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Nonzero numbers are written in the form where b is an integer; a is called the significand. The same number can be written in different ways: adding one to b reduces a by a factor 10. Usually a is chosen in the range 1-10. In that case b is the integer part of the common logarithm. Such a fixed range allows easy comparison of two numbers: the one with the larger exponent is larger.
Another term used for a is mantissa, but this may give confusion with its alternative meaning of fractional part of the common logarithm.
For very small numbers the advantage is that leading zeros are not needed. Large numbers are often (rounded to) a multiple of a power of 10. In that case an advantage of scientific notation is that trailing zeros which are the result of rounding are not needed. An additional advantage is that the rounding accuracy is shown: if one or more trailing zeros are not the result of rounding they are written (unless it is clear from the context that an exact number is referred to). For example, when the speed of light is expressed as } × 10 } m/s or } × 10 } km/s then it is clear that it is between 299 500 and 300 500 km/s. (See also below and significant figures)
Additionally, 10 raised to a negative integer power −n is equal to 1/10n or, equivalently 0. (n−1 zeros)1:
Therefore, a large number such as 156,234,000,000,000,000,000,000,000,000 can be concisely recorded as 1.56234 × 1029, and a small number such as 0.0000000000234 can be written as 2.34 × 10−11 (in plain text 1.56234e29 and 2.34e-11, or with a capital E). For example, the distance to the edge of the observable universe is ~4.6 × 1026 m and the mass of a protonFor alternative meanings see proton (disambiguation). Proton Classification Subatomic particle Fermion Hadron Baryon Nucleon Proton Properties Mass: 938 MeV/ c2 Electric Charge: 1. 6 × 10−19 C Spin: 1/2 In physics, the proton is a subatomic particle is ~1.67 x 10−27 kgThe kilogram (symbol: kg is the SI base unit of mass. A gram is defined as one thousandth of a kilogram. Conversion of units describes equivalent units of mass in other systems. Multiples SI prefixes are used to name multiples and subdivisions of the kilo. Most calculatorA calculator is a device for performing numerical calculations. It should not be confused with a calculating machine. Nowadays many people have a calculator with them as part of their mobile phone and/or personal digital assistant. Engineers and accountans and many computer programA computer program (often simply called a program is an example of computer software that prescribes the actions (" computations") that are to be carried out by a computer. Most programs consist of a loadable set of instructions which determines how the cs present very large and very small results in scientific notation; the 10 is usually omitted and the letter E for exponent is used; for example, 1.56234 E+29. Note that this is not related to the base of the natural logarithmThe mathematical constant e (occasionally called Euler's number after the Swiss mathematician Leonhard Euler, or Napier's constant in honor of the Scottish mathematician John Napier who introduced logarithms) is the base of the natural logarithm function. also commonly denoted by e.
Scientific notation is useful for describing physical quantities, as they can only be measured within certain error limits, and so giving just the digits that are known to be correct (the " significant digits") conveys the information that can safely be used.
If a physical quantity is quoted using scientific notation, it is usually assumed to be accurate to the quoted number of digits of precision – for instance, if a figure 1.2340 × 106 metres is quoted, the actual figure is assumed to be between 1,233,950 metres as a lower bound and 1,234,050 metres as an upper bound. However, where precision in such measurements is crucial, more sophisticated expressions of measurement error must be used.
Scientific notation also avoids regional differences in certain quantifiers, such as "billion", where the use of scientific notation avoids misunderstanding.
| SI prefixes [ }|action=edit}} Edit }] | ||||
|---|---|---|---|---|
| (Sub)multiple | Prefix | Symbol | Short scale Name | Long scale Name |
| 1024 | yotta | Y | Septillion | Quadrillion |
| 1021 | zetta | Z | Sextillion | Thousand trillion (Trilliard) |
| 1018 | exa | E | Quintillion | Trillion |
| 1015 | peta | P | Quadrillion | Thousand billion ( Billiard) |
| 1012 | tera | T | Trillion | Billion |
| 109 | giga | G | Billion | Thousand million ( Milliard) |
| 106 | mega | M | Million | |
| 103 | kilo | k | Thousand | |
| 102 | hecto | h | Hundred | |
| 101 | deca | da | Ten | |
| 10-1 | deci | d | Tenth | |
| 10-2 | centi | c | Hundredth | |
| 10-3 | milli | m | Thousandth | |
| 10-6 | micro | µ | Millionth | |
| 10-9 | nano | n | Billionth | Milliardth |
| 10-12 | pico | p | Trillionth | Billionth |
| 10-15 | femto | f | Quadrillionth | Billiardth |
| 10-18 | atto | a | Quintillionth | Trillionth |
| 10-21 | zepto | z | Sextillionth | Trilliardth |
| 10-24 | yocto | y | Septillionth | Quadrillionth |