flag = 2 # 2 = all non-tx branches 4 = all two-winding and non-transformer branches
entry = 1 #1 = every branch once 2 = every branch from both sides
ties = 1 # 1 = inside subsystem lines, # 2 = ties only, # 3 = everything
ierr,ratio = psspy.atrnreal(sid,2,ties,flag,entry,['RATIO2'])
ratio =ratio[0]
fromflow = []
for i in range(0,len(bus_num)):
k = i + 1
fromflow.append(brnflo(bus_num[1],bus_num[0],str(k)))
ReactivePowerDifference = abs(fromflow[0].imag - fromflow[1].imag)
RealPowerDifference = abs(fromflow[0].real - fromflow[1].real)
# Determine the Load Buses to scale up the load
psspy.bsys(0,0,[ 0.2, 999.],0,[],5,ScaleLoadAtBuses,0,[],0,[])
ierr,load_bus = psspy.alodbusint(0,1,['NUMBER'])
load_bus = load_bus[0]
# determine which transformer should be controlled and how to control.
tapChangeDirection = []
for i in range(0,2):
tapChangeDirection.append(0)
if TransformerToControl:
for i in range(0,len(TransformerToControl)):
if TransformerToControl[i] == "TX4LTC_CTL":
TransformerToControlIndex = 4
TransformerRatioIndex = 0
elif TransformerToControl[i] == "TX5LTC_CTL":
TransformerToControlIndex = 5
TransformerRatioIndex = 1
if Control[i] == "RAISE":
PSSE_CASE = case_name_constant % current_percentage
psspy.case(PSSE_CASE)
# silent the output
output = StringIO.StringIO()
with silence(output):
#pick the bus in Dominion Area 345 is the index of Dominion
psspy.case(savecase)
# psspy.bsys(0,0,[ 0.2, 999.],1,[],0,[],0,[],0,[])
ierr, all_bus = psspy.abusint(-1, 1, ['NUMBER'])
bus_num = all_bus[0]
#Load Bus
psspy.bsys(sid=1, numbus=len(bus_num), buses=bus_num)
ierr, load_bus = psspy.alodbusint(1, 1, ['NUMBER'])
load_bus = load_bus[0]
# Gen Bus
psspy.bsys(sid=1, numbus=len(bus_num), buses=bus_num)
ierr, gen_bus = psspy.agenbusint(1, 1, ['NUMBER'])
gen_bus = gen_bus[0]
#change the load and the generation
percentage = 1 - (current_percentage - 5) / current_percentage
pssepylib.change_load(load_bus, percentage)
increment = pssepylib.LoadIncreaseMW(load_bus, percentage)
pssepylib.change_gen(gen_bus, increment)
# try:
# load_real_sum = sum(load_real)
def findAllLoadBuses(bus_num):
psspy.bsys(sid = 1,numbus = len(bus_num), buses = bus_num)
ierr,load_bus = psspy.alodbusint(1,1,['NUMBER'])
load_bus = load_bus[0]
return load_bus
# find all the buses
psspy.bsys(0, 0, [0.0, 0.0], 1, [1], 0, [], 0, [], 0, [])
ierr, all_bus = psspy.abusint(0, 1, ['number'])
bus_num = all_bus[0]
#List of all machines
psspy.bsys(sid=1, numbus=len(bus_num), buses=bus_num)
ierr, machine_bus = psspy.amachint(1, 1, ['NUMBER'])
machine_bus = machine_bus[0]
ierr, machine_id = psspy.amachchar(1, 1, ['ID'])
machine_id = machine_id[0]
#List of all load
psspy.bsys(sid=1, numbus=len(bus_num), buses=bus_num)
ierr, load_bus = psspy.alodbusint(1, 1, ['NUMBER'])
load_bus = load_bus[0]
ierr, load_id = psspy.aloadchar(1, 1, ['ID'])
load_id = load_id[0]
#List of branches
ierr, internal_linesfbtb = psspy.abrnint(sid=1,
ties=1,
flag=1,
string=['FROMNUMBER', 'TONUMBER'])
ierr, internal_linesid = psspy.abrnchar(sid=1,
ties=1,
flag=1,
string=['ID'])
#Building the list of contingencies
# Set the time step for the dynamic simulation
psspy.dynamics_solution_params(realar=[_f, _f, 0.005, _f, _f, _f, _f, _f])
psspy.machine_array_channel([1, 2, 6000]) # Monitor Kvilldal Power
psspy.machine_array_channel([2, 7, 6000]) # Monitor Kvilldal Frequency
ierr = psspy.strt(outfile=outputfile) # Tell PSS/E to write to the output file
# List all in service buses
sid = 1
# Create subsystem based on voltage range
sid = psspy.bsys(1, 1, [0, 1000])
# Get bus numbers
load_ids = test = psspy.alodbusint(1, 2, 'NUMBER')[1][0]
# Standard deviation of the loads
sd = 0.001
# Simulation parameters
t = 1 # Start time of the simulation
T = 90 # End time of the simulation
dt = 1 # How often to step the load
steps = int(T / dt) # Calculate how many times the loads should be stepped
pmu_td = 4 # To tell PSS/E to write to screen and file at PMU frequency
# Make all the loads in the system into Wiener proceesses
loads = [
load_models.WienerProcessLoad(load_num, steps, sd, dt)
for load_num in load_ids
def get_load_bus(bus_num):
# Get the Load Buses Numbers
psspy.bsys(0, 0, [0.2, 999.], 0, [], len(bus_num), bus_num, 0, [], 0, [])
ierr, load_bus = psspy.alodbusint(sid=0, flag=1, string=['NUMBER'])
load_bus = load_bus[0]
return load_bus
