Date/heure
17 mars 2025 - 18 mars 2025
Toute la journée
Catégorie d'évènement
Conférence
Venue:
« Salle de conférence » of the « Institut Élie Cartan de Lorraine: IECL », Nancy.
Objective:
The workshop is a moment of exchange between the Mathematics and Physics communities, specifically focusing on quantum control problems.
Organizers:
Alessandro DUCA, Killian LUTZ, Yannick PRIVAT
Senior speakers:
Gaspard BEUGNOT, Thomas CHAMBRION, Viviana GRASSELLI, Eugenio POZZOLI, Rémi ROBIN, Mario SIGALOTTI, and Dominique SUGNY.
Junior speakers:
Vincent HARDEL, Jean-Gabriel HARTMANN, Denis JANKOVIC and Killian LUTZ.
Planning Monday 17 March:
- 09H45 – 10H30 : Gaspard BEUGNOT
- 10H30 – 11H15 : Rémi ROBIN
- 11H15 – 11H35 : PAUSE
- 11H35 – 12H20 : Dominique SUGNY
- 13H00 – 14H30 : Lunch INRIA
- 14H30 – 15H15 : Viviana GRASSELLI
- 15H15 – 15H45 : Denis JANKOVIC
- 15H45 – 16H30 : COFFEE BREAK + DISCUSSION
- 16H30 – 17H00 : Jean-Gabriel HARTMANN
- 19H30 : Dinner at Café FOY
Planning Tuesday 18 March:
- 09H30 – 10H15 : Thomas CHAMBRION
- 10H15 – 10H45 : COFFEE BREAK
- 10H45 – 11H30 : Mario SIGALOTTI
- 11H30 – 12H00 : PAUSE
- 12H00 – 12H30 : Vincent HARDEL
- 13H00 – 14H30 : Lunch INRIA
- 14H30 – 15H15 : Eugenio POZZOLI
- 15H15 – 15H45 : Killian LUTZ
- 15H45 – : COFFEE BREAK
Abstracts :
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T. Chambrion
Title: Contrôle en temps petit des systèmes bilinéaires conservatifs en
dimension finieAbstract : on s’intéresse au temps nécessaire pour transférer un système
quantique fermé de dimension finie d’un état initial vers une cible
donnée. On fera le lien avec le contrôle en norme L^1 minimale pour de
tels systèmes et on en déduira des stratégies efficaces pour les cas où
les approximations riemanniennes usuelles sont inefficaces.
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V. Grasselli
Title: Semirelativistic Hartree equation and speed of propagationAbstract: We will consider the semirelativistic Hartree equation, which is the effective equation describing a boson star, a large group of gravitating bosons.
First, we will briefly describe under which conditions this non linear equation admits a global solution. Then we will study some dispersive properties of the solution, in particular how fast it propagates and its maximal and minimal velocities of propagation. These results are a joint work with Sébastien Breteaux and Jérémy Faupin.
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Vincent Hardel
Title: Classical analogs of quantum dynamics.
Abstract: Stochastic quantum mechanics offers a unique perspective on quantum phenomena by interpreting quantum dynamics through a stochastic lens reminiscent of Brownian motion. We will show how it is possible to use this mathematical framework to derive a classical analogy to quantum systems in the case of the harmonic oscillator, and how this analogy can be used to obtain an optimisation method to obtain protocols on the stiffness of the trap. Optimisation means that the protocols allow the transition between two equilibrium states in a minimum time while minimising a given cost function along the time evolution. The example of the dynamical phase is treated.
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Jean-Gabriel Hartmann
Title: Optimal control techniques for quantum computing with qudits.
Abstract: In this study, we investigate pulse-level optimal control techniques for quantum gates in qudit systems using the Givens Rotation Decomposition (GRD) and the GRAPE algorithm. These methods are evaluated using benchmark gates including the Quantum Fourier Transform (QFT), Grover’s Search Algorithm and Haar-random gates. In this talk we present some initial results of our numerical simulations, demonstrating the differences in performance between these approaches, as well as the robustness of each method to environmental noise and control errors. These results highlight the potential of qudits in offering competitive gate efficiencies, suggesting pathways for optimality in gate design as well as extensions to multi-qudit systems.
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Denis Jankovic
Titre: Gradient-based optimization of the PMP-informed generator of optimal pulses for qudit control.Abstract: This presentation explores a hybrid approach to designing control pulses for multi-level quantum systems (qudits). By combining Pontryagin’s Maximum Principle (PMP) with gradient-based optimization, we aim to guide the pulse-generation process more effectively. We discuss the theoretical foundations, outline the algorithmic framework, and present initial numerical results that suggest potential improvements in both accuracy and computational efficiency. The goal is to provide insight into how a PMP-informed strategy may offer a promising direction for quantum control of fast pulses.
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K. Lutz
Title: Estimations a priori pour la synthèse de porte logique optimal en temps et précision.Abstract: Quel temps incompressible est nécessaire à l’exécution d’un calcul quantique et quelle précision peut-on attendre de son résultat ? Ce travail porte sur le contrôle en dimension finie de l’équation de GKS-Lindblad modélisant la décohérence des états quantiques, une source d’erreurs de calculs.
En se restreignant à des contrôles bornés ponctuellement et étant donné une porte logique idéale, nous mettons en évidence l’existence d’un temps minimal de contrôle permettant son implémentation avec une précision maximale. Pour le contrôle correspondant, nous établissons des estimations a priori qui minorent et majorent à la fois le temps d’exécution et les erreurs de calculs. Ces estimations, explicites et facilement calculables à partir des données, permettent d’évaluer a posteriori la pertinence de contrôles obtenus par optimisation numérique.
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E. Pozzoli
Title: Small-time approximate controllability of bilinear Schrödinger equations and diffeomorphismsAbstract: We propose a new method to prove the global approximate controllability of bilinear Schrödinger PDEs posed on a manifold M. Contrarily to previous ones, it works in arbitrarily small time and does not require a discrete spectrum.
This approach consists in controlling separately the radial and the angular part of the wavefunction thanks to the control of the group of diffeomorphisms and the control of phases. The control of the radial part uses the transitivity of the group action of diffeomorphisms on positive densities proved by Moser.
We develop this approach on two examples of Schrödinger equations, posed tori and euclidean spaces, for which the small-time control of phases was recently proved by Duca and Nersesyan. We prove that it implies the small-time control of flows of vector fields thanks to Lie bracket techniques. Combining this property with the simplicity of the diffeomorphism group proved by Thurston, we obtain the result.
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R. Robin
Title: Numerical analysis of the Lindblad equationAbstract : In this talk, we will present recent advances in the numerical approximation of the Lindblad master equation, focusing on infinite-dimensional Hilbert spaces. After reviewing the key properties of the evolution of the Lindblad equation, we will discuss both spatial discretization using Galerkin approximations and temporal discretization methods. The first highlighted contribution is the introduction of an a posteriori error estimate. The second is the analysis of new structure-preserving time discretization schemes. These contributions are the result of joint works with Paul-Louis Etienney, Pierre Rouchon and Lev-Arcady Sellem.
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M. Sigalotti
Title: Eigenvalue intersections and controllabilityAbstract: Studying the spectrum of the Hamiltonian as a function of the control parameters plays a fundamental role in
establishing which states can be joined one to another by adiabatic control. More, generally,
conditions based on the behavior of the eigenvalue intersections can be used to establish operator controllability (not necessarily using adiabatic steering). In this talk we will present some results in this direction and also discuss how the spectrum can be used to deduce controllability when some control parameters are imposed to be constant.