Decimal system

Decimal place value system

Digits

0 (zero) , 1 (one) , 2 (two) , 3 (three) , 4 (four) , 5 (five) , 6 (six) , 7 (seven) , 8 (eight) , 9 (nine) ,

which are called decimal digits .

However, these digits are spelled differently in different parts of the world.

Indian numerals are still used today in the various Indian scripts ( Devanagari , Bengali script , Tamil script , etc.). They are very different from each other.

definition

In German-speaking countries, a decimal number is usually in the form

${\ displaystyle z_ {m} \, z_ {m-1} \, \ ldots \, z_ {0} \, \ operatorname {,} \, z _ {- 1} \, z _ {- 2} \, \ ldots \, z _ {- n} \ qquad \ left (m, n \ in \ mathbb {N} \ quad z_ {i} \ in \ {0, \ ldots, 9 \} \ right)}$

${\ displaystyle Z = \ sum _ {i = -n} ^ {m} z_ {i} \ cdot 10 ^ {i} \ geq 0 \; \ qquad Z = - \ sum _ {i = -n} ^ { m} z_ {i} \ cdot 10 ^ {i} \ leq 0}$.

This representation is also called decimal fraction development .

Example:

${\ displaystyle 7023 {,} 48 = 7 \ cdot 10 ^ {3} +0 \ cdot 10 ^ {2} +2 \ cdot 10 ^ {1} +3 \ cdot 10 ^ {0} +4 \ cdot 10 ^ {-1} +8 \ cdot 10 ^ {- 2}}$

With resolved powers we get:

${\ displaystyle 7023 {,} 48 = 7 \ cdot 1000 + 0 \ cdot 100 + 2 \ cdot 10 + 3 \ cdot 1 + 4 \ cdot 0 {,} 1 + 8 \ cdot 0 {,} 01}$

Decimal fraction development (convert periodic decimal numbers into fractions)

With the help of the expansion of decimal fractions , you can assign a sequence of digits to every real number . Each finite part of this sequence defines a decimal fraction that is an approximation of the real number. The real number itself is obtained by moving from the finite sums of the parts to the infinite series over all digits.

Formally, the value of the series is called. ${\ displaystyle z = 0, a_ {1} a_ {2} a_ {3} \ ldots}$${\ displaystyle \ textstyle \ sum _ {i = 1} ^ {\ infty} a_ {i} 10 ^ {- i}}$

It is said that the decimal fraction development stops when the sequence of digits from a position n consists of only zeros, i.e. the displayed real number is already a decimal fraction itself. Especially with all irrational numbers , the sequence of digits does not break off; there is an infinite decimal fraction expansion.

The following relationships are used to transform periodic decimal fraction expansion :

${\ displaystyle 0 {,} {\ overline {1}} = {\ frac {1} {9}}; \ quad 0 {,} {\ overline {01}} = {\ frac {1} {99}} ; \ quad 0 {,} {\ overline {001}} = {\ frac {1} {999}}; \ quad \ ldots}$.

These identities are apparent from the calculation rules for geometric series , which for applicable. In the first example one chooses and the summation only begins with the first term in the sequence. ${\ displaystyle \ textstyle \ sum _ {i = 0} ^ {\ infty} q ^ {i} = {\ frac {1} {1-q}}}$${\ displaystyle q <1}$${\ displaystyle q = 10 ^ {- 1}}$

Examples:

${\ displaystyle 0 {,} 55555 \ ldots = 0 {,} {\ overline {5}} = {\ frac {5} {9}}}$

${\ displaystyle 0 {,} 33333 \ ldots = 0 {,} {\ overline {3}} = {\ frac {3} {9}} = {\ frac {1} {3}}}$

${\ displaystyle 0 {,} 424242 \ ldots = 0 {,} {\ overline {42}} = {\ frac {42} {99}} = {\ frac {14} {33}}}$

${\ displaystyle 0 {,} 081081081 \ ldots = 0 {,} {\ overline {081}} = {\ frac {81} {999}} = {\ frac {3} {37}}}$

The period is taken over in the counter . There are as many nines in the denominator as there are places in the period. If necessary, the resulting break should be shortened .

The calculation is a little more complicated if the period does not immediately follow the decimal point:

Examples:

${\ displaystyle 0 {,} 83333 \ ldots = 0 {,} 8 {\ overline {3}} = 8 {,} {\ overline {3}}: 10 = \ left (8 + {\ frac {3} { 9}} \ right): 10 = \ left (8 + {\ frac {1} {3}} \ right): 10 = {\ frac {25} {3}}: 10 = {\ frac {25} { 30}} = {\ frac {5} {6}}}$

${\ displaystyle 0 {,} 492363636 \ ldots = 0 {,} 492 {\ overline {36}} = 492 {,} {\ overline {36}}: 1000 = 492 {\ frac {36} {99}}: 1000 = 492 {\ frac {4} {11}}: 1000 = {\ frac {5416} {11}}: 1000 = {\ frac {5416} {11000}} = {\ frac {677} {1375}} }$

${\ displaystyle 13 {,} 54323232 \ ldots = 13 {,} 54 {\ overline {32}}}$

1st step: you multiply the starting number by a power of ten so that exactly one period (in the example 32) is in front of the decimal point:

${\ displaystyle x = 13 {,} 543232 \ ldots | \ cdot 10 {.} 000}$

${\ displaystyle 10 {.} 000 \ cdot x = 135 {.} 432 {,} 3232 \ ldots}$

2nd step: then you multiply the starting number by a power of ten so that the periods start exactly after the decimal point:

${\ displaystyle x = 13 {,} 543232 \ ldots | \ cdot 100}$

${\ displaystyle 100 \ cdot x = 1 {.} 354 {,} 323232 \ ldots}$

3rd step: subtract the two lines created by step 1 and 2 from each other: (the periods after the decimal point are omitted)

${\ displaystyle 10 {.} 000 \ cdot x = 135 {.} 432 {,} 323232 \ ldots}$ (Line 1)

${\ displaystyle 100 \ cdot x = 1354 {,} 323232 \ ldots}$ (Line 2)

${\ displaystyle 9 {.} 900 \ cdot x = 135 {.} 432-1 {.} 354 = 134 {.} 078 \!}$ (Row 1 minus row 2)

4th step: switch

${\ displaystyle 9 {.} 900 \ cdot x = 134 {.} 078 |: 9 {.} 900}$

Result: ${\ displaystyle x = {\ frac {134 {.} 078} {9 {.} 900}} = 13 {,} 54 {\ overline {32}}}$

Ambiguity of representation

A special feature of the decimal fraction expansion is that many rational numbers have two different decimal fraction expansion. As described above, one can transform and make the statement ${\ displaystyle 0 {,} {\ overline {9}}}$

${\ displaystyle 0 {,} {\ overline {9}} = {\ frac {9} {9}} = 1}$

reach, see article 0.999 ...

From this identity one can further deduce that many rational numbers (namely all with finite decimal fraction expansion with the exception of 0) can be represented in two different ways: either as a finite decimal fraction with period 0, or as infinite with period 9. To make the representation unambiguous To do this, you can simply forbid period 9 (or less often period 0).

formula

The following formula can be set up for periodic decimal fractions with a zero in front of the decimal point:

${\ displaystyle p = {\ frac {x \ cdot \ left (10 ^ {n} -1 \ right) + y} {10 ^ {m} \ cdot \ left (10 ^ {n} -1 \ right)} }}$

Here p is the number, x is the number before the beginning of the period (as an integer), m is the number of digits before the beginning of the period, y is the sequence of digits of the period (as an integer) and n is the length of the period.

The application of this formula should be demonstrated using the last example:

${\ displaystyle p = 0 {,} 492363636 \ ldots = 0 {,} 492 {\ overline {36}}}$

${\ displaystyle x = 492; \ quad m = 3; \ quad y = 36; \ quad n = 2}$

${\ displaystyle p = {\ frac {x \ cdot \ left (10 ^ {n} -1 \ right) + y} {10 ^ {m} \ cdot \ left (10 ^ {n} -1 \ right)} } = {\ frac {492 \ cdot \ left (10 ^ {2} -1 \ right) +36} {10 ^ {3} \ cdot \ left (10 ^ {2} -1 \ right)}} = { \ frac {492 \ cdot 99 + 36} {1000 \ cdot 99}} = {\ frac {48744} {99000}} = {\ frac {677} {1375}}}$

period

In mathematics , the period of a decimal fraction is a digit or sequence of digits that is repeated over and over after the decimal point. All rational numbers , and only these, have a periodic expansion of decimal fractions.

Examples:

Purely periodic: (the period starts immediately after the decimal point)

1/3 = 0 3 3333 ...

1/7 = 0, 142857 142857 ...

1/9 = 0, 1 1111 ...

Mixed periodic: (after the decimal point there is a previous period before the period begins)

2/55 = 0.0 36 363636 ... (previous period 0; period length 2)

1/30 = 0.0 3 333 ... (previous period 0; period length 1)

1/6 = 0.1 6 666 ... (previous period 1; period length 1)

134078/9900 = 13.54 32 32 ... (the previous period is 54; period length is 2)

Finite decimal fractions also count among the periodic decimal fractions; after inserting an infinite number of zeros, for example 0.12 = 0.12000 ...

Real periods (i.e. no finite decimal fractions) occur in the decimal system precisely when the denominator of the underlying fraction cannot be generated solely by the prime factors 2 and 5. 2 and 5 are the prime factors of the number 10, the base of the decimal system. If the denominator is a prime number (except for 2 and 5), the period has at most a length that is one less than the value of the denominator (shown in bold in the examples). ${\ displaystyle p}$

Example for period length 6 : (10 ⁶ - 1) = 999,999:

999,999 = 3 x 3 x 3 x 7 · 11 · 13 · 37 1/ 7 = 0 142857 142857 ... and 1/ 13 = 0, 076 923 076 923 ...

Both 1/7 and 1/13 have a period length of 6 because 7 and 13 appear for the first time in the prime factorization of 10 ⁶ - 1. However, 1/37 has a period length of only 3, because already (10 ³ - 1) = 999 = 3 3 3 37.

If the denominator is not a prime number, the period length results accordingly as the number for which the denominator is a divisor of for the first time ; the prime factors 2 and 5 of the denominator are not taken into account. ${\ displaystyle n}$${\ displaystyle R_ {n} = {10 ^ {n} -1}}$

Examples: 1/185 = 1 / (5 * 37) has the same period length as 1/37, namely 3.

1/143 = 1 / (11 13) has the period length 6, because 999.999 = 3 3 3 7 143 37 (see above)

1/260 = 1 / (2 · 2 · 5 · 13) has the same period length as 1/13, i.e. 6.

In order to determine the period length efficiently, the determination of the prime factorization of the rapidly growing number sequence 9, 99, 999, 9999 etc. can be avoided by using the equivalent relationship , i.e. repeated multiplication (starting with 1) by 10 modulo the given denominator , until this equals 1 again. For example for : ${\ displaystyle n}$${\ displaystyle 10 ^ {n} \ equiv 1 {\ pmod {k}}}$${\ displaystyle k}$${\ displaystyle k = 13}$

${\ displaystyle 10 ^ {1} \ equiv 10 {\ pmod {13}}}$,

${\ displaystyle 10 ^ {2} \ equiv 10 \ cdot 10 \ equiv 100 \ equiv 9 {\ pmod {13}}}$,

${\ displaystyle 10 ^ {3} \ equiv 9 \ cdot 10 \ equiv 90 \ equiv 12 {\ pmod {13}}}$,

${\ displaystyle 10 ^ {4} \ equiv 12 \ cdot 10 \ equiv 120 \ equiv 3 {\ pmod {13}}}$,

${\ displaystyle 10 ^ {5} \ equiv 3 \ cdot 10 \ equiv 30 \ equiv 4 {\ pmod {13}}}$,

${\ displaystyle 10 ^ {6} \ equiv 4 \ cdot 10 \ equiv 40 \ equiv 1 {\ pmod {13}}}$,

so 1/13 has the period length 6.

notation

• ${\ displaystyle 1/6 = 0 {,} 1 {\ bar {6}}}$,
• ${\ displaystyle 1/7 = 0 {,} {\ overline {142857}}}$.

Due to technical restrictions, other conventions also exist. The overline can be placed in front, typographical emphasis (bold, italic, underlined) of the periodic part can be selected or it can be put in brackets:

• 1/6 = 0.1¯6 = 0.1 6 = 0.1 6 = 0.1 6 = 0.1 (6)
• 1/7 = 0, ¯142857 = 0, 142857 = 0, 142857 = 0, 142857 = 0, (142857)

Non-periodic sequence of digits after the decimal point

As explained in the article place value system , irrational numbers (also) in the decimal system have an infinite, non-periodic sequence of digits after the decimal point. Irrational numbers cannot be represented by a finite or a periodic sequence of digits. You can approximate with finite (or periodic) decimal fractions, but such a finite representation is never exact. So it is only possible to use additional symbols to indicate irrational numbers using finite representations.

Conversion into other place value systems

Methods for converting from and into the decimal system are described in the articles on other place value systems and under number base change and place value system .

history

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One of the oldest evidence of the decimal vorschriftlicher cultures found in a hoard of Oberding from the early Bronze Age (around 1650 v. Chr.) With 791 largely standardized clasp bars of copper from Salzburg and Slovakia. The majority of these bars had been deposited in groups of 10 by 10 bundles.