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sav08:intuition_for_hol [2008/05/27 23:53] vkuncak |
sav08:intuition_for_hol [2009/03/05 12:54] vkuncak |
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- | ====== Intuition for Higher-Order Logic ====== | + | ====== Intuition for 'Higher-Order' Logic ====== |
- | In first, order logic, formulas contain | + | In [[exercise 01|first-order logic]] formulas contain |
* variables | * variables | ||
* function symbols | * function symbols | ||
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\forall R. \forall f. \forall x. \lnot R(x,f(x)) | \forall R. \forall f. \forall x. \lnot R(x,f(x)) | ||
\] | \] | ||
- | The last two formulas cannot be written in FOL, because they involve quantification over functions and relations. However, these formulas can be written in HOL. Moreover, in HOL we can write more complex conditions that cannot be described directly in terms of validity or satisfiability, such as | + | The last two formulas cannot be written in FOL, because they involve quantification over functions and relations. However, these formulas can be written in HOL. Moreover, in HOL we can write more complex conditions that cannot be described directly in terms of validity or satisfiability of FOL formulas, such as |
\[ | \[ | ||
\forall R. \exists f. \forall x. \lnot R(x,f(x)) | \forall R. \exists f. \forall x. \lnot R(x,f(x)) | ||
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In multisorted logic with equality, we can introduce one binary equality symbol ${=}_\tau$ for each sort $\tau$, whose signature is $\tau \times \tau$. | In multisorted logic with equality, we can introduce one binary equality symbol ${=}_\tau$ for each sort $\tau$, whose signature is $\tau \times \tau$. | ||
- | In HOL we generalize the type system to have function types. This idea build on simply typed lambda calculus. | + | In HOL we generalize the type system to have function types, and we use functions with different types to represent functions and predicates, allowing quantification over variables of arbitrary types. This starting point for such system is simply typed lambda calculus. |