A Differential Equation for Heat Transfer According to Newton's Law of Cooling

​
proportionality constant k
1.5
initial temperature T(0) of surroundings
60
Let
u(t)
be the temperature of a building (with neither heat nor air conditioning running) at time
t
and let
T(t)
be the temperature of the surrounding air. Newton's law of cooling states that
du
dt
=-k(u-T(t))
,
where
k
is a constant independent of time.
In this example,
T(t)=T(0)+15sin(2πt)
is plotted in red;
T(0)
is the initial temperature of the air surrounding the building. The value of
k
depends on a number of factors including the insulation of the building. In this example, you can modify the proportionality constant and mean temperature.
Five specific solutions around the initial temperature are plotted as solid blue curves through the dashed blue lines that represent the direction fields.

Details

This is example 4, Heating and Cooling of a Building from[1], Section 1.1, Modeling with First Order Equations.

References

[1] J. R. Brannan and W. E. Boyce, Differential Equations with Boundary Value Problems: An Introduction to Modern Methods and Applications, New York: John Wiley and Sons, 2010.
​

External Links

Newton's Law of Cooling (ScienceWorld)
Differential Equation (Wolfram MathWorld)

Permanent Citation

Stephen Wilkerson
​
​"A Differential Equation for Heat Transfer According to Newton's Law of Cooling"​
​http://demonstrations.wolfram.com/ADifferentialEquationForHeatTransferAccordingToNewtonsLawOfC/​
​Wolfram Demonstrations Project​
​Published: December 13, 2010