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from sympy.physics.units import DimensionSystem, joule, second, ampere
from sympy.core.numbers import Rationalfrom sympy.core.singleton import Sfrom sympy.physics.units.definitions import c, kg, m, sfrom sympy.physics.units.definitions.dimension_definitions import length, timefrom sympy.physics.units.quantities import Quantityfrom sympy.physics.units.unitsystem import UnitSystemfrom sympy.physics.units.util import convert_to
def test_definition(): # want to test if the system can have several units of the same dimension dm = Quantity("dm") base = (m, s) # base_dim = (m.dimension, s.dimension) ms = UnitSystem(base, (c, dm), "MS", "MS system") ms.set_quantity_dimension(dm, length) ms.set_quantity_scale_factor(dm, Rational(1, 10))
assert set(ms._base_units) == set(base) assert set(ms._units) == {m, s, c, dm} # assert ms._units == DimensionSystem._sort_dims(base + (velocity,)) assert ms.name == "MS" assert ms.descr == "MS system"
def test_str_repr(): assert str(UnitSystem((m, s), name="MS")) == "MS" assert str(UnitSystem((m, s))) == "UnitSystem((meter, second))"
assert repr(UnitSystem((m, s))) == "<UnitSystem: (%s, %s)>" % (m, s)
def test_convert_to(): A = Quantity("A") A.set_global_relative_scale_factor(S.One, ampere)
Js = Quantity("Js") Js.set_global_relative_scale_factor(S.One, joule*second)
mksa = UnitSystem((m, kg, s, A), (Js,)) assert convert_to(Js, mksa._base_units) == m**2*kg*s**-1/1000
def test_extend(): ms = UnitSystem((m, s), (c,)) Js = Quantity("Js") Js.set_global_relative_scale_factor(1, joule*second) mks = ms.extend((kg,), (Js,))
res = UnitSystem((m, s, kg), (c, Js)) assert set(mks._base_units) == set(res._base_units) assert set(mks._units) == set(res._units)
def test_dim(): dimsys = UnitSystem((m, kg, s), (c,)) assert dimsys.dim == 3
def test_is_consistent(): dimension_system = DimensionSystem([length, time]) us = UnitSystem([m, s], dimension_system=dimension_system) assert us.is_consistent == True
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