6.6: Summary and further reading

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This chapter began with a detailed exposition of colimits in the category of sets; as we saw, these colimits describe ways of joining or interconnecting sets. Our second way of talking about interconnection was the use of Frobenius monoids and hypergraph categories; we saw these two themes come together in the idea of a decorated cospans. The decorated cospan construction uses a certain type of structured functor to construct a certain type of structured category. More generally, we might be interested in other types of structured category, or other compositional structure. To address this, we briefly saw how these ideas fit into the theory of operads.

Colimits are a fundamental concept in category theory. For more on colimits, one might refer to any of the introductory category theory textbooks we mentioned in Section 3.6.

Special commutative Frobenius monoids and hypergraph categories were first de- fined, under the names ‘separable commutative Frobenius algebra’ and ‘well-supported compact closed category’, by Carboni and Walters [CW87; Car91]. The use of deco- rated cospans to construct them is detailed in [Fon15; Fon18; Fon16]. The application to networks of passive linear systems, such as certain electrical circuits, is discussed in [BF15], while further applications, such as to Markov processes and chemistry can be found in [BFP16; BP17]. For another interesting application of hypergraph categories, we recommend the pixel array method for approximating solutions to nonlinear equa- tions [Spi+16]. The story of this chapter is fleshed out in a couple of recent, more technical papers [FS18b; FS18a].

Operads were introduced by May to describe compositional structures arising in algebraic topology [May72]; Leinster has written a great book on the subject [Lei04]. More recently, with collaborators author-David has discussed using operads in applied mathematics, to model composition of structures in logic, databases, and dynamical systems [RS13; Spi13; VSL15].

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