Parameterized 4-Qubit EWL Quantum Game Circuits with Dirac-Solow-Swan Hamiltonian Integration for Quadruple Helix Disruptive Innovation Recommender Systems

Agung Trisetyarso; Fithra Faisal Hastiadi; Kridanto Surendro

arXiv:2605.18080·quant-ph·May 19, 2026

Parameterized 4-Qubit EWL Quantum Game Circuits with Dirac-Solow-Swan Hamiltonian Integration for Quadruple Helix Disruptive Innovation Recommender Systems

Agung Trisetyarso, Fithra Faisal Hastiadi, Kridanto Surendro

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TL;DR

This paper introduces a parameterized 4-qubit quantum game circuit designed for quadruple helix innovation ecosystems, integrating real funding data and Hamiltonian dynamics to forecast disruptive innovation trajectories efficiently.

Contribution

It presents a novel quantum circuit model that combines game theory, economic Hamiltonian simulation, and real-world funding data for innovation forecasting.

Findings

01

Demonstrates high-fidelity disruption prediction on real collaboration networks.

02

Achieves low gate count and circuit depth suitable for NISQ devices.

03

Bridges quantum computing with socio-economic innovation modeling.

Abstract

We present a novel parameterized 4-qubit Eisert-Wilkens-Lewenstein (EWL) quantum game circuit for recommender systems in quadruple helix innovation ecosystems (academia, industry, government, and civil society). The local strategy operators $U_{i} = R_{y} (θ_{i})$ for each helix actor are directly tuned by normalized dominance weights extracted from real participant funding data (\texit{ecContribution}) in the European Commission CORDIS Horizon Europe database (project COVend, ID 101045956). The circuit employs a multi-qubit EWL entangler followed by parameterized local rotations, inverse entangler, and full measurement, achieving only 22 gates and circuit depth 11 while scaling as $O (n)$ for $n$ -round helix communications. Measurement probabilities after the quantum game serve as recommender scores for disruptive versus sustaining innovation trends. These scores are subsequently…

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