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component.py
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component.py
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import enum
class CircuitType(enum.Enum):
series = 1
parallel = 2
class Resistor:
roundingPlace = 5
def __init__(self, name, writeReasoning, voltage = None, current = None, resistance = None, allowBypass = False):
self.name = name.upper()
self.writeReasoning = writeReasoning
if not(voltage or current or resistance) and not allowBypass:
raise Exception(f"Voltage, current, or resistance needs to be known for Resistor '{self.name}'")
self.voltage = voltage
self.current = current
self.resistance = resistance
self.voltageReason = 'Given' if voltage else None
self.currentReason = 'Given' if current else None
self.resistanceReason = 'Given' if resistance else None
def solved(self):
return self.voltage and self.current and self.resistance
def solve(self):
return self.ohmsLaw() #If true, ohms law has been applied.
def ohmsLaw(self):
testSum = (1 if self.voltage else 0) + (1 if self.current else 0) + (1 if self.resistance else 0)
if testSum == 2: #Only 2 variables
if self.voltage and self.current:
self.resistance = self.voltage / self.current
self.resistanceReason = "Ohm's Law"
self.writeReasoning(f'{self.name} has a voltage of {round(self.voltage, Resistor.roundingPlace)} Volts and a current of {round(self.current, Resistor.roundingPlace)} Amps, so its resistance is {round(self.resistance, Resistor.roundingPlace)} Ohms. (Ohm\'s Law)')
elif self.voltage and self.resistance:
self.current = self.voltage / self.resistance
self.currentReason = "Ohm's Law"
self.writeReasoning(f'{self.name} has a voltage of {round(self.voltage, Resistor.roundingPlace)} Volts, and a resistance of {round(self.resistance, Resistor.roundingPlace)} Ohms, so its current is {round(self.current, Resistor.roundingPlace)} Amps. (Ohm\'s Law)')
else:
self.voltage = self.current * self.resistance
self.voltageReason = "Ohm's Law"
self.writeReasoning(f'{self.name} has a current of {round(self.current, Resistor.roundingPlace)} Amps and a resistance of {round(self.resistance, Resistor.roundingPlace)} Ohms, so its voltage is {round(self.voltage, Resistor.roundingPlace)} Volts. (Ohm\'s Law)')
return True
return False
def __repr__(self, pretty = False, showVoltage = True, showCurrent = True, showResistance = True):
return self.__str__(pretty = pretty, showVoltage = showVoltage, showCurrent = showCurrent, showResistance = showResistance)
def __str__(self, pretty = True, showVoltage = True, showCurrent = True, showResistance = True):
if pretty:
props = [f'Voltage: {round(self.voltage, Resistor.roundingPlace)} Volts ({self.voltageReason})', f'Current: {round(self.current, Resistor.roundingPlace)} Amps ({self.currentReason})', f'Resistance: {round(self.resistance, Resistor.roundingPlace)} Ohms ({self.resistanceReason})']
props = [p for i, p in enumerate(props) if [showVoltage, showCurrent, showResistance][i]]
return f'{self.name}:\n' + '\n'.join(props)
else:
props = [f'{self.voltage}-{self.voltageReason}', f'{self.current}-{self.currentReason}', f'{self.resistance}-{self.resistanceReason}']
props = [p for i, p in enumerate(props) if [showVoltage, showCurrent, showResistance][i]]
if props:
return f'Resistor({self.name}, {props})'
else:
return f'Resistor({self.name})'
class Leg(Resistor):
def __init__(self, name, writeReasoning, circuitType, subcomponents, voltage = None, current = None, resistance = None):
super().__init__(name, writeReasoning, voltage = voltage, current = current, resistance = resistance, allowBypass = True)
self.circuitType = circuitType
if len(subcomponents) == 0:
raise Exception(f"Leg {self.name} must have at least 1 subresistor.")
self.subcomponents = subcomponents
def solved(self):
subSolved = True
for s in self.subcomponents:
subSolved = subSolved and s.solved()
if not subSolved:
break
return self.voltage and self.current and self.resistance and subSolved
def solve(self):
if self.ohmsLaw():
return True
elif self.equalityRules():
return True
elif self.sumRules():
return True
else:
for s in self.subcomponents:
if s.solve():
return True
return False
#Subcomponent Math
def equalityRules(self):
if self.circuitType == CircuitType.series:
testSum = len([True for s in self.subcomponents if s.current]) + (1 if self.current else 0)
if testSum > 0 and testSum != len(self.subcomponents) + 1:
equalityCurrent = ([s.current for s in self.subcomponents if s.current]+([self.current] if self.current else []))[0]
if not self.current:
self.current = equalityCurrent
self.currentReason = 'Series Current Equality'
self.writeReasoning(f'{self.name} has a current of {round(self.current, Leg.roundingPlace)} Amps because all subcomponents have the same current. (Series Current Equality)')
for s in self.subcomponents:
if not s.current:
s.current = equalityCurrent
s.currentReason = 'Series Current Equality'
s.writeReasoning(f'{s.name} has a current of {round(s.current, Leg.roundingPlace)} Amps because all subcomponents have the same current. (Series Current Equality)')
return True
else:
testSum = len([True for s in self.subcomponents if s.voltage]) + (1 if self.voltage else 0)
if testSum > 0 and testSum != len(self.subcomponents) + 1:
equalityVoltage = ([s.voltage for s in self.subcomponents if s.voltage]+([self.voltage] if self.voltage else []))[0]
if not self.voltage:
self.voltage = equalityVoltage
self.voltageReason = 'Parallel Voltage Equality'
self.writeReasoning(f'{self.name} has a voltage of {round(self.voltage, Leg.roundingPlace)} Volts because all subcomponents have the same voltage. (Parallel Voltage Equality)')
for s in self.subcomponents:
if not s.voltage:
s.voltage = equalityVoltage
s.voltageReason = 'Parallel Voltage Equality'
s.writeReasoning(f'{s.name} has a voltage of {round(s.voltage, Leg.roundingPlace)} Volts because all subcomponents have the same voltage. (Parallel Voltage Equality)')
return True
return False
def sumRules(self):
if self.circuitType == CircuitType.series:
testVoltageSum = len([True for s in self.subcomponents if s.voltage]) + (1 if self.voltage else 0)
if testVoltageSum == len(self.subcomponents):
if not self.voltage: #Voltage for leg not provided. Add all subvoltages.
self.voltage = sum([s.voltage for s in self.subcomponents])
self.voltageReason = 'Series Voltage Sum'
self.writeReasoning(f'{self.name} has a voltage of {round(self.voltage, Leg.roundingPlace)} Volts because it is equal to the sum of the voltages of all subcomponents {", ".join([s.name+" ("+str(round(s.voltage, Leg.roundingPlace))+" Volts)" for s in self.subcomponents])}. (Series Voltage Sum)')
else:
subcomponentVoltageSum = 0
targetSubcomponent = None
for s in self.subcomponents:
if s.voltage:
subcomponentVoltageSum += s.voltage
else:
targetSubcomponent = s
targetSubcomponent.voltage = self.voltage - subcomponentVoltageSum
targetSubcomponent.voltageReason = 'Series Voltage Sum'
self.writeReasoning(f'{targetSubcomponent.name} has a voltage of {round(targetSubcomponent.voltage, Leg.roundingPlace)} Volts because it is equal to the difference between the voltage of {self.name} ({round(self.voltage, Leg.roundingPlace)} Volts) and the sum of the voltages of all other subcomponents ({", ".join([s.name for s in self.subcomponents if s != targetSubcomponent])}) ({round(subcomponentVoltageSum, Leg.roundingPlace)} Volts). (Series Voltage Sum)')
return True
testResistanceSum = len([True for s in self.subcomponents if s.resistance]) + (1 if self.resistance else 0)
if testResistanceSum == len(self.subcomponents):
if not self.resistance: #Resistance for leg not provided. Add all subresistances.
self.resistance = sum([s.resistance for s in self.subcomponents])
self.resistanceReason = 'Series Resistance Sum'
self.writeReasoning(f'{self.name} has a resistance of {round(self.resistance, Leg.roundingPlace)} Ohms because it is equal to the sum of the resistances of all subcomponents {", ".join([s.name+" ("+str(round(s.resistance, Leg.roundingPlace))+" Ohms)" for s in self.subcomponents])}. (Series Resistance Sum)')
else:
subcomponentResistanceSum = 0
targetSubcomponent = None
for s in self.subcomponents:
if s.resistance:
subcomponentResistanceSum += s.resistance
else:
targetSubcomponent = s
targetSubcomponent.resistance = self.resistance - subcomponentResistanceSum
targetSubcomponent.resistanceReason = 'Series Resistance Sum'
self.writeReasoning(f'{targetSubcomponent.name} has a resistance of {round(targetSubcomponent.resistance, Leg.roundingPlace)} Ohms because it is equal to the difference between the resistance of {self.name} ({round(self.resistance, Leg.roundingPlace)} Ohms) and the sum of the resistances of all other subcomponents ({", ".join([s.name for s in self.subcomponents if s != targetSubcomponent])}) ({round(subcomponentResistanceSum, Leg.roundingPlace)} Ohms). (Series Resistance Sum)')
return True
else:
testCurrentSum = len([True for s in self.subcomponents if s.current]) + (1 if self.current else 0)
if testCurrentSum == len(self.subcomponents):
if not self.current: #Current for leg not provided. Add all subcurrents.
self.current = sum([s.current for s in self.subcomponents])
self.currentReason = 'Parallel Current Sum'
self.writeReasoning(f'{self.name} has a current of {round(self.current, Leg.roundingPlace)} Amps because it is equal to the sum of the currents of all subcomponents {", ".join([s.name+" ("+str(round(s.current, Leg.roundingPlace))+" Amps)" for s in self.subcomponents])}. (Parallel Current Sum)')
else:
subcomponentCurrentSum = 0
targetSubcomponent = None
for s in self.subcomponents:
if s.current:
subcomponentCurrentSum += s.current
else:
targetSubcomponent = s
targetSubcomponent.current = self.current - subcomponentCurrentSum
targetSubcomponent.currentReason = 'Parallel Current Sum'
self.writeReasoning(f'{targetSubcomponent.name} has a current of {round(targetSubcomponent.current, Leg.roundingPlace)} Amps because it is equal to the difference between the current of {self.name} ({round(self.current, Leg.roundingPlace)} Amps) and the sum of the currents of all other subcomponents ({", ".join([s.name for s in self.subcomponents if s != targetSubcomponent])}) ({round(subcomponentCurrentSum, Leg.roundingPlace)} Amps). (Parallel Current Sum)')
return True
testResistanceSum = len([True for s in self.subcomponents if s.resistance]) + (1 if self.resistance else 0)
if testResistanceSum == len(self.subcomponents):
if not self.resistance: #Resistance for leg not provided. Add all subresistances using 1/r formula.
self.resistance = 1/sum([(1/s.resistance) for s in self.subcomponents])
self.resistanceReason = 'Parallel Resistance Sum'
self.writeReasoning(f'{self.name} has a resistance of {round(self.resistance, Leg.roundingPlace)} Ohms because it is equal to the reciprocal of the sum of the reciprocals of the resistances of all subcomponents {", ".join([s.name+" ("+str(round(s.resistance, Leg.roundingPlace))+" Ohms)" for s in self.subcomponents])}. (Parallel Resistance Sum)')
else:
subcomponentResistanceSum = 0
targetSubcomponent = None
for s in self.subcomponents:
if s.resistance:
subcomponentResistanceSum += (1/s.resistance)
else:
targetSubcomponent = s
targetSubcomponent.resistance = 1/((1/self.resistance) - subcomponentResistanceSum)
targetSubcomponent.resistanceReason = 'Parallel Resistance Sum'
self.writeReasoning(f'{targetSubcomponent.name} has a resistance of {round(targetSubcomponent.resistance, Leg.roundingPlace)} Ohms because it is equal to the reciprocal of the difference between the reciprocal of the resistance of {self.name} ({round(self.resistance, Leg.roundingPlace)} Ohms) and the sum of the reciprocals of the resistances of all other subcomponents ({", ".join([s.name for s in self.subcomponents if s != targetSubcomponent])}) ({round(subcomponentResistanceSum, Leg.roundingPlace)} Ohms). (Parallel Resistance Sum)')
return True
return False
def __str__(self, pretty = True, showVoltage = True, showCurrent = True, showResistance = True):
if pretty:
props = [f'Voltage: {round(self.voltage, Leg.roundingPlace)} Volts ({self.voltageReason})', f'Current: {round(self.current, Leg.roundingPlace)} Amps ({self.currentReason})', f'Resistance: {round(self.resistance, Leg.roundingPlace)} Ohms ({self.resistanceReason})']
props = [p for i, p in enumerate(props) if [showVoltage, showCurrent, showResistance][i]]
return f'{self.name}:\n' + '\n'.join(props)
else:
props = [f'{self.voltage}-{self.voltageReason}', f'{self.current}-{self.currentReason}', f'{self.resistance}-{self.resistanceReason}']
props = [p for i, p in enumerate(props) if [showVoltage, showCurrent, showResistance][i]]
if props:
return f'Leg({self.name}, {self.circuitType}, {[s.name for s in self.subcomponents]}, {props})'
else:
return f'Leg({self.name}, {self.circuitType}, {[s.name for s in self.subcomponents]})'