Correlation imaging (CI) is an emerging approach to imaging aimed at overcoming the limitations of conventional, intensity-based imaging modalities.
Le projet ADEQUADE s’inscrit dans le cadre des ruptures technologiques soutenues par le Fonds européen de défense.
The rapid progress in quantum sensing enables a number of defense and security related applications in the near future. Sensors based on Nitrogen-vacancy centers (NVC) in diamond provide a high
Quantum Ghost Imaging (QGI) is an imaging method based on entangled photon pairs. Current setups use gated cameras, which limit the setup to applications in Transmission.
We propose and demonstrate a direct volumetric imaging method based on spatial coherence of light and sequential illumination from pointlike sources distributed along a ring.
The paradigm of quantum metrology and sensing aims to identify a quantum advantage in precision at a fixed energy of the probe state.
Dual-comb spectroscopy is one of the most powerful techniques for multispecies trace-gas sensing, attracting growing attention in both theoretical and experimental research.
We have developed a silicon nitride-based photonic integrated circuit (PIC) that is responsible for the cooling, pumping, and imaging of cold rubidium 87 atoms.
Correlation-based imaging techniques rely on the statistical properties of partially coherent light sources. Simulating such systems is increasingly important for the design and optimization of imaging setups, the validation of
We present an advanced quantum ghost imaging (QGI) setup that enables low-noise, three-dimensional imaging and ranging of distant objects.
We present an advanced quantum ghost imaging (QGI) setup that enables low-noise, three-dimensional imaging and ranging of distant objects.
We present an advanced quantum ghost imaging (QGI) setup that enables low-noise, three-dimensional imaging and ranging of distant objects.