def get_pyomo_model():
m = aml.ConcreteModel()
m.x = aml.Var(initialize=10.0)
m.y = aml.Var(initialize=0.0)
m.c0 = aml.Constraint(expr=aml.asin(m.x) >= 0)
m.c1 = aml.Constraint(expr=aml.asin(m.y) >= 0)
m.o = aml.Objective(expr=aml.asin(m.x))
return m
def test_asin(self):
m = pe.Block(concrete=True)
m.x = pe.Var()
m.c = pe.Constraint(expr=pe.inequality(body=pe.asin(m.x), lower=-0.5, upper=0.5))
fbbt(m)
self.assertAlmostEqual(pe.value(m.x.lb), math.sin(-0.5))
self.assertAlmostEqual(pe.value(m.x.ub), math.sin(0.5))
def test_asin(self):
m = pyo.ConcreteModel()
m.x = pyo.Var(initialize=0.5)
e = pyo.asin(m.x)
derivs = reverse_ad(e)
symbolic = reverse_sd(e)
self.assertAlmostEqual(derivs[m.x], pyo.value(symbolic[m.x]), tol + 3)
self.assertAlmostEqual(derivs[m.x], approx_deriv(e, m.x), tol)
def test_asin(self):
m = pe.ConcreteModel()
m.x = pe.Var(initialize=0.5)
e = pe.asin(m.x)
derivs = reverse_ad(e)
symbolic = reverse_sd(e)
self.assertAlmostEqual(derivs[m.x], pe.value(symbolic[m.x]), tol+3)
self.assertAlmostEqual(derivs[m.x], approx_deriv(e, m.x), tol)
def test_trig_fuctions(self):
m = ConcreteModel()
m.x = Var()
e = differentiate(sin(m.x), wrt=m.x)
self.assertTrue(e.is_expression_type())
self.assertEqual(s(e), s(cos(m.x)))
e = differentiate(cos(m.x), wrt=m.x)
self.assertTrue(e.is_expression_type())
self.assertEqual(s(e), s(-1.0*sin(m.x)))
e = differentiate(tan(m.x), wrt=m.x)
self.assertTrue(e.is_expression_type())
self.assertEqual(s(e), s(1.+tan(m.x)**2.))
e = differentiate(sinh(m.x), wrt=m.x)
self.assertTrue(e.is_expression_type())
self.assertEqual(s(e), s(cosh(m.x)))
e = differentiate(cosh(m.x), wrt=m.x)
self.assertTrue(e.is_expression_type())
self.assertEqual(s(e), s(sinh(m.x)))
e = differentiate(tanh(m.x), wrt=m.x)
self.assertTrue(e.is_expression_type())
self.assertEqual(s(e), s(1.0-tanh(m.x)**2.0))
e = differentiate(asin(m.x), wrt=m.x)
self.assertTrue(e.is_expression_type())
self.assertEqual(s(e), s((1.0 + (-1.0)*m.x**2.)**-0.5))
e = differentiate(acos(m.x), wrt=m.x)
self.assertTrue(e.is_expression_type())
self.assertEqual(s(e), s(-1.*(1.+ (-1.0)*m.x**2.)**-0.5))
e = differentiate(atan(m.x), wrt=m.x)
self.assertTrue(e.is_expression_type())
self.assertEqual(s(e), s((1.+m.x**2.)**-1.))
e = differentiate(asinh(m.x), wrt=m.x)
self.assertTrue(e.is_expression_type())
self.assertEqual(s(e), s((1.+m.x**2)**-.5))
e = differentiate(acosh(m.x), wrt=m.x)
self.assertTrue(e.is_expression_type())
self.assertEqual(s(e), s((-1.+m.x**2.)**-.5))
e = differentiate(atanh(m.x), wrt=m.x)
self.assertTrue(e.is_expression_type())
self.assertEqual(s(e), s((1.+(-1.0)*m.x**2.)**-1.))
def eq_cosine_partition(lower_bound, upper_bound, Q):
#Divides the domain [lower_bound, upper_bound] into Q pieces of equal curvature for the cosine function. Domain must be contained in (-pi/2, pi/2)
if Q == 1:
return [lower_bound, upper_bound]
total_curvature = pe.atan(pe.sin(upper_bound)) - pe.atan(
pe.sin(lower_bound))
breakpoints = [lower_bound]
for i in range(Q - 1):
breakpoints.append(
pe.asin(
pe.tan(total_curvature / Q + pe.atan(pe.sin(breakpoints[i])))))
breakpoints.append(upper_bound)
return breakpoints
def test_unary_expressions(self):
m = ConcreteModel()
m.x = Var()
m.y = Var()
m.z = Var()
m.a = Var()
m.b = Var()
m.c = Var()
m.d = Var()
m.c1 = Constraint(expr=0 <= sin(m.x))
m.c2 = Constraint(expr=0 <= cos(m.y))
m.c3 = Constraint(expr=0 <= tan(m.z))
m.c4 = Constraint(expr=0 <= asin(m.a))
m.c5 = Constraint(expr=0 <= acos(m.b))
m.c6 = Constraint(expr=0 <= atan(m.c))
m.c7 = Constraint(expr=0 <= sqrt(m.d))
m.o = Objective(expr=m.x)
self.assertTrue(satisfiable(m) is not False)
def test_unary_expressions(self):
m = ConcreteModel()
m.x = Var()
m.y = Var()
m.z = Var()
m.a = Var()
m.b = Var()
m.c = Var()
m.d = Var()
m.c1 = Constraint(expr=0 <= sin(m.x))
m.c2 = Constraint(expr=0 <= cos(m.y))
m.c3 = Constraint(expr=0 <= tan(m.z))
m.c4 = Constraint(expr=0 <= asin(m.a))
m.c5 = Constraint(expr=0 <= acos(m.b))
m.c6 = Constraint(expr=0 <= atan(m.c))
m.c7 = Constraint(expr=0 <= sqrt(m.d))
m.o = Objective(expr=m.x)
self.assertTrue(satisfiable(m) is not False)
def test_arcfcn_to_string(self):
m = ConcreteModel()
m.x = Var()
lbl = NumericLabeler('x')
smap = SymbolMap(lbl)
tc = StorageTreeChecker(m)
self.assertEqual(expression_to_string(asin(m.x), tc, lbl, smap=smap),
("arcsin(x1)", False))
self.assertEqual(expression_to_string(acos(m.x), tc, lbl, smap=smap),
("arccos(x1)", False))
self.assertEqual(expression_to_string(atan(m.x), tc, lbl, smap=smap),
("arctan(x1)", False))
with self.assertRaisesRegexp(
RuntimeError,
"GAMS files cannot represent the unary function asinh"):
expression_to_string(asinh(m.x), tc, lbl, smap=smap)
with self.assertRaisesRegexp(
RuntimeError,
"GAMS files cannot represent the unary function acosh"):
expression_to_string(acosh(m.x), tc, lbl, smap=smap)
with self.assertRaisesRegexp(
RuntimeError,
"GAMS files cannot represent the unary function atanh"):
expression_to_string(atanh(m.x), tc, lbl, smap=smap)
def alpha(b, t):
return asin((b.level[t] - b.r_shell) / b.r_shell)
def test_get_check_units_on_all_expressions(self):
# this method is going to test all the expression types that should work
# to be defensive, we will also test that we actually have the expected expression type
# therefore, if the expression system changes and we get a different expression type,
# we will know we need to change these tests
uc = units
kg = uc.kg
m = uc.m
model = ConcreteModel()
model.x = Var()
model.y = Var()
model.z = Var()
model.p = Param(initialize=42.0, mutable=True)
model.xkg = Var(units=kg)
model.ym = Var(units=m)
# test equality
self._get_check_units_ok(3.0*kg == 1.0*kg, uc, 'kg', EXPR.EqualityExpression)
self._get_check_units_fail(3.0*kg == 2.0*m, uc, EXPR.EqualityExpression)
# test inequality
self._get_check_units_ok(3.0*kg <= 1.0*kg, uc, 'kg', EXPR.InequalityExpression)
self._get_check_units_fail(3.0*kg <= 2.0*m, uc, EXPR.InequalityExpression)
self._get_check_units_ok(3.0*kg >= 1.0*kg, uc, 'kg', EXPR.InequalityExpression)
self._get_check_units_fail(3.0*kg >= 2.0*m, uc, EXPR.InequalityExpression)
# test RangedExpression
self._get_check_units_ok(inequality(3.0*kg, 4.0*kg, 5.0*kg), uc, 'kg', EXPR.RangedExpression)
self._get_check_units_fail(inequality(3.0*m, 4.0*kg, 5.0*kg), uc, EXPR.RangedExpression)
self._get_check_units_fail(inequality(3.0*kg, 4.0*m, 5.0*kg), uc, EXPR.RangedExpression)
self._get_check_units_fail(inequality(3.0*kg, 4.0*kg, 5.0*m), uc, EXPR.RangedExpression)
# test SumExpression, NPV_SumExpression
self._get_check_units_ok(3.0*model.x*kg + 1.0*model.y*kg + 3.65*model.z*kg, uc, 'kg', EXPR.SumExpression)
self._get_check_units_fail(3.0*model.x*kg + 1.0*model.y*m + 3.65*model.z*kg, uc, EXPR.SumExpression)
self._get_check_units_ok(3.0*kg + 1.0*kg + 2.0*kg, uc, 'kg', EXPR.NPV_SumExpression)
self._get_check_units_fail(3.0*kg + 1.0*kg + 2.0*m, uc, EXPR.NPV_SumExpression)
# test ProductExpression, NPV_ProductExpression
self._get_check_units_ok(model.x*kg * model.y*m, uc, 'kg*m', EXPR.ProductExpression)
self._get_check_units_ok(3.0*kg * 1.0*m, uc, 'kg*m', EXPR.NPV_ProductExpression)
self._get_check_units_ok(3.0*kg*m, uc, 'kg*m', EXPR.NPV_ProductExpression)
# I don't think that there are combinations that can "fail" for products
# test MonomialTermExpression
self._get_check_units_ok(model.x*kg, uc, 'kg', EXPR.MonomialTermExpression)
# test DivisionExpression, NPV_DivisionExpression
self._get_check_units_ok(1.0/(model.x*kg), uc, '1/kg', EXPR.DivisionExpression)
self._get_check_units_ok(2.0/kg, uc, '1/kg', EXPR.NPV_DivisionExpression)
self._get_check_units_ok((model.x*kg)/1.0, uc, 'kg', EXPR.MonomialTermExpression)
self._get_check_units_ok(kg/2.0, uc, 'kg', EXPR.NPV_DivisionExpression)
self._get_check_units_ok(model.y*m/(model.x*kg), uc, 'm/kg', EXPR.DivisionExpression)
self._get_check_units_ok(m/kg, uc, 'm/kg', EXPR.NPV_DivisionExpression)
# I don't think that there are combinations that can "fail" for products
# test PowExpression, NPV_PowExpression
# ToDo: fix the str representation to combine the powers or the expression system
self._get_check_units_ok((model.x*kg**2)**3, uc, 'kg**6', EXPR.PowExpression) # would want this to be kg**6
self._get_check_units_fail(kg**model.x, uc, EXPR.PowExpression, UnitsError)
self._get_check_units_fail(model.x**kg, uc, EXPR.PowExpression, UnitsError)
self._get_check_units_ok(kg**2, uc, 'kg**2', EXPR.NPV_PowExpression)
self._get_check_units_fail(3.0**kg, uc, EXPR.NPV_PowExpression, UnitsError)
# test NegationExpression, NPV_NegationExpression
self._get_check_units_ok(-(kg*model.x*model.y), uc, 'kg', EXPR.NegationExpression)
self._get_check_units_ok(-kg, uc, 'kg', EXPR.NPV_NegationExpression)
# don't think there are combinations that fan "fail" for negation
# test AbsExpression, NPV_AbsExpression
self._get_check_units_ok(abs(kg*model.x), uc, 'kg', EXPR.AbsExpression)
self._get_check_units_ok(abs(kg), uc, 'kg', EXPR.NPV_AbsExpression)
# don't think there are combinations that fan "fail" for abs
# test the different UnaryFunctionExpression / NPV_UnaryFunctionExpression types
# log
self._get_check_units_ok(log(3.0*model.x), uc, None, EXPR.UnaryFunctionExpression)
self._get_check_units_fail(log(3.0*kg*model.x), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_ok(log(3.0*model.p), uc, None, EXPR.NPV_UnaryFunctionExpression)
self._get_check_units_fail(log(3.0*kg), uc, EXPR.NPV_UnaryFunctionExpression, UnitsError)
# log10
self._get_check_units_ok(log10(3.0*model.x), uc, None, EXPR.UnaryFunctionExpression)
self._get_check_units_fail(log10(3.0*kg*model.x), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_ok(log10(3.0*model.p), uc, None, EXPR.NPV_UnaryFunctionExpression)
self._get_check_units_fail(log10(3.0*kg), uc, EXPR.NPV_UnaryFunctionExpression, UnitsError)
# sin
self._get_check_units_ok(sin(3.0*model.x*uc.radians), uc, None, EXPR.UnaryFunctionExpression)
self._get_check_units_fail(sin(3.0*kg*model.x), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_fail(sin(3.0*kg*model.x*uc.kg), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_ok(sin(3.0*model.p*uc.radians), uc, None, EXPR.NPV_UnaryFunctionExpression)
self._get_check_units_fail(sin(3.0*kg), uc, EXPR.NPV_UnaryFunctionExpression, UnitsError)
# cos
self._get_check_units_ok(cos(3.0*model.x*uc.radians), uc, None, EXPR.UnaryFunctionExpression)
self._get_check_units_fail(cos(3.0*kg*model.x), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_fail(cos(3.0*kg*model.x*uc.kg), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_ok(cos(3.0*model.p*uc.radians), uc, None, EXPR.NPV_UnaryFunctionExpression)
self._get_check_units_fail(cos(3.0*kg), uc, EXPR.NPV_UnaryFunctionExpression, UnitsError)
# tan
self._get_check_units_ok(tan(3.0*model.x*uc.radians), uc, None, EXPR.UnaryFunctionExpression)
self._get_check_units_fail(tan(3.0*kg*model.x), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_fail(tan(3.0*kg*model.x*uc.kg), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_ok(tan(3.0*model.p*uc.radians), uc, None, EXPR.NPV_UnaryFunctionExpression)
self._get_check_units_fail(tan(3.0*kg), uc, EXPR.NPV_UnaryFunctionExpression, UnitsError)
# sin
self._get_check_units_ok(sinh(3.0*model.x*uc.radians), uc, None, EXPR.UnaryFunctionExpression)
self._get_check_units_fail(sinh(3.0*kg*model.x), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_fail(sinh(3.0*kg*model.x*uc.kg), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_ok(sinh(3.0*model.p*uc.radians), uc, None, EXPR.NPV_UnaryFunctionExpression)
self._get_check_units_fail(sinh(3.0*kg), uc, EXPR.NPV_UnaryFunctionExpression, UnitsError)
# cos
self._get_check_units_ok(cosh(3.0*model.x*uc.radians), uc, None, EXPR.UnaryFunctionExpression)
self._get_check_units_fail(cosh(3.0*kg*model.x), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_fail(cosh(3.0*kg*model.x*uc.kg), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_ok(cosh(3.0*model.p*uc.radians), uc, None, EXPR.NPV_UnaryFunctionExpression)
self._get_check_units_fail(cosh(3.0*kg), uc, EXPR.NPV_UnaryFunctionExpression, UnitsError)
# tan
self._get_check_units_ok(tanh(3.0*model.x*uc.radians), uc, None, EXPR.UnaryFunctionExpression)
self._get_check_units_fail(tanh(3.0*kg*model.x), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_fail(tanh(3.0*kg*model.x*uc.kg), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_ok(tanh(3.0*model.p*uc.radians), uc, None, EXPR.NPV_UnaryFunctionExpression)
self._get_check_units_fail(tanh(3.0*kg), uc, EXPR.NPV_UnaryFunctionExpression, UnitsError)
# asin
self._get_check_units_ok(asin(3.0*model.x), uc, 'rad', EXPR.UnaryFunctionExpression)
self._get_check_units_fail(asin(3.0*kg*model.x), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_ok(asin(3.0*model.p), uc, 'rad', EXPR.NPV_UnaryFunctionExpression)
self._get_check_units_fail(asin(3.0*model.p*kg), uc, EXPR.NPV_UnaryFunctionExpression, UnitsError)
# acos
self._get_check_units_ok(acos(3.0*model.x), uc, 'rad', EXPR.UnaryFunctionExpression)
self._get_check_units_fail(acos(3.0*kg*model.x), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_ok(acos(3.0*model.p), uc, 'rad', EXPR.NPV_UnaryFunctionExpression)
self._get_check_units_fail(acos(3.0*model.p*kg), uc, EXPR.NPV_UnaryFunctionExpression, UnitsError)
# atan
self._get_check_units_ok(atan(3.0*model.x), uc, 'rad', EXPR.UnaryFunctionExpression)
self._get_check_units_fail(atan(3.0*kg*model.x), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_ok(atan(3.0*model.p), uc, 'rad', EXPR.NPV_UnaryFunctionExpression)
self._get_check_units_fail(atan(3.0*model.p*kg), uc, EXPR.NPV_UnaryFunctionExpression, UnitsError)
# exp
self._get_check_units_ok(exp(3.0*model.x), uc, None, EXPR.UnaryFunctionExpression)
self._get_check_units_fail(exp(3.0*kg*model.x), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_ok(exp(3.0*model.p), uc, None, EXPR.NPV_UnaryFunctionExpression)
self._get_check_units_fail(exp(3.0*kg), uc, EXPR.NPV_UnaryFunctionExpression, UnitsError)
# sqrt
self._get_check_units_ok(sqrt(3.0*model.x), uc, None, EXPR.UnaryFunctionExpression)
self._get_check_units_ok(sqrt(3.0*model.x*kg**2), uc, 'kg', EXPR.UnaryFunctionExpression)
self._get_check_units_ok(sqrt(3.0*model.x*kg), uc, 'kg**0.5', EXPR.UnaryFunctionExpression)
self._get_check_units_ok(sqrt(3.0*model.p), uc, None, EXPR.NPV_UnaryFunctionExpression)
self._get_check_units_ok(sqrt(3.0*model.p*kg**2), uc, 'kg', EXPR.NPV_UnaryFunctionExpression)
self._get_check_units_ok(sqrt(3.0*model.p*kg), uc, 'kg**0.5', EXPR.NPV_UnaryFunctionExpression)
# asinh
self._get_check_units_ok(asinh(3.0*model.x), uc, 'rad', EXPR.UnaryFunctionExpression)
self._get_check_units_fail(asinh(3.0*kg*model.x), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_ok(asinh(3.0*model.p), uc, 'rad', EXPR.NPV_UnaryFunctionExpression)
self._get_check_units_fail(asinh(3.0*model.p*kg), uc, EXPR.NPV_UnaryFunctionExpression, UnitsError)
# acosh
self._get_check_units_ok(acosh(3.0*model.x), uc, 'rad', EXPR.UnaryFunctionExpression)
self._get_check_units_fail(acosh(3.0*kg*model.x), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_ok(acosh(3.0*model.p), uc, 'rad', EXPR.NPV_UnaryFunctionExpression)
self._get_check_units_fail(acosh(3.0*model.p*kg), uc, EXPR.NPV_UnaryFunctionExpression, UnitsError)
# atanh
self._get_check_units_ok(atanh(3.0*model.x), uc, 'rad', EXPR.UnaryFunctionExpression)
self._get_check_units_fail(atanh(3.0*kg*model.x), uc, EXPR.UnaryFunctionExpression, UnitsError)
self._get_check_units_ok(atanh(3.0*model.p), uc, 'rad', EXPR.NPV_UnaryFunctionExpression)
self._get_check_units_fail(atanh(3.0*model.p*kg), uc, EXPR.NPV_UnaryFunctionExpression, UnitsError)
# ceil
self._get_check_units_ok(ceil(kg*model.x), uc, 'kg', EXPR.UnaryFunctionExpression)
self._get_check_units_ok(ceil(kg), uc, 'kg', EXPR.NPV_UnaryFunctionExpression)
# don't think there are combinations that fan "fail" for ceil
# floor
self._get_check_units_ok(floor(kg*model.x), uc, 'kg', EXPR.UnaryFunctionExpression)
self._get_check_units_ok(floor(kg), uc, 'kg', EXPR.NPV_UnaryFunctionExpression)
# don't think there are combinations that fan "fail" for floor
# test Expr_ifExpression
# consistent if, consistent then/else
self._get_check_units_ok(EXPR.Expr_if(IF=model.x*kg + kg >= 2.0*kg, THEN=model.x*kg, ELSE=model.y*kg),
uc, 'kg', EXPR.Expr_ifExpression)
# unitless if, consistent then/else
self._get_check_units_ok(EXPR.Expr_if(IF=model.x >= 2.0, THEN=model.x*kg, ELSE=model.y*kg),
uc, 'kg', EXPR.Expr_ifExpression)
# consistent if, unitless then/else
self._get_check_units_ok(EXPR.Expr_if(IF=model.x*kg + kg >= 2.0*kg, THEN=model.x, ELSE=model.x),
uc, None, EXPR.Expr_ifExpression)
# inconsistent then/else
self._get_check_units_fail(EXPR.Expr_if(IF=model.x >= 2.0, THEN=model.x*m, ELSE=model.y*kg),
uc, EXPR.Expr_ifExpression)
# inconsistent then/else NPV
self._get_check_units_fail(EXPR.Expr_if(IF=model.x >= 2.0, THEN=model.p*m, ELSE=model.p*kg),
uc, EXPR.Expr_ifExpression)
# inconsistent then/else NPV units only
self._get_check_units_fail(EXPR.Expr_if(IF=model.x >= 2.0, THEN=m, ELSE=kg),
uc, EXPR.Expr_ifExpression)
# test EXPR.IndexTemplate and GetItemExpression
model.S = Set()
i = EXPR.IndexTemplate(model.S)
j = EXPR.IndexTemplate(model.S)
self._get_check_units_ok(i, uc, None, EXPR.IndexTemplate)
model.mat = Var(model.S, model.S)
self._get_check_units_ok(model.mat[i,j+1], uc, None, EXPR.GetItemExpression)
# test ExternalFunctionExpression, NPV_ExternalFunctionExpression
model.ef = ExternalFunction(python_callback_function)
self._get_check_units_ok(model.ef(model.x, model.y), uc, None, EXPR.ExternalFunctionExpression)
self._get_check_units_ok(model.ef(1.0, 2.0), uc, None, EXPR.NPV_ExternalFunctionExpression)
self._get_check_units_fail(model.ef(model.x*kg, model.y), uc, EXPR.ExternalFunctionExpression, UnitsError)
self._get_check_units_fail(model.ef(2.0*kg, 1.0), uc, EXPR.NPV_ExternalFunctionExpression, UnitsError)
# test ExternalFunctionExpression, NPV_ExternalFunctionExpression
model.ef2 = ExternalFunction(python_callback_function, units=uc.kg)
self._get_check_units_ok(model.ef2(model.x, model.y), uc, 'kg', EXPR.ExternalFunctionExpression)
self._get_check_units_ok(model.ef2(1.0, 2.0), uc, 'kg', EXPR.NPV_ExternalFunctionExpression)
self._get_check_units_fail(model.ef2(model.x*kg, model.y), uc, EXPR.ExternalFunctionExpression, UnitsError)
self._get_check_units_fail(model.ef2(2.0*kg, 1.0), uc, EXPR.NPV_ExternalFunctionExpression, UnitsError)
# test ExternalFunctionExpression, NPV_ExternalFunctionExpression
model.ef3 = ExternalFunction(python_callback_function, units=uc.kg, arg_units=[uc.kg, uc.m])
self._get_check_units_fail(model.ef3(model.x, model.y), uc, EXPR.ExternalFunctionExpression)
self._get_check_units_fail(model.ef3(1.0, 2.0), uc, EXPR.NPV_ExternalFunctionExpression)
self._get_check_units_fail(model.ef3(model.x*kg, model.y), uc, EXPR.ExternalFunctionExpression, UnitsError)
self._get_check_units_fail(model.ef3(2.0*kg, 1.0), uc, EXPR.NPV_ExternalFunctionExpression, UnitsError)
self._get_check_units_ok(model.ef3(2.0*kg, 1.0*uc.m), uc, 'kg', EXPR.NPV_ExternalFunctionExpression)
self._get_check_units_ok(model.ef3(model.x*kg, model.y*m), uc, 'kg', EXPR.ExternalFunctionExpression)
self._get_check_units_ok(model.ef3(model.xkg, model.ym), uc, 'kg', EXPR.ExternalFunctionExpression)
self._get_check_units_fail(model.ef3(model.ym, model.xkg), uc, EXPR.ExternalFunctionExpression, InconsistentUnitsError)
def alpha_tube(b):
return asin(b.thk_fin_half / b.radius_out)
def alpha(b, t):
return asin((b.level[t]-b.heater_radius)/b.heater_radius)
def alpha_slag(b, t):
return asin((b.fin_thickness_half + b.slag_thickness[t]) /
(b.radius_outer + b.slag_thickness[t]))
def alpha_tube(b):
return asin(b.fin_thickness_half/b.radius_outer)
def alpha_drum(b, t):
return asin((b.level[t] - b.radius_drum) / b.radius_drum)
def alpha_drum(b, t):
return asin((b.drum_level[t]-b.drum_radius)/b.drum_radius)
def alpha_slag(b, t):
return asin((b.thk_fin_half + b.thk_slag[t]) /
(b.radius_out + b.thk_slag[t]))
# pick a value in the domain of all of these functions model.ONE = Var(initialize=1) model.ZERO = Var(initialize=0) model.obj = Objective(expr=model.ONE + model.ZERO) model.c_log = Constraint(expr=log(model.ONE) == 0) model.c_log10 = Constraint(expr=log10(model.ONE) == 0) model.c_sin = Constraint(expr=sin(model.ZERO) == 0) model.c_cos = Constraint(expr=cos(model.ZERO) == 1) model.c_tan = Constraint(expr=tan(model.ZERO) == 0) model.c_sinh = Constraint(expr=sinh(model.ZERO) == 0) model.c_cosh = Constraint(expr=cosh(model.ZERO) == 1) model.c_tanh = Constraint(expr=tanh(model.ZERO) == 0) model.c_asin = Constraint(expr=asin(model.ZERO) == 0) model.c_acos = Constraint(expr=acos(model.ZERO) == pi / 2) model.c_atan = Constraint(expr=atan(model.ZERO) == 0) model.c_asinh = Constraint(expr=asinh(model.ZERO) == 0) model.c_acosh = Constraint(expr=acosh((e**2 + model.ONE) / (2 * e)) == 0) model.c_atanh = Constraint(expr=atanh(model.ZERO) == 0) model.c_exp = Constraint(expr=exp(model.ZERO) == 1) model.c_sqrt = Constraint(expr=sqrt(model.ONE) == 1) model.c_ceil = Constraint(expr=ceil(model.ONE) == 1) model.c_floor = Constraint(expr=floor(model.ONE) == 1) model.c_abs = Constraint(expr=abs(model.ONE) == 1)
def alpha_slag(b, t):
return asin((0.5 * b.fin_thickness + b.slag_thickness[t]) /
(b.radius_out + b.slag_thickness[t]))
def alpha_tube(b):
return asin(0.5 * b.fin_thickness / b.radius_out)
