This is likely a math problem as much as it is a programming problem, but I seem to be encountering severe oscillations in temperature in my class method "update()" when warp is set for a high value (1000+) in the code below. All temperatures are in Kelvin for simplicity.

(I am not a programmer by profession. This formatting is likely unpleasant.)

```
import math
#Critical to the Stefan-Boltzmann equation. Otherwise known as Sigma
BOLTZMANN_CONSTANT = 5.67e-8
class GeneratorObject(object):
"""Create a new object to run thermal simulation on."""
def __init__(self, mass, emissivity, surfaceArea, material, temp=0, power=5000, warp=1):
self.tK = temp #Temperature of the object.
self.mass = mass #Mass of the object.
self.emissivity = emissivity #Emissivity of the object. Always between 0 and 1.
self.surfaceArea = surfaceArea #Emissive surface area of the object.
self.material = material #Store the material name for some reason.
self.specificHeat = (0.45*1000)*self.mass #Get the specific heat of the object in J/kg (Iron: 0.45*1000=450J/kg)
self.power = power #Joules/Second (Watts) input. This is for heating the object.
self.warp = warp #Warp Multiplier. This pertains to how KSP's warp multiplier works.
def update(self):
"""Update the object's temperature according to it's properties."""
#This method updates the object's temperature according to heat losses and other factors.
self.tK -= (((self.emissivity * BOLTZMANN_CONSTANT * self.surfaceArea * (math.pow(self.tK,4) - math.pow(30+273.15,4))) / self.specificHeat) - (self.power / self.specificHeat)) * self.warp
```

The law used is the Stefan-Boltzmann law for calculating black-body heat losses:

Temp -= (Emissivity*Sigma*SurfaceArea*(Temp^4-Amb^4))/SpecificHeat)

This was ported from a KSP plugin for quicker debugging. Object.update() is called 50 times per second.

Would there be a solution to preventing these extreme oscillations that doesn't involve executing the code multiple times per step?

differentialequation that you're simulating, and you need a time in here (as Beta said). For example, if you work out the units for you expression above, they will not work because you've left out the dt term. It's difficult to say how to incorporate the time correctly into your large system because we don't know what that is. Remember, on the left hand side is reallydT/dt. – tom10 Oct 16 '13 at 1:17