In calculus, the racetrack principle describes the movement and growth of two functions in terms of their derivatives.
This principle is derived from the fact that if a horse named Frank Fleetfeet always runs faster than a horse named Greg Gooseleg, then if Frank and Greg start a race from the same place and the same time, then Frank will win. More briefly, the horse that starts fast and stays fast wins.
In symbols:
- if for all , and if , then for all .
or, substituting ≥ for > produces the theorem
- if for all , and if , then for all .
which can be proved in a similar way
Proof
This principle can be proven by considering the function . If we were to take the derivative we would notice that for ,
Also notice that . Combining these observations, we can use the mean value theorem on the interval and get
By assumption, , so multiplying both sides by gives . This implies .
Generalizations
The statement of the racetrack principle can slightly generalized as follows;
- if for all , and if , then for all .
as above, substituting ≥ for > produces the theorem
- if for all , and if , then for all .
Proof
This generalization can be proved from the racetrack principle as follows:
Consider functions and . Given that for all , and ,
for all , and , which by the proof of the racetrack principle above means for all so for all .
Application
The racetrack principle can be used to prove a lemma necessary to show that the exponential function grows faster than any power function. The lemma required is that
for all real . This is obvious for but the racetrack principle is required for . To see how it is used we consider the functions
and
Notice that and that
because the exponential function is always increasing (monotonic) so . Thus by the racetrack principle . Thus,
for all .
References
- Deborah Hughes-Hallet, et al., Calculus.