SubsidieMeestersEfficient Verification of Quantum computing architectures with Bosons
VeriQuB aims to develop a novel verification method for bosonic quantum computing architectures using continuous-variable measurements to enable scalable and fault-tolerant systems.
Projectdetails
Introduction
Quantum devices offer great promise for computation, cryptography, communication, and sensing. Alternative approaches to quantum information processing in which bosonic modes are the carriers of information have attracted increasing attention, because they offer a hardware-efficient path to fault-tolerance and scalability thanks to their inherently large Hilbert space.
Problem Statement
However, this poses the problem of providing rigorous guarantees of the correct functioning of these promising bosonic architectures, a task known as quantum verification. To date, this verification is performed by general-purpose tomographic techniques, which rapidly become intractable for large quantum systems. Thus, other methods are needed as quantum devices are scaled up to achieve real-world advantages.
Project Overview
VeriQuB will introduce a new approach to the verification of quantum computing architectures with bosons based on continuous-variable measurements. VeriQuB's technological toolbox will comprise two main elements:
- We will experimentally demonstrate the verification of multi-mode bosonic systems for optical and superconducting architectures well beyond the state-of-the-art, and provide the first demonstration of verified quantum computational speedup.
- We will develop a theory framework that defines the fundamental advantages of our contribution, putting special emphasis on identifying and verifying resourceful bosonic quantum devices.
Consortium
The VeriQuB consortium comprises world-leading scientific partners who are ideally positioned to achieve the ambitious vision of this project and build a state-of-the-art verification technology toolbox, enabling bosonic quantum computing architectures to scale up, and positioning Europe as a leader in this domain.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 3.983.635 |
| Totale projectbegroting | € 3.984.885 |
Tijdlijn
| Startdatum | 1-9-2023 |
| Einddatum | 31-8-2027 |
| Subsidiejaar | 2023 |
Partners & Locaties
Projectpartners
- INSTITUT NATIONAL DE RECHERCHE EN INFORMATIQUE ET AUTOMATIQUEpenvoerder
- CHALMERS TEKNISKA HOGSKOLA AB
- SORBONNE UNIVERSITE
- UNIVERSITA DEGLI STUDI DI MILANO
- CENTRE NATIONAL DE LA RECHERCHE SCIENTIFIQUE CNRS
Land(en)
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|---|---|---|---|---|
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The QUADRATURE project aims to develop scalable quantum computing architectures with distributed quantum cores and integrated wireless links to enhance performance and support diverse quantum algorithms.
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This project aims to develop a proof-of-concept for Quantum Reservoir Computing using Quantum Materials defects to create advanced computing devices and enhance Quantum Technologies.
Vergelijkbare projecten uit andere regelingen
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|---|---|---|---|---|
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Verifiying Noisy Quantum Devices at Scale
This project aims to develop scalable, secure methods for characterizing and certifying quantum devices using interactive proofs, facilitating reliable quantum computation and communication.
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This project aims to develop a high-coherence superconducting cavity qubit to enhance quantum computing reliability and efficiency through innovative error correction and design strategies.
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The project aims to develop advanced microwave photodetectors for high-resolution photon counting, enabling groundbreaking single-photon experiments and insights into quantum technology and many-body physics.
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ConceptQ aims to develop a novel superconducting qubit with high fidelity and power efficiency, enhancing quantum computing and enabling breakthroughs in various scientific applications.
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This project aims to develop a trapped-ion quantum processor utilizing multi-level qudits to enhance quantum information processing and achieve quantum advantage over classical systems.