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State Space Representation01:27

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The frequency-domain technique, commonly used in analyzing and designing feedback control systems, is effective for linear, time-invariant systems. However, it falls short when dealing with nonlinear, time-varying, and multiple-input multiple-output systems. The time-domain or state-space approach addresses these limitations by utilizing state variables to construct simultaneous, first-order differential equations, known as state equations, for an nth-order system.
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An experiment often consists of more than a single step. In this case, measurements at each step give rise to uncertainty. Because the measurements occur in successive steps, the uncertainty in one step necessarily contributes to that in the subsequent step. As we perform statistical analysis on these types of experiments, we must learn to account for the propagation of uncertainty from one step to the next. The propagation of uncertainty depends on the type of arithmetic operation performed on...
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The atomic mass of an element varies due to the relative ratio of its isotopes. A sample's relative proportion of oxygen isotopes influences its average atomic mass. For instance, if we were to measure the atomic mass of oxygen from a sample, the mass would be a weighted average of the isotopic masses of oxygen in that sample. Since a single sample is not likely to perfectly reflect the true atomic mass of oxygen for all the molecules of oxygen on Earth, the mass we obtain from this...
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Entropy, a measure of disorder in a system, changes during phase transitions like freezing or boiling. At the transition temperature Ttrs, where two phases are in equilibrium, the phase transition is a reversible process. The entropy change can be calculated from a substance's enthalpy of transition using the equation ΔStrs = ΔtrsH /Ttrs.When a perfect gas expands isothermally from one volume to another, entropy increases logarithmically with volume. Conversely, isothermal compression...
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Large Scale Energy Efficient Sensor Network Routing Using a Quantum Processor Unit
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Quantum-informed machine learning for predicting spatiotemporal chaos with practical quantum advantage.

Maida Wang1, Xiao Xue1, Mingyang Gao1

  • 1Centre for Computational Science, University College London, London, UK.

Science Advances
|April 17, 2026
PubMed
Summary
This summary is machine-generated.

Quantum-informed machine learning (QIML) models chaotic systems using a quantum prior for improved accuracy and memory efficiency. This framework enhances long-term predictions in complex fluid dynamics simulations.

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Area of Science:

  • Computational physics
  • Quantum machine learning
  • Fluid dynamics

Background:

  • Modeling high-dimensional chaotic systems is computationally challenging.
  • Classical methods struggle with long-term prediction accuracy and fine-scale dynamics.
  • Integrating quantum computing principles can enhance machine learning models.

Purpose of the Study:

  • Introduce a quantum-informed machine learning (QIML) framework.
  • Improve long-term modeling of high-dimensional chaotic systems.
  • Leverage quantum generative models for enhanced predictive capabilities.

Main Methods:

  • Developed a QIML framework combining a quantum generative model and a classical autoregressive predictor.
  • The quantum model learns a quantum prior (Q-Prior) to guide small-scale interactions.
  • Evaluated QIML on Kuramoto-Sivashinsky, 2D Kolmogorov flow, and 3D turbulent channel flow.

Main Results:

  • QIML improved predictive distribution accuracy by up to 17.25% and full-spectrum fidelity by up to 29.36% over classical baselines.
  • For turbulent channel inflow, QIML produced stable, physically consistent forecasts outperforming PDE solvers.
  • The Q-Prior, trained on a quantum processor, was essential for prediction stability and accuracy.

Conclusions:

  • QIML framework effectively models long-term behavior of chaotic systems.
  • Quantum priors enhance predictive accuracy and stability in complex simulations.
  • QIML offers significant memory compression and scalable integration of quantum resources for scientific modeling.