Editing Number (section)

===Real numbers===
{{Main|Real number}}

The symbol for the real numbers is '''R''', also written as <math>\mathbb{R}.</math> They include all the measuring numbers. Every real number corresponds to a point on the [[number line]]. The following paragraph will focus primarily on positive real numbers. The treatment of negative real numbers is according to the general rules of arithmetic and their denotation is simply prefixing the corresponding positive numeral by a [[minus sign]], e.g. −123.456.

Most real numbers can only be ''approximated'' by [[decimal]] numerals, in which a [[decimal point]] is placed to the right of the digit with place value&nbsp;1. Each digit to the right of the decimal point has a place value one-tenth of the place value of the digit to its left. For example, 123.456 represents {{sfrac|123456|1000}}, or, in words, one hundred, two tens, three ones, four tenths, five hundredths, and six thousandths. A real number can be expressed by a finite number of decimal digits only if it is rational and its [[fractional part]] has a denominator whose prime factors are 2 or 5 or both, because these are the prime factors of 10, the base of the decimal system. Thus, for example, one half is 0.5, one fifth is 0.2, one-tenth is 0.1, and one fiftieth is 0.02. Representing other real numbers as decimals would require an infinite sequence of digits to the right of the decimal point. If this infinite sequence of digits follows a pattern, it can be written with an ellipsis or another notation that indicates the repeating pattern. Such a decimal is called a [[repeating decimal]]. Thus {{sfrac|3}} can be written as 0.333..., with an ellipsis to indicate that the pattern continues. Forever repeating 3s are also written as 0.{{overline|3}}.<ref>{{Cite web|last=Weisstein|first=Eric W.|title=Repeating Decimal|url=https://mathworld.wolfram.com/RepeatingDecimal.html|access-date=2020-07-23|website=Wolfram MathWorld |language=en|archive-date=2020-08-05|archive-url=https://web.archive.org/web/20200805170548/https://mathworld.wolfram.com/RepeatingDecimal.html|url-status=live}}</ref>

It turns out that these repeating decimals (including the [[Trailing zero|repetition of zeroes]]) denote exactly the rational numbers, i.e., all rational numbers are also real numbers, but it is not the case that every real number is rational. A real number that is not rational is called [[irrational number|irrational]]. A famous irrational real number is the [[pi|{{pi}}]], the ratio of the [[circumference]] of any circle to its [[diameter]]. When pi is written as
:<math>\pi = 3.14159265358979\dots,</math>
as it sometimes is, the ellipsis does not mean that the decimals repeat (they do not), but rather that there is no end to them. It has been proved that [[proof that pi is irrational|{{pi}} is irrational]]. Another well-known number, proven to be an irrational real number, is
:<math>\sqrt{2} = 1.41421356237\dots,</math>
the [[square root of 2]], that is, the unique positive real number whose square is 2. Both these numbers have been approximated (by computer) to trillions {{nowrap|( 1 trillion {{=}} 10<sup>12</sup> {{=}} 1,000,000,000,000 )}} of digits.

Not only these prominent examples but [[almost all]] real numbers are irrational and therefore have no repeating patterns and hence no corresponding decimal numeral. They can only be approximated by decimal numerals, denoting [[rounding|rounded]] or [[truncation|truncated]] real numbers. Any rounded or truncated number is necessarily a rational number, of which there are only [[countably many]]. All measurements are, by their nature, approximations, and always have a [[margin of error]]. Thus 123.456 is considered an approximation of any real number greater or equal to {{sfrac|1234555|10000}} and strictly less than {{sfrac|1234565|10000}} (rounding to 3 decimals), or of any real number greater or equal to {{sfrac|123456|1000}} and strictly less than {{sfrac|123457|1000}} (truncation after the 3. decimal). Digits that suggest a greater accuracy than the measurement itself does, should be removed. The remaining digits are then called [[significant digits]]. For example, measurements with a ruler can seldom be made without a margin of error of at least 0.001 [[Metre|m]]. If the sides of a rectangle are measured as 1.23&nbsp;m and 4.56&nbsp;m, then multiplication gives an area for the rectangle between {{nowrap|5.614591 m<sup>2</sup>}} and {{nowrap|5.603011 m<sup>2</sup>}}. Since not even the second digit after the decimal place is preserved, the following digits are not ''significant''. Therefore, the result is usually rounded to 5.61.

Just as the same fraction can be written in more than one way, the same real number may have more than one decimal representation. For example, [[0.999...]], 1.0, 1.00, 1.000, ..., all represent the natural number&nbsp;1. A given real number has only the following decimal representations: an approximation to some finite number of decimal places, an approximation in which a pattern is established that continues for an unlimited number of decimal places or an exact value with only finitely many decimal places. In this last case, the last non-zero digit may be replaced by the digit one smaller followed by an unlimited number of 9s, or the last non-zero digit may be followed by an unlimited number of zeros. Thus the exact real number 3.74 can also be written 3.7399999999... and 3.74000000000.... Similarly, a decimal numeral with an unlimited number of 0s can be rewritten by dropping the 0s to the right of the rightmost nonzero digit, and a decimal numeral with an unlimited number of 9s can be rewritten by increasing by one the rightmost digit less than 9, and changing all the 9s to the right of that digit to 0s. Finally, an unlimited sequence of 0s to the right of a decimal place can be dropped. For example, 6.849999999999... = 6.85 and 6.850000000000... = 6.85. Finally, if all of the digits in a numeral are 0, the number is 0, and if all of the digits in a numeral are an unending string of 9s, you can drop the nines to the right of the decimal place, and add one to the string of 9s to the left of the decimal place. For example, 99.999... = 100.

The real numbers also have an important but highly technical property called the [[least upper bound]] property.

It can be shown that any [[ordered field]], which is also [[completeness of the real numbers|complete]], is isomorphic to the real numbers. The real numbers are not, however, an [[algebraically closed field]], because they do not include a solution (often called a [[square root of minus one]]) to the algebraic equation <math> x^2+1=0</math>.