Publications

Publication list with hyperlink 

As of 2024 June 21th, the project gathers:

21 conference publications and 11 refereed publications, and 2 defended PhD theses. 

Project overview publications

[1] SPEED: get ready for (PCS) rush hour

Martinez et al. ESO Messenger 2023 n°190

[2] The segmented pupil experiment for exoplanet detection VI. From early design to the first lights

Martinez et al. Proceeding of the SPIE 2022

[3] The segmented pupil experiment for exoplanet detection V. System control and software infrastructure 

Martinez et al. Proceeding of the SPIE 2022

[4] The segmented pupil experiment for exoplanet detection. IV. A versatile image-based wavefront sensor for active optics 

Martinez et al. Proceeding of the SPIE 2020

[5] The segmented pupil experiment for exoplanet detection. III. Advances and first light with segment cophasing 

Martinez et al. Proceeding of the SPIE 2018

[6] The segmented pupil experiment for exoplanet detection. II. Design advances and progress overview

Martinez et al. Proceeding of the SPIE 2016

[7] The segmented pupil experiment for exoplanet detection

Martinez et al. Proceeding of the SPIE 2014

[8] The segmented pupil experiment for exoplanet detection: SPEEDing up R&D towards high-contrast imaging instruments for the E-ELT

Martinez et al. ESO Messenger 2015 n°159

Key hardware studies publications

[1] Revisiting optical transfer function-based focal plane wavefront sensors for correcting NCPAs

Martinez et al. Proceeding of the SPIE 2024

[2] Differential optical transfer function (dOTF) wavefront sensing with the SPEED test-bed

[3] Phase-induced amplitude apodization complex mask coronagraph (PIAACMC) without PIAA: redesigning a phase-induced amplitude apodization to a conventional pupil amplitude apodization

Sallard et al. Proceeding of the SPIE 2024

[4] Bisymmetric pupil modification deconvolution strategy for differential optical transfer function (dOTF) wavefront sensing  

Martinez et al. A&A 684 L5 Letter 2023

[5] Design, manufacturing and testing of phase-induced amplitude apodization and phase-shifting optics for segmented telescopes  

Martinez et al. A&A 2023, Vol. 680, A6

[6] Gearing up the SPEED wavefront shaping strategy 

Doyen et al. Proceeding of the SPIE 2020

[7] Metrological characterization of the SPEED test-bed PIAACMC components  

Barjot et al. Proceeding of the SPIE 2020

[8] High contrast at small angular separations: II. Impact on the dark hole of a realistic optical setup with two deformable mirrors

Beaulieu et al. MNRAS 2020, 498 

[9] Design and manufacturing of a multi-zone phase-shifting coronagraph mask for extremely large telescopes

Martinez et al. A&A 2020, Vol. 635, A126

[10] Fast-modulation imaging with the self-coherent camera

Martinez, A&A Letter 2019, 629, L10

[11] An end-to-end Fresnel propagation model for SPEED: PIAACMC implementation and performance

Beaulieu et al. Proceeding of the SPIE 2018

[12] Design, specification and manufacturing of a PIAACMC for the SPEED testbed

Martinez et al. Proceeding of the SPIE 2018

[13] Fine cophasing of segmented aperture telescopes with ZELDA, a Zernike wavefront sensor in the diffraction-limited regime

Janin-Potiron et al. A&A 2017

[14] High-contrast imaging at small separations: impact of the optical configuration of two deformable mirrors on dark holes

Beaulieu et al. MNRAS 2017, 469

[15] Self-coherent camera as a focal plane phasing sensor

Janin-Potiron et al. A&A 2016, 592, A110

[16] The self-coherent camera as phasing sensor: from numerical simulations to early experiments

Janin-Potiron et al. Proceeding of the SPIE 2016

[17] SPEED design optimization via Fresnel propagation analysis

Beaulieu et al. Proceeding of the SPIE 2016

[18] The self-coherent camera as a focal plane phasing sensor

Janin-Potiron et al. EAS publications series 78-79 2016

[19] System analysis of the segmented pupil experiment for exoplanet detection – SPEED – in view of the ELTs

Preis et al. Proceeding of the AO4ELT 4th Edition 2015

[20] A Fresnel propagation analysis for SPEED    

Beaulieu et al. Proceeding of the AO4ELT 4th Edition 2015

[21] The self-coherent camera as a phasing sensor: overview and early comparison with the Zenike phase contrast sensor

Janin-Potiron et al. Proceeding of the AO4ELT 4th Edition 2015 

Project related publications 

[1] Differential optical transfer function (dOTF) broad spectrum wavefront sensing using integral field unit spectroscopy

Martinez, A&A 684 L5 Letter 2024

[2] Analytical decomposition of Zernike and hexagonal modes over a hexagonal segmented optical aperture

Janin-Potiron, Martinez and Carbillet, OSA Continuum  2018 - 1(2), 715-726 

[3] Laser guide stars used for cophasing broad capture ranges

Martinez and Janin-Potiron, A&A Letter 2016, 593, L1

PhD Thesis 

[1] Correction active des discontinuités pupillaires des télescopes à miroir segmenté pour l’imagerie haut contraste et la haute résolution angulaire

Janin-Potiron Pierre, Université Côte d’Azur 2017 (Prix SF2A 2018)

[2] Imagerie optique à très haut contraste : une approche instrumentale optimale

Beaulieu Mathilde, Université Côte d’Azur 2017