Order of magnitude

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 (base 10) exponent being applied to this amount (therefore, to be an order of magnitude greater is to be 10 times as large). Such differences in order of magnitude can be measured on the logarithmic scale in "decades" (i.e. factors of ten).

The order of magnitude of a physical quantity is its magnitude in powers of ten when that physical quantity is expressed in powers of ten with one digit to the left of decimal.

"We say two numbers have the same order of magnitude of a number if the big one divided by the little one is less than 10. For example, 23 and 82 have the same order of magnitude, but 23 and 820 do not."^[1] - John Baez

1 Use
2 Non-decimal orders of magnitude
- 2.1 Extremely large numbers
3 See also
4 Further reading
5 External links
6 References

Use

Orders of magnitude are generally used to make very approximate comparisons, and reflect very large differences. 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.

The order of magnitude of a number is, intuitively speaking, the number of powers of 10 contained in the number. More precisely, the order of magnitude of a number can be defined in terms of the common logarithm, usually as the integer part of the logarithm, obtained by truncation. For example, the number 4,000,000 has a logarithm (in base 10) of 6.602; its order of magnitude is 6. When truncating, a number of this order of magnitude is between 10⁶ and 10⁷. In a similar example, with the phrase "He had a seven-figure income", the order of magnitude is the number of figures minus one, so it is very easily determined without a calculator to be 6. An order of magnitude is an approximate position on a logarithmic scale.

An order-of-magnitude estimate of a variable whose precise value is unknown is an estimate rounded to the nearest power of ten. For example, an order-of-magnitude estimate for a variable between about 3 billion and 30 billion (such as the human population of the Earth) is 10 billion. To round a number to its nearest order of magnitude, one rounds its logarithm to the nearest integer. Thus 4,000,000, which has a logarithm (in base 10) of 6.602, has 7 as its nearest order of magnitude, because "nearest" implies rounding rather than truncation. For a number written in scientific notation, this logarithmic rounding scale requires rounding up to the next power of ten when the multiplier is greater than the square root of ten (about 3.162). For example, the nearest order of magnitude for 1.7 × 10⁸ is 8, whereas the nearest order of magnitude for 3.7 × 10⁸ is 9. An order-of-magnitude estimate is sometimes also called a zeroth order approximation.

An order-of-magnitude difference between two values is a factor of 10. For example, the mass of the planet Saturn is 95 times that of Earth, so Saturn is two orders of magnitude more massive than Earth. Order-of-magnitude differences are called decades when measured on a logarithmic scale.

In words (long scale)	In words (short scale)	Prefix	Symbol	Decimal	Power of ten	Order of magnitude
quadrillionth	septillionth	yocto-	y	0.000,000,000,000,000,000,000,001	10⁻²⁴	−24
trilliardth	sextillionth	zepto-	z	0.000,000,000,000,000,000,001	10⁻²¹	−21
trillionth	quintillionth	atto-	a	0.000,000,000,000,000,001	10⁻¹⁸	−18
billiardth	quadrillionth	femto-	f	0.000,000,000,000,001	10⁻¹⁵	−15
billionth	trillionth	pico-	p	0.000,000,000,001	10⁻¹²	−12
milliardth	billionth	nano-	n	0.000,000,001	10⁻⁹	−9
millionth	millionth	micro-	µ	0.000,001	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

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:

$0-1, 1-10, 10-10^{10}, 10^{10}-10^{10^{10}}, 10^{10^{10}}-10^{10^{10^{10}}}, \dots$ , or

negative numbers, 0–1, 1–10, 10–1e10, 1e10–10^1e10, 10^1e10–⁴10, ⁴10–⁵10, 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, $(10 \uparrow)^1 10^{1453}$ , $(10 \uparrow)^2 10^{1453}$ ,... (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, otherwise).

External links

The Scale of the Universe 2 Interactive tool from Planck length 10⁻³⁵ meters to universe size 10²⁷
Cosmos – an Illustrated Dimensional Journey from microcosmos to macrocosmos – from Digital Nature Agency
Powers of 10, a graphic animated illustration that starts with a view of the Milky Way at 10²³ meters and ends with subatomic particles at 10⁻¹⁶ meters.
What is Order of Magnitude?

References

^ John C. Baez, 11/28/2012

Orders of magnitude

Quantity	acceleration angular velocity area capacitance charge computing currency current data density energy entropy force frequency length luminous flux magnetic field mass numbers power pressure radiation resistance sound pressure specific energy density specific heat capacity speed temperature time voltage volume

See also	Back-of-the-envelope calculation Fermi problem Powers of 10 SI prefix

Book:Orders of magnitude Category:Orders of magnitude Portal:Science

Contents

Use

Non-decimal orders of magnitude

Extremely large numbers

See also

Further reading

External links

References