Abstract
We review the problem of finding a general framework within which one can construct quantum theories of non-standard models for space, or space-time. The starting point is the observation that entities of this type can typically be regarded as objects in a category whose arrows are structure-preserving maps. This motivates investigating the general problem of quantising a system whose `configuration space' (or history-theory analogue) is the set of objects $\Ob\Q$ in a category $\Q$.
We develop a scheme based on constructing an analogue of the group that is used in the canonical quantisation of a system whose configuration space is a manifold
Q≃G/H
, where
G
and
H
are Lie groups. In particular, we choose as the analogue of
G
the monoid of `arrow fields' on $\Q$. Physically, this means that an arrow between two objects in the category is viewed as an analogue of momentum. After finding the `category quantisation monoid', we show how suitable representations can be constructed using a bundle (or, more precisely, presheaf) of Hilbert spaces over $\Ob\Q$. For the example of a category of finite sets, we construct an explicit representation structure of this type.