Fraction: Difference between revisions

A cake with one quarter removed. The remaining three quarters are shown.

Three quarters of the area of ABC  equals the area of its copy to scale:  ACH.  No fraction equals exactly the scale ratio:  √3/ 4  is irrational.

A fraction (from Template:Lang-la, "broken") is a writing: a ratio of two integers that represents a number. These two integers are used primarily to express a comparison between parts and a whole.

The earliest fractions were reciprocals of integers: ancient symbols representing one part of two, one part of three, one part of four, and so on.^[1] A much later development were the common or "vulgar" fractions, still used today 1/2, 5/8, 3/4, etc.), which consist of a numerator and a denominator—the numerator representing a number of equal parts and the denominator telling how many of those parts make up a whole. An example is 3/4, in which the numerator, 3, tells us that the fraction represents 3 equal parts, and the denominator, 4, tells us that 4 parts make up a whole.

A still later development was the decimal fraction, now called simply a decimal, in which the denominator is a power of ten, determined by the number of digits to the right of a decimal separator, the appearance of which (e.g., a period, a raised period (•), a comma) depends on the locale (for examples, see decimal separator). Thus for 0.75 the numerator is 75 and the denominator is 10 to the second power, viz. 100, because there are two digits to the right of the decimal separator.

A third kind of fraction still in common use is the percentage, in which the denominator is always 100. Thus 75% means 75/100.

Other uses for fractions are to represent ratios, and to represent division. Thus the fraction 3/4 is also used to represent the ratio 3:4 (three to four) and the division 3 ÷ 4 (three divided by four).

In mathematics, the set of all numbers which can be expressed as a fraction m/n, where m and n are integers and n is not zero, is called the set of rational numbers. This set is represented by the symbol Q.

Terminology

Historically, any number that did not represent a whole was called a "fraction". The numbers that we now call "decimals" were originally called "decimal fractions"; the numbers we now call "fractions" were called "vulgar fractions", the word "vulgar" meaning "commonplace".

The word is also used in related expressions, such as continued fraction and algebraic fraction—see Special cases below.

Writing fractions

A common or vulgar fraction is usually written as a quad of numbers, the top number called the numerator and the bottom number called the denominator. A line usually separates the numerator and denominator. If the line is slanting it is called a solidus or forward slash, for example 3/4. If the line is horizontal, it is called a vinculum or, informally, a "fraction bar", thus: ${\displaystyle {\tfrac {3}{4}}}$.

The solidus may be omitted from the slanting style (e.g. ³₄) where space is short and the meaning is obvious from context, for example in road signs in some countries.^{[citation needed]}

In computer displays and typography, simple fractions are sometimes printed as a single character, e.g. ½ (one half).

Scientific publishing distinguishes four ways to set fractions, together with guidelines on use:^[2]

• case fractions: ${\displaystyle {\tfrac {1}{2}}}$ – these are generally used only for simple fractions;
• special fractions: ½ – these are not generally used in formal scientific publishing, but are used in other contexts;
• shilling fractions: 1/2 – so called because this notation was used for pre-decimal British currency (£sd), as in 2/6 for a half crown, meaning two shillings and six pence. This setting is particularly recommended for fractions inline (rather than displayed), to avoid uneven lines, and for fractions within fractions (complex fractions) or within exponents to increase legibility.
• built-up fractions: ${\displaystyle {\frac {1}{2}}}$ – while large and legible, these can be disruptive, particularly for simple fractions, or within complex fractions.

Usage

Fractions are used most often when the denominator is relatively small. By mental calculation, it is easier to multiply 32 by 3⁄16 than to do the same calculation using the fraction's decimal equivalent (0.1875). It is also more accurate to multiply 15 by 1⁄3, for example, than it is to multiply 15 by a decimal approximation of one third.

To change a common fraction to a decimal, divide the numerator by the denominator, and round off to the desired accuracy. Conversely, a decimal fraction may be converted to a common fraction: if dealing with a finite number of digits, this is very easy; for example, 0.1875 may be expressed as ${\displaystyle {\tfrac {1875}{10000}}}$ (and subsequently simplified, if desired).

Forms of fractions

Vulgar, proper, and improper fractions

A vulgar fraction (or common fraction or simple fraction) is a rational number written as one integer (the numerator) divided by a non-zero integer (the denominator) such as ${\displaystyle {\tfrac {1}{6}}}$.

A vulgar fraction is said to be a proper fraction if the absolute value of the numerator is less than the absolute value of the denominator—that is, if the absolute value of the entire fraction is less than 1. A vulgar fraction is said to be an improper fraction (US, British or Australian) or top-heavy fraction (British, occasionally North America) if the absolute value of the numerator is greater than or equal to the absolute value of the denominator (e.g. ${\displaystyle {\tfrac {9}{4}}}$).^[3]

Mixed numbers

A mixed number is the sum of a whole number and a proper fraction. This sum is implied without the use of any visible operator such as "+"; for example, in referring to two entire cakes and three quarters of another cake, the whole and fractional parts of the number are written next to each other: ${\displaystyle 2+{\tfrac {3}{4}}=2{\tfrac {3}{4}}}$.

This is not to be confused with the algebra idea of implying multiplication by writing two quantities next to each other without a visible multiplication operator: ${\displaystyle a{\tfrac {b}{c}}={\tfrac {a\cdot b}{c}}}$. This "change of meaning" of juxtaposing two items is at least a partial reason why for math topics beyond the level of arithmetic, improper fractions are preferred.

An improper fraction can be thought of as another way to write a mixed number. A mixed number can be converted to an improper fraction in three steps:

1. Multiply the whole part by the denominator of the fractional part.
2. Add the numerator of the fractional part to that product.
3. The resulting sum is the numerator of the new (improper) fraction, with the 'new' denominator remaining precisely the same as for the original fractional part of the mixed number.

Similarly, an improper fraction can be converted to a mixed number:

1. Divide the numerator by the denominator.
2. The quotient (without remainder) becomes the whole part and the remainder becomes the numerator of the fractional part.
3. The new denominator is the same as that of the original improper fraction.

Equivalent fractions

Multiplying the numerator and denominator of a fraction by the same (non-zero) number, the results of the new fraction is said to be equivalent to the original fraction. The word equivalent means that the two fractions have the same value. That is, they retain the same integrity - the same balance or proportion. This is true because for any non-zero number ${\displaystyle n}$, ${\displaystyle {\tfrac {n}{n}}=1}$. Therefore, multiplying by ${\displaystyle {\tfrac {n}{n}}}$ is equivalent to multiplying by one, and any number multiplied by one has the same value as the original number. For instance, consider the fraction ${\displaystyle {\tfrac {1}{2}}}$: when the numerator and denominator are both multiplied by 2, the result is ${\displaystyle {\tfrac {2}{4}}}$, which has the same value (0.5) as ${\displaystyle {\tfrac {1}{2}}}$. To picture this visually, imagine cutting the example cake into four pieces; two of the pieces together (${\displaystyle {\tfrac {2}{4}}}$) make up half the cake (${\displaystyle {\tfrac {1}{2}}}$).

For example: ${\displaystyle {\tfrac {1}{3}}}$, ${\displaystyle {\tfrac {2}{6}}}$, ${\displaystyle {\tfrac {3}{9}}}$ and ${\displaystyle {\tfrac {100}{300}}}$ are all equivalent fractions.

Dividing the numerator and denominator of a fraction by the same non-zero number will also yield an equivalent fraction. This is called reducing or simplifying the fraction. A fraction in which the numerator and denominator are coprime [this means they have no factors in common (other than 1)] is said to be irreducible or in its lowest or simplest terms. For instance, ${\displaystyle {\tfrac {3}{9}}}$ is not in lowest terms because both 3 and 9 can be exactly divided by 3. In contrast, ${\displaystyle {\tfrac {3}{8}}}$ is in lowest terms—the only number that is a factor of both 3 and 8 is 1.

Any fraction can be fully reduced to its lowest terms by dividing both the numerator and denominator by their greatest common divisor. For example, the greatest common divisor of 63 and 462 is 21, therefore, the fraction ${\displaystyle {\tfrac {63}{462}}}$ can be fully reduced by dividing the numerator and denominator by 21:

${\displaystyle {\tfrac {63}{462}}={\tfrac {63\div 21}{462\div 21}}={\tfrac {3}{22}}}$

In order to find the greatest common divisor, the Euclidean algorithm may be used.

Reciprocals and the "invisible denominator"

The multiplicative inverse or reciprocal of a fraction is another fraction with the numerator and denominator reversed. The reciprocal of ${\displaystyle {\tfrac {3}{7}}}$, for instance, is ${\displaystyle {\tfrac {7}{3}}}$. Any integer can be written as a fraction with the number one as denominator. For example, 17 can be written as ${\displaystyle {\tfrac {17}{1}}}$, where 1 is sometimes referred to as the invisible denominator. Therefore, every fraction or integer except for zero has a reciprocal. The reciprocal of 17 is ${\displaystyle {\tfrac {1}{17}}}$.

Complex fractions

A complex fraction (or compound fraction) is a fraction in which the numerator or denominator contains a fraction. For example, ${\displaystyle {\cfrac {\tfrac {1}{2}}{\tfrac {1}{3}}}}$ and ${\displaystyle {\frac {12{\frac {3}{4}}}{26}}}$ are complex fractions. To simplify a complex fraction, divide the numerator by the denominator, as with any other fraction (see the section on division for more details):

${\displaystyle {\cfrac {\tfrac {1}{2}}{\tfrac {1}{3}}}={\tfrac {1}{2}}\times {\tfrac {3}{1}}={\tfrac {3}{2}}=1{\frac {1}{2}}.}$

${\displaystyle {\frac {12{\frac {3}{4}}}{26}}=12{\tfrac {3}{4}}\cdot {\tfrac {1}{26}}={\tfrac {12\cdot 4+3}{4}}\cdot {\tfrac {1}{26}}={\tfrac {51}{4}}\cdot {\tfrac {1}{26}}={\tfrac {51}{104}}}$

${\displaystyle {\cfrac {\tfrac {3}{2}}{5}}={\tfrac {3}{2}}\times {\tfrac {1}{5}}={\tfrac {3}{10}}.}$

${\displaystyle {\cfrac {8}{\tfrac {1}{3}}}=8\times {\tfrac {3}{1}}=24.}$

Arithmetic with fractions

Fractions, like whole numbers, obey the commutative, associative, and distributive laws, and the rule against division by zero.

Comparing fractions

Comparing fractions with the same denominator only requires comparing the numerators.

${\displaystyle {\tfrac {3}{4}}>{\tfrac {2}{4}}}$ because 3>2.

One way to compare fractions with different denominators is to find a common denominator. To compare ${\displaystyle {\tfrac {a}{b}}}$ and ${\displaystyle {\tfrac {c}{d}}}$, these are converted to ${\displaystyle {\tfrac {ad}{bd}}}$ and ${\displaystyle {\tfrac {bc}{bd}}}$. Then bd is a common denominator and the numerators ad and bc can be compared.

${\displaystyle {\tfrac {2}{3}}}$ ? ${\displaystyle {\tfrac {1}{2}}}$ gives ${\displaystyle {\tfrac {4}{6}}>{\tfrac {3}{6}}}$

As a short cut, known as "cross multiplying", you can just compare ad and bc, without computing the denominator.

${\displaystyle {\tfrac {5}{18}}}$ ? ${\displaystyle {\tfrac {4}{17}}}$

Multiply 17 by 5 and multiply 18 by 4. Since 85 is greater than 72, ${\displaystyle {\tfrac {5}{18}}>{\tfrac {4}{17}}}$.

Another method of comparing fractions is this: if two fractions have the same numerator, then the fraction with the smaller denominator is the larger fraction. The reasoning is that since, in the first fraction, fewer equal pieces are needed to make up a whole, each piece must be larger.

Also note that every negative number, including negative fractions, is less than zero, and every positive number, including positive fractions, is greater than zero, so every negative fraction is less than any positive fraction.

Addition

The first rule of addition is that only like quantities can be added; for example, various quantities of quarters. Unlike quantities, such as adding thirds to quarters, must first be converted to like quantities as described below: Imagine a pocket containing two quarters, and another pocket containing three quarters; in total, there are five quarters. Since four quarters is equivalent to one (dollar), this can be represented as follows:

${\displaystyle {\tfrac {2}{4}}+{\tfrac {3}{4}}={\tfrac {5}{4}}=1{\tfrac {1}{4}}}$.

If ${\displaystyle {\tfrac {1}{2}}}$ of a cake is to be added to ${\displaystyle {\tfrac {1}{4}}}$ of a cake, the pieces need to be converted into comparable quantities, such as cake-eighths or cake-quarters.

Adding unlike quantities

To add fractions containing unlike quantities (e.g. quarters and thirds), it is necessary to convert all amounts to like quantities. It is easy to work out the chosen type of fraction to convert to; simply multiply together the two denominators (bottom number) of each fraction.

For adding quarters to thirds, both types of fraction are converted to ${\displaystyle {\tfrac {1}{4}}\times {\tfrac {1}{3}}={\tfrac {1}{12}}}$ (twelfths).

Consider adding the following two quantities:

${\displaystyle {\tfrac {3}{4}}+{\tfrac {2}{3}}}$

First, convert ${\displaystyle {\tfrac {3}{4}}}$ into twelfths by multiplying both the numerator and denominator by three: ${\displaystyle {\tfrac {3}{4}}\times {\tfrac {3}{3}}={\tfrac {9}{12}}}$. Note that ${\displaystyle {\tfrac {3}{3}}}$ is equivalent to 1, which shows that ${\displaystyle {\tfrac {3}{4}}}$ is equivalent to the resulting ${\displaystyle {\tfrac {9}{12}}}$.

Secondly, convert ${\displaystyle {\tfrac {2}{3}}}$ into twelfths by multiplying both the numerator and denominator by four: ${\displaystyle {\tfrac {2}{3}}\times {\tfrac {4}{4}}={\tfrac {8}{12}}}$. Note that ${\displaystyle {\tfrac {4}{4}}}$ is equivalent to 1, which shows that ${\displaystyle {\tfrac {2}{3}}}$ is equivalent to the resulting ${\displaystyle {\tfrac {8}{12}}}$.

Now it can be seen that:

${\displaystyle {\tfrac {3}{4}}+{\tfrac {2}{3}}}$

is equivalent to:

${\displaystyle {\tfrac {9}{12}}+{\tfrac {8}{12}}={\tfrac {17}{12}}=1{\tfrac {5}{12}}}$

This method can be expressed algebraically:

${\displaystyle {\tfrac {a}{b}}+{\tfrac {c}{d}}={\tfrac {ad+cb}{bd}}}$

And for expressions consisting of the addition of three fractions:

${\displaystyle {\tfrac {a}{b}}+{\tfrac {c}{d}}+{\tfrac {e}{f}}={\tfrac {a(df)+c(bf)+e(bd)}{bdf}}}$

This method always works, but sometimes there is a smaller denominator that can be used (a least common denominator). For example, to add ${\displaystyle {\tfrac {3}{4}}}$ and ${\displaystyle {\tfrac {5}{12}}}$ the denominator 48 can be used (the product of 4 and 12), but the smaller denominator 12 may also be used, being the least common multiple of 4 and 12.

${\displaystyle {\tfrac {3}{4}}+{\tfrac {5}{12}}={\tfrac {9}{12}}+{\tfrac {5}{12}}={\tfrac {14}{12}}={\tfrac {7}{6}}=1{\tfrac {1}{6}}}$

Subtraction

The process for subtracting fractions is, in essence, the same as that of adding them: find a common denominator, and change each fraction to an equivalent fraction with the chosen common denominator. The resulting fraction will have that denominator, and its numerator will be the result of subtracting the numerators of the original fractions. For instance,

${\displaystyle {\tfrac {2}{3}}-{\tfrac {1}{2}}={\tfrac {4}{6}}-{\tfrac {3}{6}}={\tfrac {1}{6}}}$

Multiplication

Multiplying a fraction by another fraction

To multiply fractions, multiply the numerators and multiply the denominators. Thus:

${\displaystyle \textstyle {2 \over 3}\times {3 \over 4}={6 \over 12}\,\!}$

Why does this work? First, consider one third of one quarter. Using the example of a cake, if three small slices of equal size make up a quarter, and four quarters make up a whole, twelve of these small, equal slices make up a whole. Therefore a third of a quarter is a twelfth. Now consider the numerators. The first fraction, two thirds, is twice as large as one third. Since one third of a quarter is one twelfth, two thirds of a quarter is two twelfth. The second fraction, three quarters, is three times as large as one quarter, so two thirds of three quarters is three times as large as two thirds of one quarter. Thus two thirds times three quarters is six twelfths.

A short cut for multiplying fractions is called "cancellation". In effect, we reduce the answer to lowest terms during multiplication. For example:

${\displaystyle \textstyle {2 \over 3}\times {3 \over 4}={{\cancel {2}}^{~1} \over {\cancel {3}}^{~1}}\times {{\cancel {3}}^{~1} \over {\cancel {4}}^{~2}}={1 \over 1}\times {1 \over 2}={1 \over 2}\,\!}$

A two is a common factor in both the numerator of the left fraction and the denominator of the right and is divided out of both. Three is a common factor of the left denominator and right numerator and is divided out of both.

Multiplying a fraction by a whole number

Place the whole number over one and multiply.

${\displaystyle \textstyle 6\times {3 \over 4}={6 \over 1}\times {3 \over 4}={18 \over 4}\,\!}$

This method works because the fraction 6/1 means six equal parts, each one of which is a whole.

Mixed numbers

When multiplying mixed numbers, it's best to convert the mixed number into an improper fraction. For example:

${\displaystyle \textstyle {3\times 2{3 \over 4}=3\times \left({{8 \over 4}+{3 \over 4}}\right)=3\times {11 \over 4}={33 \over 4}=8{1 \over 4}}\,\!}$

In other words, ${\displaystyle \textstyle {2{3 \over 4}}}$ is the same as ${\displaystyle \textstyle {({8 \over 4}+{3 \over 4})}}$, making 11 quarters in total (because 2 cakes, each split into quarters makes 8 quarters total) and 33 quarters is ${\displaystyle \textstyle {8{1 \over 4}}}$, since 8 cakes, each made of quarters, is 32 quarters in total.

Division

Division by a fraction is done by multiplying the dividend by the reciprocal of the divisor, in accordance with the identity

${\displaystyle m\div {\frac {a}{b}}=m\times {\frac {b}{a}}.}$

A proof for the identity, from fundamental principles, can be given as follows:

${\displaystyle m\;\div \;{\frac {a}{b}}={\frac {m}{\frac {a}{b}}}=m\;\times \;{\frac {1}{\frac {a}{b}}}=m\;\times \;\left({\frac {a}{b}}\right)^{-1}=m\;\times \;{\frac {\frac {1}{a}}{\frac {1}{b}}}=m\;\times \;{\frac {1}{a}}\;\times \;{\frac {1}{\frac {1}{b}}}=m\;\times \;{\frac {1}{a}}\;\times \;b=m\;\times \;{\frac {b}{a}}.}$

An algebraic proof is as follows. Set x equal to the quotient we are looking for (m ÷ a/b). By the definition of division, this means we are looking for the number x such that:

${\displaystyle x\times {\frac {a}{b}}=m}$

Multiply both sides of this equation by ${\displaystyle {\frac {b}{a}}}$:

${\displaystyle x\times {\frac {a}{b}}\times {\frac {b}{a}}=m\times {\frac {b}{a}}}$

${\displaystyle x\times 1=m\times {\frac {b}{a}}}$

${\displaystyle x=m\times {\frac {b}{a}}}$

About 4,000 years ago Egyptians divided with fractions using slightly different methods. They used least common multiples with unit fractions. Their methods gave the same answer that our modern methods give.^[4]

Converting repeating decimals to fractions

See also: Repeating decimal

Decimal numbers, while arguably more useful to work with when performing calculations, lack the same kind of precision that regular fractions (as they are explained in this article) have. Sometimes an infinite number of decimals is required to convey the same kind of precision. Thus, it is often useful to convert repeating decimals into fractions.

For repeating patterns where the repeating pattern begins immediately after the decimal point, a simple division of the pattern by the same number of nines as numbers it has will suffice. For example (the pattern is highlighted in bold):

0.555555555555… = 5/9

0.626262626262… = 62/99

0.264264264264… = 264/999

0.629162916291… = 6291/9999

In case zeros precede the pattern, the nines are suffixed by the same number of zeros:

0.0555… = 5/90

0.000392392392… = 392/999000

0.00121212… = 12/9900

In case a non-repeating set of decimals precede the pattern (such as 0.1523987987987…), we must equate it as the sum of the non-repeating and repeating parts:

0.1523 + 0.0000987987987…

Then, convert both of these to fractions. Since the first part is not repeating, it is not converted according to the pattern given above:

1523/10000 + 987/9990000

We add these fractions by expressing both with a common divisor...

1521477/9990000 + 987/9990000

And add them.

1522464/9990000

Finally, we simplify it:

31718/208125

Rationalization

Main article: Rationalisation (mathematics)

A fraction may need to be rationalized if the denominator contains irrational numbers, imaginary numbers or complex numbers, in order to make it easier to work with. When the denominator is a monomial square root, it can be rationalized by multiplying top and the bottom of the fraction by the denominator:

${\displaystyle {\frac {3}{\sqrt {7}}}={\frac {3}{\sqrt {7}}}\cdot {\frac {\sqrt {7}}{\sqrt {7}}}={\frac {3{\sqrt {7}}}{7}}}$

The process of rationalization of binomial involves multiplying the top and the bottom of a fraction by the conjugate of the denominator so that the denominator becomes a rational number. For example:

${\displaystyle {\frac {3}{3-2{\sqrt {5}}}}={\frac {3}{3-2{\sqrt {5}}}}\cdot {\frac {3+2{\sqrt {5}}}{3+2{\sqrt {5}}}}={\frac {3(3+2{\sqrt {5}})}{{3}^{2}-(2{\sqrt {5}})^{2}}}={\frac {3(3+2{\sqrt {5}})}{9-20}}=-{\frac {9+6{\sqrt {5}}}{11}}}$

${\displaystyle {\frac {3}{3+2{\sqrt {5}}}}={\frac {3}{3+2{\sqrt {5}}}}\cdot {\frac {3-2{\sqrt {5}}}{3-2{\sqrt {5}}}}={\frac {3(3-2{\sqrt {5}})}{{3}^{2}-(2{\sqrt {5}})^{2}}}={\frac {3(3-2{\sqrt {5}})}{9-20}}=-{\frac {9-6{\sqrt {5}}}{11}}}$

${\displaystyle {\frac {3+i}{2-2\cdot i}}={\frac {3+i}{2-2\cdot i}}\cdot {\frac {2+2\cdot i}{2+2\cdot i}}={\frac {3+i}{2-2\cdot i}}\cdot {\frac {2+2\cdot i}{2+2\cdot i}}={\frac {6+2\cdot i+6\cdot i-2}{4+4}}={\frac {4+8i}{8}}={\frac {1}{2}}+i}$

Even if this process results in the numerator being irrational or complex, like in the examples above, the process may still facilitate subsequent manipulations by reducing the number of irrationals one has to work with in the denominator, or by making the denominator real in the case of a complex expression.

Special cases

A unit fraction is a vulgar fraction with a numerator of 1, e.g. ${\displaystyle {\tfrac {1}{7}}}$.

An Egyptian fraction is the sum of distinct unit fractions, e.g. ${\displaystyle {\tfrac {1}{2}}+{\tfrac {1}{3}}}$. This term derives from the fact that the ancient Egyptians expressed all fractions except ${\displaystyle {\tfrac {1}{2}}}$, ${\displaystyle {\tfrac {2}{3}}}$ and ${\displaystyle {\tfrac {3}{4}}}$ in this manner.

A dyadic fraction is a vulgar fraction in which the denominator is a power of two, e.g. ${\displaystyle {\tfrac {1}{8}}}$.

An expression that has the form of a fraction but actually represents division by or into an irrational number is sometimes called an "irrational fraction". A common example is ${\displaystyle \textstyle {\frac {\pi }{2}}}$, the radian measure of a right angle.

Rational numbers are the quotient field of integers. Rational functions are functions evaluated in the form of a fraction, where the numerator and denominator are polynomials. These rational expressions are the quotient field of the polynomials (over some integral domain).

A continued fraction is an expression such as

${\displaystyle a_{0}+{\cfrac {1}{a_{1}+{\cfrac {1}{a_{2}+\ddots }}}},}$

where the a_i are integers. This is not an element of a quotient field.

The term partial fraction is used in algebra, when decomposing rational expressions (a fraction with an algebraic expression in the denominator). The goal is to write the rational expression as the sum of other rational expressions with denominators of lesser degree. For example, the rational expression ${\displaystyle \textstyle {2x \over x^{2}-1}}$ can be rewritten as the sum of two fractions: ${\displaystyle \textstyle {1 \over x+1}}$ and ${\displaystyle \textstyle {1 \over x-1}}$. This is useful for calculating certain integrals in calculus.

Pedagogical tools

In primary schools, fractions have been demonstrated through Cuisenaire rods, fraction bars, fraction strips, fraction circles, paper (for folding or cutting), pattern blocks, pie-shaped pieces, plastic rectangles, grid paper, dot paper, geoboards, counters and computer software.

History

See also: History of irrational numbers

The Egyptians used Egyptian fractions ca. 1000 BC. The Greeks used unit fractions and later continued fractions and followers of the Greek philosopher Pythagoras, ca. 530 BC, discovered that the square root of two cannot be expressed as a fraction. In 150 BC Jain mathematicians in India wrote the "Sthananga Sutra", which contains work on the theory of numbers, arithmetical operations, operations with fractions.

In Sanskrit literature, fractions, or rational numbers were always expressed by an integer followed by a fraction. When the integer is written on a line, the fraction is placed below it and is itself written on two lines, the numerator called amsa part on the first line, the denominator called cheda “divisor” on the second below. If the fraction is written without any particular additional sign, one understands that it is added to the integer above it. If it is marked by a small circle or a cross (the shape of the “plus” sign in the West) placed on its right, one understands that it is subtracted from the integer. For example, Bhaskara I writes^[5]

६   १   २
१   १   १०
४   ५   ९

That is,

6   1   2
1   1   1०
4   5   9

to denote 6+1/4, 1+1/5, and 2–1/9

Al-Hassār, a Muslim mathematician from Fez, Morocco specializing in Islamic inheritance jurisprudence during the 12th century, developed the modern symbolic mathematical notation for fractions, where the numerator and denominator are separated by a horizontal bar.^{[citation needed]} This same fractional notation appears soon after in the work of Leonardo Fibonacci in the 13th century.^{[citation needed]}

In discussing the origins of decimal fractions, Dirk Jan Struik states that (p. 7):^[6]

"The introduction of decimal fractions as a common computational practice can be dated back to the Flemish pamphlet De Thiende, published at Leyden in 1585, together with a French translation, La Disme, by the Flemish mathematician Simon Stevin (1548-1620), then settled in the Northern Netherlands. It is true that decimal fractions were used by the Chinese many centuries before Stevin and that the Persian astronomer Al-Kāshī used both decimal and sexagesimal fractions with great ease in his Key to arithmetic (Samarkand, early fifteenth century).^[7]"

While the Persian mathematician Jamshīd al-Kāshī claimed to have discovered decimal fractions himself in the 15th century, J. Lennart Berggren notes that he was mistaken, as decimal fractions were first used five centuries before him by the Baghdadi mathematician Abu'l-Hasan al-Uqlidisi as early as the 10th century.^{[8][verification needed]}

See also

• Rational number

References

1. Eves, Howard Eves ; with cultural connections by Jamie H. (1990). An introduction to the history of mathematics (6th ed. ed.). Philadelphia: Saunders College Pub. ISBN 0030295580. {{cite book}}: |edition= has extra text (help)
2. Galen, Leslie Blackwell (2004), "Putting Fractions in Their Place" (PDF), American Mathematical Monthly, 111 (3) {{citation}}: Unknown parameter |month= ignored (help)
3. World Wide Words: Vulgar fractions
4. Milo Gardner (December 19, 2005). "Math History". Retrieved 2006-01-18. See for examples and an explanation.
5. (Filliozat 2004, p. 152)
6. D.J. Struik, A Source Book in Mathematics 1200-1800 (Princeton University Press, New Jersey, 1986). ISBN 0-691-02397-2
7. P. Luckey, Die Rechenkunst bei Ğamšīd b. Mas'ūd al-Kāšī (Steiner, Wiesbaden, 1951).
8. Berggren, J. Lennart (2007). "Mathematics in Medieval Islam". The Mathematics of Egypt, Mesopotamia, China, India, and Islam: A Sourcebook. Princeton University Press. p. 518. ISBN 9780691114859.