The goal of the LENA project is to investigate new data analysis methods based on non-linear signal processing, with applications to challenges in Astrophysics. In this particular, we will mainly focus on solving inverse problems for multivalued (e.g. multispectral/hyperspectral) signal and imaging processing, which are central in a large number of astrophysical applications. These models and methods will take their roots in recent advances in applied mathematics: sparse signal modelling, proximal algorithms and machine learning. It will allow extending sparse models and methods to the non-linear world. These developments will further provide a bridge between signal processing and machine learning providing new approaches to model and restore signal and image beyond the standard linear methods.
These algorithms will be deployed to the following applications in Astrophysics:
- A new look at the Planck data: the ability to use sparse non-linear physical models in addition to effective numerical algorithms will allow for a precise decomposition of the sky seen by Planck into its elementary constituents: CMB, SZ, galactic emissions, etc.
-With the current LoFAR project and the advent of the next generation large radio-telescopes such as SKA, fundamental signals such as the cosmological signal at the epoch or reionization (EoR signal) will be accessible. However, this requires designing highly effective component separation methods, which share strongly similarities with the ones we are developing for Planck.
-Euclid is the next European space telescope that will be able to investigating the distribution and nature of the so-called Dark Matter. This type of matter is not observed directly but via the weak gravitational lensing effect, which is measured by evaluating the shape of observed galaxies. However, these measures are highly tricky measure: they are tiny and highly sensitive to all sorts of instrumental effects and noise. In this context, the numerical tools developed in the LENA project are expected to significantly improve the estimation of the lensing effect.