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In [[mathematics]], specifically in [[elementary arithmetic]] and [[elementary algebra]], given an equation between two [[Fraction (mathematics)|fraction]]s or [[rational expression]]s, one can '''cross-multiply''' to simplify the equation or determine the value of a variable.
 
For an equation like the following:
 
:<math>\frac a b = \frac c d</math> (note that "b" and "d" must be non-zero for these to be [[real number|real]] fractions)
 
one can cross-multiply to get
 
:<math>ad = bc \quad \mathrm {or} \quad a = \frac {bc} {d}.</math>
 
== Procedure ==
 
In practice, the method of ''cross-multiplying'' means that we multiply the numerator of each (or one) side by the denominator of the other side, effectively "crossing" the terms over.  
 
:<math>\frac a b \nwarrow \frac c d \quad \frac a b \nearrow \frac c d.</math>
 
The mathematical justification for the method is from the following longer mathematical procedure.
 
If we start with the basic equation:
 
:<math>\frac {a} {b} = \frac {c} {d}</math>
 
We can multiply the terms on each side by the same number and the terms will remain equal.  Therefore, if we multiply the fraction on each side by the product of the denominators of both sides - <math>(bd)\,\!</math>  - we get:
 
:<math>\frac {a} {b} \times {bd} = \frac {c} {d} \times {bd}</math>
 
We can reduce the fractions to lowest terms by noting that the b's on the left hand side and the d's on the right hand side cancel, leaving:
 
:<math>ad = bc \,</math>.
 
and we can divide both sides of the equation by any of the elements - in this case we will use "d" - yielding:
 
:<math>a = \frac {bc} {d}.</math>
 
Another variation of the same process
 
:<math>\frac {a} {b} = \frac {c} {d}</math>
 
:<math>\frac {a} {b} \times \frac {d} {d} = \frac {c} {d} \times \frac {b} {b}</math>&nbsp; &nbsp; &nbsp; &nbsp; &nbsp;  multiply by 1 using alternate denominators
 
:<math>\frac {ad} {bd} = \frac {cb} {db}</math> &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; divide out the common denominator
 
:<math>{ad} = {cb}</math>
 
These give the same results as cross-multiplication. 
 
Each step in these processes is based on a single, fundamental property of [[equation]]s.  Cross-multiplication was devised as a shortcut, in particular as an easily understood procedure to teach students.
 
== Use ==
This is a common procedure in mathematics, used to reduce fractions or calculate a value for a given variable in a fraction. If we have an equation like (where ''x'' is a variable):
 
:<math>\frac x b = \frac c d</math>
 
we can use cross multiplication to determine that:
 
:<math>dx = bc \quad \mathrm {or} \quad x = \frac {bc} {d}</math>
 
For a simple example, let's say that we want to know how far a car will get in 7 hours, if we happen to know that its speed is constant and that it already travelled 90 miles in the last 3 hours.  Converting the word problem into ratios we get
 
:<math>\frac {\mathrm {x}\ miles} {7\ hours} = \frac {90\ miles} {3\ hours}</math>
 
Cross-multiplying yields:
 
:<math>\begin{align}
& \frac x {7} \times 21 = \frac {90} {3} \times 21 \\
& x \times 3 = {90} \times 7 = 630 \\
& x = 210\ \mathrm {miles} \\
\end{align}</math>
 
It is important to keep track of the units, in this case 'miles' and 'hours', though they have been left out of the above equations for simplicity. 
 
note that even simple equations like this:
 
:<math>a = \frac {x} {d}</math>
 
are solved using cross multiplication, since the missing "b" term is implicitly equal to 1: e.g.:
 
:<math>\frac a 1 = \frac x d.</math>
 
Any equation containing fractions or rational expressions can be simplified by multiplying both sides by the [[least common denominator]]. This step is called "clearing fractions".
 
== Rule of Three ==
 
The Rule of Three<ref>This was sometimes also referred to as the Golden Rule - see [http://www.bartleby.com/81/7351.html Golden Rule], [[Brewer's Dictionary of Phrase and Fable]] though that usage is rare compared to other uses of [[Golden Rule]]</ref> was a shorthand version for a particular form of cross multiplication, often taught to students by rote.  This rule was already known to Hebrews by the 15th century BCE as it is a special case of the Kal va-chomer (קל וחומר). It was also known by Indian (Vedic) mathematicians in the 6th century BCE{{Citation needed|date=July 2008}} and Chinese mathematicians prior to the 7th century CE,<ref>Shen, Kangren et al, tr. The Nine Chapters on the Mathematical Art: Companion and Commentary. Oxford: Oxford University Press, 1999.</ref> though it was not used in Europe until much later. The Rule of Three gained notoriety for being particularly difficult to explain: see [[Cocker's Arithmetick]] for an example of how the premier textbook in the 17th century approached the subject.
 
For an equation of the form:
 
:<math>\frac a b = \frac c x</math>
 
where the variable to be evaluated is in the right-hand denominator, the Rule of Three states that:
 
:<math>x = \frac {bc} {a}.</math>
 
For instance, if we re-wrote the equation used as an example above like so (inverting the proportions and swapping sides):
 
:<math>\frac {3\ \mathrm {hours}} {90\ \mathrm {miles}} = \frac {7\ \mathrm {hours}} {x\ \mathrm {miles}} \quad</math>
 
the Rule of Three can be used to calculate <math>x</math> directly
 
:<math>x = \frac {90\ \mathrm {miles} \times 7\ \mathrm {hours} } {3\ \mathrm {hours}} = 210\ \mathrm {miles}</math>
 
In this context, <math>a</math> is referred to as the 'extreme' of the proportion, and <math>b</math> and <math>c</math> are called the 'means'.
 
==References==
<references />
 
== Further reading ==
* [http://mathforum.org/library/drmath/view/60822.html 'Dr Math', ''Rule of Three'']
* [http://mathforum.org/library/drmath/view/62685.html 'Dr Math', ''Abraham Lincoln and the Rule of Three'']
* [http://www.pballew.net/arithm18.html ''Pike's System of arithmetick abridged: designed to facilitate the study of the science of numbers, comprehending the most perspicuous and accurate rules, illustrated by useful examples: to which are added appropriate questions, for the examination of scholars, and a short system of book-keeping.'', 1827] - facsimile of the relevant section
* [http://faculty.ed.uiuc.edu/westbury/paradigm/Hersee.html Hersee J, ''Multiplication is vexation''] - an article tracing the history of the rule from 1781
* [http://brunelleschi.imss.fi.it/michaelofrhodes/math_toolkit_three.html The Rule of Three as applied by Michael of Rhodes in the fifteenth century]
* [http://www.rhymes.org.uk/a61-multiplication.htm The Rule Of Three in Mother Goose]
* [http://www.literaturepage.com/read/thejunglebook-127.html Rudyard Kipling: You can work it out by Fractions or by simple Rule of Three, But the way of Tweedle-dum is not the way of Tweedle-dee.]
 
[[Category:Fractions]]

Revision as of 17:24, 14 July 2013

In mathematics, specifically in elementary arithmetic and elementary algebra, given an equation between two fractions or rational expressions, one can cross-multiply to simplify the equation or determine the value of a variable.

For an equation like the following:

ab=cd (note that "b" and "d" must be non-zero for these to be real fractions)

one can cross-multiply to get

ad=bcora=bcd.

Procedure

In practice, the method of cross-multiplying means that we multiply the numerator of each (or one) side by the denominator of the other side, effectively "crossing" the terms over.

abcdabcd.

The mathematical justification for the method is from the following longer mathematical procedure.

If we start with the basic equation:

ab=cd

We can multiply the terms on each side by the same number and the terms will remain equal. Therefore, if we multiply the fraction on each side by the product of the denominators of both sides - (bd) - we get:

ab×bd=cd×bd

We can reduce the fractions to lowest terms by noting that the b's on the left hand side and the d's on the right hand side cancel, leaving:

ad=bc.

and we can divide both sides of the equation by any of the elements - in this case we will use "d" - yielding:

a=bcd.

Another variation of the same process

ab=cd
ab×dd=cd×bb          multiply by 1 using alternate denominators
adbd=cbdb           divide out the common denominator
ad=cb

These give the same results as cross-multiplication.

Each step in these processes is based on a single, fundamental property of equations. Cross-multiplication was devised as a shortcut, in particular as an easily understood procedure to teach students.

Use

This is a common procedure in mathematics, used to reduce fractions or calculate a value for a given variable in a fraction. If we have an equation like (where x is a variable):

xb=cd

we can use cross multiplication to determine that:

dx=bcorx=bcd

For a simple example, let's say that we want to know how far a car will get in 7 hours, if we happen to know that its speed is constant and that it already travelled 90 miles in the last 3 hours. Converting the word problem into ratios we get

xmiles7hours=90miles3hours

Cross-multiplying yields:

x7×21=903×21x×3=90×7=630x=210miles

It is important to keep track of the units, in this case 'miles' and 'hours', though they have been left out of the above equations for simplicity.

note that even simple equations like this:

a=xd

are solved using cross multiplication, since the missing "b" term is implicitly equal to 1: e.g.:

a1=xd.

Any equation containing fractions or rational expressions can be simplified by multiplying both sides by the least common denominator. This step is called "clearing fractions".

Rule of Three

The Rule of Three[1] was a shorthand version for a particular form of cross multiplication, often taught to students by rote. This rule was already known to Hebrews by the 15th century BCE as it is a special case of the Kal va-chomer (קל וחומר). It was also known by Indian (Vedic) mathematicians in the 6th century BCEPotter or Ceramic Artist Truman Bedell from Rexton, has interests which include ceramics, best property developers in singapore developers in singapore and scrabble. Was especially enthused after visiting Alejandro de Humboldt National Park. and Chinese mathematicians prior to the 7th century CE,[2] though it was not used in Europe until much later. The Rule of Three gained notoriety for being particularly difficult to explain: see Cocker's Arithmetick for an example of how the premier textbook in the 17th century approached the subject.

For an equation of the form:

ab=cx

where the variable to be evaluated is in the right-hand denominator, the Rule of Three states that:

x=bca.

For instance, if we re-wrote the equation used as an example above like so (inverting the proportions and swapping sides):

3hours90miles=7hoursxmiles

the Rule of Three can be used to calculate x directly

x=90miles×7hours3hours=210miles

In this context, a is referred to as the 'extreme' of the proportion, and b and c are called the 'means'.

References

  1. This was sometimes also referred to as the Golden Rule - see Golden Rule, Brewer's Dictionary of Phrase and Fable though that usage is rare compared to other uses of Golden Rule
  2. Shen, Kangren et al, tr. The Nine Chapters on the Mathematical Art: Companion and Commentary. Oxford: Oxford University Press, 1999.

Further reading