Theory of Computing Report

Authors: Alonso Botero, Matthias Christandl, Thomas C. Fraser, Itai Leigh, Harold Nieuwboer

Upper and lower quantum functionals, introduced by Christandl, Vrana and Zuiddam (STOC 2018, J. Amer. Math. Soc. 2023), are families of monotone functions of tensors indexed by a weighting on the set of subsets of the tensor legs. Inspired by quantum information theory, they were crafted as obstructions to asymptotic tensor transformations, relevant in algebraic complexity theory. For tensors of order three, and more generally for weightings on singletons for higher-order tensors, the upper and lower quantum functionals coincide and are spectral points in Strassen's asymptotic spectrum. Moreover, the singleton quantum functionals characterize the asymptotic slice rank, whereas general weightings provide upper bounds on asymptotic partition rank. It has been an open question whether the upper and lower quantum functionals also coincide for other cases, or more generally, how to construct further spectral points, especially for higher-order tensors. In this work, we show that upper and lower quantum functionals generally do not coincide, but that they anchor new spectral points. With this we mean that there exist new spectral points, which equal the quantum functionals on the set of tensors on which upper and lower coincide. The set is shown to include embedded three-tensors and W-like states and concerns all laminar weightings, significantly extending the singleton case.

Authors: Xiao Wang

The key-value (KV) cache is the dominant memory bottleneck during Transformer inference, yet little is known theoretically about how aggressively it can be compressed before multi-step reasoning degrades. We study this through $k$-hop pointer chasing on $n$ tokens under a shared KV cache of size $s$, attention dimension $m$, $H$ heads, $p$-bit precision, and a locality-respecting cache controller (satisfied by all standard KV-compression methods). We give three results. (1) Product depth lower bound (conjectured). We conjecture that any such Transformer ($n \geq 4k$, $s \leq \sqrt{n}/4$) requires depth $L = Ω(\lceil k/s \rceil \cdot \lceil \log_2 n/(Hmp) \rceil)$, and isolate the sole remaining gap as a probabilistic step on the joint distribution of cache trace and pointer chain. Unconditionally, we prove a matching upper bound $L = O(\min(k, \lceil k/s \rceil \log s) \cdot \log n/(mp))$ via windowed pointer doubling, and a max-bound $L = Ω(\max(\lceil k/s \rceil, \log n/(Hmp)))$. Closing the conjecture amounts to upgrading max to product. (2) Bandwidth barrier. The product bound binds only when $Hmp \lesssim \log n$. Any lower bound provable via per-window distinguishability counting -- including reachability, bandwidth, and combinations -- cannot exceed $\lceil k/s \rceil$ once $Hmp \geq \log_2 n$. Breaking this requires lifting unconditional communication-complexity bounds for pointer chasing to Cache-Transformer depth. (3) Adaptive vs oblivious error scaling. Under random cache over $T = \lceil \log_2 k \rceil$ doubling stages, oblivious caches give $\Pr[\mathcal{E}] \leq (s/(n-T))^T + 2T^3/n$ (exponential in $T$), while adaptive locality-respecting caches achieve $\Pr[\mathcal{E}] = s/n$ exactly, independent of $T$. The $Ω((n/s)^{T-1})$ separation explains why heavy-hitter eviction empirically dominates random eviction for multi-hop reasoning.

Authors: Divya Bajaj, Bin Fu, Ryan Knobel, Austin Luchsinger, Aiden Massie, Pablo Santos, Ramiro Santos, Robert Schweller, Evan Tomai, Tim Wylie

Chemical Reaction Networks (CRNs) are a well-established model of distributed computing characterized by quantities of molecular species that can transform or change through applications of reactions. A fundamental problem in CRNs is the reachability problem, which asks if an initial configuration of species can transition to a target configuration through an applicable sequence of reactions. It is well-known that the reachability problem in general CRNs was recently proven to be Ackermann-complete. However, if the CRN's reactions are restricted in both power, such as only deleting species (deletion-only rules) or consuming and producing an equal number of species (volume-preserving rules), and size (unimolecular or bimolecular rules), then reachability falls below Ackermann-completeness, and is even solvable in polynomial time for deletion-only systems. In this paper, we investigate reachability under this set of restricted unimolecular and bimolecular reactions, but in the Priority-Inhibitory CRN and Inhibitory CRN models. These models extend a traditional CRN by allowing some reactions to be inhibited from firing in a configuration if certain species are present; the exact inhibition behavior varies between the models. We first show that reachability with Priority iCRNs mostly remains in P for deletion-only systems, but becomes NP-complete for one case. We then show that reachability with deletion-only reactions for iCRNs is mostly NP-complete, and PSPACE-complete even for (1,1)-size (general) reactions. We also provide FPT algorithms for solving most of the reachability problems for the iCRN model. Finally, we show reachability for CRNs with states is already NP-hard for the simplest deletion-only systems, and is PSPACE-complete even for (general) (1,1)-size reactions.

Authors: Johannes Bund, Amir Leshem, Moti Medina

Metastability is a spurious mode of operation in digital signals, where an electrical signal fails to settle into a stable state within a specified time, leading to uncertainty and potentially failing downstream hardware. A system that computes the closure over all possibilities, given an uncertain input, is called a Metastability-containing system. While prior work has addressed metastability-containing systems in the context of combinational and clocked circuits, state machines, and logic formulas, its implications for general-purpose computation remain largely unexplored. In this work, we study the metastability-containing systems within an abstract computational model: The Turing Machine. This approach allows us to investigate the computational limits and capabilities of Turing Machines operating under uncertain inputs. Specifically, we prove that in general the metastable closure of a Turing Machine is non-computable. Then we discuss cases where the meta-stable closure is computable: For EXPTIME problems, we prove that resolving even a single uncertain bit is EXPTIME-complete. In contrast, we prove that for polynomial time problems, the meta-stable closure is polynomial time computable for a logarithmic number of uncertain bits, but coNP-complete, when the number of undefined inputs is arbitrary. Finally, we describe a hardware-realizable Universal Turning Machine that computes the metastable closure of any given bounded-time Turing Machine with at most an exponential blowup in time.

Authors: Enoch Hyunwook Kang

Iterative alignment methods based on purely greedy updates are remarkably effective in practice, yet existing theoretical guarantees of \(O(\log T)\) KL-regularized regret can seem pessimistic relative to their empirical performance. In this paper, we argue that this mismatch arises from the regret criterion itself: KL-regularized regret conflates the statistical cost of learning with the exploratory randomization induced by the softened training policy. To separate these effects, we study the traditional temperature-zero regret criterion, which evaluates only the top-ranked response at inference time. Under this decision-centric notion of performance, we prove that standard greedy online alignment methods, including online RLHF and online DPO, achieve constant \((O(1))\) cumulative regret. By isolating the cost of identifying the best response from the stochasticity induced by regularization, our results provide a sharper theoretical explanation for the practical superb efficiency of greedy alignment.

Authors: Angshul Majumdar

We study the computational complexity of singularity for multilinear maps. While the determinant characterizes singularity for matrices, its multilinear analogue -- the hyperdeterminant -- is defined only in boundary format and quickly becomes algebraically unwieldy. We show that the intrinsic notion of tensor singularity, namely degeneracy, is complete for the existential theory of the reals. The reduction is exact and entirely algebraic: homogeneous quadratic feasibility is reduced to projective bilinear feasibility, then to singular matrix-pencil feasibility, and finally encoded directly as tensor degeneracy. No combinatorial gadgets are used. In boundary format, degeneracy coincides with hyperdeterminant vanishing. We therefore isolate the exact gap between intrinsic tensor singularity and its classical polynomial certificate. We show that deterministic hardness transfer to the hyperdeterminant reduces to selecting a point outside the zero set of a completion polynomial, yielding a structured instance of polynomial identity testing. We further formalize the failure of several natural deterministic embedding strategies. This identifies a sharp frontier: real 3-tensor degeneracy is fully characterized at the level of \(\ER\)-completeness, while the deterministic complexity of hyperdeterminant vanishing remains tied to a derandomization problem in algebraic complexity.

Authors: Michael T. M. Emmerich

We investigate \emph{magnitude} as a new unary and strictly Pareto-compliant quality indicator for finite approximation sets to the Pareto front in multiobjective optimization. Magnitude originates in enriched category theory and metric geometry, where it is a notion of size or point content for compact metric spaces and a generalization of cardinality. For dominated regions in the \(\ell_1\) box setting, magnitude is close to hypervolume but not identical: it contains the top-dimensional hypervolume term together with positive lower-dimensional projection and boundary contributions. This paper gives a first theoretical study of magnitude as an indicator. We consider multiobjective maximization with a common anchor point. For dominated sets generated by finite approximation sets, we derive an all-dimensional projection formula, prove weak and strict set monotonicity on finite unions of anchored boxes, and thereby obtain weak and strict Pareto compliance. Unlike hypervolume, magnitude assigns positive value to boundary points sharing one or more coordinates with the anchor point, even when their top-dimensional hypervolume contribution vanishes. We then formulate projected set-gradient methods and compare hypervolume and magnitude on biobjective and three-dimensional simplex examples. Numerically, magnitude favors boundary-including populations and, for suitable cardinalities, complete Das--Dennis grids, whereas hypervolume prefers more interior-filling configurations. Computationally, magnitude reduces to hypervolume on coordinate projections; for fixed dimension this yields the same asymptotic complexity up to a factor \(2^d-1\), and in dimensions two and three \(Θ(n\log n)\) time. These results identify magnitude as a mathematically natural and computationally viable alternative to hypervolume for finite Pareto front approximations.

Authors: Omrit Filtser, Tzalik Maimon, Ofir Yomtovyan

The minimum convex cover problem seeks to cover a polygon $P$ with the fewest convex polygons that lie within $P$. This problem is $\exists\mathbb R$-complete, and the best previously known algorithm, due to Eidenbenz and Widmayer (2001), achieves an $O(\log n)$-approximation in $O(n^{29} \log n)$ time, where $n$ is the complexity of $P$. In this work we present a novel approach that preserves the $O(\log n)$ approximation guarantee while significantly reducing the running time. By discretizing the problem and formulating it as a set cover problem, we focus on efficiently finding a convex polygon that covers the largest number of uncovered regions, in each iteration of the greedy algorithm. This core subproblem, which we call the rotten potato peeling problem, is a variant of the classic potato peeling problem. We solve it by finding maximum weighted paths in Directed Acyclic Graphs (DAGs) that correspond to visibility polygons, with the DAG construction carefully constrained to manage complexity. Our approach yields a substantial improvement in the overall running time and introduces techniques that may be of independent interest for other geometric covering problems.

Authors: David Avis, Luc Devroye

In this paper, we investigate the relationships between the volumes of four convex bodies: the cut polytope, metric polytope, rooted metric polytope, and elliptope, defined on graphs with $n$ vertices. The cut polytope is contained in each of the other three, which, for optimization purposes, provide polynomial-time relaxations. It is therefore of interest to see how tight these relaxations are. Worst-case ratio bounds are well known, but these are limited to objective functions with non-negative coefficients. Volume ratios, pioneered by Jon Lee with several co-authors, give global bounds and are the subject of this paper. For the rooted metric polytope over the complete graph, we show that its volume is much greater than that of the elliptope. For the metric polytope, for small values of $n$, we show that its volume is smaller than that of the elliptope; however, for large values, volume estimates suggest the converse is true. We also give exact formulae for the volume of the cut polytope for some families of sparse graphs.

Authors: József Pintér, Regina Stangl

Network caching asks how to place contents in distributed caches so that future requests are served close to their users. Ganian, Mc Inerney and Tsigkari recently initiated the parameterized-complexity study of the problem and, for the homogeneous unit-size variant (HomNC), isolated an unresolved family of six parameterizations: by the number of caches $C$, the number of users $U$, $U+K$, $C+U$, $C+λ$, and the vertex-cover number $\text{vc}(G)$, where $K$ is the maximum cache capacity and $λ$ is the maximum number of contents requested with nonzero probability by any user. Their interreducibility theorem showed that these six cases stand or fall together under parameterized reductions, and they conjectured the family to be W[1]-hard. We resolve this conjecture in the opposite direction. We prove that HomNC is fixed-parameter tractable parameterized by $C$ alone, and therefore fixed-parameter tractable for all six parameterizations. Our algorithm is based on an exact $n$-fold integer programming formulation that reveals a nontrivial block structure in homogeneous network caching, with the repeated part depending only on $C$. Standard algorithms for $n$-fold integer programming then yield a running time of the form $f(C)\lvert I\rvert^{O(1)}$.

Authors: Seongbin Park, Eunjin Oh

In this paper, we study the many-to-many matching problem on planar point sets with integer coordinates: Given two disjoint sets $R,B \subset [Δ]^2$ with $|R|+|B|=n$, the goal is to select a set of edges between $R$ and $B$ so that every point is incident to at least one edge and the total Euclidean length is minimized. In the general case that $R$ and $B$ are point sets in the plane, the best-known algorithm for the many-to-many matching problem takes $\tilde{O}(n^2)$ time. We present an exact $\tilde{O}(n^{1.5} \log Δ)$ time algorithm for point sets in $[Δ]^2$. To the best of our knowledge, this is the first subquadratic exact algorithm for planar many-to-many matching under bounded integer coordinates.

Authors: Hannaneh Akrami, Alexander Mayorov, Kurt Mehlhorn, Shreyas Srinivas, Christoph Weidenbach

SAT solving has recently been proven effective in tackling open combinatorial problems. We contribute two additional results in the context of fair distribution of indivisible goods. Specifically, we demonstrate that EFX (envy-freeness up to any good) allocations always exist for three agents and seven goods, while we provide a counterexample for the case of $n \ge 3$ agents and $m \ge n + 5$ goods. An allocation is EFX if no agent would envy the allocation of any other agent if any single item were to be removed from the other agent's bundle of goods. Each agent's preferences are modeled by a monotone valuation function on all potential bundles. After analyzing theoretical aspects of the problem, we encode the negation of the EFX instances into SAT. Satisfiability of the respective SAT formula constitute a counter-example to EFX, unsatisfiability of the respective SAT formula implies that EFX holds. The theoretical foundations of the encoding are proven correct in LEAN. For the three agents and seven goods case, we obtained a proof of unsatisfiability using SPASS-SAT of size about 30 GB in about 30 hours. It was shown to be correct by DRAT-trim. In the case of three agents and eight goods, SPASS-SAT computed satisfiability indicating a counterexample in the form of three specific agent valuations in about 20 hours. It was verified by probing all possible bundle assignments; the verification takes seconds. The extension of the counterexample to $n \ge 4$ agents and $m \ge n + 5$ goods does not involve SAT-solving. This counterexample resolves, in the negative, one of the central questions in the theory of discrete fair division.

Authors: Maximilian von Aspern, Felix Buld, Michael Pinedo

We study flow shop scheduling with stochastic reentry, where jobs must complete multiple passes through the entire shop, and the number of passes that a job requires for completion is drawn from a discrete probability distribution. The goal is to find policies that minimize performance measures in expectation. Our main contribution is a reduction to a classical parallel machine scheduling problem augmented with machine arrivals. This reduction preserves expected objective values and enables transferring structural results and performance guarantees from the auxiliary problems to the reentrant flow shop setting. We demonstrate the usefulness of this reduction by proving the optimality of simple priority policies for minimizing the makespan and the total completion time in expectation under geometric and, more generally, monotone hazard rate distributions. For minimizing the total weighted completion time, we derive an approximation guarantee that depends only on the squared coefficient of variation of the underlying distributions for a simple priority policy. Our results constitute the first optimality and approximation guarantees for flow shops with stochastic reentry and demonstrate that established scheduling policies naturally extend to this setting through the proposed reduction.

Authors: Lloyd Allison

Conway's surreal numbers were aptly named by Knuth. This note examines how far one can get towards implementing surreals and the arithmetic operations on them so that they execute efficiently. Lazy evaluation and recursive data structures yield a considerable speed up.

Authors: Jianming Tong, Jingtian Dang, Simon Langowski, Tianhao Huang, Asra Ali, Jeremy Kun, Jevin Jiang, Srinivas Devadas, Tushar Krishna

Zero-knowledge proof (ZKP) provers remain costly because multi-scalar multiplication (MSM) and number-theoretic transforms (NTTs) dominate runtime as they need significant computation. AI ASICs such as TPUs provide massive matrix throughput and SotA energy efficiency. We present MORPH, the first framework that reformulates ZKP kernels to match AI-ASIC execution. We introduce Big-T complexity, a hardware-aware complexity model that exposes heterogeneous bottlenecks and layout-transformation costs ignored by Big-O. Guided by this analysis, (1) at arithmetic level, MORPH develops an MXU-centric extended-RNS lazy reduction that converts high-precision modular arithmetic into dense low-precision GEMMs, eliminating all carry chains, and (2) at dataflow level, MORPH constructs a unified-sharding layout-stationary TPU Pippenger MSM and optimized 3/5-step NTT that avoid on-TPU shuffles to minimize costly memory reorganization. Implemented in JAX, MORPH enables TPUv6e8 to achieve up-to 10x higher throughput on NTT and comparable throughput on MSM than GZKP. Our code: https://github.com/EfficientPPML/MORPH.

Authors: Dionysis Arvanitakis, Vaggos Chatziafratis, Yiyuan Luo, Konstantin Makarychev

Quartet Reconstruction, the task of recovering a phylogenetic tree from smaller trees on four species called \textit{quartets}, is a well-studied problem in theoretical computer science with far-reaching connections to statistics, graph theory and biology. Given a random sample containing $m$ noisy quartets, labeled by an unknown ground-truth tree $T$ on $n$ taxa, we want to output a tree $\widehat T$ that is \textit{close} to $T$ in terms of quartet distance and can predict unseen quartets. Unfortunately, the empirical risk minimizer corresponds to the $\mathsf{NP}$-hard problem of finding a tree that maximizes agreements with the sampled quartets, and earlier works in approximation algorithms gave $(1-\eps)$-approximation schemes (PTAS) for dense instances with $m=Θ(n^4)$ quartets, or for $m=Θ(n^2\log n)$ quartets \textit{randomly} sampled from $T$. Prior to our work, it was unknown how many samples are information-theoretically required to learn the tree, and whether there is an efficient reconstruction algorithm. We present optimal results for reconstructing an unknown phylogenetic tree $T$ from a random sample of $m=Θ(n)$ quartets, corrupted under the Random Classification Noise (RCN) model. This matches the $Ω(n)$ lower bound required for any meaningful tree reconstruction. Our contribution is twofold: first, we give a tree reconstruction algorithm that, not only achieves a $(1-\eps)$-approximation, but most importantly \textit{recovers} a tree close to $T$ in quartet distance; second, we show a new $Θ(n)$ bound on the Natarajan dimension of phylogenies (an analog of VC dimension in multiclass classification). Our analysis relies on a new \textit{Quartet-based Embedding and Detection} procedure that identifies and removes well-clustered subtrees from the (unknown) ground-truth $T$ via semidefinite programming.

Authors: Zhangsong Li

The low-degree polynomial framework has emerged as a powerful tool for providing evidence of statistical-computational gaps in high-dimensional inference. For detection problems, the standard approach bounds the low-degree advantage through an explicit orthonormal basis. However, this method does not extend naturally to estimation tasks, and thus fails to capture the \emph{detection-recovery gap phenomenon} that arises in many high-dimensional problems. Although several important advances have been made to overcome this limitation \cite{SW22, SW25, CGGV25+}, the existing approaches often rely on delicate, model-specific combinatorial arguments. In this work, we develop a general approach for obtaining \emph{conditional computational lower bounds} for recovery problems from mild bounds on low-degree testing advantage. Our method combines the notion of algorithmic contiguity in \cite{Li25} with a cross-validation reduction in \cite{DHSS25} that converts successful recovery into a hypothesis test with lopsided success probabilities. In contrast to prior unconditional lower bounds, our argument is conceptually simple, flexible, and largely model-independent. We apply this framework to several canonical inference problems, including planted submatrix, planted dense subgraph, stochastic block model, multi-frequency angular synchronization, orthogonal group synchronization, and multi-layer stochastic block model. In the first three settings, our method recovers existing low-degree lower bounds for recovery in \cite{SW22, SW25} via a substantially simpler argument. In the latter three, it gives new evidence for conjectured computational thresholds including the persistence of detection-recovery gaps. Together, these results suggest that mild control of low-degree advantage is often sufficient to explain computational barriers for recovery in high-dimensional statistical models.

Authors: Henry Shugart, Shuyi Wang, Jason M. Altschuler

This paper revisits momentum in the context of min-max optimization. Momentum is a celebrated mechanism for accelerating gradient dynamics in settings like convex minimization, but its direct use in min-max optimization makes gradient dynamics diverge. Surprisingly, Gidel et al. 2019 showed that negative momentum can help fix convergence. However, despite these promising initial results and progress since, the power of momentum remains unclear for min-max optimization in two key ways. (1) Generality: is global convergence possible for the foundational setting of convex-concave optimization? This is the direct analog of convex minimization and is a standard testing ground for min-max algorithms. (2) Fast convergence: is accelerated convergence possible for strongly-convex-strong-concave optimization (the only non-linear setting where global convergence is known)? Recent work has even argued that this is impossible. We answer both these questions in the affirmative. Together, these results put negative momentum on more equal footing with competitor algorithms, and show that negative momentum enables convergence significantly faster and more generally than was known possible.

Authors: Rosina Kharal, Trevor Brown, Justus Henneberg, Felix Schuhknecht

GPU-based concurrent data structures (CDSs) achieve high throughput for read-only queries, but efficient support for dynamic updates on fully GPU-resident data remains challenging. Ordered CDSs (e.g., B-trees and LSM-trees) maintain an index layer that directs operations to a data layer (buckets or leaves), while hash tables avoid the cost of maintaining order but do not support range or successor queries. On GPUs, maintaining and traversing an index layer under frequent updates introduces contention and warp divergence. To tackle these problems, we flip the indexing paradigm on its head with FliX, a comparison-based, flipped indexing strategy for dynamic, fully GPU-resident CDSs. Traditional GPU CDSs typically take a batch of operations and assign each operation to a GPU thread or warp. FliX, however, assigns compute (e.g., a warp) to each bucket in the data layer, and each bucket then locates operations it is responsible for in the batch. FliX can replace many index layer traversals with a single binary search on the batch, reducing redundant work and warp divergence. Further, FliX simplifies updates as no index layer must be maintained. In our experiments, FliX achieves 6.5x reduced query latency compared to a leading GPU B-tree and 1.5x compared to a leading GPU LSM-tree, while delivering 4x higher throughput per memory footprint than ordered competitors. Despite maintaining order, FliX also surpasses state-of-the-art unordered GPU hash tables in query and deletion performance, and is highly competitive in insertion performance. In update-heavy workloads, it outperforms the closest fully dynamic ordered baseline by over 8x in insertion throughput while supporting dynamic memory reclamation. These results suggest that eliminating the index layer and adopting a compute-to-bucket mapping can enable practical, fully dynamic GPU indexing without sacrificing query performance.

As annoounced on the CONCUR 2026 website, the 2026 CONCUR Test-of-Time Award Committee, consisting of Anca Muscholl (chair), Javier Esparza and Prakash Panangaden, has selected the following two papers for the 2006-2009 ToT award.

• CONCUR 2006: "A New Type System for Deadlock-Free Processes" by Naoki Kobayashi, and
• CONCUR 2007: "Strategy Logic" by Krishnendu Chatterjee, Thomas A. Henzinger and Nir Piterman. 

By Luca Aceto

The Summer School on the Theory and Practice of Blockchain Consensus will be held May 26–29, 2026, at Columbia University. The program is hosted by the Columbia-Ethereum Research Center for Blockchain Protocol Design. Confirmed speakers include Ittai Abraham (a16z crypto), Maria Apostolaki (Princeton), Natacha Crooks (UC Berkeley), Francesco d’Amato (Ethereum Foundation), Sourav Das (Category Labs), Andrew Lewis-Pye (London School of Economics/Commonware), Barnabe Monnot (Ethereum Foundation), Joachim Neu (a16z crypto), Patrick O’ Grady (Commonware), Alberto Sonnino (Mysten Labs), Roger Wattenhofer (ETH Zurich/Anza Labs), and more.
 
There is no registration fee; however, space is limited. To apply (by April 25th) and for more details visit https://timroughgarden.org/summerschool26.html

By timroughgarden

John Doyle, he of robust control infamy, has been a close friend and mentor of mine for over two decades. And for the entirety of those two decades, he’s been yelling about the need for a unified theory of engineering architecture. If you know John, you’ve likely heard the same rants and seen his psychedelic PowerPoint slides with bowties, hourglasses, and bonobos. He’ll show you a picture of the internet stack and a picture of the organization of bacterial metabolism, and expect you to see that they are the same thing.

Now, I spent a good chunk of the last week trying to figure out how to pack John’s grand unified theory into a single lecture. Just like with simulation, I failed. However, I came out much more convinced that John is onto something than I went in. Let me do my best to explain why without sounding like a complex-systems crazy person.

In this class, and in control research more generally, we keep getting trapped by optimization. It’s always easiest to frame problems in terms of optimization problems, and then worry about the particulars of the solution method. However, optimal control is far too limited and brittle for any practical application. It is more often than not a simulation steering problem: we build a simulator at some abstraction level, and then shape a policy by designing an appropriate set of costs and constraints. The framework forces us to operate at a particular abstraction layer, which means we end up at a specific point on the action-impact trade-off curve. We can’t design for hidden states, and we’re sensitive to modeling errors. It forces us to model unknowns as average-case or worst-case disturbances. Optimization is specific and rigid, whereas control systems need to be diverse and flexible. What’s the right way to think about diversity and flexibility?

Fortunately, we have a lot of existence proofs to learn from when trying to answer that question. The world is run on complex, engineered feedback systems with astounding robustness, diversity, and flexibility. We transmit thousands of trillions of bits to each other every second on the internet. We maintain electricity for billions of people. We can have any product we can imagine delivered to our doorstep. We can get from our house to almost any point on earth in a couple of days. We carry around supercomputers in our pockets so we can watch vertical videos whenever we’re bored. We live in a world of engineering miracles that are more robust than any LQR system. So how in the world do they work?

John Doyle is not alone in arguing that the answer is architecture, a set of organizing principles for engineering design. Architecture is the rules and protocols for assembling components to enable diversity in system execution. You want systems that can accommodate a diversity of objectives: balancing speed, accuracy, and impact. You’d like to be able to solve a diversity of tasks. You’d like to accommodate a diversity of end users. Diversity is a particular kind of robustness. It’s robustness to intent. And you have to design for it.

Looking at the last hundred years of engineering, you definitely see repeated patterns in architectural design. First, the need for hierarchy to handle complexity isn’t surprising. Herb Simon was already on this in the sixties. But graph structure and emergulence are not enough.

Feedback is essential. As we’ve seen throughout the class, you can take two systems with dramatically different behaviors and put together a system with “best of both worlds” through feedback. A powerful amplifier and a precise attenuator combine in feedback to make a powerful, precise amplifier. A language machine that can recapitulate all software in feedback, using a simple agent harness with iterative exception handling, lets you build and manage complex software packages. Architecture lets you scale this feedback design principle.

The key to scalable architectures is protocols. Computer science — the engineering discipline of scaling logical systems — is obsessed with architectural protocols. To build a complex system like the internet or the modern computer, you build a hierarchy of abstraction boundaries. You design interfaces to talk across these boundaries with clean, well-specified protocols. The protocols let each system operate with a particular set of agreements about what the other will do. When you stack these protocols together, you get ridiculously impressive diversity. From this design strategy, you can build out the internet, the integrated circuit, the cell, and the control system. The internet serves arbitrary applications on arbitrary physical layers, all funneled through a set of contracts with IP in the middle. We can design a diversity of complex computer chips from standard cells and data flow models. In each of these cases, each layer only speaks to its neighbors in a structured hierarchy.

Finally, there is a central concept that seems to drive architectural design: constraints that deconstrain. They are restrictions on what we can do at one point of the hierarchy that end up enabling diversity at another. Constraints that deconstrain were proposed by Marc W. Kirschner and John Gerhart as a facilitator of evolution. Systems engineers like Alberto Sangiovanni-Vincentelli and Edward Lee emphasize how they provide a Devo-esque “Freedom of choice,” removing the paradox of choice and enabling more efficient design cycles. I’ll connect this to similar architectural theories of computer scientists and electrical engineers.

Engineering architecture is far too much to cram into a single lecture, but I’ll give a brief introduction to the ideas this week on the blog. I’ve come to the conclusion that there’s a whole semester’s class to be taught here. How better to end a class than by describing what the next class looks like?

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By Ben Recht

The Center for AI and Natural Sciences invites applications from PhD holders in mathematics, theoretical computer science, or related fields. We seek candidates with strong research potential in mathematics and/or algorithms. The position offers an annual salary of 77,880,000 KRW plus a research grant. The initial 2-year term may be renewed once. – CV, publication list, research plan, 3 letters

Website: https://jobs.kias.re.kr/ext/rec/rec_1001.do?ANNC_NO=REC202604060001
Email: aikias@kias.re.kr

By shacharlovett

Authors: Álvaro Yángüez, Noam Avidan, Jan Kochanowski, Thomas A. Hahn

Quantum systems may contain underlying correlations which are inaccessible to computationally bounded observers. We capture this distinction through a framework that analyses bipartite states only using efficiently implementable quantum channels. This leads to a complexity-constrained max-divergence and a corresponding computational min-entropy. The latter quantity recovers the standard operational meaning of the conditional min-entropy: in the fully quantum case, it quantifies the largest overlap with a maximally entangled state attainable via efficient operations on the conditional subsystem. For classical-quantum states, it further reduces to the optimal guessing probability of a computationally bounded observer with access to side information. Lastly, in the absence of side information, the computational min-entropy simplifies to a computational notion of the operator norm. We then establish strong separations between the information-theoretic and complexity-constrained notions of min-entropy. For pure states, there exist highly entangled families of states with extremal min-entropy whose efficiently accessible entanglement in terms of computational min-entropy is exponentially suppressed. For mixed states, the separation is even sharper: the information-theoretic conditional min-entropy can be highly negative while the complexity-constrained quantity remains nearly maximal. Overall, our results demonstrate that computational constraints can fundamentally limit the quantum correlations that are observable in practice.

Authors: Takashi Yoshino, Supanut Chaidee

We consider a new treatment for making polyhedron nets referred to as ``apple peel unfolding'': drawing the nets as if we were peeling off appleskins. We define apple peel unfolding strictly and implement a program that derives the sequential selection of the polyhedral faces for a target polyhedron in accordance with the definition. Consequently, the program determines whether the polyhedron is peelable (can be peeled completely). We classify Archimedean solids and their duals (Catalan solids) as perfect (always peelable), possible (peelable for restricted cases), or impossible. The results show that three Archimedean and six Catalan solids are perfect, and three Archimedean and three Catalan ones are possible.

Authors: Stefan Huber, Dominik Kaaser

We study the patient zero problem in epidemic spreading processes in the independent cascade model and propose a geometric approach for source reconstruction. Using Johnson-Lindenstrauss projections, we embed the contact network into a low-dimensional Euclidean space and estimate the infection source as the node closest to the center of gravity of infected nodes. Simulations on Erdős-Rényi graphs demonstrate that our estimator achieves meaningful reconstruction accuracy despite operating on compressed observations.

Authors: Dursun Bulutoglu

We provide a method for parallelizing the branch-and-bound with isomorphism pruning algorithm developed by Margot [Symmetric ILP: Coloring and small integers, Discrete Optimization (4) (2007), 40-62]. We apply our method to classify orthogonal arrays. For classifying all non-OD- equivalent OA(128, 9, 2, 4) and OA(144, 9, 2, 4) our method results in linear speedups. Finally, our method enables classifying all non-OD-equivalent OA(192, k, 2, 4) for k = 9, 10, 11 for the first time.

Authors: Michał Dereziński, Yuji Nakatsukasa, Elizaveta Rebrova

The quest for an algorithm that solves an $n\times n$ linear system in $O(n^2)$ time complexity, or $O(n^2 \text{poly}(1/ε))$ when solving up to $ε$ relative error, is a long-standing open problem in numerical linear algebra and theoretical computer science. There are two predominant paradigms for measuring relative error: forward error (i.e., distance from the output to the optimum solution) and backward error (i.e., distance to the nearest problem solved by the output). In most prior studies, convergence of iterative linear system solvers is measured via various notions of forward error, and as a result, depends heavily on the conditioning of the input. Yet, the numerical analysis literature has long advocated for backward error as the more practically relevant notion of approximation. In this work, we show that -- surprisingly -- the classical and simple Richardson iteration incurs at most $1/k$ (relative) backward error after $k$ iterations on any positive semidefinite (PSD) linear system, irrespective of its condition number. This universal convergence rate implies an $O(n^2/ε)$ complexity algorithm for solving a PSD linear system to $ε$ backward error, and we establish similar or better complexity when using a variety of Krylov solvers beyond Richardson. Then, by directly minimizing backward error over a Krylov subspace, we attain an even faster $O(1/k^2)$ universal rate, and we turn this into an efficient algorithm, MINBERR, with complexity $O(n^2/\sqrtε)$. We extend this approach via normal equations to solving general linear systems, for which we empirically observe $O(1/k)$ convergence. We report strong numerical performance of our algorithms on benchmark problems.

Authors: Nicole Funk, Annika Hennes, Johanna Hillebrand, Sarah Sturm

We study discrete k-clustering problems in general metric spaces that are constrained by a combination of two different fairness conditions within the demographic fairness model. Given a metric space (P,d), where every point in P is equipped with a protected attribute, and a number k, the goal is to partition P into k clusters with a designated center each, such that a center-based objective function is minimized and the attributes are fairly distributed with respect to the following two fairness concepts: 1) group fairness: We aim for clusters with balanced numbers of attributes by specifying lower and upper bounds for the desired attribute proportions. 2) diverse center selection: Clusters have natural representatives, i.e., their centers. We ask for a balanced set of representatives by specifying the desired number of centers to choose from each attribute. Dickerson, Esmaeili, Morgenstern and Zhang (2023) denote the combination of these two constraints as doubly constrained fair clustering. They present algorithms whose guarantees depend on the best known approximation factors for either of these problems. Currently, this implies an 8-approximation with a small additive violation on the group fairness constraint. For k-center, we improve this approximation factor to 4 with a small additive violation. This guarantee also depends on the currently best algorithm for DS-fair k-center given by Jones, Nguyen and Nguyen (2020). For k-median and k-means, we propose the first constant-factor approximation algorithms. Our algorithms transform a solution that satisfies diverse center selection into a doubly constrained fair clustering using an LP-based approach. Furthermore, our results are generalizable to other center-selection constraints, such as matroid k-clustering and knapsack constraints.

Authors: Sotiris Kanellopoulos, Giorgos Mitropoulos, Christos Pergaminelis, Thanos Tolias

The k-Visits problem is a recently introduced finite version of Pinwheel Scheduling [Kanellopoulos et al., SODA 2026]. Given the deadlines of n tasks, the problem asks whether there exists a schedule of length kn executing each task exactly k times, with no deadline expiring between consecutive visits (executions) of each task. In this work we prove that 2-Visits is strongly NP-complete even when the maximum multiplicity of the input is equal to 2, settling an open question from [Kanellopoulos et al., SODA 2026] and contrasting the tractability of 2-Visits for simple sets. On the other hand, we prove that 2-Visits is in RP when the number of distinct deadlines is constant, thus making progress on another open question regarding the parameterization of 2-Visits by the number of numbers. We then generalize all existing positive results for 2-Visits to a version of the problem where some tasks must be visited once and some other tasks twice, while providing evidence that some of these results are unlikely to transfer to 3-Visits. Lastly, we establish bounds for the density thresholds of k-Visits, analogous to the $(5/6)$-threshold of Pinwheel Scheduling [Kawamura, STOC 2024]; in particular, we show a $\sqrt{2}-1/2\approx 0.9142$ lower bound for the density threshold of 2-Visits and prove that the density threshold of k-Visits approaches $5/6\approx 0.8333$ for $k \to \infty$.

Authors: Xujin Chen, Xiaodong Hu, Changjun Wang, Yuchun Xiong, Qingjie Ye

This paper studies an online trading variant of the classical secretary problem, called secretary problem variant trading (SPVT), from the perspective of an intermediary who facilitates trade between a seller and $n$ buyers (collectively referred to as agents). The seller has an item, and each buyer demands the item. These agents arrive sequentially in a uniformly random order to meet the intermediary, each revealing their valuation of the item upon arrival. After each arrival, the intermediary must make an immediate and irrevocable decision before the next agent appears. The intermediary's objective is to maximize the price of the agent who ultimately holds the item at the end of the process. We evaluate the performance of online algorithms for SPVT using two notions of competitive ratio: strong and weak. The strong notion benchmarks the online algorithm against a powerful offline optimum: the highest price among the $n+1$ agents. We propose an online algorithm for SPVT achieving a strong competitive ratio of $\frac{4e^2}{e^2+1} \approx 3.523$, which is the best possible even when the seller's price may be zero. This tight ratio closes the gap between the previous best upper bound of $4.189$ and lower bound of $3.258$. In contrast, the weak notion restricts the offline optimal algorithm to the given arrival order. The offline algorithm can no longer alter the predetermined arrival order to always place the item in the hands of the agent offering the highest price. Against this weaker benchmark, we design a simple online algorithm for SPVT, achieving a weak competitive ratio of $2$. We further investigate the special case in which the seller's price is zero. For this special SPVT, we develop a double-threshold algorithm achieving a weak competitive ratio of at most $1.83683$ and establish a lower bound of $1.76239$.

Authors: Leif Eriksson, Victor Lagerkvist, Sebastian Ordyniak, George Osipov, Fahad Panolan, Mateusz Rychlicki

The quantified Boolean formula problem (QBF) is a well-known PSpace-complete problem with rich expressive power, and is generally viewed as the SAT analogue for PSpace. Given that many problems today are solved in practice by reducing to SAT, and then using highly optimized SAT solvers, it is natural to ask whether problems in PSpace are amenable to this approach. While SAT solvers exploit hidden structural properties, such as backdoors to tractability, backdoor analysis for QBF is comparatively very limited. We present a comprehensive study of the (parameterized) complexity of QBF parameterized by backdoor size to the largest tractable syntactic classes: HORN, 2-SAT, and AFFINE. While SAT is in FPT under this parameterization, we prove that QBF remains PSpace-hard even on formulas with backdoors of constant size. Parameterizing additionally by the quantifier depth, we design FPT-algorithms for the classes 2-SAT and AFFINE, and show that 3-HORN is W[1]-hard. As our next contribution, we vastly extend the applicability of QBF backdoors not only for the syntactic classes defined above but also for tractable classes defined via structural restrictions, such as formulas with bounded incidence treewidth and quantifier depth. To this end, we introduce enhanced backdoors: these are separators S of size at most k in the primal graph such that S together with all variables contained in any purely universal component of the primal graph minus S is a backdoor. We design FPT-algorithms with respect to k for both evaluation and detection of enhanced backdoors to all tractable classes of QBF listed above and more.

Authors: Tomasz Kociumaka, Jakob Nogler, Philip Wellnitz

In the decades-old Pattern Matching with Edits problem, given a length-$n$ string $T$ (the text), a length-$m$ string $P$ (the pattern), and a positive integer $k$ (the threshold), the task is to list the $k$-error occurrences of $P$ in $T$, that is, all fragments of $T$ whose edit distance to $P$ is at most $k$. The one-way communication complexity of Pattern Matching with Edits is the minimum number of bits that Alice, given an instance $(P, T, k)$ of the problem, must send to Bob so that Bob can reconstruct the answer solely from that message. For the natural parameter regime of $0 < k < m < n/2$, our recent work [STOC'24] yields that $Ω(n/m \cdot k \log(m/k))$ bits are necessary and $O(n/m \cdot k \log^2 m)$ bits are sufficient for Pattern Matching with Edits. More generally, for strings over an alphabet $Σ$, our recent work [STOC'24] gives an $O(n/m \cdot k \log m \log(m|Σ|))$-bit encoding that allows one to recover a shortest sequence of edits for every $k$-error occurrence of $P$ in $T$. In this work, we revisit the original proof and improve the encoding size to $O(n/m \cdot k \log(m|Σ|/k))$, which matches the lower bound for constant-sized alphabets. We further establish a new tight lower bound of $Ω(n/m \cdot k \log(m|Σ|/k))$ for the edit sequence reporting variant that we solve. Our encoding size also matches the communication complexity established for the simpler Pattern Matching with Mismatches problem in the context of streaming algorithms [Clifford, Kociumaka, Porat; SODA'19].

Authors: John Burke, Ciaran McGoldrick

Quantum search is among the most important algorithms in quantum computing. At its core is quantum amplitude amplification, a technique that achieves a quadratic speedup over classical search by combining two global reflections: the oracle, which marks the target, and the diffusion operator, which reflects about the initial state. We show that this speedup can be preserved when the oracle is the only global operator, with all other operations acting locally on non-overlapping partitions of the search register. We present a recursive construction that, when the initial and target states both decompose as tensor products over these chosen partitions, admits an exact closed-form solution for the algorithm's dynamics. This is enabled by an intriguing degeneracy in the principal angles between successive reflections, which collapse to just two distinct values governed by a single recursively defined angle. Applied to unstructured search, a problem that naturally satisfies the tensor decomposition, the approach retains the $O(\sqrt{N})$ oracle complexity of Grover search when each partition contains at least $\log_2(\log_2 N)$ qubits. On an 18-qubit search problem, partitioning into two stages reduces the non-oracle circuit depth by as much as 51%-96% relative to Grover, requiring up to 9% additional oracle calls. For larger problem sizes this oracle overhead rapidly diminishes, and valuable depth reductions persist when the oracle circuit is substantially deeper than the diffusion operator. More broadly, these results show that a global diffusion operator is not necessary to achieve the quadratic speedup in quantum search, offering a new perspective on this foundational algorithm. Moreover, the scalar reduction at the heart of our analysis inspires and motivates new directions and innovations in quantum algorithm design and evaluation.

We consider (almost) $k$-wise independent hash functions, whose evaluations on any $k$ inputs are (almost) uniformly random, for very large values of $k$. Such hash functions need to have a large key that grows linearly with $k$. However, it may be possible to evaluate them in sub-linear time by only reading a small subset of $t \ll k$ locations during each evaluation; we call such hash functions $t$-local. Local hash functions were previously studied in several works starting with Siegel (FOCS'89, SICOMP'04). For a hash function with $n$-bit input and output size, we get the following new results: * There exist (non-constructively) perfectly $k$-wise independent $t$-local hash functions with key size $O(kn)$ and locality of $t = O(n)$ bits. An analogous prior result of Larsen et al. (ICALP '24) had a locality of $t=O(n)$ words consisting of $w= O(n)$ bits each, and hence a suboptimal $O(n^2)$ bits total. Furthermore, we show that such hash functions could be made explicit if we had explicit optimal constructions of unbalanced bipartite lossless expanders. Plugging in currently best known suboptimal explicit expanders yields correspondingly suboptimal hash functions. * Perfectly $k$-wise independent local hash functions generically yield expanders with corresponding parameters. This is true even if the locations accessed by the hash function can be chosen adaptively and shows that progress on explicit hash functions inherently requires progress on explicit expanders. * We initiate the study of $\epsilon$-almost $k$-wise independent hash functions, where any $k$ adaptive queries to the hash function are $\epsilon$-statistically indistinguishable from $k$ queries to a random function. We construct an explicit family of such hash functions with optimal key size $O(kn)$ bits, optimal locality $t = O(n)$ bits, and $\epsilon= 2^{-n}$, significantly improving over the best known parameters for explicit perfectly independent hashing. * More generally, if we consider a word model with larger word size $w$, then we get an explicit, efficient construction of $\epsilon$-almost $k$-wise independent hash functions with key size $O(kn/w)$ words, locality $t = O(n/\sqrt{w})$ words, and statistical distance $\epsilon= 2^{-n}$, which we show to be nearly optimal. Such parameters go beyond what is possible for perfect independence. We discuss applications to nearly optimal bounded-use information-theoretic cryptography.

Sir Charles Antony Richard Hoare (1934-2026) won the 1980 Turing Award for numerous contributions to computer science, including foundational work on concurrency and formal verification and the invention (with Dijkstra) of the dining philosophers problem. But he’s perhaps best known, to pretty much everyone who’s ever studied CS, as the inventor of the Quicksort algorithm. I’m sorry that I never got to meet him.

Michael O. Rabin (1931-2026), of Harvard University, was one of the founders of theoretical computer science and winner of the 1976 Turing Award. In 1959, he and Dana Scott introduced the concept of a “nondeterministic machine”—that is, a machine with exponentially many possible computation paths, which accepts if and only if there exists an accepting path—which would of course later play a central role in the formulation of P vs. NP problem. He’s also known for the Miller-Rabin primality test, which helped to establish randomness as a central concept in algorithms, and for many other things. He’s survived by his daughter Tal Rabin, also a distinguished theoretical computer scientist. I was privileged to meet the elder Rabin on several visits to Harvard, where he showed me great kindness.

Sir Anthony Leggett (1938-2026), of the University of Illinois Urbana-Champaign, was one of the great quantum physicists of the late 20th century, and recipient of the 2003 Nobel Prize for his work on superfluidity. When I knew him, he was a sort of elder statesman of quantum computing and information, who helped remind the rest of us of why we got into the field in the first place—not to solve Element Distinctness moderately faster, but to learn the truth of quantum mechanics itself. Tony insisted, over and over, that the validity of quantum mechanics on the scale of everyday life is an open empirical problem, to be settled by better experiments and not by a-priori principles. I first met Tony at a Gordon Research Conference in southern California. Even though I was then a nobody and he a recent Nobel laureate, he took the time to listen to my ideas about Sure/Shor separators, and to suggest (correctly) what we now call 2D cluster states as an excellent candidate for what I wanted. In all my later interactions with Tony, at both the University of Waterloo (where he was visiting faculty for a while) and at UIUC (where my wife Dana and I considered taking jobs), he was basically the friendliest, funniest guy you could possibly meet at his level of achievement and renown. I was bummed to hear about his passing.

By Scott

We give new explicit constructions of several fundamental objects in linear-algebraic pseudorandomness and combinatorics, including lossless rank extractors, weak subspace designs, and strong $s$-blocking sets over finite fields. Our focus is on the small-field regime, where the field size depends only on a secondary parameter (such as the rank or codimension) and is independent of the ambient dimension. This regime is central to several applications, yet remains poorly understood from the perspective of explicit constructions. In this setting, we obtain the first explicit constructions of lossless rank extractors and weak subspace designs for $r\ll k$, where $r$ denotes the rank (or codimension), over finite fields $\mathbb{F}_q$ with $q \ge \mathrm{poly}(r)$ and $q$ non-prime, with near-optimal parameters. For other finite fields, including prime fields and small fields, we obtain weaker but still improved bounds. As a consequence, we construct explicit strong $s$-blocking sets in $\mathrm{PG}(k-1,q)$ of size $O(s(k-s)q^s)$ for all sufficiently large non-prime fields $q \ge \mathrm{poly}(s)$, matching the best known non-explicit bounds up to constant factors. This significantly improves the previous best bound $2^{O(s^2 \log s)} q^s k$ of Bishnoi and Tomon (Combinatorica, 2026), which requires $q \ge 2^{\Omega(s)}$. Our approach is primarily algebraic, combining techniques from function fields and polynomial identity testing. In addition, we develop a complementary Fourier-analytic framework based on $\varepsilon$-biased sets, which yields improved explicit constructions of strong $s$-blocking sets over small fields.

Located in the center of Beijing, the College of Artificial Intelligence at Capital Normal University invites applications for full-time faculty positions and research positions at all ranks. Submit a single PDF to t116@cnu.edu.cn containing:
1. Curriculum vitae
2. 3–5 publications
3. Research statement
4. Three letters of recommendation (sent directly by recommenders to t116@cnu.edu.cn)

Website: https://aic.cnu.edu.cn/
Email: t116@cnu.edu.cn

By shacharlovett

This is a live blog of Lecture 9 of my graduate seminar “Feedback, Learning, and Adaptation.” A table of contents is here.

The problem with a fast-paced course is that I keep hitting topics I want to dig into but am forced to move on. Simulation is fascinating, and I need to spend more time with its history and nuance. I guess that just means I’m going to add it to the syllabus of my next graduate course.1

But I wanted to post about one fun thing I learned this week that, while not directly related to simulation, does seem to have some broader lessons. I came to better appreciate John Doyle’s structured singular value, often called by its Greek name “𝜇” or “mu.” The lessons it teaches about interconnection and uncertainty, though perhaps not always computable, are quite general and important.

Let’s go back to the recurring simple feedback loop.

Here, C is the controller we’re designing, P is the plant we’re trying to steer. I’ve added a new block, Δ, to represent some uncertain system in our feedback loop. When Δ equals zero, we have our nominal system model. The structured singular value asks the following question: if I have a design that works without uncertainty, how much margin for error do I have? How large can Δ be before the system goes unstable?

A standard problem in linear control models Δ as a simple scalar. In that case, because of how the equations work out, the uncertainty question is about the gain margin of the linear system. How much can you amplify or attenuate the plant before the closed-loop system goes unstable? Asked another way, how well do you need to know the amplification factor to guarantee stable operation? Or, let’s say you have a bunch of plants that all have reasonably similar dynamics but different gains. Is your controller good enough for all of them? The uncertainty could model the mass of a flying vehicle or the insulin sensitivity of a person with diabetes. Steady-state control of both of these systems relies on some robustness to uncertainty.

One of the classic results about the linear quadratic regulator is that its stability is maintained for any Δ between -½ and infinity. That’s a good gain margin! Many other control design techniques from classical control using Nyquist plots can also guarantee large gain margins for single-input, single-output systems.

However, the problem becomes a lot trickier when you need to control a plant with many inputs and outputs. Most control systems are networks of interconnected feedback loops, not just simple single-input, single-output systems. In my favorite control system, the espresso machine, you might have a PID controller for water temperature and another for water pressure. You could calibrate these by tuning each PID parameter, one at a time. But obviously, these two loops interact with each other. They also interact with your grind and your tamping.

An industrial process, a chemical plant, or a robot has a networked control system of far greater complexity. You might be able to write out performance guarantees for each loop in the system, and that might look fine on its face. But if these loops are coupled, your margin calculations might be misleading.

To see why, we can look at a static example, like we did with the feedback amplifier. Imagine we’re trying to get a plant to track a constant reference signal. The controller compares the reference signal with the plant’s output and applies a new input if the difference is large. This signal sets a different set point for each loop. We can compute the steady state of our system by looking at a matrix equation. Indeed, slightly abusing notation, we can think of the steady-state maps C, P, and Δ as matrices (these are the DC responses of each system). The map from the error signal input of the controller, e, to the output of the uncertainty, y, is a system of equations:

Using the fact that the error is the difference between the reference and the output, e = r - y, we can compute the steady-state output as a function of the reference signal. It’s not the prettiest formula, but you can write it out in closed form and stare at it:

If the open-loop map from the controller input to plant output — the matrix (I+Δ) PC — is sufficiently large, the output of the plant will be approximately equal to the reference input. However, there’s a catch. We need to know that matrix never has an eigenvalue of -1 for any instantiation of the uncertainty. If it does, then the inverse in the above matrix expression isn’t defined, and the expression blows up in unpleasant ways. We’d say the closed-loop system was unstable.

Hence, we can capture a notion of multivariate robustness by finding the smallest perturbation that makes that matrix singular. The tricky part is that you get different answers based on what sorts of uncertainties you believe are plausible.

Consider the classic gain margin question. For simplicity, define the matrix

When Δ is a scalar, you are just looking for the smallest number such that

This number is precisely equal to the inverse of the magnitude of the largest eigenvalue of T. By contrast, if you think that you can have uncertainty that couples channels of your system together, the size of the uncertainty you can handle is much smaller. Indeed, you can check that if you allow for the uncertainty to be an arbitrary matrix, the norm of the uncertainty has to be smaller than the inverse of the magnitude of the largest singular value of T.

Singular values are always larger than eigenvalues. Sometimes, they can be much larger. For instance if

Then the eigenvalues of T are ½, and the maximum singular value of T is approximately 250. If the uncertainties were just a multiple of the identity, it would appear very robust to perturbations, handling disturbances with gains up to a magnitude of 2. However, if general matrix uncertainty were allowed, you could only handle disturbances with gains of magnitude at most 0.004.

The structured singular value lets you figure out what this magnitude is for whatever plausible model of uncertainty you can construct. Maybe only a subset of the loops is coupled. Maybe Δ has block structure. Each structure gives you a different number in between the spectral radius and the norm of your system’s complementary sensitivity, T. The structured singular value generalizes beyond this simple matrix example to general linear systems. It lets you compute bounds even when the uncertain blocks are themselves structured dynamical systems.

For people designing mission-critical linear feedback systems, you should learn all of the details. For everyone else who is stuck with nonlinear systems, there are still lessons to take away. Nonlinearity seldom makes our lives easier! If a robustness problem presents itself when we look at simple linear instances, we shouldn’t just hope that it’s not there on hard nonlinear ones. This is one of the reasons that in our post-math age of YOLO scaling, it’s useful to learn a little bit of math to be a little bit chastened. Though I suppose if you do it that way, you’ll never make a dime.

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By Ben Recht

Authors: Antonio Lauerbach, Konstanty Junosza-Szaniawski, Marie Diana Sieper, Alexander Wolff

A mixed graph contains (undirected) edges as well as (directed) arcs, thus generalizing undirected and directed graphs. A proper coloring c of a mixed graph G assigns a positive integer to each vertex such that c(u)!=c(v) for every edge {u,v} and c(u)

Authors: Quentin Buzet, André Chailloux

The 2-Forrelation problem provides an optimal separation between classical and quantum query complexity and is also the problem used for separating $\mathsf{BQP}$ and $\mathsf{PH}$ relative to an oracle. A natural question is therefore to ask what are the minimal quantum resources needed to solve this problem. We show that 2-Forrelation can be solved using Instantaneous Quantum Polynomial-time ($\mathsf{IQP}$) circuits, a restricted model of quantum computation in which all gates commute. Concretely, two $\mathsf{IQP}$ circuits with two quantum queries and efficient classical processing suffice. For the signed variant of 2-Forrelation, even a single $\mathsf{IQP}$ circuit and query suffices. This answers a recent open question of Girish (arXiv:2510.06385) on the power of commuting quantum computations. We use this to show that $(\mathsf{BPP}^{\mathsf{IQP}})^O \not\subseteq \mathsf{PH}^O$ relative to an oracle $O$, strengthening the result of Raz and Tal (STOC 2019). Our results show that $\mathsf{IQP}$ circuits can be used for classically hard decision problems, thus providing a new route for showing quantum advantage with $\mathsf{IQP}$ circuits, avoiding the verification difficulties associated with sampling tasks. We also prove Fourier growth bounds for $\mathsf{IQP}$ circuits in terms of the size of their accepting set. The key ingredient is an algebraic identity of the quadratic function $Q(x) = \sum_{i < j} x_ix_j$ that allows extracting inner-product phases within an $\mathsf{IQP}$ circuit.

Authors: Rohan Goyal, Venkatesan Guruswami, Jun-Ting Hsieh

The subspace design property for additive codes is a higher-dimensional generalization of the minimum distance property. As shown recently by Brakensiek, Chen, Dhar and Zhang, it implies that the code has similar performance as random linear codes with respect to all "local properties". Explicit algebraic codes, such as folded Reed-Solomon and multiplicity codes, are known to have the subspace design property, but they need alphabet sizes that grow as a large polynomial in the block length. Constructing explicit constant-alphabet subspace design codes was subsequently posed as an open question in Brakensiek, Chen, Dhar and Zhang. In this work, we answer their question and give explicit constructions of subspace design codes over constant-sized alphabets, using the expander-based Alon-Edmonds-Luby (AEL) framework. This generalizes the recent work of Jeronimo and Shagrithaya, which showed that such codes share local properties of random linear codes. Our work obtains this consequence in a unified manner via the subspace design property. In addition, our approach yields some improvements in parameters for list-recovery.

Authors: Enrico Formenti, Eric Goles, Kévin Perrot, Martín Ríos-Wilson, Domingo Ruiz-Tala

Fungal automata are a nature-inspired computational model, where a rule is alternatively applied verticaly and horizontaly. In this work we study the computational complexity of predicting the dynamics of all fungal freezing totalistic one-dimentional rules of radius $1$, exhibiting various behaviors. Despite efficiently predictable in most cases (with non-deterministic logspace algorithms), a non-linear rule is left open to characterize. We further explore the freezing majority rule (which is totalistic), and prove that at radius $1.5$ it becomes $\mathbf{P}$-complete to predict.

Authors: Zicheng Han, Yupeng Lin, Jie Ma, Xiande Zhang

We develop a hypergraph container method for the Boolean Satisfiability Problem (SAT) via the newly developed container results [Campos and Samotij (2024)]. This provides an explicit connection between the extent of spread of clauses and the efficiency of container-based algorithms. Informally, the more evenly the clauses are distributed, the stronger the shrinking effect of the containers, which leads to faster algorithms for SAT. To quantify the extent of spread, we use a weighted point of view, in which a clause of size $s$ receives weight $p^s$ for some $0

Authors: Nikola Zubić, Qian Li, Yuyi Wang, Davide Scaramuzza

We study the expressive power and limitations of multi-layer state-space models (SSMs). First, we show that multi-layer SSMs face fundamental limitations in compositional tasks, revealing an inherent gap between SSMs and streaming models. Then, we examine the role of chain-of-thought (CoT), showing that offline CoT does not fundamentally increase the expressiveness, while online CoT can substantially increase its power. Indeed, with online CoT, multi-layer SSMs become equivalent in power to streaming algorithms. Finally, we investigate the tradeoff between width and precision, showing that these resources are not interchangeable in the base model, but admit a clean equivalence once online CoT is allowed. Overall, our results offer a unified perspective on how depth, finite precision, and CoT shape the power and limits of SSMs.

Authors: Ravi Kini, David Doty

Chemical reaction networks, or CRNs, are known to stably compute semilinear Boolean-valued predicates and functions, provided that all reactions are irreversible. However, this property does not hold for wet-lab implementations, as all chemical reactions are reversible, even at very slow rates. We study the computational power of CRNs under the reverse-robust computation model, where reactions are permitted to occur either in forward or in reverse up to a cutoff point, after which they may only occur in forward. Our main results show that all semilinear predicates and all semilinear functions can be computed reverse-robustly, and in fact, that existing constructions continue to hold under the reverse-robust computational model. A key tool used to prove correctness under the reverse-robust computation model is invariants: linear (or linear modulo some $m$) combinations of the counts of the species that are preserved by all reactions.

Authors: Jaehoon Chung

We study a variant of a polygon partition problem, introduced by Chung, Iwama, Liao, and Ahn [ISAAC'25]. Given orthogonal unit vectors $\mathbf{u},\mathbf{v}\in \mathbb{R}^2$ and a polygon $P$ with $n$ vertices, we partition $P$ into connected pieces by cuts parallel to $\mathbf{v}$ such that each resulting subpolygon has width at most one in direction $\mathbf{u}$. We consider the value version, which asks for the minimum number of strips, and the reporting version, which outputs a compact encoding of the cuts in an optimal strip partition. We give efficient algorithms and lower bounds for both versions on three classes of polygons of increasing generality: convex, simple, and self-overlapping. For convex polygons, we solve the value version in $O(\log n)$ time and the reporting version in $O\!\left(h \log\left(1 + \frac{n}{h}\right)\right)$ time, where $h$ is the width of $P$ in direction $\mathbf{u}$. We prove matching lower bounds in the decision-tree model, showing that the reporting algorithm is input-sensitive optimal with respect to $h$. For simple polygons, we present $O(n \log n)$-time, $O(n)$-space algorithms for both versions and prove an $Ω(n)$ lower bound. For self-overlapping polygons, we extend the approach for simple polygons to obtain $O(n \log n)$-time, $O(n)$-space algorithms for both versions, and we prove a matching $Ω(n \log n)$ lower bound in the algebraic computation-tree model via a reduction from the $δ$-closeness problem. Our approach relies on a lattice-theoretic formulation of the problem. We represent strip partitions as antichains of intervals in the Clarke--Cormack--Burkowski lattice, originally developed for minimal-interval semantics in information retrieval. Within this lattice framework, we design a dynamic programming algorithm that uses the lattice operations of meet and join.

Authors: Bingwei Zhang, Thomas Chen, Kai Hormann, Chee Yap

Range functions are a fundamental tool for certified computations in geometric modeling, computer graphics, and robotics, but traditional range functions have only quadratic convergence order ($m=2$). For ``superior'' convergence order (i.e., $m>2$), we exploit the Cornelius--Lohner framework in order to introduce new bivariate range functions based on Taylor, Lagrange, and Hermite interpolation. In particular, we focus on practical range functions with cubic and quartic convergence order. We implemented them in Julia and provide experimental validation of their performance in terms of efficiency and efficacy.

Authors: Nguyen Phan, Brian Kim, Adeel Zafar, Guoning Chen

Streamlines have been widely used to represent and analyze various steady vector fields. To sufficiently represent important features in complex vector fields (like flow), a large number of streamlines are required. Due to the lack of a rigorous definition of features or patterns in streamlines, user interaction and exploration are required to achieve effective interpretation. Existing approaches based on clustering or pattern search, while valuable for specific analysis tasks, often face challenges in supporting interactive and level-of-detail exploration of large-scale curve-based data, particularly when real-time parameter adjustment and iterative refinement are needed. To address this, we design and implement an interactive web-based system. Our system utilizes a Curve Segment Neighborhood Graph (CSNG) to encode the neighboring relationships between curve segments. CSNG enables us to adapt a fast community detection algorithm to identify coherent flow structures and spatial groupings in the streamlines interactively. CSNG also supports a multi-level exploration through an enhanced force-directed layout. Furthermore, our system integrates an adjacency matrix representation to reveal detailed inter-relations among segments. To achieve real-time performance within a web browser, our system employs matrix compression for memory-efficient CSNG storage and parallel processing. We have applied our system to analyze and interpret complex patterns in several streamline datasets. Our experiments show that we achieve real-time performance on datasets with hundreds of thousands of segments.

Authors: Minati De, Satyam Singh

In the classical online model, the maximum independent set problem admits an $Ω(n)$ lower bound on the competitive ratio even for interval graphs, motivating the study of the problem under additional assumptions. We first study the problem on graphs with a bounded independent kissing number $ζ$, defined as the size of the largest induced star in the graph minus one. We show that a simple greedy algorithm, requiring no geometric representation, achieves a competitive ratio of $ζ$. Moreover, this bound is optimal for deterministic online algorithms and asymptotically optimal for randomized ones. This extends previous results from specific geometric graph families to more general graph classes. Since this bound rules out further improvements through randomization alone, we investigate the power of randomization with access to geometric representation. When the geometric representation of the objects is known, we present randomized online algorithms with improved guarantees. For unit ball graphs in $\mathbb{R}^3$, we present an algorithm whose expected competitive ratio is strictly smaller than the deterministic lower bound implied by the independent kissing number. For $α$-fat objects and for axis-aligned hyper-rectangles in $\mathbb{R}^d$ with bounded diameters, we obtain algorithms with expected competitive ratios that depend polylogarithmically on the ratio between the maximum and minimum object diameters. In both cases, the randomized lower bound implied by the independent kissing number grows polynomially with the ratio between the maximum and minimum object diameters, implying substantial performance guarantees for our algorithms.