Orders of magnitude

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An order of magnitude is the class of scale or magnitude of any amount, where each class contains values of a fixed ratio to the class preceding it. In its most common usage, the amount being scaled is 10 and the scale is the exponent being applied to this amount. Such differences in order of magnitude can be measured on the logarithmic scale in "factors of ten" or decades (meaning "power of ten", not "10 years"). The entries in the table below lead to lists of items that are of the same order of magnitude in various units of measurement. This is useful for getting an intuitive sense of the comparative scale of familiar objects.

Orders of magnitude are generally used to make very approximate comparisons. If two numbers differ by one order of magnitude, one is about ten times larger than the other. If they differ by two orders of magnitude, they differ by a factor of about 100. Two numbers of the same order of magnitude have roughly the same scale: the larger value is less than ten times the smaller value. This is the reasoning behind significant figures: the amount rounded by is usually a few orders of magnitude less than the total, and therefore insignificant.

In
words (long scale)
In
words (short scale)
Prefix Symbol Decimal Power
of ten
Order of
magnitude
quadrillionth septillionth yocto- y 0.000000000000000000000001 10−24 −24
trilliardth sextillionth zepto- z 0.000000000000000000001 10−21 −21
trillionth quintillionth atto- a 0.000000000000000001 10−18 −18
billiardth quadrillionth femto- f 0.000000000000001 10−15 −15
billionth trillionth pico- p 0.000000000001 10−12 −12
milliardth billionth nano- n 0.000000001 10−9 −9
millionth millionth micro- µ 0.000001 10−6 −6
thousandth thousandth milli- m 0.001 10−3 −3
hundredth hundredth centi- c 0.01 10−2 −2
tenth tenth deci- d 0.1 10−1 −1
one one - - 1 100 0
ten ten deca- da 10 101 1
hundred hundred hecto- h 100 102 2
thousand thousand kilo- k 1,000 103 3
million million mega- M 1,000,000 106 6
milliard billion giga- G 1,000,000,000 109 9
billion trillion tera- T 1,000,000,000,000 1012 12
billiard quadrillion peta- P 1,000,000,000,000,000 1015 15
trillion quintillion exa- E 1,000,000,000,000,000,000 1018 18
trilliard sextillion zetta- Z 1,000,000,000,000,000,000,000 1021 21
quadrillion septillion yotta- Y 1,000,000,000,000,000,000,000,000 1024 24

Non-decimal orders of magnitude

Other orders of magnitude may be calculated using bases other than 10. The ancient Greeks ranked the nighttime brightness of celestial bodies by 6 levels in which each level was twice as bright as the nearest weaker level of brightness, so that the brightest level is 5 orders of magnitude brighter than the weakest, which can also be stated as a factor of 32 times brighter.

The different decimal numeral systems of the world use a larger base to better envision the size of the number, and have created names for the powers of this larger base. The table shows what number the order of magnitude aim at for base 10 and for base 1,000,000. It can be seen that the order of magnitude is included in the number name in this example, because bi- means 2 and tri- means 3, and the suffix -illion tells that the base is 1,000,000. But the number names billion, trillion themselves (here with other meaning than in the first chapter) are not names of the orders of magnitudes, they are names of "magnitudes", that is the numbers 1,000,000,000,000 etc.

order of magnitude is log10 of is log1000000 of
1 10 1,000,000 million
2 100 1,000,000,000,000 trillion
3 1000 1,000,000,000,000,000,000 quintillion

SI units in the table at right are used together with SI prefixes, which were devised with mainly base 1000 magnitudes in mind. The IEC standard prefixes with base 1024 was invented for use in context of electronic technology.

The ancient apparent magnitudes for the brightness of stars uses the base and is reversed. The modernized version has however turned into a logarithmic scale with non-integer values.

Extremely large numbers

For extremely large numbers, a generalized order of magnitude can be based on their double logarithm or super-logarithm. Rounding these downward to an integer gives categories between very "round numbers", rounding them to the nearest integer and applying the inverse function gives the "nearest" round number.

The double logarithm yields the categories:

..., 1.0023–1.023, 1.023–1.26, 1.26–10, 10–1010, 1010–10100, 10100–101000, ...

(the first two mentioned, and the extension to the left, may not be very useful, they merely demonstrate how the sequence mathematically continues to the left).

The super-logarithm yields the categories:

, or
negative numbers, 0–1, 1–10, 10–1e10, 1e10–10^1e10, 10^1e10–10^^4, 10^^4–10^^5, etc. (see tetration)

The "midpoints" which determine which round number is nearer are in the first case:

1.076, 2.071, 1453, 4.20e31, 1.69e316,...

and, depending on the interpolation method, in the second case

−.301, .5, 3.162, 1453, 1e1453, 10^1e1453, 10^^2@1e1453,... (see notation of extremely large numbers)

For extremely small numbers (in the sense of close to zero) neither method is suitable directly, but of course the generalized order of magnitude of the reciprocal can be considered.

Similar to the logarithmic scale one can have a double logarithmic scale (example provided here) and super-logarithmic scale. The intervals above all have the same length on them, with the "midpoints" actually midway. More generally, a point midway between two points corresponds to the generalised f-mean with f(x) the corresponding function log log x or slog x. In the case of log log x, this mean of two numbers (e.g. 2 and 16 giving 4) does not depend on the base of the logarithm, just like in the case of log x (geometric mean, 2 and 8 giving 4), but unlike in the case of log log log x (4 and 65536 giving 16 if the base is 2, but different otherwise).

See also

External links


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