldu,\boldu\rangle ⋅ \langle\boldv,\boldv\rangle

where

\langle ⋅ , ⋅ \rangle

is the inner product. Examples of inner products include the real and complex dot product; see the examples in inner product. Every inner product gives rise to a Euclidean

l₂

norm, called the or, where the norm of a vector

is denoted and defined by

\|u\|:=\sqrt{\langleu,u\rangle},

where

\langleu,u\rangle

is always a non-negative real number (even if the inner product is complex-valued). By taking the square root of both sides of the above inequality, the Cauchy–Schwarz inequality can be written in its more familiar form in terms of the norm:^[8] ^[9]

\left\vert\langle\boldu,\boldv\rangle\right\vert\leq\langle\boldu,\boldu\rangle ⋅ \langle\boldv,\boldv\rangle

Moreover, the two sides are equal if and only if

and

are linearly dependent.^[10] ^[11] ^[12]

Combinatorial laws

Pigeonhole principle: If items are put into containers, with, then at least one container must contain more than one item. For example, of three gloves (none of which is ambidextrous/reversible), at least two must be right-handed or at least two must be left-handed, because there are three objects but only two categories of handedness to put them into.

Logical laws

De Morgan's laws: In propositional logic and Boolean algebra, De Morgan's laws,^[13] ^[14] also known as De Morgan's theorem,^[15] are a pair of transformation rules that are both valid rules of inference. They are named after Augustus De Morgan, a 19th-century British mathematician. The rules allow the expression of conjunctions and disjunctions purely in terms of each other via negation. The rules can be expressed in English as:
- not (A or B) = (not A) and (not B)
- not (A and B) = (not A) or (not B) where "A or B" is an "inclusive or" meaning at least one of A or B rather than an "exclusive or" that means exactly one of A or B. In formal language, the rules are written as

\neg(P\lorQ)\iff(\negP)\land(\negQ),

and

\neg(P\landQ)\iff(\negP)\lor(\negQ)

where

- P and Q are propositions,
- \neg
  
  is the negation logic operator (NOT),
- \land
  
  is the conjunction logic operator (AND),
- \lor
  
  is the disjunction logic operator (OR),
- \iff
  
  is a metalogical symbol meaning "can be replaced in a logical proof with", often read as "if and only if". For any combination of true/false values for P and Q, the left and right sides of the arrow will hold the same truth value after evaluation.
The three Laws of thought
- The law of identity: 'Whatever is, is.'^[16] For all a: a = a.
- The law of non-contradiction (alternately the 'law of contradiction'^[17]): 'Nothing can both be and not be.'
- The law of excluded middle: 'Everything must either be or not be.' In accordance with the law of excluded middle or excluded third, for every proposition, either its positive or negative form is true: A∨¬A.

Phinominological laws

Benford's law: An observation that in many real-life sets of numerical data, the leading digit is likely to be small.^[18] In sets that obey the law, the number 1 appears as the leading significant digit about 30% of the time, while 9 appears as the leading significant digit less than 5% of the time. Uniformly distributed digits would each occur about 11.1% of the time.^[19]
Strong law of small numbers: (Humerous) Any given small number appears in far more contexts than may seem reasonable, leading to many apparently surprising coincidences in mathematics, simply because small numbers appear so often and yet are so few.

References

Bertrand Russell, The Problems of Philosophy (1912), Oxford University Press, New York, 1997, .

External links

The Encyclopedia of Equation Online encyclopedia of mathematical identities (archived)
A Collection of Algebraic Identities

Notes and References

Web site: Weisstein . Eric W. . Law . 2024-08-19 . mathworld.wolfram.com . en.
Pratt, Vaughan, "Algebra", The Stanford Encyclopedia of Philosophy (Winter 2022 Edition), Edward N. Zalta & Uri Nodelman (eds.), URL: https://plato.stanford.edu/entries/algebra/#Laws
Equation. Springer Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Equation&oldid=32613
Web site: Mathwords: Identity . 2019-12-01 . www.mathwords.com.
Book: Judith D. Sally . Roots to research: a vertical development of mathematical problems . Paul Sally . American Mathematical Society Bookstore . 2007 . 978-0-8218-4403-8 . 63 . Chapter 3: Pythagorean triples . https://books.google.com/books?id=nHxBw-WlECUC&pg=PA63.
Web site: Stapel . Elizabeth . Trigonometric Identities . 2019-12-01 . Purplemath.
Book: Steele, J. Michael . The Cauchy–Schwarz Master Class: an Introduction to the Art of Mathematical Inequalities . The Mathematical Association of America . 2004 . 978-0521546775 . 1 . ...there is no doubt that this is one of the most widely used and most important inequalities in all of mathematics..
Book: Strang, Gilbert . Linear Algebra and its Applications . 19 July 2005 . Cengage Learning . 978-0030105678 . 4th . Stamford, CT . 154–155 . 3.2.
Book: Hunter . John K. . Applied Analysis . Nachtergaele . Bruno . World Scientific . 2001 . 981-02-4191-7.
Book: Bachmann . George . Fourier and Wavelet Analysis . Narici . Lawrence . Beckenstein . Edward . 2012-12-06 . Springer Science & Business Media . 9781461205050 . 14.
Book: Hassani, Sadri . Mathematical Physics: A Modern Introduction to Its Foundations . Springer . 1999 . 0-387-98579-4 . 29 . Equality holds iff =0 or c>=0. From the definition of c>, we conclude that a> and b> must be proportional..
Book: Axler . Sheldon . Linear Algebra Done Right, 3rd Ed. . 2015 . Springer International Publishing . 978-3-319-11079-0 . 172 . This inequality is an equality if and only if one of u, v is a scalar multiple of the other..
Book: Copi . Irving M. . Introduction to Logic . Cohen . Carl . McMahon . Kenneth . 2016 . 9781315510880 . 10.4324/9781315510897.
Book: Moore, Brooke Noel . Critical thinking . 2012 . McGraw-Hill . Richard Parker . 978-0-07-803828-0 . 10th . New York . 689858599.
http://hyperphysics.phy-astr.gsu.edu/hbase/Electronic/DeMorgan.html DeMorgan's [sic] Theorem
Russell 1912:72,1997 edition.
Russell 1912:72, 1997 edition.
Arno Berger and Theodore P. Hill, Benford's Law Strikes Back: No Simple Explanation in Sight for Mathematical Gem, 2011.
Web site: Weisstein, Eric W. . Benford's Law . 7 June 2015 . MathWorld, A Wolfram web resource.

Law (mathematics) explained

Notable Examples

Geometric laws

Trigonometric identities

Algebraic laws

Combinatorial laws

Logical laws

Phinominological laws

See also

References

External links

Notes and References