def test_double_calculation(self): deriver = FluidSolver(add_assumptions=('Tv equals T',), **self.vars2) Tv = deriver.calculate('Tv') rho = deriver.calculate('rho') assert (rho == 1/Rd).all() assert isinstance(rho, np.ndarray) assert isinstance(Tv, np.ndarray)
def test_double_calculation(self): deriver = FluidSolver(add_assumptions=('Tv equals T', ), **self.vars2) Tv = deriver.calculate('Tv') rho = deriver.calculate('rho') assert (rho == 1 / Rd).all() assert isinstance(rho, np.ndarray) assert isinstance(Tv, np.ndarray)
def test_depth_2_calculation(self): deriver = FluidSolver(assumptions=FluidSolver.default_assumptions + ('Tv equals T', ), **self.vars2) rho = deriver.calculate('rho') assert (rho == 1 / Rd).all() assert isinstance(rho, np.ndarray)
def test_depth_2_calculation(self): deriver = FluidSolver(assumptions=FluidSolver.default_assumptions + ('Tv equals T',), **self.vars2) rho = deriver.calculate('rho') assert (rho == 1/Rd).all() assert isinstance(rho, np.ndarray)
def test_simple_calculation(self): deriver = FluidSolver(**self.vars1) rho = deriver.calculate('rho') assert (rho == 1/Rd).all() assert isinstance(rho, np.ndarray)
def test_simple_calculation(self): deriver = FluidSolver(**self.vars1) rho = deriver.calculate('rho') assert (rho == 1 / Rd).all() assert isinstance(rho, np.ndarray)