Seminars

Dependence and independence concepts are ubiquitous in natural science, social science, humanities as well as in everyday life. The sentences “I park on this side of the road depending only on the day of the week” and “the time of descent is independent of the weight of the object” are examples of this. The question arises, do these concepts possess enough exactness for us to investigate their logic? There is currently a whole literature on this topic. It is the purpose of this talk to give a non-technical overview of this area of logic.

A 2½-day workshop dedicated to current and future trends in cyclic and illfounded forms of provability and justification. The event is sponsored by the Knut and Alice Wallenberg Foundation via the research project Taming Jörmungandr: The Logical Foundations of Circularity, the Swedish Research Council through the research project Proofs with Cycles and Computation, and the Department of Philosophy, Linguistics and Theory of Science at the University of Gothenburg.

Gödel intended his Dialectica interpretation to provide a foundational reduction of first-order arithmetic to a quantifier-free theory T. It has widely been objected, however, that this theory T tacitly presupposes the very quantificational logic that Gödel was trying to eliminate, hidden within its complicated definition of “computable function of finite type.” This would render the translation philosophically circular. Gödel was adamant that there was no circularity here. He sketched a defense of this claim in a page-long footnote, which however has left readers baffled. In this talk, I will explain Gödel’s footnote and show that there really is no circularity here. Thus, Gödel has achieved a significant foundational reduction. The foundations of T turn out to be stranger than meets the eye; they utilize a (broadly) Leibnizian notion of analyticity in a surprising way.

In this talk I will briefly outline Krister’s biography, focusing mainly on the early nineties onwards when I became Krister’s first PhD student. By appeal (mostly) to anecdote I will try to highlight what I take to be some of the most notable features in Krister’s approach to and views on pilosophically inspired logical research and education.

Krister Segerberg was one of the architects of modal logic as we know it today. I will highlight a few of his major contributions and show some of their subsequent impact in various academic communities. I conclude with some thoughts on the blend of philosophical logic and formal philosophy embodied in Krister’s distinguished career.

On Monday, 25 August the Nordic Online Logic Seminar will host a special event in memory of Krister Segerberg, who passed away in January this year. Krister Segerberg was Professor of Theoretical Philosophy at Uppsala and, among logicians, is widely known for his pioneering work in modal logic where he initiated an influential systematic study of completeness proofs that still is standard in the field.

The seminar will feature talks by two academics that knew Krister Segerberg well:

• Johan van Benthem (UvA), Building Modern Modal Logic: Honoring Krister Segerberg
• John Cantwell (KTH), Some reflections on Krister’s philosophy of philosopy

A URL for this seminar will be distributed via the GU Logic and Nordic Online Logic mailing lists.

Akama et al. [1] introduced a hierarchical classification of first-order formulas and investigated them in the context of semi-classical arithmetic. In this talk, we first give a justification for the hierarchical classification in a general context of first-order theories. In fact, we formalize the standard transformation procedure for prenex normalization, and show that the classes E_k and U_k introduced in [1] are exactly the classes induced by Sigma_k and Pi_k respectively via the transformation procedure. See [2] for the details. In addition, we restrict the prenex normalization procedures to those which are possible over intuitionistic logic with assuming the decidability of formulas of degree n. Then we introduce new classes E^n_k and U^n_k of formulas with two parameters k and n, and show that they are exactly the classes induced by Sigma_k and Pi_k respectively according to the n-th level semi-classical prenex normalization. This is a joint work with Taishi Kurahashi.

[1] Yohji Akama, Stefano Berardi, Susumu Hayashi, and Ulrich Kohlenbach, An arithmetical hierarchy of the law of excluded middle and related principles. In Proceedings of the 19th Annual IEEE Symposium on Logic in Computer Science (LICS ’04), pp.192–201, 2004.

[2] Makoto Fujiwara and Taishi Kurahashi, Prenex normalization and the hierarchical classification of formulas, Archive for Mathematical Logic, vol. 63, pp. 391-403, 2024.

Logics that are obtained by constraining the available syntactic resources, such as first-order logic with a finite number of variables or with bounded quantifier rank, are central to finite model theory and descriptive complexity. In this talk, I will describe a categorical approach, which is model-theoretic in spirit, to study these logics using so-called game comonads. I will explain how these comonads capture various logic fragments (positive, existential, etc.) and combinatorial parameters of structures in a syntax-free manner. Furthermore, I will argue that this categorical perspective suggests a modal approach to various resource-bounded logics.

Logical inferentialists hold that the meaning of logical operators is given by their rules of inference. Arthur Prior cast doubt on this by introducing rules for his tonk operator that would allow for the derivation of any sentence whatsoever from any sentence whatsoever. The obvious inferentialist reply was to require some constraints on the defining rules, such as conservativeness (Belnap) or harmony (Dummett). In this talk, I will defend and investigate a different constraint: rules define a classical logical operator just in case they translate into an explicit definition in pure classical second-order logic. The right-hand side of this criterion will be found (i) to be philosophically principled in taking the idea of rules as definitions perfectly seriously, (ii) to explain how the semantic meaning of the operators can be determined from their rules, (iii) to be local in a similar sense as harmony, (iv) to validate the intuitionistic natural deduction rules and the intuitionistic/classical sequent calculus rules as defining the classical propositional operators while ruling out Prior’s rules for tonk, (v) to make clear why already the intuitionistic natural deduction rules define the classical meaning of logical operators so long as metavariables are interpreted as expressing classical propositions, (vi) to validate the classical natural deduction rules as analytic, (vii) to entail consistency, and, in the case of propositional operators (not quantifiers), (viii) to be decidable and (ix) to determine precisely those operators to be definable by rules that correspond to truth-functions.