Seminars
Seminars, workshops and other events organised by our group
The Logic Group runs a bi-weekly Research Seminar in Logic, monthly Nordic Online Logic Seminar and the annual Lindström Lecture series, as well as other events. See below for a list of recent and upcoming events or follow the links to jump straight to a category.
The research seminar in Logic meets on alternate Fridays at 10.15. Unless otherwise stated, seminars are held at the department building (Humanisten). Details of online talks are distributed in the GU Logic mailing list. Alternatively, contact Graham E Leigh directly.
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A workshop dedicated to current and future trens in cyclic and illfounded notions 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 and the Department of Philosophy, Linguistics and Theory of Science.
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Opponent: Jakub Szymanik, Associate professor at the Center for Brain/Mind Sciences and the Computer Science Department at the University of Trento.
Abstract Description logics are designed to reason efficiently with ontologies in knowledge bases, which are widely used in several industries. Human errors commonly cause mistakes to occur in the axioms of these ontologies, which leads to the logics deducing false conclusions. Ontology engineers spend much time on finding these false axioms to repair the ontology. This process can be facilitated by presenting a justification of the false conclusion, i.e. a set of axioms that entail the conclusion. Typically, the number of justifications for a given conclusion is very large and it is not clear which one should be presented.
It is therefore useful to estimate the cognitively adequate complexity of description logic so that the simplest justification(s) can be identified and selected. This work focusses on the cognitive complexity of deciding the consistency of ABoxes in the description logic $\mathcal{ALE}$. Conceptual considerations entail that the complexity of the ABox consistency problem is expressed as a linear preorder on a large enough set of ABoxes. This linear preorder can be estimated by an ACT-R model called SHARP. The model is a tableau algorithm implemented in a cognitive architecture, thereby modelling a human brain executing the tableau algorithm, which forms an approximation of the cognitive complexity ordering.
A complexity ordering that is a linear preorder can be obtained from experimental data by aggregating the different individual orders from a sample into one so-called proto-order, in which the largest transitive subrelation is the desired linear pre-order. The predicted complexity ordering by SHARP agrees well with the empirical data.
To enable applications in ontology debugging, a surrogate model is needed that accurately approximates SHARP’s output with great computational efficiency. Such a surrogate model can be obtained by the Random Forest algorithm trained on an appropriate dataset generated by SHARP. The complexity ordering thus obtained agrees well with the one predicted by SHARP but can be estimated in a fraction of the time enabling it for practical applications.
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Frame definability is a well-studied notion for a plethora of logics: a class of frames is defined by a set of formulas if and only if such formulas are validities for all and only the frames in such class.
In this talk, I will present a series of results about frame definability in a fragment of conditional logic. Conditional logic is an extension of propositional logic that includes a binary “counterfactual” conditional operator \(\leadsto\). We specifically make the following choices: (i), we consider the non-nested fragment of conditional logic (i.e., where conditionals are not allowed in the scope of other conditionals), and (ii), we consider only finite posets as the underlying structure of the models of our logic. Given these assumptions, a formula of the form \(\varphi \leadsto \psi\) is intuitively true if the consequent \(\psi\) is true in all the minimal (with respect to the partial order of the poset) worlds where the antecedent \(\varphi\) is true. Via these semantics, this fragment of conditional logic becomes relevant in several fields, such as default reasoning and belief revision.
I will present the following results: (i) a set of non-nested conditional formulas each defining a different class of finite posets; (ii) a characterization theorem identifying the classes of finite posets that can be defined by a non-nested conditional formula; and (iii), a Sahlqvist-like theorem proving that every class of finite posets definable via a non-nested conditional formula is definable also by a first-order formula.
This talk is based on the paper Frame Definability in Conditional Logic, a joint work with Damiano Fornasiere and Johannes Marti, which was published at AiML 2024.
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Sun Tzu was a military strategist who lived in China about 2500 years ago. His book is still popular today, especially in business circles.
This talk presents a study of “The Art of War” from the perspectives of logic, mathematics, and computer science. We explain briefly what a mind map is and our strict text tree interpretation of it, for the purpose of analyzing Sun Tzu’s text. We show that you can improve the translation and find more meaning in the text, representing the text as mind maps. If time permits, we will illustrate that, surprisingly, the text still helps us to understand what is happening in warfare today.
The title of this talk is also the title of our book, co-authored by Kaibo Xie (Tsinghua Univ. Beijing), and Bonan Zhao (Univ. of Edinburgh), and published in 2022 by Springer. The book is the result of a joint study of the Institute of Language, Logic and Computation, Univ. of Amsterdam and the Institute for Philosophy, Tsinghua University, Beijing, China.
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Ivan Di Liberti (FLoV)
A modular approach to completeness, Beth-definability and Craig interpolation
We provide an algebraic definition of “fragment of geometric logic”. Those are understood as families of locales enjoying algebraic properties. Meet-semilattices, Distributive lattices, and other relevant classes of posets corresponding to established propositional logics arise as fragments of geometric logic in this sense. Thanks for the modularity of our approach we can tell what family of fragments of geometric logic verify a completeness theorem (with respect to booleans), Craig-interpolation, and Beth definability. In its current form, the framework cannot encompass modal logics, as modal operators are structure (as opposed to property). This is a report of joint work with Lingyuan Ye.
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What is the meaning of a logical connective? This is a very difficult and controversial question, primarily because its answer depends on the underlying logical framework. In model-theoretic semantics, the meaning of logical connectives is grounded in mathematical structures that define validity in terms of truth. Proof-theoretic semantics (PtS), by contrast, offers an alternative perspective in which truth is replaced by proof. This shift highlights the role of proofs as the foundation for demonstrative knowledge, particularly in mathematical reasoning. Philosophically, PtS aligns with inferentialism, which holds that the meaning of expressions is determined by inference rules. This makes PtS particularly well-suited for understanding reasoning, as it defines logical connectives based on their role in inference.
Base-extension semantics (BeS) is a strand of PtS where proof-theoretic validity is defined relative to a given collection of inference rules regarding basic formulas of the language. Although the BeS project has been successfully developed for intuitionistic propositional logic, first-order classical logic and the multiplicative fragment of linear logic among others, its progression as a comprehensive foundation for logical reasoning is still in its early stages.
In this talk, we will explore Pt-S with a focus on BeS. First, we will introduce an ecumenical perspective to BeS, inspired by Prawitz’s proposal of a system combining classical and intuitionistic logics. The aim is to deepen our understanding of logical reasoning disagreements by investigating the ecumenical approach and developing a unified proof-theoretic foundation for logical reasoning.
We will then address a major challenge in PtS, often called its “original sin”, which is its strong reliance on the natural deduction framework. To overcome this, we propose a version of BeS that employs atomic systems based on sequent calculus rules rather than natural deduction. In this approach, structural rules are treated as properties of atomic systems rather than the logical calculus itself. This allows for a semantics of substructural logics to emerge naturally by modifying the underlying atomic systems. Furthermore, this framework supports a Sandqvist-style completeness proof, but instead of extracting a proof in natural deduction, we obtain one in sequent calculus.
This is based is an ongoing and joint work with Victor Barroso-Nascimento, Luiz Carlos Pereira and Katya Piotrovskaya.
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We extend homotopy type theory with four extra axioms. The resulting theory should describe the higher topos of light condensed sets. From the axioms, we can prove Markov’s principle, the lesser limited principle of omniscience, and the negation of the weak lesser principle of omniscience. We define a type of open propositions, which induces a topology on each type. With this topology, every map is continuous. We then introduce Stone and compact Hausdorff spaces internally, and the induced topologies on these types are as expected. In particular, we can deduce that all maps from the real unit interval to itself are continuous in the epsilon-delta sense.
This talk is based on a paper submitted to TYPES24, which was authored by Felix Cherubini, Thierry Coquand, Freek Geerligs and Hugo Moeneclaey. The paper is part of the synthetic algebraic geometry project.
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Team semantics extends traditional semantics by shifting the interpretation of formulas from individual semantic objects (e.g., assignments, valuations, or worlds) to sets of such objects, commonly referred to as teams. This approach enables the expression of properties, such as variable dependency, that are inaccessible in traditional semantics. Since its introduction by Hodges and subsequent refinement by Väänänen, team semantics has been used to develop expressively enriched logics that retain desirable properties such as compactness.
However, these logics are typically non-substitutional, limiting their algebraic treatment and preventing the development of schematic proof systems. This limitation can be attributed to the flatness principle which is commonly adhered to in many constructions of team semantics for logics.
In this talk, we approach the formation of propositional logic of teams from an algebraic perspective, explicitly discarding the flatness principle. We propose a substitutional logic of teams that is expressive enough to axiomatize key propositional team logics, such as propositional dependence logic.
Our construction parallels the algebraic construction of classical propositional logic from Boolean algebras. The algebras we are using are powersets of Boolean algebras equipped with both internal (pointwise) and external (set-theoretic) operations. The resulting logic is clearly substitutional, and is shown to be sound and complete with respect to a labelled natural deduction system.
If time permits, we will also discuss how we might do to extend this construction to the framework of first-order logic.
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We investigate the cyclic proof theory of extensions of Peano Arithmetic, in particular µPA, a theory that extends Peano Arithmetic with least and greatest fixed point operators. Our cyclic system CµPA subsumes Simpson’s cyclic arithmetic and the stronger CID<ω. Our main result, which is still work in progress, is that the inductive system µPA and the cyclic system CµPA prove the same arithmetical theorems. We intend to conduct a metamathematical argument for Cyclic Arithmetic to formalize the soundness of cyclic proofs within second-order arithmetic by a form of induction on closure ordinals and then appealing to conservativity results. Since the closure ordinals of our inductive definitions far exceed the recursive ordinals we cannot rely on ordinal notations and must instead formalize a theory of ordinals within second-order arithmetic. This is similar to what is for CID<ω except here we also need to use the reverse mathematics of a more powerful version of Knaster–Tarski.
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The Logic Group at the University of Gothenburg hosts its annual World Logic Day Pub Quiz. For information on World Logic Day events around the world, see http://wld.cipsh.international/wld2025.html.
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Fagin’s seminal result characterizing NP in terms of existential second-order logic started the fruitful field of descriptive complexity theory. In recent years, there has been much interest in the investigation of quantitative (weighted) models of computations. In this paper, we start the study of descriptive complexity based on weighted Turing machines over arbitrary semirings. We provide machine-independent characterizations (over ordered structures) of the weighted complexity classes NP[S], FP[S], FPLOG[S], FPSPACE[S], and FPSPACEpoly[S] in terms of definability in suitable weighted logics for an arbitrary semiring S. In particular, we prove weighted versions of Fagin’s theorem (even for arbitrary structures, not necessarily ordered, provided that the semiring is idempotent and commutative), the Immerman–Vardi’s theorem (originally for P) and the Abiteboul–Vianu–Vardi’s theorem (originally for PSPACE). We also discuss a recent open problem proposed by Eiter and Kiesel.
Recently, the above mentioned weighted complexity classes have been investigated in connection to classical counting complexity classes. Furthermore, several classical counting complexity classes have been characterized in terms of particular weighted logics over the semiring N of natural numbers. In this work, we cover several of these classes and obtain new results for others such as NPMV, ⊕P, or the collection of real-valued languages realized by nondeterministic polynomial-time real-valued Turing machines. Furthermore, our results apply to classes based on many other important semirings, such as the max-plus and the min-plus semirings over the natural numbers which correspond to the classical classes MaxP[O(log n)] and MinP[O(log n)], respectively.
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Several areas of computer science (databases, knowledge representation, program verification, reasoning about knowledge and actions) feature logical languages in which one can construct complex binary relations from basic ones, through a certain set of operations (e.g., relational composition, union, inverse, …). Examples include propositional dynamic logics such as PDL and KAT (Kleene Algebra with Tests) as well as various query languages for graph databases. Underlying each of these is a “binary relation algebra” , i.e., an algebraic signature consisting of finitely many operations on binary relations. The specific set of operators, in each of the aforementioned languages, is typically chosen as a compromise between computational complexity and expressive power and/or may be based on a requirement to preserve certain natural structural properties such as functionality or bisimulation.
Preservation theorems link semantics properties of formulas to their syntactic shape. The most famous example is the Łoś-Tarski theorem, which states that a first-order formula is preserved under induced substructures (i.e., remains true if one passes from a structure to an induced substructure) if and only if it can be written without using any existential quantifiers (assuming negation normal form). In this talk, we will review some recent results (both positive and negative) about the existence of preservation theorems for algebras of binary relations. (Algebraically, the results I will present can be equivalently viewed as addressing the question whether certain clones admit a finite set of generators).
Specifically, I will discuss results about Tarski’s relation algebra from a joint paper with Bart Bogaerts, Brett McLean, and Jan van den Bussche (LMCS 2024) as well as results about Kleene Algebra with Tests (KAT) from a joint paper with Tobias Kappé (POPL 2025).
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Disquotational truth can play a justificatory role for new mathematical knowledge. In particular, we focus on the known case of consistently extending a theory of first-order arithmetic (PA) with a truth predicate governed by disquotational principles for positive sentences. One philosophically interesting feature is that the addition of this truth predicate is conservative over the arithmetical theory, giving disquotational truth the same epistemic status of a mathematical definition. Following Feferman and McGee, we argue in favour of the open-ended nature of the induction schema: once a new mathematical concept is legitimately defined the schema should hold for the extended language. For truth, this results in more justificatory power as one can prove the consistency statement of the arithmetical theory. Moreover, the exact nature of the justificatory power of positive disquotational truth can be pinned down via an ordinal analysis of the theory, as done by Halbach.
We explore the possibility of extending this disquotational definition of truth via a principle of Generalised Induction introduced by Cantini. The principle is conservative over PA, meaning it preserves the epistemic status of a definition. Furthermore, we argue that the adoption of this principle is particularly motivated in the case of positive disquotational truth. Once this new truth predicate is allowed in the induction schema, we obtain significantly more justificatory power than the original disquotational theory. I conclude by sketching a possible strategy via a collapsing procedure to show that this result is sharp.
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Non-classical logics have been proposed in a number of domains, including constructive mathematics and quantum mechanics. In this talk, I will identify a base logic beneath some of these non-classical logics that I suggest has a certain fundamental status. I will give an introduction to the proof theory and semantics of this “Fundamental Logic.”
An associated paper is available at https://arxiv.org/abs/2207.06993.
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Previous works by Goré, Postniece and Tiu have provided sound and cut-free complete proof systems for modal logics extended with path axioms using the formalism of nested sequent. Our aim is to provide (i) a constructive cut-elimination procedure and (ii) alternative modular formulations for these systems. We present our methodology to achieve these two goals on a subclass of path axioms, namely quasi-transitivity axioms.
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The axioms of quantum mechanics present the state of a quantum system as a unit vector in complex Hilbert space. However, when Dirac [1] presented his bra- and ket-vectors, he had a more general space in mind. Schwartz [4] later gave a rigorous account for Dirac’s “vectors” as distributions, but in elementary physics books one still encounters presentations where ket-vectors are presented just as elements of a Hilbert space, and treated with methods from finite-dimensional linear algebra.
During the last years Tapani Hyttinen and I [2,3] have been looking at various models justifying the finite dimensional approaches from such textbooks. Our approaches are based on various embeddings of a Hilbert space into metric ultraproducts of finite-dimensional Hilbert spaces. In this talk I will present the basic ideas, their benefits and limitations. Time permitting, I will also contrast our approach to Boris Zilber’s work on the same questions, that was the original inspiration for us.
- P.A.M. Dirac. The principles of Quantum Mechanics, 3rd ed, Clarendon Press, Oxford, 1947.
- Å. Hirvonen, T. Hyttinen, On eigenvectors, approximations and the Feynman propagator, Ann. Pure Appl. Logic 170 (2019).
- Å. Hirvonen, T. Hyttinen, On Ultraproducts, the Spectral Theorem and Rigged Hilbert Spaces, to appear in J. Symb. Log.
- L. Schwartz, Théory de Distributions, Hermann, Paris, 1950.