public override string GetExplanationUnfinalized(StatRequest req, ToStringNumberSense numberSense)
{
StringBuilder stringBuilder = new StringBuilder();
CompTempControl tempControl = req.Thing.TryGetComp <CompTempControl>();
Thing tempController = req.Thing;
float roomTemp = tempController.Position.GetTemperature(tempController.Map);
float energyPerSecond = tempControl.Props.energyPerSecond; // the power of the radiator
float roomSurface = tempController.Position.GetRoomGroup(tempController.Map).CellCount;
float coolingConversionRate = 4.16666651f; // Celsius cooled per Joules*Second*Meter^2 conversion rate
float minTemp = 20;
float maxTemp = 120;
float efficiency = 1 - Mathf.Min(Mathf.Max((roomTemp - minTemp) / (maxTemp - minTemp), 0), 1);
float maxACPerSecond = energyPerSecond * efficiency / roomSurface * coolingConversionRate; // max cooling power possible
SEB seb = new SEB("StatsReport_RWHS");
seb.Simple("AmbientRoomTemp", roomTemp);
seb.Simple("EnergyPerSecond", energyPerSecond);
seb.Simple("RoomSurface", roomSurface);
seb.Simple("ACConversionRate", coolingConversionRate);
seb.Full("LerpEfficiency", efficiency * 100, roomTemp, minTemp, maxTemp);
seb.Full("MaxACPerSecond", maxACPerSecond, energyPerSecond, efficiency, roomSurface, coolingConversionRate);
return(seb.ToString());
}
public override string GetExplanationUnfinalized(StatRequest req, ToStringNumberSense numberSense)
{
CompTempControl tempControl = req.Thing.TryGetComp <CompTempControl>();
Thing tempController = req.Thing;
IntVec3 intVec3_2 = tempController.Position + IntVec3.North.RotatedBy(tempController.Rotation);
IntVec3 intVec3_1 = tempController.Position + IntVec3.South.RotatedBy(tempController.Rotation);
float cooledRoomTemp = intVec3_1.GetTemperature(tempController.Map);
float extRoomTemp = intVec3_2.GetTemperature(tempController.Map);
float efficiencyLossPerDegree = 1.0f / 130.0f; // SOS2 internal value, means loss of efficiency for each degree above targettemp, lose 50% at 65C above targetTemp, 100% at 130+
float energyPerSecond = tempControl.Props.energyPerSecond; // the power of the radiator
float roomSurface = intVec3_1.GetRoomGroup(tempController.Map).CellCount;
float coolingConversionRate = 4.16666651f; // Celsius cooled per Joules*Second*Meter^2 conversion rate
float sidesTempGradient = extRoomTemp - (cooledRoomTemp < 40 ? cooledRoomTemp : 40);
float efficiency = (1f - sidesTempGradient * efficiencyLossPerDegree); // a negative value indicates heat generation
float maxACPerSecond = energyPerSecond * efficiency / roomSurface * coolingConversionRate; // max cooling power possible, positive value indicates heat generation
SEB seb = new SEB("StatsReport_RWHS");
seb.Simple("CooledRoomTemp", cooledRoomTemp);
seb.Simple("ExteriorRoomTemp", extRoomTemp);
seb.Simple("EfficiencyLossPerDegree", efficiencyLossPerDegree);
seb.Simple("EnergyPerSecond", energyPerSecond);
seb.Simple("CooledRoomSurface", roomSurface);
seb.Simple("ACConversionRate", coolingConversionRate);
seb.Full("SidesTempGradient", sidesTempGradient, extRoomTemp, cooledRoomTemp);
seb.Full("RelativeEfficiency", efficiency * 100, sidesTempGradient, efficiencyLossPerDegree);
seb.Full("MaxACPerSecond", maxACPerSecond, energyPerSecond, efficiency, roomSurface, coolingConversionRate);
return(seb.ToString());
}
public override string GetExplanationUnfinalized(StatRequest req, ToStringNumberSense numberSense)
{
CompHeatPusher comp = req.Thing.TryGetComp <CompHeatPusher>();
float heatPerSecond = comp.Props.heatPerSecond;
float surface = comp.parent.PositionHeld.GetRoomGroup(comp.parent.Map).CellCount;
float heatPushedPerSecond = heatPerSecond / surface;
SEB seb = new SEB("StatsReport_RWHS");
seb.Simple("HeatPushedPerSecond", heatPerSecond);
seb.Simple("RoomSurface", surface);
seb.Full("HeatOutputPerSecond", heatPushedPerSecond, heatPerSecond, surface);
return(seb.ToString());
}
public override string GetExplanationUnfinalized(StatRequest req, ToStringNumberSense numberSense)
{
float heatPerSecond = RWHS_PowerPlantSteam.GetHeatPerSecond();
float surface = 25;
RoomGroup roomGroup = req.Thing.Position.GetRoomGroup(req.Thing.Map);
if (roomGroup != null)
{
surface = roomGroup.CellCount; // TODO DEBUG THIS LINE
}
float heatPushedPerSecond = heatPerSecond / surface;
SEB seb = new SEB("StatsReport_RWHS");
seb.Simple("HeatPushedPerSecond", heatPerSecond);
seb.Simple("RoomSurface", surface);
seb.Full("HeatOutputPerSecond", heatPushedPerSecond, heatPerSecond, surface);
return(seb.ToString());
}
public override string GetExplanationUnfinalized(StatRequest req, ToStringNumberSense numberSense)
{
StringBuilder stringBuilder = new StringBuilder();
CompTempControl tempControl = req.Thing.TryGetComp<CompTempControl>();
Thing tempController = req.Thing;
IntVec3 intVec3_1 = tempController.Position + IntVec3.South.RotatedBy(tempController.Rotation);
float cooledRoomTemp = intVec3_1.GetTemperature(tempController.Map);
float targetTemp = tempControl.targetTemperature;
float targetTempDiff = targetTemp - cooledRoomTemp;
float maxACPerSecond = RWHS_TempControl_RoomExchange.GetMaxACPerSecond(req); // max cooling power possible
bool isHeater = tempControl.Props.energyPerSecond > 0;
float actualAC;
if (isHeater)
{
actualAC = Mathf.Max(Mathf.Min(targetTempDiff, maxACPerSecond), 0);
}
else
{
actualAC = Mathf.Min(Mathf.Max(targetTempDiff, maxACPerSecond), 0);
}
SEB seb = new SEB("StatsReport_RWHS");
seb.Simple("CooledRoomTemp", cooledRoomTemp);
seb.Simple("TargetTemperature", targetTemp);
seb.Full("TargetTempDiff", targetTempDiff, targetTemp, cooledRoomTemp );
seb.Simple("MaxACPerSecond", maxACPerSecond);
if (isHeater)
{
seb.Full("ActualHeaterACPerSecond", actualAC, targetTempDiff, maxACPerSecond);
}
else
{
seb.Full("ActualCoolerACPerSecond", actualAC, targetTempDiff, maxACPerSecond);
}
return seb.ToString();
}
public override string GetExplanationUnfinalized(StatRequest req, ToStringNumberSense numberSense)
{
CompTempControl tempControl = req.Thing.TryGetComp <CompTempControl>();
Thing tempController = req.Thing;
float roomTemp = tempController.Position.GetTemperature(tempController.Map);
float targetTemp = tempControl.targetTemperature;
float targetTempDiff = targetTemp - roomTemp;
float maxACPerSecond = RWHS_TempControl_InPlace.GetMaxACPerSecond(req); // max cooling power possible
bool isHeater = tempControl.Props.energyPerSecond > 0;
float actualAC;
if (isHeater)
{
actualAC = Mathf.Max(Mathf.Min(targetTempDiff, maxACPerSecond), 0);
}
else
{
actualAC = Mathf.Min(Mathf.Max(targetTempDiff, maxACPerSecond), 0);
}
SEB seb = new SEB("StatsReport_RWHS");
seb.Simple("AmbientRoomTemp", roomTemp);
seb.Simple("TargetTemperature", targetTemp);
seb.Full("TargetTempDiff", targetTempDiff, targetTemp, roomTemp);
seb.Simple("MaxACPerSecond", maxACPerSecond);
if (isHeater)
{
seb.Full("ActualHeaterACPerSecond", actualAC, targetTempDiff, maxACPerSecond);
}
else
{
seb.Full("ActualCoolerACPerSecond", actualAC, targetTempDiff, maxACPerSecond);
}
return(seb.ToString());
}
