In antiquity,
systems of measurement were defined locally: the different units might be defined independently according to the length of a king's thumb or the size of his foot, the length of stride, the length of arm, or maybe the weight of water in a keg of specific size, perhaps itself defined in
hands and
knuckles. The unifying characteristic is that there was some definition based on some standard. Eventually
cubits and
strides gave way to "customary units" to meet the needs of merchants and scientists. The preference for a more universal and consistent system only gradually spread with the growth of international trade and science. Changing a measurement system has costs in the near term, which often results in resistance to such a change. The substantial benefit of conversion to a more rational and internationally consistent system of measurement has been recognized and promoted by scientists, engineers, businesses and politicians, and has resulted in most of the world adopting a commonly agreed metric system. The
French Revolution gave rise to the
metric system, and this has spread around the world, replacing most customary units of measure. In most systems,
length (distance),
mass, and
time are
base quantities. Later, science developments showed that an electromagnetic quantity such as
electric charge or electric current could be added to extend the set of base quantities.
Gaussian units have only length, mass, and time as base quantities, with no separate electromagnetic dimension. Other quantities, such as
power and
speed, are derived from the base quantities: for example, speed is distance per unit time. Historically, a wide range of units was used for the same type of quantity. In different contexts length was measured in
inches,
feet,
yards,
fathoms,
rods,
chains,
furlongs,
miles,
nautical miles,
stadia,
leagues, with conversion factors that were not based on power of ten. In the metric system and other recent systems, underlying relationships between quantities, as expressed by formulae of physics such as
Newton's laws of motion, is used to select a small number of base quantities for which a unit is defined for each, from which all other units may be derived. Secondary units (multiples and submultiples) are derived from these base and derived units by multiplying by powers of ten. For example, where the unit of length is the
metre; a distance of 1 metre is 1,000 millimetres, or 0.001 kilometres.
Current practice Metrication is complete or nearly complete in most countries. However,
US customary units remain heavily used in the
United States and to some degree in
Liberia. Traditional
Burmese units of measurement are used in
Burma, with partial transition to the metric system. U.S. units are used in limited contexts in Canada due to the large volume of trade with the U.S. There is also considerable use of imperial weights and measures, despite
de jure Canadian conversion to metric. A number of other jurisdictions have laws mandating or permitting other systems of measurement in some or all contexts, such as the United Kingdom whose
road signage legislation, for instance, only allows distance signs displaying
imperial units (miles or yards){{cite web In the United States, metric units are virtually always used in science, frequently in the military, and partially in industry. U.S. customary units are primarily used in U.S. households. At retail stores, the litre (spelled 'liter' in the U.S.) is a commonly used unit for volume, especially on bottles of beverages, and milligrams, rather than
grains, are used for medications. Some other non-
SI units are still in international use, such as
nautical miles and
knots in aviation and shipping, and
feet for aircraft altitude. ==Metric system==