Kraus Constrained Sequence Learning For Quantum Trajectories from Continuous Measurement
- URL: http://arxiv.org/abs/2603.05468v1
- Date: Thu, 05 Mar 2026 18:37:05 GMT
- Title: Kraus Constrained Sequence Learning For Quantum Trajectories from Continuous Measurement
- Authors: Priyanshi Singh, Krishna Bhatia,
- Abstract summary: We propose a Kraus-structured output layer that converts the hidden representation of a generic sequence backbone into a positive trace preserving (CPTP) quantum operation.<n>Across all models, Kraus-LS achieves the strongest results, improving state estimation quality by 7% over its unconstrained counterpart.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Real-time reconstruction of conditional quantum states from continuous measurement records is a fundamental requirement for quantum feedback control, yet standard stochastic master equation (SME) solvers require exact model specification, known system parameters, and are sensitive to parameter mismatch. While neural sequence models can fit these stochastic dynamics, the unconstrained predictors can violate physicality such as positivity or trace constraints, leading to unstable rollouts and unphysical estimates. We propose a Kraus-structured output layer that converts the hidden representation of a generic sequence backbone into a completely positive trace preserving (CPTP) quantum operation, yielding physically valid state updates by construction. We instantiate this layer across diverse backbones, RNN, GRU, LSTM, TCN, ESN and Mamba; including Neural ODE as a comparative baseline, on stochastic trajectories characterized by parameter drift. Our evaluation reveals distinct trade-offs between gating mechanisms, linear recurrence, and global attention. Across all models, Kraus-LSTM achieves the strongest results, improving state estimation quality by 7% over its unconstrained counterpart while guaranteeing physically valid predictions in non-stationary regimes.
Related papers
- Continual Quantum Architecture Search with Tensor-Train Encoding: Theory and Applications to Signal Processing [68.35481158940401]
CL-QAS is a continual quantum architecture search framework.<n>It mitigates challenges of costly encoding amplitude and forgetting in variational quantum circuits.<n>It achieves controllable robustness expressivity, sample-efficient generalization, and smooth convergence without barren plateaus.
arXiv Detail & Related papers (2026-01-10T02:36:03Z) - Hybrid Quantum-Classical Recurrent Neural Networks [0.10152838128195468]
We present a hybrid quantum-classical recurrent neural network architecture.<n>The hidden state is the quantum state of an $n$-qubit quantum circuit (PQC) controlled by a classical feedforward network.<n>We evaluate the model in simulation with up to 14 qubits on sentiment analysis, MNIST, permuted MNIST, copying memory, and language modeling.
arXiv Detail & Related papers (2025-10-29T14:21:49Z) - Towards Quantum Enhanced Adversarial Robustness with Rydberg Reservoir Learning [45.92935470813908]
Quantum computing reservoir (QRC) leverages the high-dimensional, nonlinear dynamics inherent in quantum many-body systems.<n>Recent studies indicate that perturbation quantums based on variational circuits remain susceptible to adversarials.<n>We investigate the first systematic evaluation of adversarial robustness in a QR based learning model.
arXiv Detail & Related papers (2025-10-15T12:17:23Z) - Parameter Estimation for Jump-Diffusion Stochastic Master Equations [9.167963523963936]
This paper investigates parameter estimation for open quantum systems under continuous observation.<n>We first establish the existence and well-posedness of a reduced quantum filter.<n>We extend the stability theory of quantum filters, showing that exponential convergence persists under mismatched initial states.
arXiv Detail & Related papers (2025-09-24T08:09:06Z) - Quantum Filtering and Stabilization of Dissipative Quantum Systems via Augmented Neural Ordinary Differential Equations [5.819937157229223]
AQNODE is a framework that learns quantum trajectories and dissipation parameters directly from measurement data.<n>Our approach integrates weak measurement data to reconstruct qubit states and time-dependent decoherence rates.<n> AQNODE is a scalable, differentiable, and experimentally compatible framework for real-time modeling and control of dissipative quantum systems.
arXiv Detail & Related papers (2025-09-08T20:23:45Z) - A Simple Approximate Bayesian Inference Neural Surrogate for Stochastic Petri Net Models [0.0]
We introduce a neural-network-based approximation of the posterior distribution framework.<n>Our model employs a lightweight 1D Convolutional Residual Network trained end-to-end on Gillespie-simulated SPN realizations.<n>On synthetic SPNs with 20% missing events, our surrogate recovers rate-function coefficients with an RMSE = 0.108 and substantially runs faster than traditional Bayesian approaches.
arXiv Detail & Related papers (2025-07-14T18:31:19Z) - Grassmann Variational Monte Carlo with neural wave functions [45.935798913942904]
We formalize the framework introduced by Pfau et al.citepfau2024accurate in terms of Grassmann geometry of the Hilbert space.<n>We validate our approach on the Heisenberg quantum spin model on the square lattice, achieving highly accurate energies and physical observables for a large number of excited states.
arXiv Detail & Related papers (2025-07-14T13:53:13Z) - Efficient Transformed Gaussian Process State-Space Models for Non-Stationary High-Dimensional Dynamical Systems [49.819436680336786]
We propose an efficient transformed Gaussian process state-space model (ETGPSSM) for scalable and flexible modeling of high-dimensional, non-stationary dynamical systems.<n>Specifically, our ETGPSSM integrates a single shared GP with input-dependent normalizing flows, yielding an expressive implicit process prior that captures complex, non-stationary transition dynamics.<n>Our ETGPSSM outperforms existing GPSSMs and neural network-based SSMs in terms of computational efficiency and accuracy.
arXiv Detail & Related papers (2025-03-24T03:19:45Z) - A Poisson-Gamma Dynamic Factor Model with Time-Varying Transition Dynamics [51.147876395589925]
A non-stationary PGDS is proposed to allow the underlying transition matrices to evolve over time.
A fully-conjugate and efficient Gibbs sampler is developed to perform posterior simulation.
Experiments show that, in comparison with related models, the proposed non-stationary PGDS achieves improved predictive performance.
arXiv Detail & Related papers (2024-02-26T04:39:01Z) - Symmetric Pruning in Quantum Neural Networks [111.438286016951]
Quantum neural networks (QNNs) exert the power of modern quantum machines.
QNNs with handcraft symmetric ansatzes generally experience better trainability than those with asymmetric ansatzes.
We propose the effective quantum neural tangent kernel (EQNTK) to quantify the convergence of QNNs towards the global optima.
arXiv Detail & Related papers (2022-08-30T08:17:55Z) - Realizing a dynamical topological phase in a trapped-ion quantum
simulator [0.0]
Nascent platforms for programmable quantum simulation offer unprecedented access to new regimes of far-from-equilibrium quantum many-body dynamics.
We show how to create, protect, and manipulate quantum entanglement that self-correct against large classes of errors.
Our work paves the way for implementation of more complex dynamical topological orders that would enable error-resilient techniques to manipulate quantum information.
arXiv Detail & Related papers (2021-07-20T18:00:00Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.