See: Description
| Class | Description |
|---|---|
| Amount<Q extends Quantity> |
This class represents a determinate or estimated amount for which
operations such as addition, subtraction, multiplication and division
can be performed (it implements the
Field interface). |
| AmountFormat |
This class provides the interface for formatting and parsing
measures instances. |
| Constants |
This class provides most accurate physical constants measurement;
the more accurate the constants, the higher the precision
of the calculations making use of these constants.
|
| Exception | Description |
|---|---|
| AmountException |
Signals that an illegal measure operation has been performed.
|
Provides support for exact or arbitrary precision measurements.
measurable quantity:Amount
base class is parameterized with the quantity onto which the measure applies
(Amount<Q extends Quantity>). If the quantity is not known then
<?> can be used. For example:[code]
Amount carMileage = Amount.valueOf(20, MILE.divide(GALLON_LIQUID_US));
Amount gazPrice = Amount.valueOf(1.2, EUR.divide(LITER)); // 1.2 €/L
[/code]
If the expected quantity result for a measure is known but has been lost
due to the calculations performed; better than using <?>, the measure can
be stated in a known unit for this quantity. It ensures dynamic check of
the measure dimension/unit and avoid compiler warnings. For example:[code]
// No problem here as the measure type is infered from the unit.
Amount tripDistance = Amount.valueOf(400, KILO(SI.METRE));
// Warning as the measure type is lost during calculation.
Amount tripCost = tripDistance.divide(carMileage).times(gazPrice);
// Better: Dimension check and no warning (USD is a Currency (Unit))
Amount tripCost = tripDistance.divide(carMileage).times(gazPrice).to(USD);
[/code]
It should be noted that this conversion is immediate if the specified
unit is the actual unit for the amount (which is then returned unchanged).
Error calculations:
Amount take into account measurement and calculation errors. For example:[code]
import static org.jscience.physics.units.SI.*;
...
Amount x = Amount.valueOf(1.0, METRE);
Amount v = Amount.valueOf(0.01, METRE_PER_SECOND);
Amount t = Amount.valueOf(1.0, MICRO(SECOND));
for (int i = 0; i < 10000000; i++) {
x = x.plus(v.times(t));
}
AmountFormat.setInstance(AmountFormat.getExactDigitsInstance());
System.out.println(x);
> 1.10000000 m
The exact value is guaranteed to be in the range: ]1.09999999 m, 1.10000001 m[
The same calculation using primitive double type would have display:
> 1.099999999392253
with no idea on the accuracy of the result.[/code]
Dimension checking.
The unit of an amount determinates its type.
For example, Amount.valueOf("1 µm") and Amount.valueOf("1.2 ft")
are Length amounts (both "µm" and "ft" units
are derived from SI.METRE). Multiple physical models are supported (e.g. Standard,
Relativistic, High-Energy, Quantum
and Natural). The physical model sets which conversions are allowed or disallowed.
For example:[code]
RelativisticModel.select(); // Selects a relativistic model.
Amount x = Amount.valueOf(100, NonSI.INCH);
x = x.plus(Amount.valueOf("2.3 µs")).to(METRE); // Length and Duration can be added.
Amount m = Amount.valueOf("12 GeV").to(KILOGRAM); // Energy is compatible with mass (E=mc2)
System.out.println(x);
System.out.println(m);
> (692.06265340000008 ± 5.1E-13) m
> (2.1391940763025056E-26 ± 4.3E-42) kg[/code]
Physical Constants
Finally, this package holds the latest physical constants measurements
with the best known accuracy (the more accurate the constant, the higher the precision of the calculations
making use of these constants).