Theory of Computing Report

Authors: Timon Barlag, Vivian Holzapfel, Laura Strieker, Jonni Virtema, Heribert Vollmer

We characterise the computational power of recurrent graph neural networks (GNNs) in terms of arithmetic circuits over the real numbers. Our networks are not restricted to aggregate-combine GNNs or other particular types. Generalizing similar notions from the literature, we introduce the model of recurrent arithmetic circuits, which can be seen as arithmetic analogues of sequential or logical circuits. These circuits utilise so-called memory gates which are used to store data between iterations of the recurrent circuit. While (recurrent) GNNs work on labelled graphs, we construct arithmetic circuits that obtain encoded labelled graphs as real valued tuples and then compute the same function. For the other direction we construct recurrent GNNs which are able to simulate the computations of recurrent circuits. These GNNs are given the circuit-input as initial feature vectors and then, after the GNN-computation, have the circuit-output among the feature vectors of its nodes. In this way we establish an exact correspondence between the expressivity of recurrent GNNs and recurrent arithmetic circuits operating over real numbers.

Authors: Timon Barlag, Vivian Holzapfel, Laura Strieker, Jonni Virtema, Heribert Vollmer

We characterise the computational power of recurrent graph neural networks (GNNs) in terms of arithmetic circuits over the real numbers. Our networks are not restricted to aggregate-combine GNNs or other particular types. Generalizing similar notions from the literature, we introduce the model of recurrent arithmetic circuits, which can be seen as arithmetic analogues of sequential or logical circuits. These circuits utilise so-called memory gates which are used to store data between iterations of the recurrent circuit. While (recurrent) GNNs work on labelled graphs, we construct arithmetic circuits that obtain encoded labelled graphs as real valued tuples and then compute the same function. For the other direction we construct recurrent GNNs which are able to simulate the computations of recurrent circuits. These GNNs are given the circuit-input as initial feature vectors and then, after the GNN-computation, have the circuit-output among the feature vectors of its nodes. In this way we establish an exact correspondence between the expressivity of recurrent GNNs and recurrent arithmetic circuits operating over real numbers.

Friday, March 06 2026, 01:00

Attacking the Polynomials in the Maze of Finite Fields problem

Authors: Àngela Barbero, Ragnar Freij-Hollanti, Camilla Hollanti, Håvard Raddum, Øyvind Ytrehus, Morten Øygarden

In April 2025 GMV announced a competition for finding the best method to solve a particular polynomial system over a finite field. In this paper we provide a method for solving the given equation system significantly faster than what is possible by brute-force or standard Gröbner basis approaches. The method exploits the structured sparsity of the polynomial system to compute a univariate polynomial in the associated ideal through successive computations of resultants. A solution to the system can then be efficiently recovered from this univariate polynomial. Pseudocode is given for the proposed ResultantSolver algorithm, along with experiments and comparisons to rival methods. We also discuss further potential improvements, such as parallelizing parts of the computations.

Authors: Àngela Barbero, Ragnar Freij-Hollanti, Camilla Hollanti, Håvard Raddum, Øyvind Ytrehus, Morten Øygarden

In April 2025 GMV announced a competition for finding the best method to solve a particular polynomial system over a finite field. In this paper we provide a method for solving the given equation system significantly faster than what is possible by brute-force or standard Gröbner basis approaches. The method exploits the structured sparsity of the polynomial system to compute a univariate polynomial in the associated ideal through successive computations of resultants. A solution to the system can then be efficiently recovered from this univariate polynomial. Pseudocode is given for the proposed ResultantSolver algorithm, along with experiments and comparisons to rival methods. We also discuss further potential improvements, such as parallelizing parts of the computations.

Friday, March 06 2026, 01:00

Garment numbers of bi-colored point sets in the plane

Authors: Oswin Aichholzer, Helena Bergold, Simon D. Fink, Maarten Löffler, Patrick Schnider, Josef Tkadlec

We consider colored variants of a class of geometric-combinatorial questions on $k$-gons and empty $k$-gons that have been started around 1935 by Erdős and Szekeres. In our setting we have $n$ points in general position in the plane, each one colored either red or blue. A structure on $k$ points is a geometric graph where the edges are spanned by (some of) these points and is called monochromatic if all $k$ points have the same color. Already for $k=4$ there exist interesting open problems. Most prominently, it is still open whether for any sufficiently large bichromatic set there always exists a convex empty, monochromatic quadrilateral. In order to shed more light on the underlying geometry we study the existence of five different monochromatic structures that all use exactly 4 points of a bichromatic point set. We provide several improved lower and upper bounds on the smallest $n$ such that every bichromatic set of at least $n$ points contains (some of) those monochromatic structures.

Authors: Oswin Aichholzer, Helena Bergold, Simon D. Fink, Maarten Löffler, Patrick Schnider, Josef Tkadlec

We consider colored variants of a class of geometric-combinatorial questions on $k$-gons and empty $k$-gons that have been started around 1935 by Erdős and Szekeres. In our setting we have $n$ points in general position in the plane, each one colored either red or blue. A structure on $k$ points is a geometric graph where the edges are spanned by (some of) these points and is called monochromatic if all $k$ points have the same color. Already for $k=4$ there exist interesting open problems. Most prominently, it is still open whether for any sufficiently large bichromatic set there always exists a convex empty, monochromatic quadrilateral. In order to shed more light on the underlying geometry we study the existence of five different monochromatic structures that all use exactly 4 points of a bichromatic point set. We provide several improved lower and upper bounds on the smallest $n$ such that every bichromatic set of at least $n$ points contains (some of) those monochromatic structures.

Friday, March 06 2026, 01:00

Drone Air Traffic Control: Tracking a Set of Moving Objects with Minimal Power

Authors: Chek-Manh Loi, Michael Perk, Malte Hoffmann, Sándor Fekete

A common sensing problem is to use a set of stationary tracking locations to monitor a collection of moving devices: Given $n$ objects that need to be tracked, each following its own trajectory, and $m$ stationary traffic control stations, each with a sensing region of adjustable range; how should we adjust the individual sensor ranges in order to optimize energy consumption? We provide both negative theoretical and positive practical results for this important and natural challenge. On the theoretical side, we show that even if all objects move at constant speed along straight lines, no polynomial-time algorithm can guarantee optimal coverage for a given starting solution. On the practical side, we present an algorithm based on geometric insights that is able to find optimal solutions for the $\min \max$ variant of the problem, which aims at minimizing peak power consumption. Runtimes for instances with 500 moving objects and 25 stations are in the order of seconds for scenarios that take minutes to play out in the real world, demonstrating real-time capability of our methods.

Authors: Chek-Manh Loi, Michael Perk, Malte Hoffmann, Sándor Fekete

A common sensing problem is to use a set of stationary tracking locations to monitor a collection of moving devices: Given $n$ objects that need to be tracked, each following its own trajectory, and $m$ stationary traffic control stations, each with a sensing region of adjustable range; how should we adjust the individual sensor ranges in order to optimize energy consumption? We provide both negative theoretical and positive practical results for this important and natural challenge. On the theoretical side, we show that even if all objects move at constant speed along straight lines, no polynomial-time algorithm can guarantee optimal coverage for a given starting solution. On the practical side, we present an algorithm based on geometric insights that is able to find optimal solutions for the $\min \max$ variant of the problem, which aims at minimizing peak power consumption. Runtimes for instances with 500 moving objects and 25 stations are in the order of seconds for scenarios that take minutes to play out in the real world, demonstrating real-time capability of our methods.

Friday, March 06 2026, 01:00

What induces plane structures in complete graph drawings?

Authors: Alexandra Weinberger, Ji Zeng

This paper considers the task of connecting points on a piece of paper by drawing a curve between each pair of them. Under mild assumptions, we prove that many pairwise disjoint curves are unavoidable if either of the following rules is obeyed: any two adjacent curves do not cross, or any two non-adjacent curves cross at most once. Here, two curves are called adjacent if they share an endpoint. On the other hand, we demonstrate how to draw all curves such that any two adjacent curves cross exactly once, any two non-adjacent curves cross at least once and at most twice, and thus no two curves are disjoint. Furthermore, we analyze the emergence of disjoint curves without these mild assumptions, and characterize the plane structures in complete graph drawings guaranteed by each of the rules above.

Authors: Alexandra Weinberger, Ji Zeng

This paper considers the task of connecting points on a piece of paper by drawing a curve between each pair of them. Under mild assumptions, we prove that many pairwise disjoint curves are unavoidable if either of the following rules is obeyed: any two adjacent curves do not cross, or any two non-adjacent curves cross at most once. Here, two curves are called adjacent if they share an endpoint. On the other hand, we demonstrate how to draw all curves such that any two adjacent curves cross exactly once, any two non-adjacent curves cross at least once and at most twice, and thus no two curves are disjoint. Furthermore, we analyze the emergence of disjoint curves without these mild assumptions, and characterize the plane structures in complete graph drawings guaranteed by each of the rules above.

Friday, March 06 2026, 01:00

Structural Properties of Shortest Flip Sequences Between Plane Spanning Trees

Authors: Oswin Aichholzer, Joseph Dorfer, Peter Kramer, Christian Rieck, Birgit Vogtenhuber

We study the reconfiguration of plane spanning trees on point sets in the plane in convex position, where a reconfiguration step (flip) replaces one edge with another, yielding again a plane spanning tree. The flip distance between two trees is then the minimum number of flips needed to transform one tree into the other. We study structural properties of shortest flip sequences. The folklore happy edge conjecture suggests that any edge shared by both the initial and target tree is never flipped in a shortest flip sequence. The more recent parking edge conjecture, which would have implied the happy edge conjecture, states that there exist shortest flip sequences which use only edges of the start and target tree, and edges in the convex hull of the point set. Finally, another conjecture that is implicit in the literature is the reparking conjecture which states that no edge is flipped more than twice. Essentially all recent flip algorithms respect these three conjectures and the properties they imply. We study cases in which the latter two conjectures hold and disprove them for the general setting. (Shortened abstract due to arXiv restrictions.)

Authors: Oswin Aichholzer, Joseph Dorfer, Peter Kramer, Christian Rieck, Birgit Vogtenhuber

We study the reconfiguration of plane spanning trees on point sets in the plane in convex position, where a reconfiguration step (flip) replaces one edge with another, yielding again a plane spanning tree. The flip distance between two trees is then the minimum number of flips needed to transform one tree into the other. We study structural properties of shortest flip sequences. The folklore happy edge conjecture suggests that any edge shared by both the initial and target tree is never flipped in a shortest flip sequence. The more recent parking edge conjecture, which would have implied the happy edge conjecture, states that there exist shortest flip sequences which use only edges of the start and target tree, and edges in the convex hull of the point set. Finally, another conjecture that is implicit in the literature is the reparking conjecture which states that no edge is flipped more than twice. Essentially all recent flip algorithms respect these three conjectures and the properties they imply. We study cases in which the latter two conjectures hold and disprove them for the general setting. (Shortened abstract due to arXiv restrictions.)

Friday, March 06 2026, 01:00

Reconfiguration of Squares Using a Constant Number of Moves Each

Authors: Thijs van der Horst, Maarten Löffler, Tim Ophelders, Tom Peters

Multi-robot motion planning is a hard problem. We investigate restricted variants of the problem where square robots are allowed to slide over an arbitrary curve to a new position only a constant number of times each. We show that the problem remains NP-hard in most cases, except when the squares have unit size and when the problem is unlabeled, i.e., the location of each square in the target configuration is left unspecified.

Authors: Thijs van der Horst, Maarten Löffler, Tim Ophelders, Tom Peters

Multi-robot motion planning is a hard problem. We investigate restricted variants of the problem where square robots are allowed to slide over an arbitrary curve to a new position only a constant number of times each. We show that the problem remains NP-hard in most cases, except when the squares have unit size and when the problem is unlabeled, i.e., the location of each square in the target configuration is left unspecified.

Friday, March 06 2026, 01:00

An Optimal Algorithm for Computing Many Faces in Line Arrangements

Authors: Haitao Wang

Given a set of $m$ points and a set of $n$ lines in the plane, we consider the problem of computing the faces of the arrangement of the lines that contain at least one point. In this paper, we present an $O(m^{2/3}n^{2/3}+(n+m)\log n)$ time algorithm for the problem. We also show that this matches the lower bound under the algebraic decision tree model and thus our algorithm is optimal. In particular, when $m=n$, the runtime is $O(n^{4/3})$, which matches the worst case combinatorial complexity $Ω(n^{4/3})$ of all output faces. This is the first optimal algorithm since the problem was first studied more than three decades ago [Edelsbrunner, Guibas, and Sharir, SoCG 1988].

Authors: Haitao Wang

Given a set of $m$ points and a set of $n$ lines in the plane, we consider the problem of computing the faces of the arrangement of the lines that contain at least one point. In this paper, we present an $O(m^{2/3}n^{2/3}+(n+m)\log n)$ time algorithm for the problem. We also show that this matches the lower bound under the algebraic decision tree model and thus our algorithm is optimal. In particular, when $m=n$, the runtime is $O(n^{4/3})$, which matches the worst case combinatorial complexity $Ω(n^{4/3})$ of all output faces. This is the first optimal algorithm since the problem was first studied more than three decades ago [Edelsbrunner, Guibas, and Sharir, SoCG 1988].

Friday, March 06 2026, 01:00

Quadratic polarity and polar Fenchel-Young divergences from the canonical Legendre polarity

Authors: Frank Nielsen, Basile Plus-Gourdon, Mahito Sugiyama

Polarity is a fundamental reciprocal duality of $n$-dimensional projective geometry which associates to points polar hyperplanes, and more generally $k$-dimensional convex bodies to polar $(n-1-k)$-dimensional convex bodies. It is well-known that the Legendre-Fenchel transformation of functions can be interpreted from the polarity viewpoint of their graphs using an extra dimension. In this paper, we first show that generic polarities induced by quadratic polarity functionals can be expressed either as deformed Legendre polarity or as the Legendre polarity of deformed convex bodies, and be efficiently manipulated using linear algebra on $(n+2)\times (n+2)$ matrices operating on homogeneous coordinates. Second, we define polar divergences using the Legendre polarity and show that they generalize the Fenchel-Young divergence or equivalent Bregman divergence. This polarity study brings new understanding of the core reference duality in information geometry. Last, we show that the total Bregman divergences can be considered as a total polar Fenchel-Young divergence from which we newly exhibit the reference duality using dual polar conformal factors.

Authors: Frank Nielsen, Basile Plus-Gourdon, Mahito Sugiyama

Polarity is a fundamental reciprocal duality of $n$-dimensional projective geometry which associates to points polar hyperplanes, and more generally $k$-dimensional convex bodies to polar $(n-1-k)$-dimensional convex bodies. It is well-known that the Legendre-Fenchel transformation of functions can be interpreted from the polarity viewpoint of their graphs using an extra dimension. In this paper, we first show that generic polarities induced by quadratic polarity functionals can be expressed either as deformed Legendre polarity or as the Legendre polarity of deformed convex bodies, and be efficiently manipulated using linear algebra on $(n+2)\times (n+2)$ matrices operating on homogeneous coordinates. Second, we define polar divergences using the Legendre polarity and show that they generalize the Fenchel-Young divergence or equivalent Bregman divergence. This polarity study brings new understanding of the core reference duality in information geometry. Last, we show that the total Bregman divergences can be considered as a total polar Fenchel-Young divergence from which we newly exhibit the reference duality using dual polar conformal factors.

Friday, March 06 2026, 01:00

Hypercube drawings with no long plane paths

Authors: Todor Antić, Niloufar Fuladi, Anna Margarethe Limbach, Pavel Valtr

We study the existence of plane substructures in drawings of the $d$-dimensional hypercube graph $Q_d$. We construct drawings of $Q_d$ which contain no plane subgraph with more than $2d-2$ edges, no plane path with more than $2d-3$ edges, and no plane matching of size more than $2d-4$. On the other hand, we prove that every rectilinear drawing of $Q_d$ with vertices in convex position contains a plane path of length $d$ (if $d$ is odd) or $d-1$ (if $d$ is even). We also prove that if a graph $G$ is a plane subgraph of every drawing of $Q_d$ for a sufficiently large $d$, then $G$ is necessarily a forest of caterpillars. Lastly, we give a short proof of a generalization of a result by Alpert et al. [Cong. Numerantium, 2009] on the maximum rectilinear crossing number of $Q_d$.

Authors: Todor Antić, Niloufar Fuladi, Anna Margarethe Limbach, Pavel Valtr

We study the existence of plane substructures in drawings of the $d$-dimensional hypercube graph $Q_d$. We construct drawings of $Q_d$ which contain no plane subgraph with more than $2d-2$ edges, no plane path with more than $2d-3$ edges, and no plane matching of size more than $2d-4$. On the other hand, we prove that every rectilinear drawing of $Q_d$ with vertices in convex position contains a plane path of length $d$ (if $d$ is odd) or $d-1$ (if $d$ is even). We also prove that if a graph $G$ is a plane subgraph of every drawing of $Q_d$ for a sufficiently large $d$, then $G$ is necessarily a forest of caterpillars. Lastly, we give a short proof of a generalization of a result by Alpert et al. [Cong. Numerantium, 2009] on the maximum rectilinear crossing number of $Q_d$.

Friday, March 06 2026, 01:00

Estimation of Persistence Diagrams via the Three Gap Theorem

Authors: Luis Suarez Salas, Jose A. Perea

The time delay (or Sliding Window) embedding is a technique from dynamical systems to reconstruct attractors from time series data. Recently, descriptors from Topological Data Analysis (TDA) -- specifically, persistence diagrams -- have been used to measure the shape of said reconstructed attractors in applications including periodicity and quasiperiodicity quantification. Despite their utility, the fast computation of persistence diagrams of sliding window embeddings is still poorly understood. In this work, we present theoretical and computational schemes to approximate the persistence diagrams of sliding window embeddings from quasiperiodic functions. We do so by combining the Three Gap Theorem from number theory with the Persistent Künneth formula from TDA, and derive fast and provably correct persistent homology approximations. The input to our procedure is the spectrum of the signal, and we provide numerical as well as theoretical evidence of its utility to capture the shape of toroidal attractors.

Authors: Luis Suarez Salas, Jose A. Perea

The time delay (or Sliding Window) embedding is a technique from dynamical systems to reconstruct attractors from time series data. Recently, descriptors from Topological Data Analysis (TDA) -- specifically, persistence diagrams -- have been used to measure the shape of said reconstructed attractors in applications including periodicity and quasiperiodicity quantification. Despite their utility, the fast computation of persistence diagrams of sliding window embeddings is still poorly understood. In this work, we present theoretical and computational schemes to approximate the persistence diagrams of sliding window embeddings from quasiperiodic functions. We do so by combining the Three Gap Theorem from number theory with the Persistent Künneth formula from TDA, and derive fast and provably correct persistent homology approximations. The input to our procedure is the spectrum of the signal, and we provide numerical as well as theoretical evidence of its utility to capture the shape of toroidal attractors.

Friday, March 06 2026, 01:00

ETH-Tight Complexity of Optimal Morse Matching on Bounded-Treewidth Complexes

Authors: Geevarghese Philip, Erlend Raa Vågset

The Optimal Morse Matching (OMM) problem asks for a discrete gradient vector field on a simplicial complex that minimizes the number of critical simplices. It is NP-hard and has been studied extensively in heuristic, approximation, and parameterized complexity settings. Parameterized by treewidth $k$, OMM has long been known to be solvable on triangulations of $3$-manifolds in $2^{O(k^2)} n^{O(1)}$ time and in FPT time for triangulations of arbitrary manifolds, but the exact dependence on $k$ has remained an open question. We resolve this by giving a new $2^{O(k \log k)} n$-time algorithm for any finite regular CW complex, and show that no $2^{o(k \log k)} n^{O(1)}$-time algorithm exists unless the Exponential Time Hypothesis (ETH) fails.

Authors: Geevarghese Philip, Erlend Raa Vågset

The Optimal Morse Matching (OMM) problem asks for a discrete gradient vector field on a simplicial complex that minimizes the number of critical simplices. It is NP-hard and has been studied extensively in heuristic, approximation, and parameterized complexity settings. Parameterized by treewidth $k$, OMM has long been known to be solvable on triangulations of $3$-manifolds in $2^{O(k^2)} n^{O(1)}$ time and in FPT time for triangulations of arbitrary manifolds, but the exact dependence on $k$ has remained an open question. We resolve this by giving a new $2^{O(k \log k)} n$-time algorithm for any finite regular CW complex, and show that no $2^{o(k \log k)} n^{O(1)}$-time algorithm exists unless the Exponential Time Hypothesis (ETH) fails.

Friday, March 06 2026, 01:00

Quantum Algorithms for Network Signal Coordination

Authors: Vinayak Dixit, Richard Pech

There has been increasing interest in developing efficient quantum algorithms for hard classical problems. The Network Signal Coordination (NSC) problem is one such problem known to be NP complete. We implement Grover's search algorithm to solve the NSC problem to provide quadratic speedup. We further extend the algorithm to a Robust NSC formulation and analyse its complexity under both constant and polynomial-precision robustness parameters. The Robust NSC problem determines whether there exists a fraction (alpha) of solutions space that will lead to system delays less than a maximum threshold (K). The key contributions of this work are (1) development of a quantum algorithm for the NSC problem, and (2) a quantum algorithm for the Robust NSC problem whose iteration count is O(1/sqrt(alpha)), independent of the search space size, and (3) an extension to polynomial-precision robustness where alpha = alpha_o/p(N) decays polynomially with network size, retaining a quadratic quantum speedup. We demonstrate its implementation through simulation and on an actual quantum computer.

Authors: Vinayak Dixit, Richard Pech

There has been increasing interest in developing efficient quantum algorithms for hard classical problems. The Network Signal Coordination (NSC) problem is one such problem known to be NP complete. We implement Grover's search algorithm to solve the NSC problem to provide quadratic speedup. We further extend the algorithm to a Robust NSC formulation and analyse its complexity under both constant and polynomial-precision robustness parameters. The Robust NSC problem determines whether there exists a fraction (alpha) of solutions space that will lead to system delays less than a maximum threshold (K). The key contributions of this work are (1) development of a quantum algorithm for the NSC problem, and (2) a quantum algorithm for the Robust NSC problem whose iteration count is O(1/sqrt(alpha)), independent of the search space size, and (3) an extension to polynomial-precision robustness where alpha = alpha_o/p(N) decays polynomially with network size, retaining a quadratic quantum speedup. We demonstrate its implementation through simulation and on an actual quantum computer.

Friday, March 06 2026, 01:00

Generalizing Fair Top-$k$ Selection: An Integrative Approach

Authors: Guangya Cai

Fair top-$k$ selection, which ensures appropriate proportional representation of members from minority or historically disadvantaged groups among the top-$k$ selected candidates, has drawn significant attention. We study the problem of finding a fair (linear) scoring function with multiple protected groups while also minimizing the disparity from a reference scoring function. This generalizes the prior setup, which was restricted to the single-group setting without disparity minimization. Previous studies imply that the number of protected groups may have a limited impact on the runtime efficiency. However, driven by the need for experimental exploration, we find that this implication overlooks a critical issue that may affect the fairness of the outcome. Once this issue is properly considered, our hardness analysis shows that the problem may become computationally intractable even for a two-dimensional dataset and small values of $k$. However, our analysis also reveals a gap in the hardness barrier, enabling us to recover the efficiency for the case of small $k$ when the number of protected groups is sufficiently small. Furthermore, beyond measuring disparity as the "distance" between the fair and the reference scoring functions, we introduce an alternative disparity measure$\unicode{x2014}$utility loss$\unicode{x2014}$that may yield a more stable scoring function under small weight perturbations. Through careful engineering trade-offs that balance implementation complexity, robustness, and performance, our augmented two-pronged solution demonstrates strong empirical performance on real-world datasets, with experimental observations also informing algorithm design and implementation decisions.

Authors: Guangya Cai

Fair top-$k$ selection, which ensures appropriate proportional representation of members from minority or historically disadvantaged groups among the top-$k$ selected candidates, has drawn significant attention. We study the problem of finding a fair (linear) scoring function with multiple protected groups while also minimizing the disparity from a reference scoring function. This generalizes the prior setup, which was restricted to the single-group setting without disparity minimization. Previous studies imply that the number of protected groups may have a limited impact on the runtime efficiency. However, driven by the need for experimental exploration, we find that this implication overlooks a critical issue that may affect the fairness of the outcome. Once this issue is properly considered, our hardness analysis shows that the problem may become computationally intractable even for a two-dimensional dataset and small values of $k$. However, our analysis also reveals a gap in the hardness barrier, enabling us to recover the efficiency for the case of small $k$ when the number of protected groups is sufficiently small. Furthermore, beyond measuring disparity as the "distance" between the fair and the reference scoring functions, we introduce an alternative disparity measure$\unicode{x2014}$utility loss$\unicode{x2014}$that may yield a more stable scoring function under small weight perturbations. Through careful engineering trade-offs that balance implementation complexity, robustness, and performance, our augmented two-pronged solution demonstrates strong empirical performance on real-world datasets, with experimental observations also informing algorithm design and implementation decisions.

Friday, March 06 2026, 01:00

Revisiting Graph Modification via Disk Scaling: From One Radius to Interval-Based Radii

Authors: Thomas Depian, Frank Sommer

For a fixed graph class $Π$, the goal of $Π$-Modification is to transform an input graph $G$ into a graph $H\inΠ$ using at most $k$ modifications. Vertex and edge deletions are common operations, and their (parameterized) complexity for various $Π$ is well-studied. Classic graph modification operations such as edge deletion do not consider the geometric nature of geometric graphs such as (unit) disk graphs. This led Fomin et al. [ITCS' 25] to initiate the study of disk scaling as a geometric graph modification operation for unit disk graphs: For a given radius $r$, each modified disk will be rescaled to radius $r$. In this paper, we generalize their model by allowing rescaled disks to choose a radius within a given interval $[r_{\min}, r_{\max}]$ and study the (parameterized) complexity (with respect to $k$) of the corresponding problem $Π$-Scaling. We show that $Π$-Scaling is in XP for every graph class $Π$ that can be recognized in polynomial time. Furthermore, we show that $Π$-Scaling: (1) is NP-hard and FPT for cluster graphs, (2) can be solved in polynomial time for complete graphs, and (3) is W[1]-hard for connected graphs. In particular, (1) and (2) answer open questions of Fomin et al. and (3) generalizes the hardness result for their variant where the set of scalable disks is restricted.

Authors: Thomas Depian, Frank Sommer

For a fixed graph class $Π$, the goal of $Π$-Modification is to transform an input graph $G$ into a graph $H\inΠ$ using at most $k$ modifications. Vertex and edge deletions are common operations, and their (parameterized) complexity for various $Π$ is well-studied. Classic graph modification operations such as edge deletion do not consider the geometric nature of geometric graphs such as (unit) disk graphs. This led Fomin et al. [ITCS' 25] to initiate the study of disk scaling as a geometric graph modification operation for unit disk graphs: For a given radius $r$, each modified disk will be rescaled to radius $r$. In this paper, we generalize their model by allowing rescaled disks to choose a radius within a given interval $[r_{\min}, r_{\max}]$ and study the (parameterized) complexity (with respect to $k$) of the corresponding problem $Π$-Scaling. We show that $Π$-Scaling is in XP for every graph class $Π$ that can be recognized in polynomial time. Furthermore, we show that $Π$-Scaling: (1) is NP-hard and FPT for cluster graphs, (2) can be solved in polynomial time for complete graphs, and (3) is W[1]-hard for connected graphs. In particular, (1) and (2) answer open questions of Fomin et al. and (3) generalizes the hardness result for their variant where the set of scalable disks is restricted.

Friday, March 06 2026, 01:00

Finding Short Paths on Simple Polytopes

Authors: Alexander E. Black, Raphael Steiner

We prove that computing a shortest monotone path to the optimum of a linear program over a simple polytope is NP-hard, thus resolving a 2022 open question of De Loera, Kafer, and Sanità. As a consequence, finding a shortest sequence of pivots to an optimal basis with the simplex method is NP-hard. In fact, we show this is NP-hard already for fractional knapsack polytopes. By applying an additional polyhedral construction, we show that computing the diameter of a simple polytope is NP-hard, resolving a 2003 open problem by Kaibel and Pfetsch. Finally, on the positive side we show that every polytope has a small, simple extended formulation for which a linear length path may be found between any pair of vertices in polynomial time building upon a result of Kaibel and Kukharenko.

Authors: Alexander E. Black, Raphael Steiner

We prove that computing a shortest monotone path to the optimum of a linear program over a simple polytope is NP-hard, thus resolving a 2022 open question of De Loera, Kafer, and Sanità. As a consequence, finding a shortest sequence of pivots to an optimal basis with the simplex method is NP-hard. In fact, we show this is NP-hard already for fractional knapsack polytopes. By applying an additional polyhedral construction, we show that computing the diameter of a simple polytope is NP-hard, resolving a 2003 open problem by Kaibel and Pfetsch. Finally, on the positive side we show that every polytope has a small, simple extended formulation for which a linear length path may be found between any pair of vertices in polynomial time building upon a result of Kaibel and Kukharenko.

Friday, March 06 2026, 01:00

Generalized matching decoders for 2D topological translationally-invariant codes

Authors: Shi Jie Samuel Tan, Ian Gill, Eric Huang, Pengyu Liu, Chen Zhao, Hossein Dehghani, Aleksander Kubica, Hengyun Zhou, Arpit Dua

Two-dimensional topological translationally-invariant (TTI) quantum codes, such as the toric code (TC) and bivariate bicycle (BB) codes, are promising candidates for fault-tolerant quantum computation. For such codes to be practically relevant, their decoders must successfully correct the most likely errors while remaining computationally efficient. For the TC, graph-matching decoders satisfy both requirements and, additionally, admit provable performance guarantees. Given the equivalence between TTI codes and (multiple copies of) the TC, one may then ask whether TTI codes also admit analogous graph-matching decoders. In this work, we develop a graph-matching approach to decoding general TTI codes. Intuitively, our approach coarse-grains the TTI code to obtain an effective description of the syndrome in terms of TC excitations, which can then be removed using graph-matching techniques. We prove that our decoders correct errors of weight up to a constant fraction of the code distance and achieve non-zero code-capacity thresholds. We further numerically study a variant optimized for practically relevant BB codes and observe performance comparable to that of the belief propagation with ordered statistics decoder. Our results indicate that graph-matching decoders are a viable approach to decoding BB codes and other TTI codes.

Authors: Shi Jie Samuel Tan, Ian Gill, Eric Huang, Pengyu Liu, Chen Zhao, Hossein Dehghani, Aleksander Kubica, Hengyun Zhou, Arpit Dua

Two-dimensional topological translationally-invariant (TTI) quantum codes, such as the toric code (TC) and bivariate bicycle (BB) codes, are promising candidates for fault-tolerant quantum computation. For such codes to be practically relevant, their decoders must successfully correct the most likely errors while remaining computationally efficient. For the TC, graph-matching decoders satisfy both requirements and, additionally, admit provable performance guarantees. Given the equivalence between TTI codes and (multiple copies of) the TC, one may then ask whether TTI codes also admit analogous graph-matching decoders. In this work, we develop a graph-matching approach to decoding general TTI codes. Intuitively, our approach coarse-grains the TTI code to obtain an effective description of the syndrome in terms of TC excitations, which can then be removed using graph-matching techniques. We prove that our decoders correct errors of weight up to a constant fraction of the code distance and achieve non-zero code-capacity thresholds. We further numerically study a variant optimized for practically relevant BB codes and observe performance comparable to that of the belief propagation with ordered statistics decoder. Our results indicate that graph-matching decoders are a viable approach to decoding BB codes and other TTI codes.

Friday, March 06 2026, 01:00

Optimal Prediction-Augmented Algorithms for Testing Independence of Distributions

Authors: Maryam Aliakbarpour, Alireza Azizi, Ria Stevens

Independence testing is a fundamental problem in statistical inference: given samples from a joint distribution $p$ over multiple random variables, the goal is to determine whether $p$ is a product distribution or is $ε$-far from all product distributions in total variation distance. In the non-parametric finite-sample regime, this task is notoriously expensive, as the minimax sample complexity scales polynomially with the support size. In this work, we move beyond these worst-case limitations by leveraging the framework of \textit{augmented distribution testing}. We design independence testers that incorporate auxiliary, but potentially untrustworthy, predictive information. Our framework ensures that the tester remains robust, maintaining worst-case validity regardless of the prediction's quality, while significantly improving sample efficiency when the prediction is accurate. Our main contributions include: (i) a bivariate independence tester for discrete distributions that adaptively reduces sample complexity based on the prediction error; (ii) a generalization to the high-dimensional multivariate setting for testing the independence of $d$ random variables; and (iii) matching minimax lower bounds demonstrating that our testers achieve optimal sample complexity.

Authors: Maryam Aliakbarpour, Alireza Azizi, Ria Stevens

Independence testing is a fundamental problem in statistical inference: given samples from a joint distribution $p$ over multiple random variables, the goal is to determine whether $p$ is a product distribution or is $ε$-far from all product distributions in total variation distance. In the non-parametric finite-sample regime, this task is notoriously expensive, as the minimax sample complexity scales polynomially with the support size. In this work, we move beyond these worst-case limitations by leveraging the framework of \textit{augmented distribution testing}. We design independence testers that incorporate auxiliary, but potentially untrustworthy, predictive information. Our framework ensures that the tester remains robust, maintaining worst-case validity regardless of the prediction's quality, while significantly improving sample efficiency when the prediction is accurate. Our main contributions include: (i) a bivariate independence tester for discrete distributions that adaptively reduces sample complexity based on the prediction error; (ii) a generalization to the high-dimensional multivariate setting for testing the independence of $d$ random variables; and (iii) matching minimax lower bounds demonstrating that our testers achieve optimal sample complexity.

Friday, March 06 2026, 01:00

Moar Updatez

from Scott Aaronson

To start on a somber note: those of us at UT Austin are in mourning this week for Savitha Shan, an undergrad double major here in economics and information systems, who was murdered over the weekend by an Islamist terrorist who started randomly shooting people on Sixth Street, apparently angry about the war in Iran. […]

To start on a somber note: those of us at UT Austin are in mourning this week for Savitha Shan, an undergrad double major here in economics and information systems, who was murdered over the weekend by an Islamist terrorist who started randomly shooting people on Sixth Street, apparently angry about the war in Iran. Two other innocents were also killed.

As it happens, these murders happened just a few hours after the end of my daughter’s bat mitzvah, and in walking distance from the venue. The bat mitzvah itself was an incredibly joyful and successful event that consumed most of my time lately, and which I might or might not say more about—the nastier the online trolls get, the more I need to think about my family’s privacy.

Of all the many quantum computing podcasts/interviews I’ve done recently, I’m probably happiest with this one, with Yuval Boger of QuEra. It covers all the main points about where the hardware currently is, the threat to public-key cryptography, my decades-long battle against quantum applications hype, etc. etc., and there’s even an AI-created transcript that eliminates my verbal infelicities!

A month ago, I blogged about “The Time I Didn’t Meet Jeffrey Epstein” (basically, because my mom warned me not to). Now the story has been written up in Science magazine, under the clickbaity headline “Meet Three Scientists Who Said No to Epstein.” (Besides yours truly, the other two scientists are friend-of-the-blog Sean Carroll, whose not-meeting-Epstein story I’d already heard directly from him, and David Agus, whose story I hadn’t heard.)

To be clear: as I explained in my post, I never actually said “no” to Epstein. Instead, based on my mom’s advice, I simply failed to follow up with his emissary, to the point where no meeting ever happened.

Anyway, ever since Science ran this story and it started making the rounds on social media, my mom has been getting congratulatory messages from friends of hers who saw it!

I’ve been a huge fan of the philosopher-novelist Rebecca Newberger Goldstein ever since I read her celebrated debut work, The Mind-Body Problem, back in 2005. Getting to know Rebecca and her husband, Steven Pinker, was a highlight of my last years at MIT. So I’m thrilled that Rebecca will be visiting UT Austin next week to give a talk on Spinoza, related to her latest book The Mattering Instinct (which I’m reading right now), and hosted by me and my colleague Galen Strawson in UT’s philosophy department. More info is in the poster below. If you’re in Austin, I hope to see you there!

The 88-year-old Donald Knuth has published a 5-page document about how Claude was able to solve a tricky graph theory problem that arose while he was working on the latest volume of The Art of Computer Programming—a series that Knuth is still writing after half a century. As you’d expect from Knuth, the document is almost entirely about the graph theory problem itself and Claude’s solution to it, eschewing broader questions about the nature of machine intelligence and how LLMs are changing life on Earth. To anyone who’s been following AI-for-math lately, the fact that Claude now can help with this sort of problem won’t come as a great shock. The virality is presumably because Knuth is such a legend that to watch him interact productively with an LLM is sort of like watching Leibniz, Babbage, or Turing do the same.

John Baez is a brilliant mathematical physicist and writer, who was blogging about science before the concept of “blogging” even existed, and from whom I’ve learned an enormous amount. But regarding John’s quest for the past 15 years — namely, to use category theory to help solve the climate crisis (!) — I always felt like the Cookie Monster would, with equal intellectual justification, say that the key to arresting climate change was for him to eat more Oreos. Then I read this Quanta article on the details of Baez’s project, and … uh … I confess it failed to change my view. Maybe someday I’ll understand why it’s better to say using category theory what I would’ve said in a 100x simpler way without category theory, but I fear that day is not today.

By Scott

Thursday, March 05 2026, 23:36

Learning From the Mess

from Ben Recht

What the vitamin story tells us about reproducibility, discovery, and human nature.

This is Part 6 (of 7!) of a blogged essay “Steampunk Data Science.” A table of contents is here.

Having followed the tumultuous thirty-year journey from Eijkman’s chickens to Davis’ rats, let’s return to where we started: the question of reproducible, rigorous research. If there was an era of gold standard reproducible research, the early 20th century wasn’t it. I described multiple examples of important work that not only weren’t reproducible but were flat-out wrong.

McCollum’s first paper on nutrition couldn’t have been more wrong. Led astray by the work of Pavlov, McCollum was convinced that “the psychic influence of palatability is one of the most important factors in nutrition.” McCollum considered the possibility of vitamins, which he described as “certain organic complexes in the food given, which the body was not able to supply through its synthetic power from the materials at hand,” to be completely ruled out by his experiments. He would completely change his mind in the course of only a couple of years.

Was this paper published by McCollum bad for the scientific discovery of vitamins? The reality is the opposite. The fact that McCollum was dead wrong inspired further investigations, and the breakthroughs occurred in figuring out why he was wrong. Mendel’s team at Yale was inspired by McCollum’s synthetic diets and intrigued by his findings on palatability. In their replication attempts, they not only disproved McCollum’s hypothesis but also strengthened the case for the existence of essential amino acids. This work by Mendel’s team subsequently inspired McCollum and Davis’ investigations into the extracts of milk and egg yolks, resulting in their discovery of Vitamin A.

At the opposite end of the spectrum was German physician Wilhelm Stepp, who had conducted experiments removing the ether-soluble contents of bread and feeding them to mice. He claimed that after removing the ether-soluble contents, the mice quickly perished. When the ether-soluble materials were added as a supplement, the mice thrived. This sounds a lot like McCollum and Davis’ experimental setup, but Stepp’s results were deemed “far from conclusive” by Mendel and Osborne. His data was fishy. George Wolf and Kenneth Carpenter reanalyzed Stepp’s experiments from our contemporary understanding and found Stepp’s mice died far too quickly for the cause to be Vitamin A deficiency. What exactly Stepp had done remained unclear, and his work was not reproducible. But he had the right answer! He was clearly on the right track to finding Vitamin A.

We can and do learn from a lack of reproduction. Failure to reproduce tells us something about why our earlier assumptions were wrong, and digging into reproduction failures leads us to new discoveries. Nothing in the evidence points to malicious fraud or scientific misbehavior by those involved in the search for vitamins. It’s not clear how many of these errors would have been corrected by better statistical or scientific methodology. We should not expect science to be perfect and should be open to learning from mess.

And what about rigorous tools and research practices? Might these have accelerated our understanding of nutrition? Here, the evidence again points to no. The discovery of vitamins required a remarkably diverse set of investigative tools. As is always the case, well-controlled experiments designed to deliberately refute hypotheses were only one of many methods used to generate evidence. Natural experiments, such as Eijkman’s work with chickens and Vorderman’s prison observations, provided the initial clues that brown rice contained essential vitamins. The case studies initiated by Mendel, Osborne, and Ferry were experiments on single animals. They applied varied interventions over the course of the rat’s life, probing varied inputs into its diet, scouring for clues as they compared to a baseline. The individual case series of McCollum and Davis provided the definitive evidence that a simple organic compound could start and stop growth. Each of these methods provided a piece of the puzzle, but the researchers were learning how to do nutrition research as they went.

And though it was clear to Christiaan Eijkman that white and brown rice were different from each other, it took thirty years for that difference to be given a name. Sure, we can point back to single experiments that are as clear as day in hindsight, but the vitamins weren’t “discovered” until they were named. It took Funk’s bold survey article to name the problem (deficiency diseases) and the cure (vitamines). Only after Funk did everyone converge on the answer. The clean articulation of the problem and solution, of the cause and the effect, marked the actual discovery.

Perhaps the only pattern I can extract from the scientific processes here is that everyone involved was driven by a definitive purpose. The discovery of vitamins arose out of a deliberate, interventionist mindset. The researchers in Wisconsin wanted to identify the best diet for raising cattle. The researchers in the Dutch colonies sought a cure for beriberi. Nutrition research wasn’t aimed at breaking down the world for understanding, but rather at identifying interventions. They were trying to figure out cause and effect so that they could do something. The entire purpose was intervening, whether to save farmers money or cure terrible diseases. In finding what worked for their problems, they also discovered new chemistry and biology.

Would vitamins have been discovered sooner if the nutrition scientists had a more rigorous set of scientific tools? Could we imagine a counterfactual acceleration had they had access to computers loaded with spreadsheets and statistical software? We could also ask this question differently without assuming the present was wiser than the past. Was this discovery made possible by a rigorous practice that we can learn from?

The vitamin saga suggests the answer to all of these questions is probably no! If anything, the confines of scientific rigor of the day, like Koch’s rigid postulates for determining disease etiology, would have left us stuck with germ theory. I worry that contemporary quests for standardization and formalization of research practice lose sight of the value of creative experimentation and investigation. We can’t let reproducibility checklists stifle creative exploration.

What I also love about this story is how there’s no single hero. I understand the motivational power of the simple great-man science stories, like John Snow and his Broad Street Pump, or Alexander Fleming and his Petri dishes. But historians of science have been scolding us for decades that most of these scientific beatifications are far oversimplified. The muddled mess of vitamin discovery is more the rule than the exception. Though there were multiple Nobel Prizes, it’s really hard to extract a single hero.

On the other hand, it’s easy to find lots of petty fights. Babcock chided Atwater about his protein theories. McCollum was humiliated by Mendel’s work, which proved his palatability hypothesis erroneous. In his autobiography, he admits embarrassment and revenge were among his motivations for studying milk extracts. Harry Steenbock felt like he should have been on McCollum and Davis’ Vitamin A paper and held a grudge for years. He even wrote a letter to Science magazine in 1918, accusing McCollum of academic misconduct when he moved his lab from Wisconsin to Johns Hopkins.

The process of searching for vitamins was a mess. But we learned from the mess. And when we did, we found undeniable effects that completely transformed our understanding of food and our ability to treat disease.

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By Ben Recht

Thursday, March 05 2026, 14:59

Closed-form dynamics beyond quadratics

from Francis Bach

Quadratic functions are the workhorse of the analysis of iterative algorithms such as gradient-based optimization. They lead, in discrete and continuous time, to closed-form dynamics that treat all eigensubspaces of the Hessian matrix independently. This leads to simple math for understanding convergence behaviors (maximal step-size, condition number, acceleration, scaling laws for gradient descent or its...

Quadratic functions are the workhorse of the analysis of iterative algorithms such as gradient-based optimization. They lead, in discrete and continuous time, to closed-form dynamics that treat all eigensubspaces of the Hessian matrix independently. This leads to simple math for understanding convergence behaviors (maximal step-size, condition number, acceleration, scaling laws for gradient descent or its stochastic version, etc.).

An important success of the optimization field is to have shown that the same behaviors hold for convex functions, where the analysis now relies on Lyapunov functions rather than closed-form computations (see, e.g., this post on automated proofs), with some extensions to non-convex functions, but only regarding convergence to stationary points.

Going (globally) non-convex is of major interest in different fields, including machine learning for neural networks or matrix factorizations. In this post, I try to answer the following question: What are dynamics that lead to closed form or enough of it to get relevant insights?

Over the years, several have emerged, allowing us to give some nice and explicit intuitive results on the global behavior of gradient descent in certain non-convex cases. This blog post is about them. Note that this complements the analysis of diagonal networks from [1, 2] that we described in an earlier post.

We focus on linear neural networks, with a prediction function $x \mapsto A_2^\top A_1^\top x$, where $x \in \mathbb{R}^d$ is the input, $A_1 \in \mathbb{R}^{d \times m}$ is the matrix of input weights, and $A_2 \in \mathbb{R}^{m \times k}$ is the matrix of output weights, with an overall weight matrix $\Theta = A_1 A_2 \in \mathbb{R}^{d \times k}$. This is a linear model corresponding to multi-task / multi-category classification / multi-label supervised problems, or an auto-encoder for unsupervised learning. Clearly, using the parameterization $\Theta = A_1 A_2$ is not the most efficient for optimization (as we could simply use convex optimization directly on $\Theta$), but we use it for understanding non-convex dynamics.

Given data matrices $Y \in \mathbb{R}^{n \times k}$ and $X \in \mathbb{R}^{n \times d}$, the empirical risk is $$ L(A_1,A_2) = \frac{1}{2n} \big\| Y – X A_1 A_2 \big\|_{\rm F}^2,$$ where $\| M \|_{\rm F} = \sqrt{ {\rm tr} (M^\top M)}$ is the Frobenius norm of $M$.

The gradient flow dynamics are then $$ \left\{ \begin{array}{lcrcr} \dot{A}_1 & = & – \nabla_{A_1} L(A_1,A_2) & = & \frac{1}{n} X^\top ( Y – X A_1 A_2) A_2^\top \\ \dot{A}_2 & = &- \nabla_{A_2} L(A_1,A_2) & = & \frac{1}{n} A_1^\top X^\top ( Y – X A_1 A_2). \\ \end{array} \right.$$

We denote by $B_1 \in \mathbb{R}^{d \times m}, B_2 \in \mathbb{R}^{m \times k}$ the initialization of the dynamics. As first outlined by [3] and used in most subsequence analyses (e.g., [4, 6, 7]), there is an invariant of the dynamics, as $$\frac{d}{dt} ( A_1^\top A_1 ) = 2 {\rm Sym} \big( A_1^\top \frac{1}{n} X^\top ( Y – X A_1 A_2) A_2^\top \big) = \frac{d}{dt} ( A_2 A_2^\top ), $$ where ${\rm Sym}(M) = \frac{1}{2} ( M + M^\top)$ is the symmetrization of the square matrix $M$. This implies that $A_1^\top A_1 – A_2 A_2^\top \in \mathbb{R}^{m \times m}$ is constant along the dynamics. This will allow considerable simplifications (the presence of such invariants is not limited to linear networks, see [16] for a nice detailed account on these conservation laws).

There are several lines of work to go further. I will use a non-chronological presentation and start with the simplest case where singular vectors are aligned, before moving to the real magic first detailed by Kenji Fukumizu in [3].

Aligned initialization and commuting moments

The first set of assumptions that lead to a closed form is, from [4] with $X^\top X $ proportional to identity, and [5] for this present version:

Commuting moments: $X^\top X$ and $X^\top YY^\top X$ commute, which is equivalent to aligned singular value decompositions $C = \frac{1}{n} X^\top Y = U {\rm Diag}(c) V^\top$ and $\Sigma = \frac{1}{n} X^\top X = U {\rm Diag}(s) U^\top$ for matrices $U \in \mathbb{R}^{d \times r},V \in \mathbb{R}^{k \times r}$ with orthonormal columns (that is, $U^\top U = V^\top V = I$), and $c,s \in \mathbb{R}_+^r$ non-negative vectors of singular values (this is thus the “economy-size” version of the SVD where $U$ and $V$ have the same number of columns). We only need to take $r$ as big as $\max \{ {\rm rank}(C), {\rm rank}(\Sigma) \}$. This occurs, for example, when $X^\top X \propto I$ (whitened data), or for auto-encoders, where $Y = X$.
Aligned initialization: $B_1 = U {\rm Diag}(b_1) W^\top$ and $B_2 = W {\rm Diag}(b_2) V^\top$ are the singular value decompositions, with $W \in \mathbb{R}^{m \times r}$ with orthonormal columns (which implies that we need to assume $m \geqslant r$), with singular vectors of $B_1 B_2 = U {\rm Diag}(b_1 b_2) V^\top$ aligned with the one of $X^\top Y$.

Note that throughout the blog post, as done just above, multiplication and divisions of the (singular) vectors of the same size will be considered component-wise.

With these assumptions, throughout the dynamics, it turns out that we keep aligned singular vectors, and thus, if $a_1, a_2$ are the vectors of singular values of $A_1, A_2$, we get the coupled ODEs: $$ \left\{ \begin{array}{lcr} \dot{a}_1 & = & ( c \, – s a_1 a_2 ) a_2 \\ \dot{a}_2 & = & ( c \, – s a_1 a_2 ) a_1 . \\ \end{array} \right.$$ The invariant mentioned above leads to $$ a_1 a_1 – a_2 a_2 = {\rm cst}.$$ Overall we get the dynamics for $\theta = a_1 a_2$, $$ \dot{\theta}= ( c \, – s a_1 a_2 ) ( a_1 a_1 + a_2 a_2).$$

If $b_1 = b_2 = \alpha $ at initialization (for all singular values) with $\alpha$ a positive scalar, then this remains true throughout the dynamics, and we get $$ \dot{\theta} = 2 ( c \, – s \theta ) \theta, $$ with a closed form dynamics by integration $$\theta = \frac{c}{s} \Big( \frac{e^{2ct} {\alpha^2 }}{\frac{c}{s} – \alpha^2+e^{2ct} {\alpha^2}}\Big) = \frac{1}{ \frac{1}{\alpha^2} e^{-2ct} + \frac{s}{c} ( 1 – e^{-2ct} )}.$$

Insights. We see the sequential learning of each singular values when the initialization scale $\alpha$ tends to zero, as then we have $$ \theta \sim \frac{1}{ \frac{1}{\alpha^2} e^{-2ct} + \frac{s}{c}},$$ with a sharp jump from $0$ to $\frac{c}{s}$, around the time $\frac{1}{c} \log \frac{1}{\alpha}$.

To prove it, we rescale time as $t= u \log \frac{1}{\alpha}$ and we get $$\theta = \frac{1}{ \alpha^{2(cu-1)} + \frac{s}{c}},$$ which, with $u$ fixed, has its $i$-th component that converges to $0$ for $u < \frac{1}{c_i}$ and to $c_i / s_i$ for $u > \frac{1}{c_i}$.

Linear networks with aligned initialization. Plotting the singular values $\theta_t$ as a function of (rescaled) time $t$, for various initialization scales $\alpha$.

Extension to deeper models. Following [4], we can consider more layers and minimize $$ \frac{1}{2n} \| Y – X A_1 \cdots A_L\|_{\rm F}^2.$$ If at initialization, all singular vectors of all $A_i$’s align, then we get dynamics directly on the singular values, and starting from equal values, we get after a few lines $$\dot{\theta} = L (c-s\theta) \theta^{2 – 2/L},$$ which can also be integrated and analyzed. See [4] for details, and [18] for deep linear networks beyond aligned initialization.

Other dynamics. In this simple case, we can easily compare the dynamics of learning for three common algorithms, which all leads to dynamics on singular values $\theta$ in this aligned case:

Gradient descent on $(A_1,A_2)$: As seen above $\displaystyle \theta = \frac{1}{ \frac{1}{\alpha^2} e^{-2ct} + \frac{s}{c} ( 1 – e^{-2ct} )}$. The singular values $c$ of $\frac{1}{n} X^\top Y$ characterize the dynamics, with each singular value appearing one by one when $\alpha$ is small.
Gradient descent on $\Theta = A_1 A_2$ starting from zero (e.g., $\alpha=0$): $\theta = \frac{c}{s} ( 1 – e^{-st})$. The singular values $s$ of $\frac{1}{n} X^\top X$ characterize the dynamics.
Muon: this is the new cool algorithm (“stylé” my kids would say). It corresponds to orthogonalizing the matrix updates, and thus, to do sign descent with vanishing step-size on the singular values, that is, $\dot{a}_1 = \dot{a}_2 = 1$ until reaching the solution. This leads to $\theta = \min \{ t^2, c/s\}$, with a conditioning that does not depend on $s$ or $c$. No singular values is impacting the dynamics, hence the “automatic” reconditioning, which extends what can be seen for sign descent (see previous post). Note that if we implement Muon directly on $\Theta$, we would obtain instead $\theta = \min \{ t, c/s\}$.

Comparison of three dynamics. Top: singular values $\theta_t$, bottom: loss functions $R(\theta_t)$ as a function of time $t$.

Matrix Riccati equation

The second set of assumptions is:

White moment matrix: $\Sigma = \frac{1}{n} X^\top X = I$. Thus, the only data matrix left is $C = \frac{1}{n} X^\top Y$.
Balanced initialization: $B_1^\top B_1 = B_2 B_2^\top$, which implies that throughout the dynamics, we have $A_1^\top A_1 = A_2 A_2^\top$ (because of the invariant).

Note that there are no assumptions regarding the alignments of singular vectors at initialization. We also assume that $m \leqslant r = {\rm rank}(C) \leqslant \min\{d,k\}$. See [17] for closed-form expressions with larger width $m$.

Then something magical happens, first outlined by Kenji Fukumizu [3], and then further used in several works (e.g., [7, 17, 18]). Defining $R = { A_1 \choose A_2^\top} \in \mathbb{R}^{(d+k) \times m}$, we have $$R^\top R = A_1^\top A_1 + A_2 A_2^\top = 2A_1^\top A_1 = 2 A_2 A_2^\top,$$ which leads to the rewriting of the dynamics as: $$\dot{R} = \Delta R \, – \frac{1}{2} RR^\top R \mbox{ with } \Delta = \left( \begin{array}{cc} 0 & \!\frac{1}{n}X^\top Y \!\\ \! \frac{1}{n} Y^\top X \! & 0 \end{array} \right)= \left( \begin{array}{cc} 0 & \! C \!\\ \! C^\top \! & 0 \end{array} \right),$$ initialized with $R_0 = { B_1 \choose B_2^\top} \in \mathbb{R}^{(d+k) \times m}$.

This is now a matrix Riccati equation [8, 9], with a closed form and nice links with several branches of mathematics, such as control (linear-quadratic regulator), probabilistic modelling (Kalman filtering), and machine learning (Oja flow for principal component analysis [10]). In this present post, we will only scratch the surface of this fascinating topic, but a future post will most likely do it justice.

Denoting $P = RR^\top$, we get $$\dot{P} = \Delta P + P \Delta\, – P^2,$$ and we can then write $$P = NM^{-1}$$ with $M$ initialized at $I$ and $N$ initialized at $R_0 R_0^\top = { B_1 \choose B_2^\top}{ B_1 \choose B_2^\top}^\top$, and the linear dynamics $$\frac{d}{dt} { M \choose N} = \left( \begin{array}{cc} \! – \Delta \! & \! I \! \\ \! 0 \! & \! \Delta \! \end{array} \right){ M \choose N}.$$ The magical proof (see [10]) is really simple: $$\dot{P} = \dot{N} M^{-1} – N M^{-1} \dot{M} M^{-1} = \Delta N M^{-1} – N M^{-1} ( -\Delta M + N) M^{-1} = \Delta P + P \Delta\, – P^2.$$ This dynamics can be rewritten as $$ \left\{ \begin{array}{rcl} \frac{d}{dt} N & = & \Delta N \\ \frac{d}{dt} ( N\, – 2 \Delta M) & = & – \Delta ( N \, – 2 \Delta M), \end{array} \right.$$ and thus leads to the closed form $$ P = e^{\Delta t} R_0 R_0^\top \Big( e^{-\Delta t} + \frac{e^{\Delta t} – e^{-\Delta t}}{2\Delta } R_0 R_0^\top \Big)^{-1} = e^{\Delta t} R_0 \Big( I + R_0^\top \frac{e^{2\Delta t}-I}{2\Delta } R_0 \Big)^{-1} R_0^\top e^{\Delta t}.$$

We can now analyze this closed-form expression precisely with the following eigenvalue decomposition of $\Delta$ $$\Delta = \frac{1}{2} { U \choose V} {\rm Diag}(c) { U \choose V}^\top +\frac{1}{2} { U \choose -V} {\rm Diag}(-c) { U \choose -V}^\top,$$ classically obtained for the Jordan-Wielandt matrix $\Delta$ associated with $C$ (see an earlier post) with singular value decomposition $C = U {\rm Diag}(c) V^\top$.

Recovering aligned initialization. We start with aligned initialization (as before, and with the same notations), that is, $b_1= b_2 =a$. By taking $B_1 = U {\rm Diag}(a) W^\top$ and $B_2 = W {\rm Diag}(a) V^\top$, we get $R_0 = { U \choose V} {\rm Diag}(a) W^\top$, and for any function $f: \mathbb{R} \to \mathbb{R}$, we have $f(\Delta) R_0 = { U \choose V} {\rm Diag}(a f(c)) W^\top$, where $c$ is the vector of singular values of $C =\frac{1}{n} X^\top Y$, leading to $$P = { U \choose V} {\rm Diag} \Big( \frac{a^2 e^{2 c t}}{ 1 + a^2 \frac{e^{2c t}-1}{c}} \Big){ U \choose V}^\top,$$ which leads to $$ A_1 A_2 = U {\rm Diag} \Big( \frac{a^2 e^{2 c t}}{ 1 + a^2 \frac{e^{2c t}-1}{c}} \Big) V^\top,$$ which is exactly the same as the “aligned” result (OUF!). Note that the aligned initialization only requires that $C$ and $\Sigma$ commute, which is weaker than the assumption $\Sigma =I$ that is made here (but we can go much further below).

Beyond aligned initialization. When $R_0$ is initialized randomly (and thus with full rank on all subspaces) with balanced initialization and norm proportional to $\alpha^2$, then, with $t = u \log \frac{1}{\alpha}$, we also can prove sequential learning of all singular subspaces. More precisely, if $c_1 > \cdots > c_r$, then, when $\alpha$ tends to zero (see proof below the reference section):

If $u<\frac{1}{c_1}$, $P \sim 0$. This is the initial phase with no apparent movements, but an alignment of singular vectors, nicely cast as silent alignment by [7].
When $u \in ( \frac{1}{c_i}, \frac{1}{c_{i+1}})$ for $i \in \{1,\dots,m-1\}$, we get $P \sim C_i$, the optimal rank $i$ approximation of $C$.
When $u > \frac{1}{c_m}$, $P \sim C_m$, which is the global minimizer of the cost function.

Note that when $m = r$, we get $C_m = C$. Overall, this is exactly sequential learning, with both the singular values and the singular vectors learned from scratch. In the plot below, we see how singular vectors align early in the dynamics when $\alpha$ is small, while singular values are learned step-by-step.

Dynamics of linear network learning as a function of rescaled time: components of $\Theta$ (left, one curve per component) with their limit as crosses, singular values of $\Theta$ (middle), absolute projections of singular vectors of $\Theta$ onto the ones of $C$ (right). $\alpha$ is going from $10^{-1}$ to $10^{-9}$.

Conclusion

Overall, we obtain a precise behavior for data with an identity covariance matrix, showing that features (singular vector directions) are learned early on, while their weights (singular values) are learned sequentially. This was done using a balanced initialization (see [11] for an extension beyond balanced initialization and large layer width).

However, this study only applies to linear neural networks (without any non-linear activation function). Extensions to the simplest architectures remain an active area of research (see, e.g., [12] and references therein), with in particular similar early alignment behaviors [13, 14]. In addition, matrix product parameterizations also arise in attention architectures through the product of the key and query matrices. As a result, sequential learning phenomena can also be observed in this setting; see [15] for an analysis of sequential learning in linear attention.

Acknowledgements. I would like to thank Raphaël Berthier, Pierre Marion, Loucas Pillaud-Vivien, and Aditya Varre for proofreading this blog post and making good, clarifying suggestions.

References

[1] Blake Woodworth, Suriya Gunasekar, Jason D. Lee, Edward Moroshko, Pedro Savarese, Itay Golan, Daniel Soudry, Nathan Srebro. Kernel and rich regimes in overparametrized models. Conference on Learning Theory, 2020.
[2] Scott Pesme, Loucas Pillaud-Vivien, and Nicolas Flammarion. Implicit bias of SGD for diagonal linear networks: a provable benefit of stochasticity. Advances in Neural Information Processing Systems, 2021.
[3] Kenji Fukumizu. Effect of batch learning in multilayer neural networks. International Conference on Neural Information Processing, 1998.
[4] Andrew M. Saxe, James L. McClelland, Surya Ganguli. Exact solutions to the nonlinear dynamics of learning in deep linear neural networks. International Conference on Learning Representations, 2014.
[5] Gauthier Gidel, Francis Bach, and Simon Lacoste-Julien. Implicit Regularization of Discrete Gradient Dynamics in Linear Neural Networks. Advances in Neural Information Processing Systems, 2019.
[6] Simon S. Du, Wei Hu, and Jason D. Lee. Algorithmic regularization in learning deep homogeneous models: Layers are automatically balanced. Advances in Neural Information Processing Systems, 2018.
[7] Alexander Atanasov, Blake Bordelon, and Cengiz Pehlevan. Neural Networks as Kernel Learners: The Silent Alignment Effect. International Conference on Learning Representations, 2022.
[8] Vladimír Kučera. A review of the matrix Riccati equation. Kybernetika, 9.1:42-61, 1973.
[9] Richard S. Bucy. Global theory of the Riccati equation. Journal of Computer and System Sciences, 1.4:349-361, 1967.
[10] Wei-Yong Yan, Uwe Helmke, and John B. Moore. Global analysis of Oja’s flow for neural networks. IEEE Transactions on Neural Networks, 5.5:674-683, 1994.
[11] Aditya Vardhan Varre, Maria-Luiza Vladarean, Loucas Pillaud-Vivien, Nicolas Flammarion. On the spectral bias of two-layer linear networks. Advances in Neural Information Processing Systems, 2023.
[12] Alberto Bietti, Joan Bruna, and Loucas Pillaud-Vivien. On learning Gaussian multi-index models with gradient flow. Technical report arXiv:2310.19793, 2023.
[13] Hartmut Maennel, Olivier Bousquet, and Sylvain Gelly. Gradient descent quantizes ReLU network features. Technical report arXiv:1803.08367, 2018.
[14] Etienne Boursier and Nicolas Flammarion. Early alignment in two-layer networks training is a two-edged sword. Journal of Machine Learning Research 26:1-75, 2025.
[15] Yedi Zhang, Aaditya K. Singh, Peter E. Latham, Andrew Saxe. Training Dynamics of In-Context Learning in Linear Attention. International Conference on Machine Learning, 2025.
[16] Sibylle Marcotte, Rémi Gribonval, and Gabriel Peyré. Abide by the law and follow the flow: Conservation laws for gradient flows. Advances in Neural Information Processing Systems, 2023.
[17] Lukas Braun, Clémentine C. J. Dominé, James E. Fitzgerald, Andrew M. Saxe. Exact learning dynamics of deep linear networks with prior knowledge. Advances in Neural Information Processing Systems, 2022.
[18] Sanjeev Arora, Nadav Cohen, Wei Hu, Yuping Luo. Implicit regularization in deep matrix factorization. Advances in Neural Information Processing Systems, 2019.

Proofs

We can rewrite the dynamics as (note that $\Delta$ is not positive semidefinite) $$ P = \Big( \frac{ 2 \Delta}{1-e^{-2\Delta t}}\Big)^{1/2} H ( H + I)^{-1} \Big( \frac{ 2 \Delta}{1-e^{-2\Delta t}}\Big)^{1/2} ,$$ with $$H = \Big( \frac{e^{2\Delta t}-I}{2\Delta } \Big)^{1/2} R_0 R_0^\top \Big( \frac{e^{2\Delta t}-I}{2\Delta } \Big)^{1/2}.$$ We note that the eigenvalues of $\Delta$ are singular values of $C$ as well as their opposite, together with zeros.

The term $\big( \frac{ 2 \Delta}{1-e^{-2\Delta t}}\big)^{1/2}$ is a spectral function of $\Delta$ which will set to zero all negative eigenvalues and set to $( 2 c)^{1/2}$ all positive ones $c$. We can therefore only consider the positive ones, and consider these terms as identity. Zeros eigenvalues of $\Delta$ also lead to decay, this time in $1/t$, and can be discarded as well in the asymptotic analysis.

The term $\big( \frac{e^{2\Delta t}-I}{2\Delta } \big)^{1/2}$, with strictly positive eigenvalues, is equivalent to $e^{\Delta t} ( 2 \Delta)^{-1/2}$, and we are faced with studying the dynamics of $H(I+H)^{-1}$ for $H = e^{\Delta t} \alpha^2 M e^{\Delta t}$ for $M = \Delta^{-1} R_0 R_0^\top \Delta^{-1}$ a rank-$m$ $r \times r$ matrix, when $\alpha$ tends to zero. We rewrite $t = u \log \frac{1}{\alpha}$, and we then have, once in the basis of singular vectors $$H = {\rm Diag}(\alpha^{1-cu}) M {\rm Diag}(\alpha^{1-cu}),$$ with $N \in \mathbb{R}^{r\times r}$ a rank-$m$ matrix. We assume $c_1 > \cdots > c_r$ for simplicity and consider three cases.

Case 1. If $1- c_i u > 0$ for all $i$, that is, $u < 1/c_1$, then the matrix ${\rm Diag}(\alpha^{1-cu}$ goes to zero, and thus $P$ goes to zero.

Case 2. For $j \in \{1,\dots,m\}$, and $u \in [\frac{1}{c_j}, \frac{1}{c_{j+1}}]$, then we have $$H = \left( \begin{array}{cc} D_\infty A D_\infty & D_\infty B D_0 \\ D_0 B^\top D_\infty & D_0 C D_0 \end{array} \right),$$ for a diagonal matrix $D_\infty$ (of size $j$) that goes to infinity and a diagonal matrix $D_0$ goes to zero. Using $H (H+I)^{-1} = I – (H+I)^{-1}$ and using Schur complements, we have $$ (H+I)^{-1} = \left( \begin{array}{cc} \bar{A} & \bar{B} \\ \bar{B}^\top & \bar{C} \end{array} \right),$$ with $$\bar{A}^{-1} = I + D_\infty A D_\infty – D_\infty B D_0 ( D_0 C D_0 +I )^{-1}D_0 B^\top D_\infty \sim I + D_\infty A D_\infty,$$ so that $\bar{A}$ tends to zero (since $A$ is invertible). We also have $$\bar{C}^{-1} = I + D_0 C D_0 – D_0 B^\top D_\infty ( D_\infty C D_\infty +I )^{-1}D_\infty B D_\infty \sim I,$$ with a similar limit for the off-diagonal block. Therefore $(H+I)^{-1}$ tends to $\left( \begin{array}{cc} 0 & 0 \\ 0 &I \end{array} \right)$, which leads to the desired result.

Case 3. For $u > 1/c_m$, using the same formula for $(H+I)^{-1}$, with now $D_0$ not tending to zero, we can use the fact that $C = B^\top A^{-1} B$ to obtain the desired limit.

By Francis Bach

Thursday, March 05 2026, 06:49

Strong Chain Quality

from Decentralized Thoughts

Chain Quality (CQ) is a core blockchain property. Roughly speaking, it says: Owning $3\%$ of the stake gives you control over $3\%$ of the blockspace over time. For Nakamoto style chains, this is called Ideal CQ (see here). Chain quality was sufficient for early generations of blockchains that had low throughput, but modern blockchains have much higher bandwidth and can commit many transactions within a single block. This motivates a...

By Ittai Abraham, Pranav Garimidi, Joachim Neu

Chain Quality (CQ) is a core blockchain property. Roughly speaking, it says: Owning $3\%$ of the stake gives you control over $3\%$ of the blockspace over time. For Nakamoto style chains, this is called Ideal CQ (see here). Chain quality was sufficient for early generations of blockchains that had low throughput, but modern blockchains have much higher bandwidth and can commit many transactions within a single block. This motivates a...

By Ittai Abraham, Pranav Garimidi, Joachim Neu

Thursday, March 05 2026, 05:00

Learning Read-Once Determinants and the Principal Minor Assignment Problem

Authors: Abhiram Aravind, Abhranil Chatterjee, Sumanta Ghosh, Rohit Gurjar, Roshan Raj, Chandan Saha

A symbolic determinant under rank-one restriction computes a polynomial of the form $\det(A_0+A_1y_1+\ldots+A_ny_n)$, where $A_0,A_1,\ldots,A_n$ are square matrices over a field $\mathbb{F}$ and $rank(A_i)=1$ for each $i\in[n]$. This class of polynomials has been studied extensively, since the work of Edmonds (1967), in the context of linear matroids, matching, matrix completion and polynomial identity testing. We study the following learning problem for this class: Given black-box access to an $n$-variate polynomial $f=\det(A_0+A_1y_1+ \ldots+A_ny_n)$, where $A_0,A_1,\ldots,A_n$ are unknown square matrices over $\mathbb{F}$ and rank$(A_i)=1$ for each $i\in[n]$, find a square matrix $B_0$ and rank-one square matrices $B_1,\ldots,B_n$ over $\mathbb{F}$ such that $f=\det(B_0+B_1y_1+\ldots+B_ny_n)$. In this work, we give a randomized poly(n) time algorithm to solve this problem. As the above-mentioned class is known to be equivalent to the class of read-once determinants (RODs), we will refer to the problem as learning RODs. The algorithm for learning RODs is obtained by connecting with a well-known open problem in linear algebra, namely the Principal Minor Assignment Problem (PMAP), which asks to find (if possible) a matrix having prescribed principal minors. PMAP has also been studied in machine learning to learn the kernel matrix of a determinantal point process. Here, we study a natural black-box version of PMAP: Given black-box access to an $n$-variate polynomial $f = \det(A + Y)$, where $A \in \mathbb{F}^{n \times n}$ is unknown and $Y = diag(y_1,\ldots,y_n)$, find a $B\in\mathbb{F}^{n\times n}$ such that $f=det(B+Y)$. We show that black-box PMAP can be solved in randomized poly(n) time, and further, it is randomized polynomial-time equivalent to learning RODs. We resolve black-box PMAP by investigating a property of dense matrices that we call the rank-one extension property.

Authors: Abhiram Aravind, Abhranil Chatterjee, Sumanta Ghosh, Rohit Gurjar, Roshan Raj, Chandan Saha

A symbolic determinant under rank-one restriction computes a polynomial of the form $\det(A_0+A_1y_1+\ldots+A_ny_n)$, where $A_0,A_1,\ldots,A_n$ are square matrices over a field $\mathbb{F}$ and $rank(A_i)=1$ for each $i\in[n]$. This class of polynomials has been studied extensively, since the work of Edmonds (1967), in the context of linear matroids, matching, matrix completion and polynomial identity testing. We study the following learning problem for this class: Given black-box access to an $n$-variate polynomial $f=\det(A_0+A_1y_1+ \ldots+A_ny_n)$, where $A_0,A_1,\ldots,A_n$ are unknown square matrices over $\mathbb{F}$ and rank$(A_i)=1$ for each $i\in[n]$, find a square matrix $B_0$ and rank-one square matrices $B_1,\ldots,B_n$ over $\mathbb{F}$ such that $f=\det(B_0+B_1y_1+\ldots+B_ny_n)$. In this work, we give a randomized poly(n) time algorithm to solve this problem. As the above-mentioned class is known to be equivalent to the class of read-once determinants (RODs), we will refer to the problem as learning RODs. The algorithm for learning RODs is obtained by connecting with a well-known open problem in linear algebra, namely the Principal Minor Assignment Problem (PMAP), which asks to find (if possible) a matrix having prescribed principal minors. PMAP has also been studied in machine learning to learn the kernel matrix of a determinantal point process. Here, we study a natural black-box version of PMAP: Given black-box access to an $n$-variate polynomial $f = \det(A + Y)$, where $A \in \mathbb{F}^{n \times n}$ is unknown and $Y = diag(y_1,\ldots,y_n)$, find a $B\in\mathbb{F}^{n\times n}$ such that $f=det(B+Y)$. We show that black-box PMAP can be solved in randomized poly(n) time, and further, it is randomized polynomial-time equivalent to learning RODs. We resolve black-box PMAP by investigating a property of dense matrices that we call the rank-one extension property.

Thursday, March 05 2026, 01:00

Truth Predicate of Inductive Definitions and Logical Complexity of Infinite-Descent Proofs

Authors: Sohei Ito, Makoto Tatsuta

Formal reasoning about inductively defined relations and structures is widely recognized not only for its mathematical interest but also for its importance in computer science, and has applications in verifying properties of programs and algorithms. Recently, several proof systems of inductively defined predicates based on sequent calculus including the cyclic proof system CLKID-omega and the infinite-descent proof system LKID-omega have attracted much attention. Although the relation among their provabilities has been clarified so far, the logical complexity of these systems has not been much studied. The infinite-descent proof system LKID-omega is an infinite proof system for inductive definitions and allows infinite paths in proof figures. It serves as a basis for the cyclic proof system. This paper shows that the logical complexity of the provability in LKID-omega is (Pi-1-1)-complete. To show this, first it is shown that the validity for inductive definitions in standard models is equivalent to the validity for inductive definitions in standard term models. Next, using this equivalence, this paper extends the truth predicate of omega-languages, as given in Girard's textbook, to inductive definitions by employing arithmetical coding of inductive definitions. This shows that the validity of inductive definitions in standard models is a (Pi-1-1) relation. Then, using the completeness of LKID-omega for standard models, it is shown that the logical complexity of the provability in LKID-omega is (Pi-1-1)-complete.

Authors: Sohei Ito, Makoto Tatsuta

Formal reasoning about inductively defined relations and structures is widely recognized not only for its mathematical interest but also for its importance in computer science, and has applications in verifying properties of programs and algorithms. Recently, several proof systems of inductively defined predicates based on sequent calculus including the cyclic proof system CLKID-omega and the infinite-descent proof system LKID-omega have attracted much attention. Although the relation among their provabilities has been clarified so far, the logical complexity of these systems has not been much studied. The infinite-descent proof system LKID-omega is an infinite proof system for inductive definitions and allows infinite paths in proof figures. It serves as a basis for the cyclic proof system. This paper shows that the logical complexity of the provability in LKID-omega is (Pi-1-1)-complete. To show this, first it is shown that the validity for inductive definitions in standard models is equivalent to the validity for inductive definitions in standard term models. Next, using this equivalence, this paper extends the truth predicate of omega-languages, as given in Girard's textbook, to inductive definitions by employing arithmetical coding of inductive definitions. This shows that the validity of inductive definitions in standard models is a (Pi-1-1) relation. Then, using the completeness of LKID-omega for standard models, it is shown that the logical complexity of the provability in LKID-omega is (Pi-1-1)-complete.

Thursday, March 05 2026, 01:00

Advances in List Decoding of Polynomial Codes

Authors: Mrinal Kumar, Noga Ron-Zewi

Error-correcting codes are a method for representing data, so that one can recover the original information even if some parts of it were corrupted. The basic idea, which dates back to the revolutionary work of Shannon and Hamming about a century ago, is to encode the data into a redundant form, so that the original information can be decoded from the redundant encoding even in the presence of some noise or corruption. One prominent family of error-correcting codes are Reed-Solomon Codes which encode the data using evaluations of low-degree polynomials. Nearly six decades after they were introduced, Reed-Solomon Codes, as well as some related families of polynomial-based codes, continue to be widely studied, both from a theoretical perspective and from the point of view of applications. Besides their obvious use in communication, error-correcting codes such as Reed-Solomon Codes are also useful for various applications in theoretical computer science. These applications often require the ability to cope with many errors, much more than what is possible information-theoretically. List-decodable codes are a special class of error-correcting codes that enable correction from more errors than is traditionally possible by allowing a small list of candidate decodings. These codes have turned out to be extremely useful in various applications across theoretical computer science and coding theory. In recent years, there have been significant advances in list decoding of Reed-Solomon Codes and related families of polynomial-based codes. This includes efficient list decoding of such codes up to the information-theoretic capacity, with optimal list-size, and using fast nearly-linear time, and even sublinear-time, algorithms. In this book, we survey these developments.

Authors: Mrinal Kumar, Noga Ron-Zewi

Error-correcting codes are a method for representing data, so that one can recover the original information even if some parts of it were corrupted. The basic idea, which dates back to the revolutionary work of Shannon and Hamming about a century ago, is to encode the data into a redundant form, so that the original information can be decoded from the redundant encoding even in the presence of some noise or corruption. One prominent family of error-correcting codes are Reed-Solomon Codes which encode the data using evaluations of low-degree polynomials. Nearly six decades after they were introduced, Reed-Solomon Codes, as well as some related families of polynomial-based codes, continue to be widely studied, both from a theoretical perspective and from the point of view of applications. Besides their obvious use in communication, error-correcting codes such as Reed-Solomon Codes are also useful for various applications in theoretical computer science. These applications often require the ability to cope with many errors, much more than what is possible information-theoretically. List-decodable codes are a special class of error-correcting codes that enable correction from more errors than is traditionally possible by allowing a small list of candidate decodings. These codes have turned out to be extremely useful in various applications across theoretical computer science and coding theory. In recent years, there have been significant advances in list decoding of Reed-Solomon Codes and related families of polynomial-based codes. This includes efficient list decoding of such codes up to the information-theoretic capacity, with optimal list-size, and using fast nearly-linear time, and even sublinear-time, algorithms. In this book, we survey these developments.

Thursday, March 05 2026, 01:00

When Relaxation Does Not Help: RLDCs with Small Soundness Yield LDCs

Authors: Kuan Cheng, Xin Li, Songtao Mao

Locally decodable codes (LDCs) are error correction codes that allow recovery of any single message symbol by probing only a small number of positions from the (possibly corrupted) codeword. Relaxed locally decodable codes (RLDCs) further allow the decoder to output a special failure symbol $\bot$ on a corrupted codeword. While known constructions of RLDCs achieve much better parameters than standard LDCs, it is intriguing to understand the relationship between LDCs and RLDCs. Separation results (i.e., the existence of $q$-query RLDCs that are not $q$-query LDCs) are known for $q=3$ (Gur, Minzer, Weissenberg, and Zheng, arXiv:2512.12960, 2025) and $q \geq 15$ (Grigorescu, Kumar, Manohar, and Mon, arXiv:2511.02633, 2025), while any $2$-query RLDC also gives a $2$-query LDC (Block, Blocki, Cheng, Grigorescu, Li, Zheng, and Zhu, CCC 2023). In this work, we generalize and strengthen the main result in Grigorescu, Kumar, Manohar, and Mon (arXiv:2511.02633, 2025), by removing the requirement of linear codes. Specifically, we show that any $q$-query RLDC with soundness error below some threshold $s(q)$ also yields a $q$-query LDC with comparable parameters. This holds even if the RLDC has imperfect completeness but with a non-adaptive decoder. Our results also extend to the setting of locally correctable codes (LCCs) and relaxed locally correctable codes (RLCCs). Using our results, we further derive improved lower bounds for arbitrary RLDCs and RLCCs, as well as probabilistically checkable proofs of proximity (PCPPs).

Authors: Kuan Cheng, Xin Li, Songtao Mao

Locally decodable codes (LDCs) are error correction codes that allow recovery of any single message symbol by probing only a small number of positions from the (possibly corrupted) codeword. Relaxed locally decodable codes (RLDCs) further allow the decoder to output a special failure symbol $\bot$ on a corrupted codeword. While known constructions of RLDCs achieve much better parameters than standard LDCs, it is intriguing to understand the relationship between LDCs and RLDCs. Separation results (i.e., the existence of $q$-query RLDCs that are not $q$-query LDCs) are known for $q=3$ (Gur, Minzer, Weissenberg, and Zheng, arXiv:2512.12960, 2025) and $q \geq 15$ (Grigorescu, Kumar, Manohar, and Mon, arXiv:2511.02633, 2025), while any $2$-query RLDC also gives a $2$-query LDC (Block, Blocki, Cheng, Grigorescu, Li, Zheng, and Zhu, CCC 2023). In this work, we generalize and strengthen the main result in Grigorescu, Kumar, Manohar, and Mon (arXiv:2511.02633, 2025), by removing the requirement of linear codes. Specifically, we show that any $q$-query RLDC with soundness error below some threshold $s(q)$ also yields a $q$-query LDC with comparable parameters. This holds even if the RLDC has imperfect completeness but with a non-adaptive decoder. Our results also extend to the setting of locally correctable codes (LCCs) and relaxed locally correctable codes (RLCCs). Using our results, we further derive improved lower bounds for arbitrary RLDCs and RLCCs, as well as probabilistically checkable proofs of proximity (PCPPs).

Thursday, March 05 2026, 01:00

Planar Graph Orientation Frameworks, Applied to KPlumber and Polyomino Tiling

Authors: MIT Hardness Group, Zachary Abel, Erik D. Demaine, Jenny Diomidova, Jeffery Li, Zixiang Zhou

Given a graph, when can we orient the edges to satisfy local constraints at the vertices, where each vertex specifies which local orientations of its incident edges are allowed? This family of graph orientation problems is a special kind of SAT problem, where each variable (edge orientation) appears in exactly two clauses (vertex constraints) -- once positively and once negatively. We analyze the complexity of many natural vertex types (patterns of allowed vertex neighborhoods), most notably all sets of symmetric vertex types which depend on only the number of incoming edges. In many scenarios, including Planar and Non-Planar Symmetric Graph Orientation with constants, we give a full dichotomy characterizing P vs. NP-complete problem classes. We apply our results to obtain new polynomial-time algorithms, resolving a 20-year-old open problem about KPlumber; to simplify existing NP-hardness proofs for tiling with trominoes; and to prove new NP-completeness results for tiling with tetrominoes.

Authors: MIT Hardness Group, Zachary Abel, Erik D. Demaine, Jenny Diomidova, Jeffery Li, Zixiang Zhou

Given a graph, when can we orient the edges to satisfy local constraints at the vertices, where each vertex specifies which local orientations of its incident edges are allowed? This family of graph orientation problems is a special kind of SAT problem, where each variable (edge orientation) appears in exactly two clauses (vertex constraints) -- once positively and once negatively. We analyze the complexity of many natural vertex types (patterns of allowed vertex neighborhoods), most notably all sets of symmetric vertex types which depend on only the number of incoming edges. In many scenarios, including Planar and Non-Planar Symmetric Graph Orientation with constants, we give a full dichotomy characterizing P vs. NP-complete problem classes. We apply our results to obtain new polynomial-time algorithms, resolving a 20-year-old open problem about KPlumber; to simplify existing NP-hardness proofs for tiling with trominoes; and to prove new NP-completeness results for tiling with tetrominoes.

Thursday, March 05 2026, 01:00

Ultrabubble enumeration via a lowest common ancestor approach

Authors: Athanasios E. Zisis, Pål Sætrom

Pangenomics uses graph-based models to represent and study the genetic variation between individuals of the same species or between different species. In such variation graphs, a path through the graph represents one individual genome. Subgraphs that encode locally distinct paths are therefore genomic regions with distinct genetic variation and detecting such subgraphs is integral for studying genetic variation. Biedged graphs is a type of variation graph that use two types of edges, black and grey, to represent genomic sequences and adjacencies between sequences, respectively. Ultrabubbles in biedged graphs are minimal subgraphs that represent a finite set of sequence variants that all start and end with two distinct sequences; that is, ultrabubbles are acyclic and all paths in an ultrabubble enter and exit through two distinct black edges. Ultrabubbles are therefore a special case of snarls, which are minimal subgraphs that are connected with two black edges to the rest of the graph. Here, we show that any bidirected graph can be transformed to a bipartite biedged graph in which lowest common ancestor queries can determine whether a snarl is an ultrabubble. This leads to an O(Kn) algorithm for finding all ultrabubbles in a set of K snarls, improving on the prior naive approach of O(K(n + m)) in a biedged graph with n nodes and m edges. Accordingly, our benchmark experiments on real and synthetic variation graphs show improved run times on graphs with few cycles and dead end paths, and dense graphs with many edges.

Authors: Athanasios E. Zisis, Pål Sætrom

Pangenomics uses graph-based models to represent and study the genetic variation between individuals of the same species or between different species. In such variation graphs, a path through the graph represents one individual genome. Subgraphs that encode locally distinct paths are therefore genomic regions with distinct genetic variation and detecting such subgraphs is integral for studying genetic variation. Biedged graphs is a type of variation graph that use two types of edges, black and grey, to represent genomic sequences and adjacencies between sequences, respectively. Ultrabubbles in biedged graphs are minimal subgraphs that represent a finite set of sequence variants that all start and end with two distinct sequences; that is, ultrabubbles are acyclic and all paths in an ultrabubble enter and exit through two distinct black edges. Ultrabubbles are therefore a special case of snarls, which are minimal subgraphs that are connected with two black edges to the rest of the graph. Here, we show that any bidirected graph can be transformed to a bipartite biedged graph in which lowest common ancestor queries can determine whether a snarl is an ultrabubble. This leads to an O(Kn) algorithm for finding all ultrabubbles in a set of K snarls, improving on the prior naive approach of O(K(n + m)) in a biedged graph with n nodes and m edges. Accordingly, our benchmark experiments on real and synthetic variation graphs show improved run times on graphs with few cycles and dead end paths, and dense graphs with many edges.

Thursday, March 05 2026, 01:00

Stringology-Based Motif Discovery from EEG Signals: an ADHD Case Study