Corporate Website
Contatti
en
Technology Transfer
Chi siamo
Brevetti
Pubblicazioni
News
Cerca
it
Created with Sketch.
Chiudi menu
English
italiano
Back
en
Chiudi menu
Chi siamo
Brevetti
Pubblicazioni
News
Corporate Website
Contatti
Lista pubblicazioni
Visualizza PUB_LIST
Versione:
1.1
Approvato
it-IT
it-IT
en-US
LDO-ID
2015-02-18-09
Titolo
Fluorescence Imaging Spectrometer (FLORIS): A High Accuracy Instrument with Proven Technologies and Robust Design
Abstract
The Fluorescence Explorer (FLEX) mission is a candidate of the ESA’s 8th Earth Explorer opportunity mission. FLORIS is a push-broom hyperspectral imager, foreseen to be embarked on board of a medium size satellite, flying in tandem with Sentinel-3 in a Sun synchronous orbit at a height of about 815 km. FLORIS will observe the vegetation fluorescence in the visible spectral range (500-780 nm) at medium spatial resolution (300 m) for vegetation health evaluation by means also of data of Sentinel 3 mission (vegetation colour and land temperature). Earth scenes are acquired in two spectral channels, High Resolution (HR) and Low Resolution (LR), with spectral resolution of 0.3 and 2 nm respectively and spectral oversampling of a factor 3. The ESA-funded phase A-B1 study has been devoted to demonstrating the system feasibility and a breadboard activity is on-going. A common fore optic enhances by design the spatial co-registration between the two spectral channels, with 300 m of spatial sampling and 147 km of swath, while an overlapped spectral range simplifies the spectral coregistration. A thermally stabilized aluminum optical bench and three cooled back-side illuminated and fast CCDs are used to guarantee the required SNR and the stability accuracy (both spectral and radiometric) between two consecutive on board calibrations. The absolute radiometric calibration is achieved by observing a dedicated Sun illuminated Lambertian diffuser, with a solar port, while the spectral calibration is done by using the atmospheric absorption lines. The thermal stabilization is achieved by using two passive radiators looking directly to the cold space, counterbalanced by heaters in a closed loop system. The CCD design is improved for high clouds signal measurements, mitigating smearing effects during reading. A compact opto-mechanical solution with all spherical and plane optical elements is proposed. A dual Babinet scrambler is placed in front of the telescope in order to reduce the polarization degree of the incoming light and a dioptric fore-optic images the ground scene onto a double slit. Then the radiation is dispersed onto two detectors by means of the HR and LR grating spectrometers in a modified Offnër configuration with unitary magnification (VIRTIS, VIMS heritage). Special attention has been given to the mitigation of spatial and spectral stray-light which could impact on the fluorescence measurement accuracy. The opto-mechanical design is robust, stable vs temperature, easy to align, showing high optical quality with excellent corrections (by design) of transverse aberration and distortions (keystone and smile).
Autori
Coppo Peter Mario, Taiti Alessio, Rossi Maurizio, Battistelli Enrico
Tipologia
Paper for Seminar/Symposium/Conference
Media
IAC 2015 - International Astronautical Congress (12-16 October 2015, Jerusalem, Israel)
Sito web
Anno
2015
Annulla
popup-close
Previous
Next
popup-close
popup-close
Close page
Inserisci il testo di ricerca
popup-close
LinkedIn
Twitter
Facebook
This application needs JavaScript to be enabled
2024-11-07T10:26:02Z
cookie_disclaimer:true
page_disclaimer :false