def solve_ac(self, net: pfnet.Network):
"""
Resuelve un flujo de potencia de forma ac
"""
net.clear_flags()
# bus voltage angles
net.set_flags('bus', 'variable', 'not slack', 'voltage angle')
# bus voltage magnitudes
net.set_flags('bus', 'variable', 'not regulated by generator',
'voltage magnitude')
# slack gens active powers
net.set_flags('generator', 'variable', 'slack', 'active power')
# regulator gens reactive powers
net.set_flags('generator', 'variable', 'regulator', 'reactive power')
p = pfnet.Problem(net)
p.add_constraint(pfnet.Constraint('AC power balance', net))
p.add_constraint(
pfnet.Constraint('generator active power participation', net))
p.add_constraint(pfnet.Constraint('PVPQ switching', net))
p.add_heuristic(pfnet.Heuristic('PVPQ switching', net))
p.analyze()
self.solve(p, net)
def solve_dc(self, net: pfnet.Network):
"""
Resuelve un flujo de potencia de forma dc
"""
net.clear_flags()
# bus voltage angles
net.set_flags('bus', 'variable', 'not slack', 'voltage angle')
# slack gens active powers
net.set_flags('generator', 'variable', 'slack', 'active power')
p = pfnet.Problem(net)
p.add_constraint(pfnet.Constraint('DC power balance', net))
p.add_constraint(
pfnet.Constraint('generator active power participation', net))
p.analyze()
self.solve(p, net)
