def setResults(self, schedule):
"""
Save resulting state of charge, charging and discharging powers, filled and removed water
"""
PCharge_schedule=np.zeros(len(schedule))
PDischarge_schedule=np.zeros(len(schedule))
PCharge_schedule[schedule<0]=-schedule[schedule<0]
PDischarge_schedule[schedule>0]=schedule[schedule>0]
#TODO: Change the length issue
ff=np.array([self.ffInit*self.energyCapacity]*len(schedule))
add2ff=np.concatenate((np.array([0]), np.cumsum((PCharge_schedule*self.etaCharge-PDischarge_schedule/self.etaDischarge)*self.dT)[:len(schedule)-1]), axis=0)
ff_schedule=ff+add2ff
#Save schedule
results = handleData.saveResult(self.environment.timer,
self.currentSchedule,
self.totalSchedule,
schedule)
(self.currentSchedule, self.totalSchedule) = results
# Save fill factor
results = handleData.saveResultInit(self.environment.timer,
self.currentFF,
self.totalFF,
ff_schedule/self.energyCapacity)
(self.currentFF, self.totalFF, self.ffInit) = results
# Save charging power
results = handleData.saveResult(self.environment.timer,
self.currentPCharge,
self.totalPCharge,
PCharge_schedule)
(self.currentPCharge, self.totalPCharge) = results
# Save discharging power
results = handleData.saveResult(self.environment.timer,
self.currentPDischarge,
self.totalPDischarge,
PDischarge_schedule)
(self.currentPDischarge, self.totalPDischarge) = results
# Save filled water
results = handleData.saveResult(self.environment.timer,
self.currentWCharge,
self.totalWCharge,
PCharge_schedule*self.etaCharge/(self.d*self.g*self.h))
(self.currentWCharge, self.totalWCharge) = results
# Save remowed water
results = handleData.saveResult(self.environment.timer,
self.currentWDischarge,
self.totalWDischarge,
PDischarge_schedule/(self.etaDischarge*self.d*self.g*self.h))
(self.currentWDischarge, self.totalWDischarge) = results
def _setFInput(self, fInput, emmisionRate=None):
results = handleData.saveResult(self.environment.timer,
self.currentFInput, self.totalFInput,
fInput)
(self.currentFInput, self.totalFInput) = results
if emmisionRate != None:
results = handleData.saveResult(self.environment.timer,
self.currentEmission,
self.totalEmission,
fInput * emmisionRate)
(self.currentEmission, self.totalEmission) = results
def setResults(self, pInput, pOutput):
"""
Save electricity input and output of the inverter.
"""
results = handleData.saveResult(self.environment.timer,
self.currentPInput, self.totalPInput,
pInput)
(self.currentPInput, self.totalPInput) = results
results = handleData.saveResult(self.environment.timer,
self.currentPOutput, self.totalPOutput,
pOutput)
(self.currentPOutput, self.totalPOutput) = results
def _setNonFlowQuantity(self, nonflowQuantity):
""" Save the computed non flow quantity drop across the heating device """
results = handleData.saveResult(self.environment.timer,
self.currentNonFlowQuantity,
self.totalNonFlowQuantity,
nonflowQuantity)
(self.currentNonFlowQuantity, self.totalNonFlowQuantity) = results
def setResults(self, schedule):
"""
Save resulting fill factor, charging and discharging gas powers
"""
print()
print("Schedule assinged to storage")
GCharge_schedule = np.zeros(len(schedule))
GDischarge_schedule = np.zeros(len(schedule))
GCharge_schedule[schedule < 0] = -schedule[schedule < 0]
GDischarge_schedule[schedule > 0] = schedule[schedule > 0]
ff = np.array([self.ffInit * self.capacity] * len(schedule))
add2ff = np.concatenate(
(np.array([0]),
np.cumsum((GCharge_schedule * self.etaCharge -
GDischarge_schedule / self.etaDischarge) *
self.dT)[:len(schedule) - 1]),
axis=0)
ff_schedule = ff + add2ff
#Save schedule
results = handleData.saveResult(self.environment.timer,
self.currentSchedule,
self.totalSchedule, schedule)
(self.currentSchedule, self.totalSchedule) = results
# Save fill factor
results = handleData.saveResultInit(self.environment.timer,
self.currentFF, self.totalFF,
ff_schedule / self.capacity)
(self.currentFF, self.totalFF, self.ffInit) = results
# Save charging power
results = handleData.saveResult(self.environment.timer,
self.currentGInput, self.totalGInput,
GCharge_schedule)
(self.currentGInput, self.totalGInput) = results
# Save discharging power
results = handleData.saveResult(self.environment.timer,
self.currentGOutput, self.totalGOutput,
GDischarge_schedule)
(self.currentGOutput, self.totalGOutput) = results
def setResults(self, schedule):
"""
Save resulting gas power output
"""
# Save gas power removal
results = handleData.saveResult(self.environment.timer,
self.currentGOutput, self.totalGOutput,
schedule)
(self.currentGOutput, self.totalGOutput) = results
def setResults(self, schedule):
"""
Save resulting water volume output
"""
# Save water removal
results = handleData.saveResult(self.environment.timer,
self.currentWOutput, self.totalWOutput,
schedule)
(self.currentWOutput, self.totalWOutput) = results
def setResults(self, pOutput, qOutput, schedule):
"""
Save resulting electricty, heat output and operational schedule.
"""
self._setSchedule(schedule)
self._setQOutput(qOutput)
result = handleData.saveResult(self.environment.timer,
self.currentPOutput,
self.totalPOutput,
pOutput)
(self.currentPOutput, self.totalPOutput) = result
def setResults(self, schedule):
"""
Save resulting electricty, heat output, fuel input (also emission indirectly) and operational schedule.
"""
self._setSchedule(schedule)
self._setQOutput(schedule * self.pNominal / self.sigma)
self._setFInput(schedule * self.fNominal, self.specificEmission)
result = handleData.saveResult(self.environment.timer,
self.currentPOutput, self.totalPOutput,
schedule * self.pNominal)
(self.currentPOutput, self.totalPOutput) = result
def setResults(self, soc, charge, discharge):
"""
Save resulting state of charge, charging and discharging powers.
"""
# Save state of charge
results = handleData.saveResultInit(self.environment.timer,
self.currentSoc, self.totalSoc,
soc)
(self.currentSoc, self.totalSoc, self.socInit) = results
# Save charging power
results = handleData.saveResult(self.environment.timer,
self.currentPCharge, self.totalPCharge,
charge)
(self.currentPCharge, self.totalPCharge) = results
# Save discharging power
results = handleData.saveResult(self.environment.timer,
self.currentPDischarge,
self.totalPDischarge, discharge)
(self.currentPDischarge, self.totalPDischarge) = results
def setResults(self, schedule):
"""
Save resulting state of charge, charging and discharging powers.
"""
# Save state of charge
charge_schedule = np.zeros(len(schedule))
discharge_schedule = np.zeros(len(schedule))
soc = np.array([self.socInit * self.capacity] * len(schedule))
charge_schedule[schedule < 0] = -schedule[schedule < 0]
discharge_schedule[schedule > 0] = schedule[schedule > 0]
add2soc = np.concatenate(
(np.array([0]),
np.cumsum((charge_schedule * self.etaCharge -
discharge_schedule / self.etaDischarge) *
self.dT)[:len(schedule) - 1]),
axis=0)
soc_schedule = soc + add2soc
results = handleData.saveResultInit(self.environment.timer,
self.currentSoc, self.totalSoc,
soc_schedule / self.capacity)
(self.currentSoc, self.totalSoc, self.socInit) = results
# Save charging power
results = handleData.saveResult(self.environment.timer,
self.currentPCharge, self.totalPCharge,
charge_schedule)
(self.currentPCharge, self.totalPCharge) = results
# Save discharging power
results = handleData.saveResult(self.environment.timer,
self.currentPDischarge,
self.totalPDischarge,
discharge_schedule)
(self.currentPDischarge, self.totalPDischarge) = results
def setResults(self, flowTemp, schedule):
#TODO: Ask if this method fits
"""
Save resulting electricty consumption, heat output and
operational schedule.
"""
nominals = self.getNominalValues(flowTemp)
self._setSchedule(schedule)
self._setQOutput(schedule * nominals[1])
result = handleData.saveResult(self.environment.timer,
self.currentPConsumption,
self.totalPConsumption,
schedule * nominals[0])
(self.currentPConsumption, self.totalPConsumption) = result
def _setSchedule(self, schedule):
""" Save the computed schedule to the device """
results = handleData.saveResult(self.environment.timer,
self.currentSchedule,
self.totalSchedule, schedule)
(self.currentSchedule, self.totalSchedule) = results
def _setFlowQuantity(self, flowQuantity):
""" Save the computed flow through the heating device """
results = handleData.saveResult(self.environment.timer,
self.currentFlowQuantity,
self.totalFlowQuantity, flowQuantity)
(self.currentFlowQuantity, self.totalFlowQuantity) = results
def _setQOutput(self, qOutput):
""" Save the computed heat output to the heating device """
results = handleData.saveResult(self.environment.timer,
self.currentQOutput, self.totalQOutput,
qOutput)
(self.currentQOutput, self.totalQOutput) = results
