| HPS 0628 | Paradox | |
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For submission
1. Additive measures
allow us to find the measure of some totality from the measure of its
parts. That is, when we join two systems together, the measure assigned to
the joined system is the arithmetic sum of the measures assigned to each
part. Which of the following are additive measures:
length, weight, area, volume, density, temperature?
Explain why those that aren't additive measures fail to be so.
2. In some fictional matter theory, a body consists of infinitely many points of no mass.
a.
If the body consists of a countable infinity of points, what is the mass
of the body?
b. If the
body consists of any uncountable (e.g. continuum sized) infinity of
points, what can we say about its mass?
3. How does your answer to 2b. assist in resolving the classical paradoxes of measure?
Not for submission
A. Democritus used Zeno's paradox of measure as an argument for the existence of atoms. How cogent is this argument? Does it force us to conclude that space must consist of non-zero magnitude spatial atoms and that time consists of non-zero magnitude temporal atoms?
B. Is a line such as the circumference of a circle nothing but a set of points? If so, why are the two circumferences not the same in all their properties, including length? But if they differ, what extra property is there that distinguishes them?
C. Consider an account of measure that allows only finite additivity, but not countable additivity. What do we gain? What do we lose?
D. Is there no way to sum an uncountable infinity of measures? Perhaps we should just try harder?
E. Consider the three paradoxes resolved in this chapter: Zeno's paradoxes of measure and the stadium and the geometric version Aristotle's wheel. They use notions derived from modern measure theory. Might it be possible to explain to thinkers in antiquity how the paradoxes are resolved in terms compatible with their methods.