Fractions

For each fraction there are many (infinitely many) different representations , different fractions , all of which represent the same value (the same quantity ), but in different ways. One can get from one fraction to another by expanding and shortening . This does not change the value of a fraction, but you get different ways of representing this number: different fractions.

Definition and terms

Fractions can initially be divided into common fractions (also called ordinary fractions ) and decimal fractions (= decimal number, colloquially: "point number"), and there is also the representation as a mixed fraction. When one speaks of a fraction, one usually means a common fraction, calculating with decimal fractions is usually not called a fraction calculation.

The table below summarizes the common fractions used and explained in this section. The terms in the table below each fall under the generic terms above, for example every pseudo fraction is a common fraction, adjacent terms need not be mutually exclusive. Please note that these are designations for number spellings and not for the numbers shown. A certain number can have different representations, each of which is identified with different terms from the table. For example, you can write every improper fraction as a mixed fraction.

Other forms in which fractions can be displayed ( continued fraction , percentage and per thousand notation , binary fractions , etc.) are dealt with in each separate articles and not included in this table.

Common fractions

Description of a common fraction

Common fractions are generally represented by superimposing the numerator and denominator , separated by a horizontal line:

${\ displaystyle {\ frac {Z} {N}}}$

${\ displaystyle Z: N = {\ frac {Z} {N}}}$

The decisive factor in fractions is that every division (except by zero) is possible and has a result that can be easily represented, while the rules of divisibility apply to whole numbers .

In a variant of this notation, which is often used when common fractions occur in texts, the numerator, fraction line and denominator are written one after the other and a slash is used as the fraction line , for example 1/2, 3/8. In the notation slash in place of the horizontal fraction bar are (especially) digit numerator and denominator sometimes reduced over or written under the slash: ⁶ / ₇ . For this purpose, there are special characters in many printing character sets, such as or ½.

Real and spurious fractions

So real fractions are those whose amount is smaller than a whole.

Trunk breaks and branch breaks

Pseudo breaks

Mixed fractions

Improper fractions that are not pseudo-fractions can always be represented as mixed fractions (also: as mixed numbers, in mixed notation).

First of all, the whole number part, i.e. H. the number rounded to zero, written and then immediately afterwards the remaining portion as a real fraction. For example instead of or instead of . ${\ displaystyle 1 {\ tfrac {1} {3}}}$${\ displaystyle {\ tfrac {4} {3}}}$${\ displaystyle -3 {\ tfrac {3} {5}}}$${\ displaystyle - {\ tfrac {18} {5}}}$

One problem with mixed spelling is that it can be misunderstood as a product:

So mostly stands for and not for . ${\ displaystyle 2 {\ tfrac {1} {3}}}$${\ displaystyle 2 + {\ tfrac {1} {3}} = {\ tfrac {7} {3}}}$${\ displaystyle 2 \ cdot {\ tfrac {1} {3}} = {\ tfrac {2} {3}}}$

Calculation rules

Practical arithmetic with fractions

When calculating with fractions in the four basic arithmetic operations of addition , subtraction , multiplication and division , two fractions are linked to create a third number. This must not be confused with reshaping fractions, whereby a single fraction is given a new shape without changing its value.

The forming (the change in shape) is often the prerequisite for fractures to be expected. So it will be dealt with here first.

Change in shape of fractures

Convert to a decimal number

To convert a fraction to a decimal, simply divide the numerator by the denominator. gives 0.75 or 75% of the whole. ${\ displaystyle {\ tfrac {3} {4}}}$

Expand and shorten

The value of the fraction represented by a fraction does not change if you multiply the numerator and denominator of the fraction by the same number (not equal to 0) ( expand the fraction ) or divide the fraction by a common factor of the numerator and denominator ( shorten the fraction ).

Example: . Read from left to right the fraction has been expanded, and from right to left shortened. ${\ displaystyle {\ tfrac {2} {3}} = {\ tfrac {2 \ cdot 3} {3 \ cdot 3}} = {\ tfrac {6} {9}}}$

Set up mixed numbers and split off whole ones

The value of a fraction shown in mixed notation does not change if the integer part is written as a dummy fraction with the denominator of the fraction and the remaining fractions are added. Conversely, with an improper fraction, you can split off the fractions that make up the whole and add the remaining fractions.

Example: . Whole numbers were split off from left to right, and mixed numbers were set up from right to left. ${\ displaystyle {\ tfrac {8} {3}} = {\ tfrac {6} {3}} + {\ tfrac {2} {3}} = 2 + {\ tfrac {2} {3}} = 2 {\ tfrac {2} {3}}}$

Make fractions with the same name

Common fractions that have the same denominator have the same name . If fractions are expanded in such a way that they then have the same denominator, this is called making the same name . In practical arithmetic, the main denominator of the fractions should be determined, which is the lowest common multiple (lcm) of the denominator.

Example: The fractions should have the same name. The LCM is the denominator , so all three fractions are expanded so that their denominator is 42: ${\ displaystyle {\ tfrac {2} {7}}; {\ tfrac {1} {6}}; {\ tfrac {9} {14}}}$${\ displaystyle 2 \ times 3 \ times 7 = 42}$

${\ displaystyle {\ tfrac {2} {7}} = {\ tfrac {2 \ cdot 6} {42}} = {\ tfrac {12} {42}}; \ quad {\ tfrac {1} {6} } = {\ tfrac {1 \ cdot 7} {42}} = {\ tfrac {7} {42}}; \ quad {\ tfrac {9} {14}} = {\ tfrac {9 \ cdot 3} { 42}} = {\ tfrac {27} {42}}}$.

The representations of the same name can now be used, for example, to order the displayed fractions according to size by comparing their counters:

${\ displaystyle {\ tfrac {7} {42}} <{\ tfrac {12} {42}} <{\ tfrac {27} {42}} \; \;}$, so must apply.${\ displaystyle \; \; {\ tfrac {1} {6}} <{\ tfrac {2} {7}} <{\ tfrac {9} {14}} \;}$

The basic arithmetic

Add and subtract

The fractions that are to be added or subtracted are first given the same name, then their counters are added or subtracted.

Example: . ${\ displaystyle {\ tfrac {1} {6}} + {\ tfrac {2} {15}} = {\ tfrac {5} {30}} + {\ tfrac {4} {30}} = {\ tfrac {9} {30}} = {\ tfrac {3} {10}}}$

Multiply

Fractions are multiplied by multiplying their numerators and denominators together. The product of the numerator is then the numerator of the result, the product of the denominator is then the denominator of the result.

Example: . ${\ displaystyle {\ tfrac {2} {3}} \ cdot {\ tfrac {9} {14}} = {\ tfrac {2 \ cdot 9} {3 \ cdot 14}} = {\ tfrac {3} { 7}}}$

To divide

A fraction is divided by multiplying by its reciprocal .

Example: . ${\ displaystyle {\ tfrac {2} {15}}: {\ tfrac {14} {27}} = {\ tfrac {2} {15}} \ cdot {\ tfrac {27} {14}} = {\ tfrac {2} {3 \ cdot 5}} \ cdot {\ tfrac {3 \ cdot 9} {2 \ cdot 7}} = {\ tfrac {1 \ cdot 9} {5 \ cdot 7}} = {\ tfrac {9} {35}}}$

As shown in the example, intermediate results can be shortened (here for example the 3 and 2 in the penultimate step).

Doing math with mixed fractions

When multiplying or dividing mixed fractions, it is usually necessary to first convert them to ordinary fractions. (Except for very simple tasks, such as .) ${\ displaystyle 6 {\ tfrac {1} {3}}: 2 = 3 {\ tfrac {1} {6}}}$

When adding and subtracting, on the other hand, it is much cheaper to look at the whole thing in isolation and only use fractions for the remaining real fractions. When adding, an additional whole can appear here, when subtracting the fractions may not be sufficient, so that one of the whole has to be split up to form an apparent fraction:

${\ displaystyle 13 {\ tfrac {3} {4}} + 27 {\ tfrac {1} {2}} = 40+ \ left ({\ tfrac {3} {4}} + {\ tfrac {1} { 2}} \ right) = 40 + 1 {\ tfrac {1} {4}} = 41 {\ tfrac {1} {4}}}$;

${\ displaystyle 16 {\ tfrac {1} {3}} - 9 {\ tfrac {1} {2}} = 7+ \ left ({\ tfrac {1} {3}} - {\ tfrac {1} { 2}} \ right) = 7 + \ left ({\ tfrac {2} {6}} - {\ tfrac {3} {6}} \ right) = 6 + \ left ({\ tfrac {6} {6 }} + {\ tfrac {2} {6}} - {\ tfrac {3} {6}} \ right) = 6 {\ tfrac {5} {6}}}$.

Abstract rules of calculation

The following rules apply to both fractions in the narrower sense and when calculating with fraction terms. When calculating with fractions, the variables in the rules represent certain whole numbers. If you instead use other expressions for these variables, e.g. If, for example, you enter real fractions, decimal fractions or terms yourself, then you get rules for calculating with fraction terms, fractions in the broader sense. ${\ displaystyle a, \; b, \; c, \; d, \; n \;}$

When calculating with fractions, the abstract calculation rules always provide correct results, and the calculation with the “practical calculation rules” is often less time-consuming.

Expand and shorten

Shorten ${\ displaystyle \ rightarrow}$
${\ displaystyle {\ frac {a \ cdot c} {b \ cdot c}} = {\ frac {a} {b}}}$
${\ displaystyle \ leftarrow}$ Expand

Helpful donkey bridges are:

• Cut factors, that's good; whoever cuts sums is a sheep.
• Differences and sums only cut the stupid.
• What you do above, you do below!

From the equivalence for any natural numbers it follows that every rational number can be represented by an infinite number of different fractions, because it holds . ${\ displaystyle {\ frac {a} {b}} = {\ frac {a \ cdot c} {b \ cdot c}}}$${\ displaystyle c> 0}$${\ displaystyle {\ frac {a} {b}} = {\ frac {2a} {2b}} = {\ frac {3a} {3b}} = {\ frac {4a} {4b}} = \ dotsb}$

addition

${\ displaystyle {\ frac {a} {b}} \; + \; {\ frac {c} {d}} \; = \; {\ frac {a \ cdot d + c \ cdot b} {b \ cdot d}}}$

subtraction

${\ displaystyle {\ frac {a} {b}} - {\ frac {c} {d}} \; = \; {\ frac {a \ cdot dc \ cdot b} {b \ cdot d}}}$

multiplication

${\ displaystyle {\ frac {a} {b}} \; \ cdot \; {\ frac {c} {d}} \; = \; {\ frac {a \ cdot c} {b \ cdot d}} }$

${\ displaystyle {\ frac {a} {b}} \; \ cdot \; n \; = \; {\ frac {a \ cdot n} {b}}}$

division

Example of division by a fraction

${\ displaystyle {\ frac {a} {b}}: {\ frac {c} {d}} \; = \; {\ frac {a} {b}} \; \ cdot \; {\ frac {d } {c}} \; = \; {\ frac {a \ cdot d} {b \ cdot c}}}$

So you divide by a fraction by multiplying by the reciprocal of the fraction, which acts as a divisor . The division is therefore reduced to the multiplication.

${\ displaystyle {\ frac {a} {b}}: n \; = \; {\ frac {a} {b \ cdot n}} \ quad {\ text {and}} \ quad n: {\ frac { a} {b}} \; = \; {\ frac {n \ cdot b} {a}}}$

Potencies

rule	example
${\ displaystyle {\ frac {a ^ {n}} {b ^ {m}}} = a ^ {n} \ cdot b ^ {- m}}$	${\ displaystyle {\ frac {3} {2}} = 3 \ cdot 2 ^ {- 1}}$
${\ displaystyle {\ frac {a ^ {n}} {a ^ {m}}} = a ^ {nm}}$	${\ displaystyle {\ frac {a ^ {3}} {a ^ {2}}} = a ^ {3} \ cdot a ^ {- 2} = a ^ {3-2} = a}$
${\ displaystyle {\ frac {a ^ {n}} {b ^ {n}}} = \ left ({\ frac {a} {b}} \ right) ^ {n}}$	${\ displaystyle {\ frac {3 ^ {2}} {2 ^ {2}}} = \ left ({\ frac {3} {2}} \ right) ^ {2}}$

Calculating with fraction terms

Fractional terms, i.e. arithmetic expressions in the form of common fractions, play an important role in elementary algebra. Generally fraction Terme also contain numbers next variables . The calculation rules for fractions can also be applied to fraction terms.

Domain of definition

Example: has the domain of definition . ${\ displaystyle {\ tfrac {x} {x ^ {2} -9}} = {\ tfrac {x} {(x + 3) (x-3)}}}$${\ displaystyle D = \ mathbb {R} \ setminus \ {- 3; +3 \}}$

Shorten

Shortening means that you divide the numerator and denominator by the same arithmetic expression. It is important that only factors of products can be removed. Sums and differences in the numerator and denominator may first have to be broken down into products ( factorization ).

Examples:

1. ${\ displaystyle \ quad {\ frac {4abc ^ {3}} {6a ^ {2} bc}} = {\ frac {2c ^ {2}} {3a}}}$
2. ${\ displaystyle \ quad {\ frac {x ^ {2} -6xy + 9y ^ {2}} {2x-6y}} = {\ frac {(x-3y) ^ {2}} {2 (x-3y )}} = {\ frac {x-3y} {2}}}$

If a fraction term is shortened, the definition range can change! In the first example, the unabridged term on the left is only defined if it applies, the one on the right is already defined if only applies. In the second example, the unabridged term is only defined if the abbreviated term is defined without restrictions. ${\ displaystyle a, b, c \ neq 0}$${\ displaystyle a \ neq 0}$${\ displaystyle x \ neq 3y}$

Addition and subtraction

As with numbers, it is necessary to give the given fraction terms the same name, i.e. H. to bring to the same denominator. The simplest possible common denominator (main denominator) is determined, which is divisible by all given denominators.

Example:

${\ displaystyle {\ frac {3} {2a ^ {2}}} - {\ frac {4ab-1} {2ab}} + 2}$

The main denominator is . The expansion factors of the three given fraction terms are obtained by dividing the main denominator found by the previous denominator. So the expansion factors are , and . ${\ displaystyle 2a ^ {2} b}$${\ displaystyle b}$${\ displaystyle a}$${\ displaystyle 2a ^ {2} b}$

${\ displaystyle {\ frac {3} {2a ^ {2}}} - {\ frac {4ab-1} {2ab}} + 2}$

${\ displaystyle = {\ frac {3 \ cdot b- (4ab-1) \ cdot a + 2 \ cdot 2a ^ {2} b} {2a ^ {2} b}}}$

${\ displaystyle = {\ frac {3b-4a ^ {2} b + a + 4a ^ {2} b} {2a ^ {2} b}} = {\ frac {3b + a} {2a ^ {2} b}}}$

Example:

${\ displaystyle {\ frac {x} {x ^ {2} -xy}} - {\ frac {y} {x ^ {2} + xy}} - {\ frac {x} {x ^ {2} - y ^ {2}}}}$

${\ displaystyle = {\ frac {x} {x (xy)}} - {\ frac {y} {x (x + y)}} - {\ frac {x} {(x + y) (xy)} }}$

${\ displaystyle = {\ frac {x \ cdot (x + y) -y \ cdot (xy) -x \ cdot x} {x (x + y) (xy)}}}$

${\ displaystyle = {\ frac {x ^ {2} + xy-xy + y ^ {2} -x ^ {2}} {x (x + y) (xy)}} = {\ frac {y ^ { 2}} {x (x + y) (xy)}}}$

Multiplication and division

When multiplying fraction terms, both the numerators and denominators must be multiplied. Common numerator and denominator factors should be truncated.

Example: ${\ displaystyle {\ frac {4xy} {z ^ {2}}} \ cdot {\ frac {xz} {6y}} = {\ frac {4x ^ {2} yz} {6yz ^ {2}}} = {\ frac {2x ^ {2}} {3z}}}$

In more complicated tasks, the numerator and denominator should be broken down into factors in order to be able to remove them before the actual multiplication.

Example: ${\ displaystyle {\ frac {a-2b} {4a + 1}} \ cdot {\ frac {16a ^ {2} -1} {a ^ {2} -4ab + 4b ^ {2}}} = {\ frac {a-2b} {4a + 1}} \ cdot {\ frac {(4a + 1) (4a-1)} {(a-2b) ^ {2}}} = {\ frac {4a-1} {a-2b}}}$

The division of fraction terms can be reduced to multiplication. You divide by a fraction term by multiplying by its reciprocal .

Example: ${\ displaystyle {\ frac {2x-3} {5x}}: {\ frac {4x ^ {2} -9} {10x ^ {2}}} = {\ frac {2x-3} {5x}} \ cdot {\ frac {10x ^ {2}} {(2x + 3) (2x-3)}} = {\ frac {2x} {2x + 3}}}$

Other forms of representation

Partial fractions

Fractions can often be broken down into so-called partial fractions , the denominators of which are whole powers of prime numbers ; z. B .:

${\ displaystyle {\ frac {5} {6}} = {\ frac {1} {2}} + {\ frac {1} {3}},}$

${\ displaystyle {\ frac {1} {6}} = {\ frac {1} {2}} - {\ frac {1} {3}}, \,}$

${\ displaystyle {\ frac {1} {72}} = {\ frac {1} {8}} - {\ frac {1} {9}},}$

${\ displaystyle {\ frac {1} {60}} = {\ frac {-1} {4}} - {\ frac {4} {3}} + {\ frac {8} {5}}.}$

Egyptian fractions

There are also decompositions as so-called Egyptian fractions ( stem fractions ), e.g. B.

${\ displaystyle {\ frac {3} {7}} = {\ frac {1} {3}} + {\ frac {1} {11}} + {\ frac {1} {231}}}$ and

${\ displaystyle {\ frac {25} {31}} = {\ frac {1} {2}} + {\ frac {1} {4}} + {\ frac {1} {18}} + {\ frac {1} {1116}}}$,

the ancient Egyptians only knew and calculated such sums.

Pythagorean fractions

${\ displaystyle \ left ({\ frac {1} {5}} \ right) ^ {2} + \ left ({\ frac {24} {35}} \ right) ^ {2} = \ left ({\ frac {5} {7}} \ right) ^ {2}}$.

Rational numerator or denominator

See rationalization (fractions) .

Generalizations

The construction of the field of rational numbers as fractions from the ring of whole numbers is generalized in abstract algebra by the concept of the quotient field to any integrity rings.

See also

• Farey episode
• Cross multiplication

literature

• Erhard Cramer, Johanna Nešlehová: preliminary course in mathematics . Workbook for the start of studies in bachelor's degree programs. 3rd, verb. Edition. Springer, Berlin / Heidelberg 2008, ISBN 978-3-540-78180-6 , pp. 77–83 (( limited online copy in Google Book Search - USA )). 
• Friedhelm Padberg: Common Fractions - Decimal Fractions . Fractional Calculation Didactics. BI-Wissenschafts-Verlag, 1989, ISBN 3-411-03207-3 . 

Web links

Individual evidence

1. ↑ Official spelling rules of August 1, 2006, §106, Canoonet