A unit of measurement is a definite magnitude of a physical quantity, defined and adopted by convention and/or by law, that is used as a standard for measurement of the same physical quantity. Any other value of the physical quantity can be expressed as a simple multiple of the unit of measurement.

For example, length is a physical quantity. The metre is a unit of length that represents a definite predetermined length. When we say 10 metres (or 10 m), we actually mean 10 times the definite predetermined length called "metre".

The definition, agreement, and practical use of units of measurement have played a crucial role in human endeavour from early ages up to this day. Different systems of units used to be very common. Now there is a global standard, the International System of Units (SI), the modern form of the metric system.

In trade, weights and measures is often a subject of governmental regulation, to ensure fairness and transparency. The Bureau international des poids et mesures (BIPM) is tasked with ensuring worldwide uniformity of measurements and their traceability to the International System of Units (SI). Metrology is the science for developing nationally and internationally accepted units of weights and measures.

In physics and metrology, units are standards for measurement of physical quantities that need clear definitions to be useful. Reproducibility of experimental results is central to the scientific method. A standard system of units facilitates this. Scientific systems of units are a refinement of the concept of weights and measures developed long ago for commercial purposes.

Science, medicine, and engineering often use larger and smaller units of measurement than those used in everyday life and indicate them more precisely. The judicious selection of the units of measurement can aid researchers in problem solving (see, for example, dimensional analysis).

In the social sciences, there are no standard units of measurement and the theory and practice of measurement is studied in psychometrics and the theory of conjoint measurement.

History

A unit of measurement is a standardised quantity of a physical property, used as a factor to express occurring quantities of that property. Units of measurement were among the earliest tools invented by humans. Primitive societies needed rudimentary measures for many tasks: constructing dwellings of an appropriate size and shape, fashioning clothing, or bartering food or raw materials.

The earliest known uniform systems of weights and measures seem to have all been created sometime in the 4th and 3rd millennia BC among the ancient peoples of Mesopotamia, Egypt and the Indus Valley, and perhaps also Elam in Persia as well.

In "The Magna Carta" of 1215 (The Great Charter) with the seal of King John, put before him by the Barons of England, King John agreed in Clause 35 "There shall be one measure of wine throughout our whole realm, and one measure of ale and one measure of corn--namely, the London quart;--and one width of dyed and russet and hauberk cloths--namely, two ells below the selvage….". The Magna Carta helped lay the foundations of freedom codified in English Law and subsequently American Law.

Many systems were based on the use of parts of the body and the natural surroundings as measuring instruments. Our present knowledge of early weights and measures comes from many sources.

Systems of units

Traditional systems

by Leonardo da Vinci, depicts nine historical units of measurement: the yard, the span, the cubit, the Flemish ell, the English ell, the French ell, the fathom, the hand, and the foot. The Vitruvian Man was drawn to scale, so the units depicted are displayed with their proper historical ratios. ]] Prior to the near global adoption of the metric system many different systems of measurement had been in use. Many of these were related to some extent or other. Often they were based on the dimensions of the human body according to the proportions described by Marcus Vitruvius Pollio. As a result, units of measure could vary not only from location to location, but from person to person.

Metric systems

A number of metric systems of units have evolved since the adoption of the original metric system in France in 1791. The current international standard metric system is the International System of Units. An important feature of modern systems is standardization. Each unit has a universally recognized size.

Both the Imperial units and US customary units derive from earlier English units. Imperial units were mostly used in the British Commonwealth and the former British Empire. US customary units are still the main system of measurement used in the United States despite Congress having legally authorized metric measure on 28 July 1866. Some steps towards US metrication have been made, particularly the redefinition of basic US units to derive exactly from SI units, so that in the US the inch is now defined as 0.0254 m (exactly), and the avoirdupois pound is now defined as 453.59237 g (exactly)

Natural systems

While the above systems of units are based on arbitrary unit values, formalised as standards, some unit values occur naturally in science. Systems of units based on these are called natural units. Similar to natural units, atomic units (au) are a convenient system of units of measurement used in atomic physics.

Also a great number of unusual and non-standard units may be encountered. These may include the Solar mass, the Megaton (1,000,000 tons of TNT).

Legal control of weights and measures

To reduce the incidence of retail fraud, many national statutes have standard definitions of weights and measures that may be used (hence "statute measure"), and these are verified by legal officers.

==Base and derived units== Different systems of units are based on different choices of a set of fundamental units. The most widely used system of units is the International System of Units, or SI. There are seven SI base units. All other SI units can be derived from these base units.

For most quantities a unit is absolutely necessary to communicate values of that physical quantity. For example, conveying to someone a particular length without using some sort of unit is impossible, because a length cannot be described without a reference used to make sense of the value given.

But not all quantities require a unit of their own. Using physical laws, units of quantities can be expressed as combinations of units of other quantities. Thus only a small set of units is required. These units are taken as the base units. Other units are derived units. Derived units are a matter of convenience, as they can be expressed in terms of basic units. Which units are considered base units is a matter of choice.

The base units of SI are actually not the smallest set possible. Smaller sets have been defined. For example, there are unit sets in which the electric and magnetic field have the same unit. This is based on physical laws that show that electric and magnetic field are actually different manifestations of the same phenomenon.

Calculations with units

Units as dimensions

Any value of a physical quantity is expressed as a comparison to a unit of that quantity. For example, the value of a physical quantity Z is expressed as the product of a unit [Z] and a numerical factor:

:$Z\; =\; n\; \backslash times\; [Z]\; =\; n\; [Z].$ For example, "2 candlesticks" Z = 2 [candlestick].

The multiplication sign is usually left out, just as it is left out between variables in scientific notation of formulas. The conventions used to express quantities is referred to as quantity calculus. In formulas the unit [Z] can be treated as if it were a specific magnitude of a kind of physical dimension: see dimensional analysis for more on this treatment.

Units can only be added or subtracted if they are the same type; however units can always be multiplied or divided, as George Gamow used to explain:

:"2 candlesticks" times "3 cabdrivers" = 6 [candlestick][cabdriver].

A distinction should be made between units and standards. A unit is fixed by its definition, and is independent of physical conditions such as temperature. By contrast, a standard is a physical realization of a unit, and realizes that unit only under certain physical conditions. For example, the metre is a unit, while a metal bar is a standard. One metre is the same length regardless of temperature, but a metal bar will be one metre long only at a certain temperature.

Guidelines

Treat units algebraically. Only add like terms. When a unit is divided by itself, the division yields a unitless one. When two different units are multiplied, the result is a new unit, referred to by the combination of the units. For instance, in SI, the unit of speed is metres per second (m/s). See dimensional analysis. A unit can be multiplied by itself, creating a unit with an exponent (e.g. m²/s²). Put simply, units obey the laws of indices. (See Exponentiation.)

Some units have special names, however these should be treated like their equivalents. For example, one newton (N) is equivalent to one kg·m/s². Thus a quantity may have several unit designations, for example: the unit for surface tension can be referred to as either N/m (newtons per metre) or kg/s² (kilograms per second squared). Whether these designations are equivalent is disputed amongst metrologists.

===Expressing a physical value in terms of another unit=== Conversion of units involves comparison of different standard physical values, either of a single physical quantity or of a physical quantity and a combination of other physical quantities.

Starting with:

:$Z\; =\; n\_i\; \backslash times\; [Z]\_i$

just replace the original unit $[Z]\_i$ with its meaning in terms of the desired unit $[Z]\_j$, e.g. if $[Z]\_i\; =\; c\_\{ij\}\; \backslash times\; [Z]\_j$, then:

:$Z\; =\; n\_i\; \backslash times\; (c\_\{ij\}\; \backslash times\; [Z]\_j)\; =\; (n\_i\; \backslash times\; c\_\{ij\})\; \backslash times\; [Z]\_j$

Now $n\_i$ and $c\_\{ij\}$ are both numerical values, so just calculate their product.

Or, which is just mathematically the same thing, multiply Z by unity, the product is still Z:

:$Z\; =\; n\_i\; \backslash times\; [Z]\_i\; \backslash times\; (\; c\_\{ij\}\; \backslash times\; [Z]\_j/[Z]\_i\; )$

For example, you have an expression for a physical value Z involving the unit feet per second ($[Z]\_i$) and you want it in terms of the unit miles per hour ($[Z]\_j$):

1. Find facts relating the original unit to the desired unit:

   :1 mile = 5280 feet and 1 hour = 3600 seconds

2. Next use the above equations to construct a fraction that has a value of unity and that contains units such that, when it is multiplied with the original physical value, will cancel the original units:

   :$1\; =\; \backslash frac\{1\backslash ,\backslash mathrm\{mi\}\}\{5280\backslash ,\backslash mathrm\{ft\}\}\backslash quad\; \backslash mathrm\{and\}\backslash quad\; 1\; =\; \backslash frac\{3600\backslash ,\backslash mathrm\{s\}\}\{1\backslash ,\backslash mathrm\{h\}\}$

3. Last,multiply the original expression of the physical value by the fraction, called a conversion factor, to obtain the same physical value expressed in terms of a different unit. Note: since valid conversion factors are dimensionless and have a numerical value of one, multiplying any physical quantity by such a conversion factor (which is 1) does not change that physical quantity.

   :$52.8\backslash ,\backslash frac\{\backslash mathrm\{ft\}\}\{\backslash mathrm\{s\}\}\; =\; 52.8\backslash ,\backslash frac\{\backslash mathrm\{ft\}\}\{\backslash mathrm\{s\}\}\; \backslash frac\{1\backslash ,\backslash mathrm\{mi\}\}\{5280\backslash ,\backslash mathrm\{ft\}\}\; \backslash frac\{3600\backslash ,\backslash mathrm\{s\}\}\{1\backslash ,\backslash mathrm\{h\}\}\; =\; \backslash frac\; \{52.8\; \backslash times\; 3600\}\{5280\}\backslash ,\backslash mathrm\{mi/h\}\; =\; 36\backslash ,\backslash mathrm\{mi/h\}$

Or as an example using the metric system, you have a value of fuel economy in the unit litres per 100 kilometres and you want it in terms of the unit microlitres per metre:

:$\backslash mathrm\{\backslash frac\{9\backslash ,\backslash rm\{L\}\}\{100\backslash ,\backslash rm\{km\}\}\}\; =\; \backslash mathrm\{\backslash frac\{9\backslash ,\backslash rm\{L\}\}\{100\backslash ,\backslash rm\{km\}\}\}\; \backslash mathrm\{\backslash frac\{1000000\backslash ,\backslash rm\{\backslash mu\; L\}\}\{1\backslash ,\backslash rm\{L\}\}\}\; \backslash mathrm\{\backslash frac\{1\backslash ,\backslash rm\{km\}\}\{1000\backslash ,\backslash rm\{m\}\}\}\; =\; \backslash frac\; \{9\; \backslash times\; 1000000\}\{100\; \backslash times\; 1000\}\backslash ,\backslash mathrm\{\backslash mu\; L/m\}\; =\; 90\backslash ,\backslash mathrm\{\backslash mu\; L/m\}$

Real-world implications

One example of the importance of agreed units is the failure of the NASA Mars Climate Orbiter, which was accidentally destroyed on a mission to the planet Mars in September 1999 instead of entering orbit, due to miscommunications about the value of forces: different computer programs used different units of measurement (newton versus pound force). Enormous amounts of effort, time, and money were wasted.

On April 15, 1999 Korean Air cargo flight 6316 from Shanghai to Seoul was lost due to the crew confusing tower instructions (in metres) and altimeter readings (in feet). Three crew and five people on the ground were killed. Thirty seven were injured.

In 1983, a Boeing 767 (which came to be known as the Gimli Glider) ran out of fuel in mid-flight because of two mistakes in figuring the fuel supply of Air Canada's first aircraft to use metric measurements. This accident is apparently the result of confusion both due to the simultaneous use of metric & Imperial measures as well as mass & volume measures.

See also

Chinese units of measurement

Conversion of units

Indian weights and measures

International System of Units

Japanese units of measurement

List of humorous units of measurement

List of unusual units of measurement

Spanish customary units

Taiwanese units of measurement

Unified Code for Units of Measure

Units conversion by factor-label

Notes

External links

General

A Dictionary of Units of Measurement - Center for Mathematics and Science Education, University of North Carolina

NIST Handbook 44, Specifications, Tolerances, and Other Technical Requirements for Weighing and Measuring Devices

NIST Handbook 44, Appendix C, General Tables of Units of Measurement

Official SI website

Quantity System Framework - Quantity System Library and Calculator for Units Conversions and Quantities predictions

Legal

Canada - Weights and Measures Act 1970-71-72

Ireland - Metrology Act 1996

US - Authorized tables

Metric information and associations

Official SI website

UK Metric Association

US Metric Association

The Unified Code for Units of Measure (UCUM)

Imperial/U.S. measure information and associations

British Weights and Measures Association

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