Metric is a proper system
... not just a collection of units
The systematic structure of metric has a number
of features.
Basic units and prefixes
Metric is based on the principle that all measurable phenomena covered by the system
- pretty well everything in the known natural world! - have one basic named
unit. All the multiples and subdivisions then follow the same logical structure
using prefixes. For example, the basic unit of power is the watt (named
after a Briton). One thousand watts is a kilowatt, one million watts is
a megawatt.
The basic named unit of length is the metre. Then for smaller distances, 1 metre
= 1 000 millimetre, whereas for longer distances 1 000 metres = 1 kilometre.
In exactly the same way, the basic named unit of mass or weight is the gram where
we have 1 gram = 1 000 milligram and 1 000 grams = 1 kilogram.
Logical symbols
The abbreviations also follow a simple logical pattern. The symbol 'm' for metre
is used as the basis for mm to mean millimetre and km to represent kilometre.
Likewise where 'g' is used to mean gram we have mg for milligram and kg for kilogram.
There are many other prefixes for various multiples and subdivisions. They are all
simple multiples of or divisions by ten and they all apply to every basic named
unit.
Links between related measurements
In everyday use, we need simple connections between measures of length, area, volume
and mass.
Commonly used units of area are defined in terms of decimal multiples of square
metres. In this case, ten times ten (ten squared):
|
unit of area |
size |
|
are (pronounced air) |
100 m2 |
|
hectare |
100 are |
|
km2 |
100 hectare |
In the opposite direction 1 m = 100 cm, therefore 1 m2 = 100 cm x 100
cm = 10 000 cm2.
As for all metric measures, all we need to do is move the decimal point. In this
case, we have moved it twice to multiply by 100:
100.000 becomes 10 000.0
In the case of volume we use the factor ten times ten times ten (ten cubed).
|
unit of volume |
size |
|
1 litre |
1 000 cm3 |
|
1 m3 |
1 000 litre |
Volume and mass are linked in a natural way by the properties of pure water. The
gram was originally defined as the mass of 1 cubic centimetre of liquid water at
a certain temperature. (The very small variation with temperature can be ignored
for everyday purposes.)
|
unit of volume |
mass of liquid water |
|
cm3 |
1 g |
|
litre |
1 kg |
|
m3 |
1 tonne |
Compare this system with imperial!
|
unit of area |
size |
|
sq foot |
144 sq inches (12 x 12) |
|
sq yard |
9 sq feet (3 x 3) |
|
acre |
4 840 sq yard (1 chain x 1 furlong
where 1 chain = 22 yd,
1 furlong = 1 eight of a mile = 220 yd) |
|
sq mile |
640 acre (80 chain x 8 furlong) |
|
unit of volume |
size |
|
UK fluid oz |
1.734 cu inches approx |
|
pint |
20 fluid oz or approx 34.7 cu inches |
|
gallon |
8 pint |
|
cu foot |
1 728 cu inches (12 x 12 x 12) or approx 6.2 gal |
|
cu yard |
27 cu foot (3 x 3 x 3) |
|
unit of volume |
mass of liquid water |
|
fluid oz |
oz |
|
pint |
20 oz = 1.25 lb |
|
gal |
10 lb |
|
cu foot |
62 lb approx |
There is no
hope of a single system to unite these measures. All the units have evolved independently
for unrelated purposes. They may be quaint, but like much that is quaint, they belong
in a museum.
Power and energy
This is where the metric system really comes into its own. The units of energy and
power are joules(J) and watts(W) respectively, regardless of whether you are measuring
electrical, mechanical or chemical systems. The table below compares the single
metric unit (the watt) with the diverse imperial units. (It should be noted that
electrical units have always been metric.)
|
Application |
metric |
imperial |
|
Motor car engines (mechanical system) |
kW |
hp |
|
Central heating boilers (chemical system) |
kW |
BTU/h |
|
Light bulbs (electrical system) |
W |
W |