Wavefront Control With Realistic Spatial Light Modulator in a Multi-aperture Imager

Wu, Guimin

January 2012

No description available.

Optics

Wavefront control

SLM

multi-aperture imaging

beam steering

conformal aperture

Développement et validation d'un analyseur de surface d'onde en plan focal pour un instrument multi-pupilles / Development and validation of a focal plane wavefront sensor for multiple aperture systems

Vievard, Sébastien

28 September 2017

L’instrumentation multi-pupille permet de repousser les limitations actuelles des diamètres des télescopes monolithiques. L’alignement des sous-pupilles est donc une problématique incontournable pour les futurs projets de télescopes au sol comme dans l’espace. Un Analyseur de Surface d’Onde (ASO) est alors nécessaire pour mesurer les aberrations spécifiques au cas multi-pupille que sont le piston différentiel (différence de marche entre les sous-pupilles), le tip et le tilt (basculements différentiels entre les sous-pupilles). Nous nous attachons à réaliser des ASOs non supervisés et simples d’implantation, permettant l’alignement total d’un instrument multi-pupille. L’algorithme ELASTIC repose sur l’analyse de la corrélation entre deux images focales prises successivement, différant par une perturbation maîtrisée et appliquée directement sur les sous-pupilles. ELASTIC permet d’une part d’estimer les grandes erreurs de tip/tilt, pour effectuer un alignement géométrique et d’autre part de stabiliser le tip/tilt pendant la minimisation des grandes erreurs de piston, pour l’alignement interférométrique. Enfin, un second algorithme appelé LAPD permet, au moyen de deux images prises simultanément dans un plan focal et dans un plan légèrement défocalisé, d’estimer les petites erreurs de piston/tip/tilt pour le cophasage fin. Ces différents algorithmes sont caractérisés au moyen de simulations numériques, pour différents types de télescopes multi-pupilles. Nous démontrons expérimentalement les briques de la chaîne d’alignement sur un instrument à 6 sous-pupilles. Ces ASOs permettent de simplifier le dimensionnement des futurs télescopes. / The resolution of a telescope is ultimately limited by its aperture diameter, but the size of mirrors is bounded by current technology to about 10m on the ground and to a few meters in space. To overcome this limitation, interferometry consists in making an array of sub-apertures interfere; the resulting instrument is called an interferometer or a multi-aperture telescope. To reach the diffraction limit of such instruments, all sub-apertures must be phased to within a small fraction of wavelength. A critical sub-system of interferometers is the Cophasing Sensor (CS), whose goal is to measure the relative positioning errors between the sub-apertures (differential piston, tip and tilt), which are the specific low-order aberration of an interferometer and the main source of wave-front degradation. We aim to develop unsupervised and easy-to-implement CSs for the global multi-aperture telescope alignment. ELASTIC algorithm provides a solution for large amplitude tip/tilt error measurement from a modified cross-spectrum of two diversity images, allowing the geometrical alignment. ELASTIC also provides tip/tilt stability for the large amplitude piston error minimization, called the interferometric alignment. Finally a second algorithm called LAPD uses focal and slightly defocused images for the small amplitude piston/tip/tilt error measurement, allowing the fine phasing. Numerical simulations of several types of multi-aperture telescopes are performed in order to test our algorithms. We experimentally demonstrate the efficiency of the different algorithms on a 6-sub-aperture instrument. These algorithms should simplify the design of the future telescopes.

Optique de Fourier

Senseur de front d'onde

Diversité de phase

Multi-Pupille

Alignement

Cophasage

Fourier optics

Phasing

Multi-aperture

530

535.2

Computational Phase Correction of a Partially Coherent Multi-Aperture System

Krug, Sarah Elaine

15 June 2020

No description available.

Optics

Physics

Electrical Engineering

Remote Sensing

computational cophasing

partially coherent imaging

multi-aperture imaging

pupil remapping

atmospheric phase corrections

Multi-Aperture Coherent Change Detection and Interferometry for Synthetic Aperture Radar

Madsen, David D.

09 March 2010

Interferometry and coherent change detection (CCD) utilize phase differences between complex SAR images to find terrain height and to detect small changes between images, respectively. A new method for improving interferometry and CCD using multiple sub-apertures is proposed. Using backprojection processing, multiple sub-aperture images are created for a pair of flights. An interferogram and coherence map is made from each sub-aperture. For CCD, each sub-aperture coherence map offers an independent estimate of the coherence over the same area. By combining coherence maps, low coherence areas associated with residual motion errors are reduced, shadowed areas are minimized, and the overall coherence of stationary objects between images is increased. For interferometry, combining independent estimates of a scene's height offers a more accurate height estimate. For repeat-pass interferometry, multiple apertures are shown to increase the coverage of valid height estimates. The benefits of multi-aperture interferometry and CCD are shown using examples with real data.

SAR

synthetic aperture radar

image registration

coherent change detection

CCD

interferometry

multi-aperture

repeat-pass interferometry

L-Band

backprojection

Electrical and Computer Engineering

Vysokofrekvenční a mezifrekvenční obvody krátkovlnné radiostanice / HF and IF circuits of shortwave radiostation

Šnajdr, Václav

January 2009

The study, description, design and implementation of selected blocks of multiband shortwave radio station are dealt with in the thesis. Focus is placed on the concept of multiband shortwave radio stations, with an emphasis on high frequency and intermediate frequency circuits. The first chapter is devoted to description of the transceiver block diagram which is designed as superheterodyne. The design of bandpass input filters, intermediate frequency crystal filters and output filters is described. Simulation results and the measured characteristics of the implemented functional blocks are presented. Furthermore, the amplifier circuits which maintain impedance matching of individual blocks are discussed. SSB signal generation in the transmitter part of radio station and final stage power amplification are depicted.