From quantum to quantum-inspired: the LogQ algorithm as a non-linear continuous relaxation of variables method

J\'er\'emie Messud; Yagnik Chatterjee

arxiv: 2604.12925 · v1 · submitted 2026-04-14 · 🧮 math.OC

From quantum to quantum-inspired: the LogQ algorithm as a non-linear continuous relaxation of variables method

J\'er\'emie Messud , Yagnik Chatterjee This is my paper

Pith reviewed 2026-05-10 14:42 UTC · model grok-4.3

classification 🧮 math.OC

keywords logqoptimizationquantumclassicalalgorithmcomputingcontinuousdecomposition

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The pith

LogQ is recast as a novel classical non-linear continuous relaxation heuristic for solving QUBO problems, removing all quantum requirements.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

QUBO problems require finding the best combination of binary choices to minimize a cost function that includes both individual and pairwise terms. These arise in practical applications such as optimizing investment portfolios or scheduling vehicle fleets. The LogQ algorithm was initially developed for quantum computers to tackle these problems more efficiently by using fewer qubits and shallower circuits than traditional quantum approaches. Recent work made it compatible with gradient-based optimization to tune its parameters better. However, it still required breaking the problem into Pauli operators for quantum implementation and dealing with measurement overhead. The current work reformulates the entire LogQ procedure as a classical algorithm. It achieves this by applying a non-linear continuous relaxation to the binary variables, allowing the optimization to proceed using standard classical techniques without any quantum elements. This bypasses the quantum-specific steps entirely. The authors position this as a new classical heuristic method. The approach highlights a pathway where efforts to create quantum algorithms can yield standalone classical methods that are easier to implement on conventional hardware.

Core claim

We here demonstrate that LogQ can be fully reformulated within a classical framework, which effectively eliminates the need for Pauli decomposition and bypasses the measurement challenges altogether. This finally leads to a classical heuristic based on a non-linear continuous relaxation of variables and is, to the best of our knowledge, novel.

Load-bearing premise

That the non-linear continuous relaxation of variables preserves the essential optimization properties and performance of the original LogQ algorithm when applied to QUBO problems.

read the original abstract

The LogQ algorithm encodes Quadratic Unconstrained Binary Optimization (QUBO) problems, which are often encountered in the industry (portfolio optimization, fleet optimization, charging stations, etc.). It was developed within the framework of quantum computing, designed as a pragmatic approach to quantum combinatorial optimization that drastically reduces the number of required qubits and quantum circuit depth. While LogQ has recently been made compliant with gradient-inspired methods, greatly improving parameter optimization efficiency, it still faced hurdles regarding Pauli decomposition and measurement overhead. We here demonstrate that LogQ can be fully reformulated within a classical framework, which effectively eliminates the need for Pauli decomposition and bypasses the measurement challenges altogether. This finally leads to a classical heuristic based on a non-linear continuous relaxation of variables and is, to the best of our knowledge, novel. The LogQ story illustrates how quantum computing can inspire classical algorithms, leading to so-called "quantum-inspired" methods.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

The paper recasts the LogQ algorithm as a classical non-linear continuous relaxation for QUBO problems, dropping the quantum overhead while claiming the same optimization behavior.

read the letter

The core move is straightforward: take the earlier LogQ method for QUBO instances that show up in portfolio and fleet problems, rewrite the binary variables via a non-linear continuous relaxation, and remove Pauli decomposition plus measurement steps entirely. The abstract lays this out cleanly and notes that the result is a classical heuristic. That reformulation step itself is the new piece, and the stress-test note is right that no obvious circularity or inconsistency appears in the claim on its own terms. The authors also reference their prior gradient-inspired update, which already improved parameter handling, so the classical version builds on that work in a logical way. Credit for keeping the industrial motivation front and center without overclaiming a field-wide shift. The soft spot is the missing substance. The abstract states the reformulation but shows no equations for how the relaxation is constructed, no derivation, and no benchmark numbers on standard QUBO sets. Without those, it is impossible to check whether the classical version actually retains the original performance or just approximates it in a weaker way. The weakest assumption flagged in the report, that essential properties carry over, is exactly where the evidence gap sits. This is for readers already working on quantum-inspired or classical heuristics for binary optimization who want a simpler implementation path. Someone tracking QUBO solvers or variational methods might pick up the reformulation idea as a starting point. I would send it to peer review so the authors can supply the math and results for proper checking.

Referee Report

2 major / 0 minor

Summary. The manuscript claims that the LogQ algorithm for QUBO problems, originally developed in a quantum computing framework to reduce qubit count and circuit depth, admits an exact classical reformulation as a non-linear continuous relaxation of the binary variables. This reformulation is asserted to eliminate Pauli decomposition and measurement overhead entirely while preserving the original algorithm's optimization behavior, yielding a novel classical heuristic.

Significance. If the claimed exact equivalence holds and the resulting heuristic retains competitive performance on QUBO instances, the work would be significant: it would furnish a concrete example of a quantum-inspired classical method that removes all quantum-specific costs while addressing industrially relevant problems such as portfolio and fleet optimization. The absence of any derivation, equations, or verification in the manuscript, however, prevents evaluation of whether the non-linear relaxation actually preserves essential properties.

major comments (2)

[Abstract] Abstract: the central claim that LogQ 'can be fully reformulated within a classical framework' and 'leads to a classical heuristic based on a non-linear continuous relaxation of variables' is stated without any supporting derivation, change-of-variables map, or proof of equivalence to the original quantum formulation. This is load-bearing for the entire contribution.
[Abstract] Abstract and main text: no numerical experiments, benchmark comparisons against established classical QUBO solvers (e.g., Gurobi, simulated annealing, or SDP relaxations), or verification that the continuous relaxation reproduces the original LogQ solution quality or convergence behavior are provided, leaving the performance-preservation assumption untested.

Axiom & Free-Parameter Ledger

0 free parameters · 0 axioms · 0 invented entities

Only the abstract is available; no specific free parameters, axioms, or invented entities are detailed in the provided text.

pith-pipeline@v0.9.0 · 5463 in / 1069 out tokens · 50666 ms · 2026-05-10T14:42:25.300347+00:00 · methodology

From quantum to quantum-inspired: the LogQ algorithm as a non-linear continuous relaxation of variables method

Core claim

Load-bearing premise

discussion (0)