Transport of structure
In mathematics, particularly in universal algebra and category theory, transport of structure refers to the process whereby a mathematical object acquires a new structure and its canonical definitions, as a result of being isomorphic to (or otherwise identified with) another object with a pre-existing structure.[1] Definitions by transport of structure are regarded as canonical.
Since mathematical structures are often defined in reference to an underlying space, many examples of transport of structure involve spaces and mappings between them. For example, if and are vector spaces with being an inner product on , such that there is an isomorphism from to , then one can define an inner product on by the following rule:
Although the equation makes sense even when is not an isomorphism, it only defines an inner product on when is, since otherwise it will cause to be degenerate. The idea is that allows one to consider and as "the same" vector space, and by following this analogy, then one can transport an inner product from one space to the other.
A more elaborated example comes from differential topology, in which the notion of smooth manifold is involved: if is such a manifold, and if is any topological space which is homeomorphic to , then one can consider as a smooth manifold as well. That is, given a homeomorphism , one can define coordinate charts on by "pulling back" coordinate charts on through . Recall that a coordinate chart on is an open set together with an injective map
for some natural number ; to get such a chart on , one uses the following rules:
- and .
Furthermore, it is required that the charts cover (the fact that the transported charts cover follows immediately from the fact that is a bijection). Since is a smooth manifold, if U and V, with their maps and , are two charts on , then the composition, the "transition map"
- (a self-map of )
is smooth. To verify this for the transported charts on , notice that
- ,
and therefore
- , and
- .
Thus the transition map for and is the same as that for and , hence smooth. That is, is a smooth manifold via transport of structure. This is a special case of transport of structures in general.[2]
The second example also illustrates why "transport of structure" is not always desirable. Namely, one can take to be the plane, and to be an infinite one-sided cone. By "flattening" the cone, a homeomorphism of and can be obtained, and therefore the structure of a smooth manifold on , but the cone is not "naturally" a smooth manifold. That is, one can consider as a subspace of 3-space, in which context it is not smooth at the cone point.
A more surprising example is that of exotic spheres, discovered by Milnor, which states that there are exactly 28 smooth manifolds which are homeomorphic (but by definition not diffeomorphic) to , the 7-dimensional sphere in 8-space. Thus, transport of structure is most productive when there exists a canonical isomorphism between the two objects.
See also
References
- Holm, Henrik (2015). "A Note on Transport of Algebraic Structures" (PDF). Theory and Applications of Categories. 30 (34): 1121–1131. arXiv:1504.07366.
- Bourbaki, Nicolas (1968), Elements of mathematics: Theory of sets, Hermann (original), Addison-Wesley (translation), Chapter IV, Section 5 "Isomorphism and transport of structures".