The decimal system is a positional numeral system; it has positions for units, tens, hundreds, etc. The position of each digit conveys the multiplier (a power of ten) to be used with that digit—each position has a value ten times that of the position to its right.
Ten is the number which is the count of fingers and thumbs on both hands (or toes on the feet). In many languages the word digit or its translation is also the anatomical term referring to fingers and toes. In English, decimal (decimus < Lat.) means tenth, decimate means reduce by a tenth, and denary (denarius < Lat.) means the unit of ten. The symbols for the digits in common use around the globe today are called Arabic numerals by Europeans and Indian numerals by Arabs, the two groups' terms both referring to the culture from which they learned the system. However, the symbols used in different areas are not identical; for instance, Western Arabic numerals (from which the European numerals are derived) differ from the forms used by other Arab cultures.
Some cultures do, or used to, use other numeral systems, including pre-Columbian Mesoamerican cultures such as the Maya, who use a vigesimal system (using all twenty fingers and toes), some Nigerians who use several duodecimal (base 12) systems, the Babylonians, who used sexagesimal (base 60), and the Yuki, who reportedly used quaternal (base 4).
Computer hardware and software systems commonly use a binary representation, internally (although a few of the earliest computers, such as ENIAC, did use decimal representation internally). For external use by computer specialists, this binary representation is sometimes presented in the related octal or hexadecimal systems. For most purposes, however, binary values are converted to the equivalent decimal values for presentation to and manipulation by humans.
Both computer hardware and software also use internal representations which are effectively decimal for storing decimal values and doing arithmetic. Often this arithmetic is done on data which are encoded using binary-coded decimal, but there are other decimal representations in use (see IEEE 754r), especially in database implementations. Decimal arithmetic is used in computers so that decimal fractional results can be computed exactly, which is not possible using a binary fractional representation. This is often important for financial and other calculations.
Decimal fractions are commonly expressed without a denominator, the decimal separator being inserted into the numerator (with leading zeros added if needed), at the position from the right corresponding to the power of ten of the denominator. e.g., 8/10, 83/100, 83/1000, and 8/10000 are expressed as: 0.8, 0.83, 0.083, and 0.0008. In English-speaking and many Asian countries, a period (.) is used as the decimal separator; in many other languages, a comma is used.
The integer part or integral part of a decimal number is the part to the left of the decimal separator (see also floor function). The part from the decimal separator to the right is the fractional part; if considered as a separate number, a zero is often written in front. Especially for negative numbers, we have to distinguish between the fractional part of the notation and the fractional part of the number itself, because the latter gets its own minus sign. It is usual for a decimal number whose absolute value is less than one to have a leading zero.
Trailing zeros after the decimal point are not necessary, although in science, engineering and statistics they can be retained to indicate a required precision or to show a level of confidence in the accuracy of the number: Whereas 0.080 and 0.08 are numerically equal, in engineering 0.080 suggests a measurement with an error of up to 1 part in two thousand (±0.0005), while 0.08 suggests a measurement with an error of up to 1 in two hundred (see Significant figures).
Ten is the product of the first and third prime numbers, is one greater than the square of the second prime number, and is one less than the fifth prime number. This leads to plenty of simple decimal fractions:
That a rational number must have a finite or recurring decimal expansion can be seen to be a consequence of the long division algorithm, in that there are only q-1 possible nonzero remainders on division by q, so that the recurring pattern will have a period less than q. For instance to find 3/7 by long division:
.4 2 8 5 7 1 4 ...
7 ) 3.0 0 0 0 0 0 0 0
2 8 30/7 = 4 r 2
1 4 20/7 = 2 r 6
5 6 60/7 = 8 r 4
3 5 40/7 = 5 r 5
4 9 50/7 = 7 r 1
7 10/7 = 1 r 3
2 8 30/7 = 4 r 2 (again)
The converse to this observation is that every recurring decimal represents a rational number p/q. This is a consequence of the fact the recurring part of a decimal representation is, in fact, an infinite geometric series which will sum to a rational number. For instance,
Every real number has a (possibly infinite) decimal representation, i.e., it can be written as
Such a sum converges as i decreases, even if there are infinitely many nonzero ai.
Consider those rational numbers which have only the factors 2 and 5 in the denominator, i.e. which can be written as p/(2a5b). In this case there is a terminating decimal representation. For instance 1/1=1, 1/2=0.5, 3/5=0.6, 3/25=0.12 and 1306/1250=1.0448. Such numbers are the only real numbers which don't have a unique decimal representation, as they can also be written as a representation that has a recurring 9, for instance 1=0.99999…, 1/2=0.499999…, etc.
This leaves the irrational numbers. They also have unique infinite decimal representation, and can be characterised as the numbers whose decimal representations neither terminate nor recur.
So in general the decimal representation is unique, if one excludes representations that end in a recurring 9.
and a version of this even holds for irrational-base numeration systems, such as golden mean base representation.
There follows a chronological list of recorded decimal writers.
Some psychologists suggest irregularities of numerals in a language may hinder children's counting ability.
Decimats: Helping Students to Make Sense of Decimal Place Value: Anne Roche Introduces "Decimats" and Describes How They Can Be Used to Make Sense of Decimal Size and Decimal Place Value
Jun 22, 2010; Background A considerable body of research exists on students' understanding of decimal fractions and the prevalence and...
The Effects of Rounding on the Consumer Price Index: Calculating Percent Changes in a Price Index Rounded to Three Decimal Places Mitigates a Problem That Can Arise When Percent Changes Are Based on the Same Index Rounded to a Single Decimal Place
Oct 01, 2006; The Bureau of Labor Statistics (BLS, the Bureau) rounds the Consumer Price Index (CPI) to a single decimal place before it is...
Pi continued. (University of Tokyo mathematicians have calculated Pi to the 3.22 billionth decimal place, setting a new record)(Brief Article)
Aug 26, 1995; It's possible to use the distribution of bright stars across the night sky to deduce a numerical value of pi ([pi]) that comes...