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  1. Moving info regarding the use of equality in definitions from equality to this page

    Anonymous

    diff, v7, current

  2. Started section on inductive definitions

    Anonymous

    diff, v7, current

  3. Inductive and recursive definitions

    Anonymous

    diff, v7, current

  4. added section on inductive and recursive definitions and addition of natural numbers as an example of a recursively defined function

    Anonymous

    diff, v10, current

  5. Adding example of isProp

    Anonymous

    diff, v12, current

  6. Added transport as an example of an inductively defined function, and added a link to natural deduction

    Anonymous

    diff, v12, current

  7. moved info originally in assignment operator

    Anonymous

    diff, v16, current

  8. moved information on inductive definitions in type theory over to inductive definition

    Anonymous

    diff, v19, current

    • CommentRowNumber9.
    • CommentAuthorGuest
    • CommentTimeNov 9th 2022

    The notion of definitional equality should be about syntactical expressions, where we define a syntactical expression to be another syntactical expression. In this sense, it should have more in common with alpha equivalence than computational equality. For example, we should be able to define the symbol Ξ\Xi as the context (Γ,a:A)(\Gamma, a:A), Ξ(Γ,a:A)ctx\Xi \equiv (\Gamma, a:A) \; \mathrm{ctx}. Currently, definitional equality is only defined for types and terms.

    Johannes Schmidt

  9. moving info over to definitional equality

    Anonymous

    diff, v20, current

    • CommentRowNumber11.
    • CommentAuthorUrs
    • CommentTimeNov 9th 2022
    • (edited Nov 9th 2022)

    At the end of the Idea-paragraph (here) it would be good to mention more typical examples of “definitions”, and how they fit in, for instance the definitions of “groups”, “algebras”, “modules”, etc.

    I guess you will mean to say that these fall under the second clause of “definition via equality with an existing type”, in that they can be defined to be certain iterated dependent products. But this would be great to make explicit.

    diff, v21, current