def create_psv_acpf_model(model_data):
model, md = _create_base_acpf_model(model_data)
gens = dict(md.elements(element_type='generator'))
buses = dict(md.elements(element_type='bus'))
bus_attrs = md.attributes(element_type='bus')
branch_attrs = md.attributes(element_type='branch')
gens_by_bus = tx_utils.gens_by_bus(buses, gens)
buses_with_gens = _buses_with_gens(gens)
bus_pairs = zip_items(branch_attrs['from_bus'], branch_attrs['to_bus'])
unique_bus_pairs = list(OrderedDict((val, None) for idx, val in bus_pairs.items()).keys())
# declare the polar voltages
libbranch.declare_var_dva(model=model,
index_set=unique_bus_pairs,
initialize=0
)
libbus.declare_var_vm(model,
bus_attrs['names'],
initialize=bus_attrs['vm']
)
libbus.declare_var_va(model,
bus_attrs['names'],
initialize=tx_utils.radians_from_degrees_dict(bus_attrs['va'])
)
### In a system with N buses and G generators, there are then 2(N-1)-(G-1) unknowns.
### fix the reference bus
ref_bus = md.data['system']['reference_bus']
ref_angle = md.data['system']['reference_bus_angle']
model.va[ref_bus].fix(radians(ref_angle))
model.vm[ref_bus].fixed = True
# if there is more than one generator at the reference
# bus, then we fix the pg for all but one
for i,g in enumerate(gens_by_bus[ref_bus]):
if i > 0:
model.pg[g].fixed = True
for bus_name in bus_attrs['names']:
if bus_name != ref_bus and bus_name in buses_with_gens:
model.vm[bus_name].fixed = True
for gen_name in gens_by_bus[bus_name]:
model.pg[gen_name].fixed = True
# relate c, s, and vmsq to vm and va
libbranch.declare_eq_delta_va(model=model,
index_set=unique_bus_pairs)
libbus.declare_eq_vmsq(model=model,
index_set=bus_attrs['names'],
coordinate_type=CoordinateType.POLAR)
libbranch.declare_eq_c(model=model,
index_set=unique_bus_pairs,
coordinate_type=CoordinateType.POLAR)
libbranch.declare_eq_s(model=model,
index_set=unique_bus_pairs,
coordinate_type=CoordinateType.POLAR)
return model, md
def create_psv_acopf_model(model_data,
include_feasibility_slack=False,
pw_cost_model='delta'):
model, md = _create_base_power_ac_model(
model_data,
include_feasibility_slack=include_feasibility_slack,
pw_cost_model=pw_cost_model)
bus_attrs = md.attributes(element_type='bus')
branch_attrs = md.attributes(element_type='branch')
bus_pairs = zip_items(branch_attrs['from_bus'], branch_attrs['to_bus'])
unique_bus_pairs = list(
OrderedDict((val, None) for idx, val in bus_pairs.items()).keys())
# declare the polar voltages
libbranch.declare_var_dva(model=model,
index_set=unique_bus_pairs,
initialize=0,
bounds=(-pi / 2, pi / 2))
libbus.declare_var_vm(model,
bus_attrs['names'],
initialize=bus_attrs['vm'],
bounds=zip_items(bus_attrs['v_min'],
bus_attrs['v_max']))
va_bounds = {k: (-pi, pi) for k in bus_attrs['va']}
libbus.declare_var_va(model,
bus_attrs['names'],
initialize=tx_utils.radians_from_degrees_dict(
bus_attrs['va']),
bounds=va_bounds)
# fix the reference bus
ref_bus = md.data['system']['reference_bus']
ref_angle = md.data['system']['reference_bus_angle']
model.va[ref_bus].fix(radians(ref_angle))
# relate c, s, and vmsq to vm and va
libbranch.declare_eq_delta_va(model=model, index_set=unique_bus_pairs)
libbus.declare_eq_vmsq(model=model,
index_set=bus_attrs['names'],
coordinate_type=CoordinateType.POLAR)
libbranch.declare_eq_c(model=model,
index_set=unique_bus_pairs,
coordinate_type=CoordinateType.POLAR)
libbranch.declare_eq_s(model=model,
index_set=unique_bus_pairs,
coordinate_type=CoordinateType.POLAR)
return model, md
def create_relaxation_of_polar_acopf(model_data,
include_soc=True,
use_linear_relaxation=False):
if not coramin_available:
raise ImportError(
'Cannot create polar relaxation unless coramin is available.')
model, md = _create_base_relaxation(model_data)
branches = dict(md.elements(element_type='branch'))
bus_attrs = md.attributes(element_type='bus')
branch_attrs = md.attributes(element_type='branch')
bus_pairs = zip_items(branch_attrs['from_bus'], branch_attrs['to_bus'])
unique_bus_pairs = list(
OrderedDict((val, None) for idx, val in bus_pairs.items()).keys())
# declare the polar voltages
libbus.declare_var_vm(model,
bus_attrs['names'],
initialize=bus_attrs['vm'],
bounds=zip_items(bus_attrs['v_min'],
bus_attrs['v_max']))
va_bounds = {k: (-pi, pi) for k in bus_attrs['va']}
libbus.declare_var_va(model,
bus_attrs['names'],
initialize=bus_attrs['va'],
bounds=va_bounds)
# fix the reference bus
ref_bus = md.data['system']['reference_bus']
ref_angle = md.data['system']['reference_bus_angle']
model.va[ref_bus].fix(radians(ref_angle))
# relate c, s, and vmsq to vm and va
libbus.declare_eq_vmsq(model=model,
index_set=bus_attrs['names'],
coordinate_type=CoordinateType.POLAR)
libbranch.declare_eq_c(model=model,
index_set=unique_bus_pairs,
coordinate_type=CoordinateType.POLAR)
libbranch.declare_eq_s(model=model,
index_set=unique_bus_pairs,
coordinate_type=CoordinateType.POLAR)
# declare angle difference limits on interconnected buses
libbranch.declare_ineq_angle_diff_branch_lbub(
model=model,
index_set=branch_attrs['names'],
branches=branches,
coordinate_type=CoordinateType.POLAR)
fbbt(model, deactivate_satisfied_constraints=False)
model = coramin.relaxations.relax(model, in_place=True, use_fbbt=False)
if not use_linear_relaxation:
for b in model.component_data_objects(pe.Block,
descend_into=True,
active=True,
sort=True):
if isinstance(b, (coramin.relaxations.BaseRelaxation,
coramin.relaxations.BaseRelaxationData)):
if polynomial_degree(b.get_rhs_expr()) == 2:
if not isinstance(
b,
(coramin.relaxations.PWMcCormickRelaxation,
coramin.relaxations.PWMcCormickRelaxationData)):
b.use_linear_relaxation = False
b.rebuild()
if include_soc:
libbranch.declare_ineq_soc(
model=model,
index_set=unique_bus_pairs,
use_outer_approximation=use_linear_relaxation)
return model, md
def create_psv_acopf_model(model_data, include_feasibility_slack=False):
md = model_data.clone_in_service()
tx_utils.scale_ModelData_to_pu(md, inplace=True)
gens = dict(md.elements(element_type='generator'))
buses = dict(md.elements(element_type='bus'))
branches = dict(md.elements(element_type='branch'))
loads = dict(md.elements(element_type='load'))
shunts = dict(md.elements(element_type='shunt'))
gen_attrs = md.attributes(element_type='generator')
bus_attrs = md.attributes(element_type='bus')
branch_attrs = md.attributes(element_type='branch')
load_attrs = md.attributes(element_type='load')
shunt_attrs = md.attributes(element_type='shunt')
inlet_branches_by_bus, outlet_branches_by_bus = \
tx_utils.inlet_outlet_branches_by_bus(branches, buses)
gens_by_bus = tx_utils.gens_by_bus(buses, gens)
model = pe.ConcreteModel()
### declare (and fix) the loads at the buses
bus_p_loads, bus_q_loads = tx_utils.dict_of_bus_loads(buses, loads)
libbus.declare_var_pl(model, bus_attrs['names'], initialize=bus_p_loads)
libbus.declare_var_ql(model, bus_attrs['names'], initialize=bus_q_loads)
model.pl.fix()
model.ql.fix()
### declare the fixed shunts at the buses
bus_bs_fixed_shunts, bus_gs_fixed_shunts = tx_utils.dict_of_bus_fixed_shunts(
buses, shunts)
### declare the polar voltages
libbus.declare_var_vm(model,
bus_attrs['names'],
initialize=bus_attrs['vm'],
bounds=zip_items(bus_attrs['v_min'],
bus_attrs['v_max']))
libbus.declare_expr_vmsq(model=model,
index_set=bus_attrs['names'],
coordinate_type=CoordinateType.POLAR)
va_bounds = {k: (-pi, pi) for k in bus_attrs['va']}
libbus.declare_var_va(model,
bus_attrs['names'],
initialize=bus_attrs['va'],
bounds=va_bounds)
### include the feasibility slack for the bus balances
p_rhs_kwargs = {}
q_rhs_kwargs = {}
if include_feasibility_slack:
p_rhs_kwargs, q_rhs_kwargs, penalty_expr = _include_feasibility_slack(
model, bus_attrs, gen_attrs, bus_p_loads, bus_q_loads)
### fix the reference bus
ref_bus = md.data['system']['reference_bus']
ref_angle = md.data['system']['reference_bus_angle']
model.va[ref_bus].fix(radians(ref_angle))
### declare the generator real and reactive power
pg_init = {
k: (gen_attrs['p_min'][k] + gen_attrs['p_max'][k]) / 2.0
for k in gen_attrs['pg']
}
libgen.declare_var_pg(model,
gen_attrs['names'],
initialize=pg_init,
bounds=zip_items(gen_attrs['p_min'],
gen_attrs['p_max']))
qg_init = {
k: (gen_attrs['q_min'][k] + gen_attrs['q_max'][k]) / 2.0
for k in gen_attrs['qg']
}
libgen.declare_var_qg(model,
gen_attrs['names'],
initialize=qg_init,
bounds=zip_items(gen_attrs['q_min'],
gen_attrs['q_max']))
### declare the current flows in the branches
vr_init = {
k: bus_attrs['vm'][k] * pe.cos(bus_attrs['va'][k])
for k in bus_attrs['vm']
}
vj_init = {
k: bus_attrs['vm'][k] * pe.sin(bus_attrs['va'][k])
for k in bus_attrs['vm']
}
s_max = {k: branches[k]['rating_long_term'] for k in branches.keys()}
s_lbub = dict()
for k in branches.keys():
if s_max[k] is None:
s_lbub[k] = (None, None)
else:
s_lbub[k] = (-s_max[k], s_max[k])
pf_bounds = s_lbub
pt_bounds = s_lbub
qf_bounds = s_lbub
qt_bounds = s_lbub
pf_init = dict()
pt_init = dict()
qf_init = dict()
qt_init = dict()
for branch_name, branch in branches.items():
from_bus = branch['from_bus']
to_bus = branch['to_bus']
y_matrix = tx_calc.calculate_y_matrix_from_branch(branch)
ifr_init = tx_calc.calculate_ifr(vr_init[from_bus], vj_init[from_bus],
vr_init[to_bus], vj_init[to_bus],
y_matrix)
ifj_init = tx_calc.calculate_ifj(vr_init[from_bus], vj_init[from_bus],
vr_init[to_bus], vj_init[to_bus],
y_matrix)
itr_init = tx_calc.calculate_itr(vr_init[from_bus], vj_init[from_bus],
vr_init[to_bus], vj_init[to_bus],
y_matrix)
itj_init = tx_calc.calculate_itj(vr_init[from_bus], vj_init[from_bus],
vr_init[to_bus], vj_init[to_bus],
y_matrix)
pf_init[branch_name] = tx_calc.calculate_p(ifr_init, ifj_init,
vr_init[from_bus],
vj_init[from_bus])
pt_init[branch_name] = tx_calc.calculate_p(itr_init, itj_init,
vr_init[to_bus],
vj_init[to_bus])
qf_init[branch_name] = tx_calc.calculate_q(ifr_init, ifj_init,
vr_init[from_bus],
vj_init[from_bus])
qt_init[branch_name] = tx_calc.calculate_q(itr_init, itj_init,
vr_init[to_bus],
vj_init[to_bus])
libbranch.declare_var_pf(model=model,
index_set=branch_attrs['names'],
initialize=pf_init,
bounds=pf_bounds)
libbranch.declare_var_pt(model=model,
index_set=branch_attrs['names'],
initialize=pt_init,
bounds=pt_bounds)
libbranch.declare_var_qf(model=model,
index_set=branch_attrs['names'],
initialize=qf_init,
bounds=qf_bounds)
libbranch.declare_var_qt(model=model,
index_set=branch_attrs['names'],
initialize=qt_init,
bounds=qt_bounds)
### declare the branch power flow constraints
bus_pairs = zip_items(branch_attrs['from_bus'], branch_attrs['to_bus'])
unique_bus_pairs = list(
OrderedDict((val, None) for idx, val in bus_pairs.items()).keys())
libbranch.declare_expr_c(model=model,
index_set=unique_bus_pairs,
coordinate_type=CoordinateType.POLAR)
libbranch.declare_expr_s(model=model,
index_set=unique_bus_pairs,
coordinate_type=CoordinateType.POLAR)
libbranch.declare_eq_branch_power(model=model,
index_set=branch_attrs['names'],
branches=branches)
### declare the pq balances
libbus.declare_eq_p_balance(model=model,
index_set=bus_attrs['names'],
bus_p_loads=bus_p_loads,
gens_by_bus=gens_by_bus,
bus_gs_fixed_shunts=bus_gs_fixed_shunts,
inlet_branches_by_bus=inlet_branches_by_bus,
outlet_branches_by_bus=outlet_branches_by_bus,
**p_rhs_kwargs)
libbus.declare_eq_q_balance(model=model,
index_set=bus_attrs['names'],
bus_q_loads=bus_q_loads,
gens_by_bus=gens_by_bus,
bus_bs_fixed_shunts=bus_bs_fixed_shunts,
inlet_branches_by_bus=inlet_branches_by_bus,
outlet_branches_by_bus=outlet_branches_by_bus,
**q_rhs_kwargs)
### declare the thermal limits
libbranch.declare_ineq_s_branch_thermal_limit(
model=model,
index_set=branch_attrs['names'],
branches=branches,
s_thermal_limits=s_max,
flow_type=FlowType.POWER)
### declare the voltage min and max inequalities
libbus.declare_ineq_vm_bus_lbub(model=model,
index_set=bus_attrs['names'],
buses=buses,
coordinate_type=CoordinateType.POLAR)
### declare angle difference limits on interconnected buses
libbranch.declare_ineq_angle_diff_branch_lbub(
model=model,
index_set=branch_attrs['names'],
branches=branches,
coordinate_type=CoordinateType.POLAR)
### declare the generator cost objective
libgen.declare_expression_pgqg_operating_cost(model=model,
index_set=gen_attrs['names'],
p_costs=gen_attrs['p_cost'],
q_costs=gen_attrs.get(
'q_cost', None))
obj_expr = sum(model.pg_operating_cost[gen_name]
for gen_name in model.pg_operating_cost)
if include_feasibility_slack:
obj_expr += penalty_expr
if hasattr(model, 'qg_operating_cost'):
obj_expr += sum(model.qg_operating_cost[gen_name]
for gen_name in model.qg_operating_cost)
model.obj = pe.Objective(expr=obj_expr)
return model, md
def create_hot_start_lpac_model(model_data,
voltages,
lower_bound=-pi / 3,
upper_bound=pi / 3,
cosine_segment_count=20,
include_feasibility_slack=False,
mode="uniform"):
"""
The hot start LPAC model assumes that voltages are known, e.g. from an AC base point solution.
"""
###Grid data
md = model_data.clone_in_service()
tx_utils.scale_ModelData_to_pu(md, inplace=True)
gens = dict(md.elements(element_type='generator'))
buses = dict(md.elements(element_type='bus'))
branches = dict(md.elements(element_type='branch'))
loads = dict(md.elements(element_type='load'))
shunts = dict(md.elements(element_type='shunt'))
gen_attrs = md.attributes(element_type='generator')
bus_attrs = md.attributes(element_type='bus')
branch_attrs = md.attributes(element_type='branch')
inlet_branches_by_bus, outlet_branches_by_bus = \
tx_utils.inlet_outlet_branches_by_bus(branches, buses)
gens_by_bus = tx_utils.gens_by_bus(buses, gens)
model = pe.ConcreteModel()
###declare (and fix) the voltage magnitudes and squares of voltage magnitudes
bus_voltage_magnitudes = voltages #Assumes voltages is given as a dictionary
libbus.declare_var_vm(model,
bus_attrs['names'],
initialize=bus_voltage_magnitudes)
model.vm.fix()
libbus.declare_var_vmsq(
model=model,
index_set=bus_attrs['names'],
initialize={k: v**2
for k, v in bus_attrs['vm'].items()},
bounds=zip_items({k: v**2
for k, v in bus_attrs['v_min'].items()},
{k: v**2
for k, v in bus_attrs['v_max'].items()}))
### declare the polar voltages
libbus.declare_var_va(model,
bus_attrs['names'],
initialize=bus_attrs['va'])
### declare the cosine approximation variables
cos_hat_bounds = {k: (0, 1) for k in branch_attrs['names']}
decl.declare_var('cos_hat',
model,
branch_attrs['names'],
bounds=cos_hat_bounds)
### fix the reference bus
ref_bus = md.data['system']['reference_bus']
#ref_angle = md.data['system']['reference_bus_angle']
model.va[ref_bus].fix(radians(0.0))
### declare the fixed shunts at the buses
bus_bs_fixed_shunts, bus_gs_fixed_shunts = tx_utils.dict_of_bus_fixed_shunts(
buses, shunts)
### declare (and fix) the loads at the buses
bus_p_loads, bus_q_loads = tx_utils.dict_of_bus_loads(buses, loads)
libbus.declare_var_pl(model, bus_attrs['names'], initialize=bus_p_loads)
libbus.declare_var_ql(model, bus_attrs['names'], initialize=bus_q_loads)
model.pl.fix()
model.ql.fix()
### include the feasibility slack for the bus balances
p_rhs_kwargs = {}
q_rhs_kwargs = {}
if include_feasibility_slack:
p_rhs_kwargs, q_rhs_kwargs, penalty_expr = _include_feasibility_slack(
model, bus_attrs, gen_attrs, bus_p_loads, bus_q_loads)
### declare the generator real and reactive power
pg_init = {
k: (gen_attrs['p_min'][k] + gen_attrs['p_max'][k]) / 2.0
for k in gen_attrs['pg']
}
libgen.declare_var_pg(model,
gen_attrs['names'],
initialize=pg_init,
bounds=zip_items(gen_attrs['p_min'],
gen_attrs['p_max']))
qg_init = {
k: (gen_attrs['q_min'][k] + gen_attrs['q_max'][k]) / 2.0
for k in gen_attrs['qg']
}
libgen.declare_var_qg(model,
gen_attrs['names'],
initialize=qg_init,
bounds=zip_items(gen_attrs['q_min'],
gen_attrs['q_max']))
### declare the current flows in the branches
vr_init = {
k: bus_attrs['vm'][k] * pe.cos(bus_attrs['va'][k])
for k in bus_attrs['vm']
}
vj_init = {
k: bus_attrs['vm'][k] * pe.sin(bus_attrs['va'][k])
for k in bus_attrs['vm']
}
s_max = {k: branches[k]['rating_long_term'] for k in branches.keys()}
s_lbub = dict()
for k in branches.keys():
if s_max[k] is None:
s_lbub[k] = (None, None)
else:
s_lbub[k] = (-s_max[k], s_max[k])
pf_bounds = s_lbub
pt_bounds = s_lbub
qf_bounds = s_lbub
qt_bounds = s_lbub
pf_init = dict()
pt_init = dict()
qf_init = dict()
qt_init = dict()
for branch_name, branch in branches.items():
from_bus = branch['from_bus']
to_bus = branch['to_bus']
y_matrix = tx_calc.calculate_y_matrix_from_branch(branch)
ifr_init = tx_calc.calculate_ifr(vr_init[from_bus], vj_init[from_bus],
vr_init[to_bus], vj_init[to_bus],
y_matrix)
ifj_init = tx_calc.calculate_ifj(vr_init[from_bus], vj_init[from_bus],
vr_init[to_bus], vj_init[to_bus],
y_matrix)
itr_init = tx_calc.calculate_itr(vr_init[from_bus], vj_init[from_bus],
vr_init[to_bus], vj_init[to_bus],
y_matrix)
itj_init = tx_calc.calculate_itj(vr_init[from_bus], vj_init[from_bus],
vr_init[to_bus], vj_init[to_bus],
y_matrix)
pf_init[branch_name] = tx_calc.calculate_p(ifr_init, ifj_init,
vr_init[from_bus],
vj_init[from_bus])
pt_init[branch_name] = tx_calc.calculate_p(itr_init, itj_init,
vr_init[to_bus],
vj_init[to_bus])
qf_init[branch_name] = tx_calc.calculate_q(ifr_init, ifj_init,
vr_init[from_bus],
vj_init[from_bus])
qt_init[branch_name] = tx_calc.calculate_q(itr_init, itj_init,
vr_init[to_bus],
vj_init[to_bus])
libbranch.declare_var_pf(model=model,
index_set=branch_attrs['names'],
initialize=pf_init,
bounds=pf_bounds)
libbranch.declare_var_pt(model=model,
index_set=branch_attrs['names'],
initialize=pt_init,
bounds=pt_bounds)
libbranch.declare_var_qf(model=model,
index_set=branch_attrs['names'],
initialize=qf_init,
bounds=qf_bounds)
libbranch.declare_var_qt(model=model,
index_set=branch_attrs['names'],
initialize=qt_init,
bounds=qt_bounds)
####################
#Constraints
####################
###Balance equations in a bus
#p balance
libbus.declare_eq_p_balance(model=model,
index_set=bus_attrs['names'],
bus_p_loads=bus_p_loads,
gens_by_bus=gens_by_bus,
bus_gs_fixed_shunts=bus_gs_fixed_shunts,
inlet_branches_by_bus=inlet_branches_by_bus,
outlet_branches_by_bus=outlet_branches_by_bus,
**p_rhs_kwargs)
#q balance
libbus.declare_eq_q_balance(model=model,
index_set=bus_attrs['names'],
bus_q_loads=bus_q_loads,
gens_by_bus=gens_by_bus,
bus_bs_fixed_shunts=bus_bs_fixed_shunts,
inlet_branches_by_bus=inlet_branches_by_bus,
outlet_branches_by_bus=outlet_branches_by_bus,
**q_rhs_kwargs)
### Power in a branch
branch_con_set = decl.declare_set('_con_eq_p_q_lpac_branch_power', model,
branch_attrs['names'])
model.eq_pf_branch_t = pe.Constraint(branch_con_set)
model.eq_pt_branch_t = pe.Constraint(branch_con_set)
model.eq_qf_branch_t = pe.Constraint(branch_con_set)
model.eq_qt_branch_t = pe.Constraint(branch_con_set)
for branch_name in branch_con_set:
branch = branches[branch_name]
from_bus = branch['from_bus']
to_bus = branch['to_bus']
g = tx_calc.calculate_conductance(branch)
b = tx_calc.calculate_susceptance(branch)
model.eq_pf_branch_t[branch_name] = \
model.pf[branch_name] == \
g*model.vmsq[from_bus] - model.vm[from_bus]*model.vm[to_bus]*(g * model.cos_hat[branch_name] + b * (model.va[from_bus] - model.va[to_bus]))
model.eq_pt_branch_t[branch_name] = \
model.pt[branch_name] == \
g*model.vmsq[to_bus] - model.vm[from_bus]*model.vm[to_bus]*(g * model.cos_hat[branch_name] + b * (model.va[to_bus] - model.va[from_bus]))
model.eq_qf_branch_t[branch_name] = \
model.qf[branch_name] == \
-b*model.vmsq[from_bus] - model.vm[from_bus]*model.vm[to_bus]*(g*(model.va[from_bus] - model.va[to_bus]) - b*model.cos_hat[branch_name])
model.eq_qt_branch_t[branch_name] = \
model.qt[branch_name] == \
-b*model.vmsq[to_bus] - model.vm[from_bus]*model.vm[to_bus]*(g*(model.va[to_bus] - model.va[from_bus]) - b*model.cos_hat[branch_name])
### Piecewise linear cosine constraints
model.N = pe.Set(initialize=list(range(cosine_segment_count + 1)))
declare_pwl_cosine_bounds(model=model,
index_set=branch_attrs['names'],
branches=branches,
lower_bound=lower_bound,
upper_bound=upper_bound,
cosine_segment_count=cosine_segment_count,
mode=mode)
### Objective is to maximize cosine hat variables
obj_expr = sum(model.cos_hat[branch_name]
for branch_name in branch_attrs['names'])
if include_feasibility_slack:
obj_expr += penalty_expr
model.obj = pe.Objective(expr=obj_expr)
return model, md
def create_psv_acopf_model(model_data):
md = tx_utils.scale_ModelData_to_pu(model_data)
gens = dict(md.elements(element_type='generator'))
buses = dict(md.elements(element_type='bus'))
branches = dict(md.elements(element_type='branch'))
loads = dict(md.elements(element_type='load'))
shunts = dict(md.elements(element_type='shunt'))
gen_attrs = md.attributes(element_type='generator')
bus_attrs = md.attributes(element_type='bus')
branch_attrs = md.attributes(element_type='branch')
load_attrs = md.attributes(element_type='load')
shunt_attrs = md.attributes(element_type='shunt')
inlet_branches_by_bus, outlet_branches_by_bus = \
tx_utils.inlet_outlet_branches_by_bus(branches, buses)
gens_by_bus = tx_utils.gens_in_service_by_bus(buses, gens)
model = pe.ConcreteModel()
### declare (and fix) the loads at the buses
bus_p_loads, bus_q_loads = tx_utils.dict_of_bus_loads(buses, loads)
libbus.declare_var_pl(model, bus_attrs['names'], initialize=bus_p_loads)
libbus.declare_var_ql(model, bus_attrs['names'], initialize=bus_q_loads)
model.pl.fix()
model.ql.fix()
### declare the fixed shunts at the buses
bus_bs_fixed_shunts, bus_gs_fixed_shunts = tx_utils.dict_of_bus_fixed_shunts(
buses, shunts)
### declare the polar voltages
libbus.declare_var_vm(model,
bus_attrs['names'],
initialize=bus_attrs['vm'],
bounds=zip_items(bus_attrs['v_min'],
bus_attrs['v_max']))
va_bounds = {k: (-pi, pi) for k in bus_attrs['va']}
libbus.declare_var_va(model,
bus_attrs['names'],
initialize=bus_attrs['va'],
bounds=va_bounds)
### fix the reference bus
ref_bus = md.data['system']['reference_bus']
model.va[ref_bus].fix(0.0)
ref_angle = md.data['system']['reference_bus_angle']
if ref_angle != 0.0:
raise ValueError('The RIV ACOPF formulation currently only supports'
' a reference bus angle of 0 degrees, but an angle'
' of {} degrees was found.'.format(ref_angle))
### declare the generator real and reactive power
pg_init = {
k: (gen_attrs['p_min'][k] + gen_attrs['p_max'][k]) / 2.0
for k in gen_attrs['pg']
}
libgen.declare_var_pg(model,
gen_attrs['names'],
initialize=pg_init,
bounds=zip_items(gen_attrs['p_min'],
gen_attrs['p_max']))
qg_init = {
k: (gen_attrs['q_min'][k] + gen_attrs['q_max'][k]) / 2.0
for k in gen_attrs['qg']
}
libgen.declare_var_qg(model,
gen_attrs['names'],
initialize=qg_init,
bounds=zip_items(gen_attrs['q_min'],
gen_attrs['q_max']))
### declare the current flows in the branches
vr_init = {
k: bus_attrs['vm'][k] * pe.cos(bus_attrs['va'][k])
for k in bus_attrs['vm']
}
vj_init = {
k: bus_attrs['vm'][k] * pe.sin(bus_attrs['va'][k])
for k in bus_attrs['vm']
}
s_max = {k: branches[k]['rating_long_term'] for k in branches.keys()}
s_lbub = {k: (-s_max[k], s_max[k]) for k in branches.keys()}
pf_bounds = s_lbub
pt_bounds = s_lbub
qf_bounds = s_lbub
qt_bounds = s_lbub
pf_init = dict()
pt_init = dict()
qf_init = dict()
qt_init = dict()
for branch_name, branch in branches.items():
from_bus = branch['from_bus']
to_bus = branch['to_bus']
y_matrix = tx_calc.calculate_y_matrix_from_branch(branch)
ifr_init = tx_calc.calculate_ifr(vr_init[from_bus], vj_init[from_bus],
vr_init[to_bus], vj_init[to_bus],
y_matrix)
ifj_init = tx_calc.calculate_ifj(vr_init[from_bus], vj_init[from_bus],
vr_init[to_bus], vj_init[to_bus],
y_matrix)
itr_init = tx_calc.calculate_itr(vr_init[from_bus], vj_init[from_bus],
vr_init[to_bus], vj_init[to_bus],
y_matrix)
itj_init = tx_calc.calculate_itj(vr_init[from_bus], vj_init[from_bus],
vr_init[to_bus], vj_init[to_bus],
y_matrix)
pf_init[branch_name] = tx_calc.calculate_p(ifr_init, ifj_init,
vr_init[from_bus],
vj_init[from_bus])
pt_init[branch_name] = tx_calc.calculate_p(itr_init, itj_init,
vr_init[to_bus],
vj_init[to_bus])
qf_init[branch_name] = tx_calc.calculate_q(ifr_init, ifj_init,
vr_init[from_bus],
vj_init[from_bus])
qt_init[branch_name] = tx_calc.calculate_q(itr_init, itj_init,
vr_init[to_bus],
vj_init[to_bus])
libbranch.declare_var_pf(model=model,
index_set=branch_attrs['names'],
initialize=pf_init,
bounds=pf_bounds)
libbranch.declare_var_pt(model=model,
index_set=branch_attrs['names'],
initialize=pt_init,
bounds=pt_bounds)
libbranch.declare_var_qf(model=model,
index_set=branch_attrs['names'],
initialize=qf_init,
bounds=qf_bounds)
libbranch.declare_var_qt(model=model,
index_set=branch_attrs['names'],
initialize=qt_init,
bounds=qt_bounds)
### declare the branch power flow constraints
libbranch.declare_eq_branch_power(model=model,
index_set=branch_attrs['names'],
branches=branches,
branch_attrs=branch_attrs,
coordinate_type=CoordinateType.POLAR)
### declare the pq balances
libbus.declare_eq_p_balance(model=model,
index_set=bus_attrs['names'],
bus_p_loads=bus_p_loads,
gens_by_bus=gens_by_bus,
bus_gs_fixed_shunts=bus_gs_fixed_shunts,
inlet_branches_by_bus=inlet_branches_by_bus,
outlet_branches_by_bus=outlet_branches_by_bus,
coordinate_type=CoordinateType.POLAR)
libbus.declare_eq_q_balance(model=model,
index_set=bus_attrs['names'],
bus_q_loads=bus_q_loads,
gens_by_bus=gens_by_bus,
bus_bs_fixed_shunts=bus_bs_fixed_shunts,
inlet_branches_by_bus=inlet_branches_by_bus,
outlet_branches_by_bus=outlet_branches_by_bus,
coordinate_type=CoordinateType.POLAR)
### declare the thermal limits
libbranch.declare_ineq_s_branch_thermal_limit(
model=model,
index_set=branch_attrs['names'],
branches=branches,
s_thermal_limits=s_max,
flow_type=FlowType.POWER)
### declare the voltage min and max inequalities
libbus.declare_ineq_vm_bus_lbub(model=model,
index_set=bus_attrs['names'],
buses=buses,
coordinate_type=CoordinateType.POLAR)
### declare angle difference limits on interconnected buses
libbranch.declare_ineq_angle_diff_branch_lbub(
model=model,
index_set=branch_attrs['names'],
branches=branches,
coordinate_type=CoordinateType.POLAR)
### declare the generator cost objective
libgen.declare_expression_pgqg_operating_cost(model=model,
index_set=gen_attrs['names'],
p_costs=gen_attrs['p_cost'],
q_costs=gen_attrs.get(
'q_cost', None))
obj_expr = sum(model.pg_operating_cost[gen_name]
for gen_name in model.pg_operating_cost)
if hasattr(model, 'qg_operating_cost'):
obj_expr += sum(model.qg_operating_cost[gen_name]
for gen_name in model.qg_operating_cost)
model.obj = pe.Objective(expr=obj_expr)
return model
def _create_base_ac_with_pwl_approx_model(model_data, branch_dict, Q, include_feasibility_slack=False):
md = model_data.clone_in_service()
tx_utils.scale_ModelData_to_pu(md, inplace = True)
gens = dict(md.elements(element_type='generator'))
buses = dict(md.elements(element_type='bus'))
branches = dict(md.elements(element_type='branch'))
loads = dict(md.elements(element_type='load'))
shunts = dict(md.elements(element_type='shunt'))
gen_attrs = md.attributes(element_type='generator')
bus_attrs = md.attributes(element_type='bus')
branch_attrs = md.attributes(element_type='branch')
inlet_branches_by_bus, outlet_branches_by_bus = \
tx_utils.inlet_outlet_branches_by_bus(branches, buses)
gens_by_bus = tx_utils.gens_by_bus(buses, gens)
bus_pairs = zip_items(branch_attrs['from_bus'], branch_attrs['to_bus'])
unique_bus_pairs = list(OrderedDict((val, None) for idx, val in bus_pairs.items()))
model = pe.ConcreteModel()
### declare (and fix) the loads at the buses
bus_p_loads, bus_q_loads = tx_utils.dict_of_bus_loads(buses, loads)
libbus.declare_var_pl(model, bus_attrs['names'], initialize=bus_p_loads)
libbus.declare_var_ql(model, bus_attrs['names'], initialize=bus_q_loads)
model.pl.fix()
model.ql.fix()
### declare the fixed shunts at the buses
bus_bs_fixed_shunts, bus_gs_fixed_shunts = tx_utils.dict_of_bus_fixed_shunts(buses, shunts)
libbus.declare_var_vm(model=model, index_set=bus_attrs['names'], initialize=bus_attrs['vm'], bounds=zip_items(bus_attrs['v_min'], bus_attrs['v_max']))
libbus.declare_var_vmsq(model=model,
index_set=bus_attrs['names'],
initialize={k: v**2 for k, v in bus_attrs['vm'].items()},
bounds=zip_items({k: v**2 for k, v in bus_attrs['v_min'].items()},
{k: v**2 for k, v in bus_attrs['v_max'].items()}))
# libbranch.declare_var_c(model=model, index_set=unique_bus_pairs)
# libbranch.declare_var_s(model=model, index_set=unique_bus_pairs)
### declare the polar voltages
va_bounds = {k: (-math.pi, math.pi) for k in bus_attrs['va']}
libbus.declare_var_va(model, bus_attrs['names'], initialize=bus_attrs['va'],
bounds=va_bounds
)
###declare the phase angle differences in each branch
libbranch.declare_var_dva(model, index_set=unique_bus_pairs)
libbranch.declare_eq_delta_va(model, index_set=unique_bus_pairs)
### include the feasibility slack for the bus balances
p_rhs_kwargs = {}
q_rhs_kwargs = {}
if include_feasibility_slack:
p_rhs_kwargs, q_rhs_kwargs, penalty_expr = _include_feasibility_slack(model, bus_attrs, gen_attrs, bus_p_loads, bus_q_loads)
### declare the generator real and reactive power
pg_init = {k: (gen_attrs['p_min'][k] + gen_attrs['p_max'][k]) / 2.0 for k in gen_attrs['pg']}
libgen.declare_var_pg(model, gen_attrs['names'], initialize=pg_init,
bounds=zip_items(gen_attrs['p_min'], gen_attrs['p_max'])
)
qg_init = {k: (gen_attrs['q_min'][k] + gen_attrs['q_max'][k]) / 2.0 for k in gen_attrs['qg']}
libgen.declare_var_qg(model, gen_attrs['names'], initialize=qg_init,
bounds=zip_items(gen_attrs['q_min'], gen_attrs['q_max'])
)
### declare the current flows in the branches
vr_init = {k: bus_attrs['vm'][k] * pe.cos(bus_attrs['va'][k]) for k in bus_attrs['vm']}
vj_init = {k: bus_attrs['vm'][k] * pe.sin(bus_attrs['va'][k]) for k in bus_attrs['vm']}
s_max = {k: branches[k]['rating_long_term'] for k in branches.keys()}
s_lbub = dict()
for k in branches.keys():
if s_max[k] is None:
s_lbub[k] = (None, None)
else:
s_lbub[k] = (-s_max[k],s_max[k])
pf_bounds = s_lbub
pt_bounds = s_lbub
qf_bounds = s_lbub
qt_bounds = s_lbub
pf_init = dict()
pt_init = dict()
qf_init = dict()
qt_init = dict()
for branch_name, branch in branches.items():
from_bus = branch['from_bus']
to_bus = branch['to_bus']
y_matrix = tx_calc.calculate_y_matrix_from_branch(branch)
ifr_init = tx_calc.calculate_ifr(vr_init[from_bus], vj_init[from_bus], vr_init[to_bus],
vj_init[to_bus], y_matrix)
ifj_init = tx_calc.calculate_ifj(vr_init[from_bus], vj_init[from_bus], vr_init[to_bus],
vj_init[to_bus], y_matrix)
itr_init = tx_calc.calculate_itr(vr_init[from_bus], vj_init[from_bus], vr_init[to_bus],
vj_init[to_bus], y_matrix)
itj_init = tx_calc.calculate_itj(vr_init[from_bus], vj_init[from_bus], vr_init[to_bus],
vj_init[to_bus], y_matrix)
pf_init[branch_name] = tx_calc.calculate_p(ifr_init, ifj_init, vr_init[from_bus], vj_init[from_bus])
pt_init[branch_name] = tx_calc.calculate_p(itr_init, itj_init, vr_init[to_bus], vj_init[to_bus])
qf_init[branch_name] = tx_calc.calculate_q(ifr_init, ifj_init, vr_init[from_bus], vj_init[from_bus])
qt_init[branch_name] = tx_calc.calculate_q(itr_init, itj_init, vr_init[to_bus], vj_init[to_bus])
libbranch.declare_var_pf(model=model,
index_set=branch_attrs['names'],
initialize=pf_init,
bounds=pf_bounds
)
libbranch.declare_var_pt(model=model,
index_set=branch_attrs['names'],
initialize=pt_init,
bounds=pt_bounds
)
libbranch.declare_var_qf(model=model,
index_set=branch_attrs['names'],
initialize=qf_init,
bounds=qf_bounds
)
libbranch.declare_var_qt(model=model,
index_set=branch_attrs['names'],
initialize=qt_init,
bounds=qt_bounds
)
### declare the branch power flow constraints
### declare a binary on/off variable for deenergizing a given branch
decl.declare_var('u', model=model, index_set=branch_attrs['names'], within=pe.Binary)
model.u.fix(1)
branch_name_set = decl.declare_set('branch_name', model=model, index_set=branch_attrs['names'])
model.box_index_set = pe.RangeSet(Q)
model.power_type_set = pe.Set(initialize=[0,1])
#Note: 0 is for power_type == "Active"; 1 is for power_type=="Reactive"
#For active power energization/deenergization
model.u_branch = pe.Var(branch_name_set, model.box_index_set, model.power_type_set, within=pe.Binary)
#For selecting the appropriate interval of the PWL approximation
model.dva_branch = pe.Var(branch_name_set, model.box_index_set, model.power_type_set)
#(5) - Constraints for the on/off variable u
def u_sum_rule(model, branch_name, j):
return model.u[branch_name] == sum(model.u_branch[branch_name, i, j] for i in model.box_index_set)
model.u_sum_Constr = pe.Constraint(branch_name_set, model.power_type_set, rule=u_sum_rule)
#(6) - Constraints that sum of dva variables should be equal to total dva
#Upper bound constraints
def delta_branch_ub_rule(model, branch_name, j):
branch = branches[branch_name]
from_bus = branch['from_bus']
to_bus = branch['to_bus']
return -model.dva[(from_bus, to_bus)] + sum(model.dva_branch[branch_name, i, j] for i in model.box_index_set) <= math.pi*(1-model.u[branch_name])
model.delta_branch_ub_Constr = pe.Constraint(branch_name_set, model.power_type_set, rule=delta_branch_ub_rule)
#Lower bound constraints
def delta_branch_lb_rule(model, branch_name, j):
branch = branches[branch_name]
from_bus = branch['from_bus']
to_bus = branch['to_bus']
return -model.dva[(from_bus, to_bus)] + sum(model.dva_branch[branch_name, i, j] for i in model.box_index_set) >= -math.pi*(1-model.u[branch_name])
model.delta_branch_lb_Constr = pe.Constraint(branch_name_set, model.power_type_set, rule=delta_branch_lb_rule)
#(7) - Constraints that force dva variable to be in only one interval
#Upper bound
def delta_branch_box_ub_rule(model, branch_name, i, j):
if j==0:
delta_ub = branch_dict["Active_from_bus"][branch_name]['boxes']['coords'][i-1][7][2]
else:
delta_ub = branch_dict["Reactive_from_bus"][branch_name]['boxes']['coords'][i-1][7][2]
return model.dva_branch[branch_name, i, j] <= delta_ub*model.u_branch[branch_name, i, j]
model.delta_branch_box_ub_Constr = pe.Constraint(branch_name_set, model.box_index_set, model.power_type_set, rule=delta_branch_box_ub_rule)
def delta_branch_box_lb_rule(model, branch_name, i, j):
if j==0:
delta_lb = branch_dict["Active_from_bus"][branch_name]['boxes']['coords'][i-1][0][2]
else:
delta_lb = branch_dict["Reactive_from_bus"][branch_name]['boxes']['coords'][i-1][0][2]
return model.dva_branch[branch_name, i, j] >= delta_lb*model.u_branch[branch_name, i, j]
model.delta_branch_box_lb_Constr = pe.Constraint(branch_name_set, model.box_index_set, model.power_type_set, rule=delta_branch_box_lb_rule)
#(8) - Approximating power flow equation by PWL approximation
#Active_from_bus
def pwl_active_from_ub_rule(model, branch_name, i):
branch = branches[branch_name]
from_bus = branch['from_bus']
to_bus = branch['to_bus']
g = tx_calc.calculate_conductance(branch)
b = tx_calc.calculate_susceptance(branch)
coeffs = branch_dict["Active_from_bus"][branch_name]['boxes']['coefficients'][i-1]
#M = 10*(g+b) + 4*(coeffs[0]+coeffs[1]+coeffs[2]+coeffs[3])
M = 2*s_max[branch_name] + 10*(np.abs(coeffs[0])+np.abs(coeffs[1])+np.abs(coeffs[2])+np.abs(coeffs[3]))
return -model.pf[branch_name] + coeffs[0]*model.vm[from_bus] + coeffs[1]*model.vm[to_bus] + coeffs[2]*model.dva_branch[branch_name, i, 0] + coeffs[3] <= M*(1-model.u_branch[branch_name, i, 0])
model.pwl_active_from_ub_Constr = pe.Constraint(branch_name_set, model.box_index_set, rule=pwl_active_from_ub_rule)
def pwl_active_from_lb_rule(model, branch_name, i):
branch = branches[branch_name]
from_bus = branch['from_bus']
to_bus = branch['to_bus']
g = tx_calc.calculate_conductance(branch)
b = tx_calc.calculate_susceptance(branch)
coeffs = branch_dict["Active_from_bus"][branch_name]['boxes']['coefficients'][i-1]
#M = -(10*(g+b) + 4*(coeffs[0]+coeffs[1]+coeffs[2]+coeffs[3]))
M = -2*s_max[branch_name] - 10*(np.abs(coeffs[0])+np.abs(coeffs[1])+np.abs(coeffs[2])+np.abs(coeffs[3]))
return -model.pf[branch_name] + coeffs[0]*model.vm[from_bus] + coeffs[1]*model.vm[to_bus] + coeffs[2]*model.dva_branch[branch_name, i, 0] + coeffs[3] >= M*(1-model.u_branch[branch_name, i, 0])
model.pwl_active_from_lb_Constr = pe.Constraint(branch_name_set, model.box_index_set, rule=pwl_active_from_lb_rule)
#Active_to_bus
def pwl_active_to_ub_rule(model, branch_name, i):
branch = branches[branch_name]
from_bus = branch['from_bus']
to_bus = branch['to_bus']
g = tx_calc.calculate_conductance(branch)
b = tx_calc.calculate_susceptance(branch)
coeffs = branch_dict["Active_to_bus"][branch_name]['boxes']['coefficients'][i-1]
#M = 10*(g+b) + 4*(coeffs[0]+coeffs[1]+coeffs[2]+coeffs[3])
M = 2*s_max[branch_name] + 10*(np.abs(coeffs[0])+np.abs(coeffs[1])+np.abs(coeffs[2])+np.abs(coeffs[3]))
return -model.pt[branch_name] + coeffs[0]*model.vm[from_bus] + coeffs[1]*model.vm[to_bus] + coeffs[2]*model.dva_branch[branch_name, i, 0] + coeffs[3] <= M*(1-model.u_branch[branch_name, i, 0])
model.pwl_active_to_ub_Constr = pe.Constraint(branch_name_set, model.box_index_set, rule=pwl_active_to_ub_rule)
def pwl_active_to_lb_rule(model, branch_name, i):
branch = branches[branch_name]
from_bus = branch['from_bus']
to_bus = branch['to_bus']
g = tx_calc.calculate_conductance(branch)
b = tx_calc.calculate_susceptance(branch)
coeffs = branch_dict["Active_to_bus"][branch_name]['boxes']['coefficients'][i-1]
#M = -(10*(g+b) + 4*(coeffs[0]+coeffs[1]+coeffs[2]+coeffs[3]))
M = -2*s_max[branch_name] - 10*(np.abs(coeffs[0])+np.abs(coeffs[1])+np.abs(coeffs[2])+np.abs(coeffs[3]))
return -model.pt[branch_name] + coeffs[0]*model.vm[from_bus] + coeffs[1]*model.vm[to_bus] + coeffs[2]*model.dva_branch[branch_name, i, 0] + coeffs[3] >= M*(1-model.u_branch[branch_name, i, 0])
model.pwl_active_to_lb_Constr = pe.Constraint(branch_name_set, model.box_index_set, rule=pwl_active_to_lb_rule)
#Reactive_from_bus
def pwl_reactive_from_ub_rule(model, branch_name, i):
branch = branches[branch_name]
from_bus = branch['from_bus']
to_bus = branch['to_bus']
g = tx_calc.calculate_conductance(branch)
b = tx_calc.calculate_susceptance(branch)
coeffs = branch_dict["Reactive_from_bus"][branch_name]['boxes']['coefficients'][i-1]
#M = 10*(g+b) + 4*(coeffs[0]+coeffs[1]+coeffs[2]+coeffs[3])
M = 2*s_max[branch_name] + 10*(np.abs(coeffs[0])+np.abs(coeffs[1])+np.abs(coeffs[2])+np.abs(coeffs[3]))
return -model.qf[branch_name] + coeffs[0]*model.vm[from_bus] + coeffs[1]*model.vm[to_bus] + coeffs[2]*model.dva_branch[branch_name, i, 1] + coeffs[3] <= M*(1-model.u_branch[branch_name, i, 1])
model.pwl_reactive_from_ub_Constr = pe.Constraint(branch_name_set, model.box_index_set, rule=pwl_reactive_from_ub_rule)
def pwl_reactive_from_lb_rule(model, branch_name, i):
branch = branches[branch_name]
from_bus = branch['from_bus']
to_bus = branch['to_bus']
g = tx_calc.calculate_conductance(branch)
b = tx_calc.calculate_susceptance(branch)
coeffs = branch_dict["Reactive_from_bus"][branch_name]['boxes']['coefficients'][i-1]
#M = -(10*(g+b) + 4*(coeffs[0]+coeffs[1]+coeffs[2]+coeffs[3]))
M = -2*s_max[branch_name] - 10*(np.abs(coeffs[0])+np.abs(coeffs[1])+np.abs(coeffs[2])+np.abs(coeffs[3]))
return -model.qf[branch_name] + coeffs[0]*model.vm[from_bus] + coeffs[1]*model.vm[to_bus] + coeffs[2]*model.dva_branch[branch_name, i, 1] + coeffs[3] >= M*(1-model.u_branch[branch_name, i, 1])
model.pwl_reactive_from_lb_Constr = pe.Constraint(branch_name_set, model.box_index_set, rule=pwl_reactive_from_lb_rule)
#Reactive_to_bus
def pwl_reactive_to_ub_rule(model, branch_name, i):
branch = branches[branch_name]
from_bus = branch['from_bus']
to_bus = branch['to_bus']
g = tx_calc.calculate_conductance(branch)
b = tx_calc.calculate_susceptance(branch)
coeffs = branch_dict["Reactive_to_bus"][branch_name]['boxes']['coefficients'][i-1]
#M = 10*(g+b) + 4*(coeffs[0]+coeffs[1]+coeffs[2]+coeffs[3])
M = 2*s_max[branch_name] + 10*(np.abs(coeffs[0])+np.abs(coeffs[1])+np.abs(coeffs[2])+np.abs(coeffs[3]))
return -model.qt[branch_name] + coeffs[0]*model.vm[from_bus] + coeffs[1]*model.vm[to_bus] + coeffs[2]*model.dva_branch[branch_name, i, 1] + coeffs[3] <= M*(1-model.u_branch[branch_name, i, 1])
model.pwl_reactive_to_ub_Constr = pe.Constraint(branch_name_set, model.box_index_set, rule=pwl_reactive_to_ub_rule)
def pwl_reactive_to_lb_rule(model, branch_name, i):
branch = branches[branch_name]
from_bus = branch['from_bus']
to_bus = branch['to_bus']
g = tx_calc.calculate_conductance(branch)
b = tx_calc.calculate_susceptance(branch)
coeffs = branch_dict["Reactive_to_bus"][branch_name]['boxes']['coefficients'][i-1]
#M = -(10*(g+b) + 4*(coeffs[0]+coeffs[1]+coeffs[2]+coeffs[3]))
M = -2*s_max[branch_name] - 10*(np.abs(coeffs[0])+np.abs(coeffs[1])+np.abs(coeffs[2])+np.abs(coeffs[3]))
return -model.qt[branch_name] + coeffs[0]*model.vm[from_bus] + coeffs[1]*model.vm[to_bus] + coeffs[2]*model.dva_branch[branch_name, i, 1] + coeffs[3] >= M*(1-model.u_branch[branch_name, i, 1])
model.pwl_reactive_to_lb_Constr = pe.Constraint(branch_name_set, model.box_index_set, rule=pwl_reactive_to_lb_rule)
### declare the pq balances
libbus.declare_eq_p_balance(model=model,
index_set=bus_attrs['names'],
bus_p_loads=bus_p_loads,
gens_by_bus=gens_by_bus,
bus_gs_fixed_shunts=bus_gs_fixed_shunts,
inlet_branches_by_bus=inlet_branches_by_bus,
outlet_branches_by_bus=outlet_branches_by_bus,
**p_rhs_kwargs
)
libbus.declare_eq_q_balance(model=model,
index_set=bus_attrs['names'],
bus_q_loads=bus_q_loads,
gens_by_bus=gens_by_bus,
bus_bs_fixed_shunts=bus_bs_fixed_shunts,
inlet_branches_by_bus=inlet_branches_by_bus,
outlet_branches_by_bus=outlet_branches_by_bus,
**q_rhs_kwargs
)
### declare the thermal limits
libbranch.declare_ineq_s_branch_thermal_limit(model=model,
index_set=branch_attrs['names'],
branches=branches,
s_thermal_limits=s_max,
flow_type=FlowType.POWER
)
# declare angle difference limits on interconnected buses
# libbranch.declare_ineq_angle_diff_branch_lbub_c_s(model=model,
# index_set=branch_attrs['names'],
# branches=branches
# )
### declare the generator cost objective
libgen.declare_expression_pgqg_operating_cost(model=model,
index_set=gen_attrs['names'],
p_costs=gen_attrs['p_cost'],
q_costs=gen_attrs.get('q_cost', None)
)
obj_expr = sum(model.pg_operating_cost[gen_name] for gen_name in model.pg_operating_cost)
if include_feasibility_slack:
obj_expr += penalty_expr
if hasattr(model, 'qg_operating_cost'):
obj_expr += sum(model.qg_operating_cost[gen_name] for gen_name in model.qg_operating_cost)
model.obj = pe.Objective(expr=obj_expr)
return model, md
