Your search keyword '"M. Dami"' showing total 8 results

1. The pre-launch on-ground characterization of Mars Multispectral Imager for Subsurface Studies (Ma_MISS) spectrometer for ExoMars rover mission: Spectral calibration

Author

S. De Angelis, M. C. De Sanctis, F. Altieri, M. Ferrari, E. Ammannito, S. Novi, M. Dami, A. Barbis, F. Antonacci, F. Villa, F. Ruggiero, S. Fonte, M. Formisano, P. Tinivelli, M. Giardino, R. Mugnuolo, and S. Pirrotta

Subjects

Instrumentation

Abstract

The Ma_MISS spectrometer is integrated within the drilling system of the Rosalind Franklin ExoMars rover. This paper reports the on-ground calibration campaign performed on the spectrometer. Here, we focus on the spectral calibration of the instrument. The experimental setup used to carry out calibration is described, and the methods used for data processing and key parameters retrieval are explained. In particular, the spectral parameters such as (i) pixel central wavelengths, (ii) spectral response function, (iii) spectral resolution, (iv) sampling, and (v) range are determined. In a follow-up paper, the linearity and radiometric calibrations are described, while in De Sanctis et al. [Planet. Sci. J. 3, 142 (2022)], the validation of spectral measurements performed on synthetic and natural rock targets is presented.

Published

2022

2. SIMBIO-SYS/STC stereo camera calibration: Geometrical distortion

Author

Emanuele Simioni, Vania Da Deppo, Alessandra Slemer, M. Dami, Maria Teresa Capria, Leonardo Tommasi, Gabriele Cremonese, Marilena Amoroso, Raffaele Mugnuolo, Cristina Re, Iacopo Ficai Veltroni, Francesco Longo, and Donato Borrelli

Subjects

010302 applied physics, Spectrometer, Simbio-sys, Computer science, business.industry, Detector, atereo camera, 01 natural sciences, 010305 fluids & plasmas, Stereo imaging, Optics, Cardinal point, Distortion, 0103 physical sciences, Calibration, Focal length, distortion, business, Instrumentation, Stereo camera

Abstract

The STereo imaging Channel (STC) is the first push-frame stereo camera on board an European Space Agency (ESA) satellite, i.e., the ESA-Japan Aerospace eXploration Agency mission BepiColombo. It was launched in October 2018, and it will reach its target, Mercury, in 2025. The STC main aim is to provide the global three-dimensional reconstruction of the Mercury surface. STC, the stereo channel of spectrometer and imagers for Mercury Planetary Orbiter BepiColombo-Integrated Observatory System, is based on an original optical design that incorporates the advantages of a compact unique detector instrument and the convenience of a double direction acquisition system. In fact, STC operates in a push-frame imaging mode and its two optical sub-channels will converge the incoming light on a single focal plane assembly allowing to minimize mass and volume. The focal plane of the instrument is housing six different filters: two panchromatic filters in the range 600-800 nm and four broadband filters with central wavelengths in the range 420-920 nm. In this paper, the geometrical calibration of the instrument, including the optical setups used, will be described. The methods used to derive the focal lengths, the boresights, and the reference systems of the different filter models are presented, and the related distortion results are discussed. The STC off-axis configuration forced to develop a distortion map model based on the RFM (rational function model). In contrast to other existing models, which allow linear estimates, the RFM is not referred to specific lens geometry, but it is sufficiently general to model a variety of distortion types, as it will be demonstrated in this particular case. Published under license by AIP Publishing.

Published

2019

3. On-ground characterization of Rosetta/VIRTIS-M. II. Spatial and radiometric calibrations

Author

A. Barbis, Eleonora Ammannito, Angioletta Coradini, Gianrico Filacchione, Giuseppe Piccioni, M. Dami, Fabrizio Capaccioni, and M. C. De Sanctis

Subjects

Physics, Matrix (mathematics), Sequence, Cardinal point, Calibration, Radiance, Instrumentation, Stability (probability), Transfer function, Characterization (materials science), Remote sensing

Abstract

After having considered the spectral and geometrical performances of the Rosetta/VIRTIS-M experiment, we complete here the analysis by evaluating quantitatively the flat-field and radiometric responses. The purpose of this work is to retrieve the flat-field matrix necessary to homogenize the focal plane response. Moreover, the most important result is the determination of the instrument transfer function that allows to convert digital numbers in physical units of spectral radiance (Wm−2μm−1sterad−1). The strategy adopted to organize measurement sequence, a basic description of the on-ground experimental setups and the analysis of the collected data, is included in this article. An analysis of the instrumental stability has been performed as well by examining how the internal calibration data are affected by environmental conditions. These data allow to evaluate the cumulative effects of thermal and vibrational stresses on the instrumental performances: up to now we have verified that this effect is neglig...

Published

2006

4. On-ground characterization of Rosetta/VIRTIS-M. I. Spectral and geometrical calibrations

Author

M. Dami, M. C. De Sanctis, Fabrizio Capaccioni, Gianrico Filacchione, Giuseppe Piccioni, Angioletta Coradini, Eleonora Ammannito, and A. Barbis

Subjects

Physics, Pixel, Spectrometer, business.industry, Resolution (electron density), Astrophysics::Instrumentation and Methods for Astrophysics, Field of view, Characterization (materials science), Optics, Sampling (signal processing), Calibration, Range (statistics), business, Instrumentation, Remote sensing

Abstract

The complete characterization of complex imaging spectrometers, such as VIRTIS-M (visual infrared thermal imaging spectrometer) aboard the Rosetta mission, requires a detailed and prolonged activity starting with the instrument integration and continuing during the entire operational life of the experiment. In this article we report the main experimental activities realized during the on-ground characterizations to evaluate the spectral and geometric performances in order to check the conformance with the technical requirements derived from the scientific goals of the experiment. Spectral calibrations allow to confirm instrumental spectral range, resolution, and sampling; geometric calibrations are necessary to estimate the pixel and slit functions, field of view extension, and possible optical aberrations. Two separate sections are dedicated to each one of these subjects, including the strategy followed to prepare measurements, a basic description of the on-ground experimental setups, and the analysis of the collected data.

Published

2006

5. The pre-launch on-ground characterization of Ma_MISS spectrometer for ExoMars-Rosalind Franklin Rover mission. II. Radiometric calibration.

Author

De Angelis S, De Sanctis MC, Altieri F, Ferrari M, Ammannito E, Novi S, Dami M, Antonacci F, Villa F, Meini M, Ruggiero F, Fonte S, Formisano M, Frigeri A, Tinivelli P, Giardino M, Mugnuolo R, and Pirrotta S

Abstract

The Ma_MISS miniaturized spectrometer is integrated within the Drilling System of the ExoMars Rosalind Franklin Rover for Mars exploration. Here we focus on the on ground calibration campaign to obtain radiometric and linearity calibrations of the Ma_MISS instrument, while the first paper dealt with the spectral calibration [De Angelis et al., Rev. Sci. Instrum. 93, 123704 (2022)]. The experimental setup used to carry out radiometric calibration is described, as are the methods used for data processing and key parameter retrieval. In particular, the Spectrometer Transfer Function (Responsivity), Signal-to-Noise Ratio, and detector linearity are determined. In a third paper [De Sanctis et al., Planet. Sci. J. 3, 142 (2022)], validation of the Ma_MISS calibration results through spectral measurements performed on rock and synthetic targets during the radiometric calibration campaign is described., (© 2023 Author(s). Published under an exclusive license by AIP Publishing.)

Published

2023

6. The pre-launch characterization of SIMBIO-SYS/VIHI imaging spectrometer for the BepiColombo mission to Mercury. I. Linearity, radiometry, and geometry calibrations.

Author

Filacchione G, Capaccioni F, Altieri F, Carli C, Ficai Veltroni I, Dami M, Tommasi L, Aroldi G, Borrelli D, Barbis A, Baroni M, Pastorini G, and Mugnuolo R

Abstract

Before integration aboard European Space Agency BepiColombo mission to Mercury, the visible and near infrared hyperspectral imager underwent an intensive calibration campaign. We report in Paper I about the radiometric and linearity responses of the instrument including the optical setups used to perform them. Paper II [F. Altieri et al., Rev. Sci. Instrum. 88, 094503 (2017)] will describe complementary spectral response calibration. The responsivity is used to calculate the expected instrumental signal-to-noise ratio for typical observation scenarios of the BepiColombo mission around Mercury. A description is provided of the internal calibration unit that will be used to verify the relative response during the instrument's lifetime. The instrumental spatial response functions as measured along and across the spectrometer's slit direction were determined by means of spatial scans performed with illuminated test slits placed at the focus of a collimator. The dedicated optical setup used for these measurements is described together with the methods used to derive the instrumental spatial responses at different positions within the 3.5 ° field of view and at different wavelengths in the 0.4-2.0 μm spectral range. Finally, instrument imaging capabilities and Modulated Transfer Function are tested by using a standard mask as a target.

Published

2017

7. The pre-launch characterization of SIMBIO-SYS/VIHI imaging spectrometer for the BepiColombo mission to Mercury. II. Spectral calibrations.

Author

Altieri F, Filacchione G, Capaccioni F, Carli C, Dami M, Tommasi L, Aroldi G, Borrelli D, Barbis A, Baroni M, Pastorini G, Ficai Veltroni I, and Mugnuolo R

Abstract

The Visible and near Infrared Hyperspectral Imager (VIHI) is the VIS-IR spectrometer with imaging capabilities aboard the ESA BepiColombo mission to Mercury. In this second paper, we report the instrument spectral characterization derived by the calibration campaign carried out before spacecraft integration. Complementary measurements concerning radiometric and linearity responses, as well as geometric performances, are described in Paper I [G. Filacchione et al., Rev. Sci. Instrum. 88, 094502 (2017)]. We have verified the VIHI spectral range, spectral dispersion, spectral response function, and spectral uniformity along the whole slit. Instrumental defects and optical aberrations due to smiling and keystone effects have been evaluated, and they are lower than the design requirement (<1/3 pixel). The instrumental response is uniform along the whole slit, while spectral dispersion is well represented by a second order curve, rather than to be constant along the spectral dimension.

Published

2017

8. The spectral imaging facility: Setup characterization.

Author

De Angelis S, Ammannito E, Di Iorio T, De Sanctis MC, Manzari PO, Liberati F, Tarchi F, Dami M, Olivieri M, Pompei C, and Mugnuolo R

Abstract

The SPectral IMager (SPIM) facility is a laboratory visible infrared spectrometer developed to support space borne observations of rocky bodies of the solar system. Currently, this laboratory setup is used to support the DAWN mission, which is in its journey towards the asteroid 1-Ceres, and to support the 2018 Exo-Mars mission in the spectral investigation of the Martian subsurface. The main part of this setup is an imaging spectrometer that is a spare of the DAWN visible infrared spectrometer. The spectrometer has been assembled and calibrated at Selex ES and then installed in the facility developed at the INAF-IAPS laboratory in Rome. The goal of SPIM is to collect data to build spectral libraries for the interpretation of the space borne and in situ hyperspectral measurements of planetary materials. Given its very high spatial resolution combined with the imaging capability, this instrument can also help in the detailed study of minerals and rocks. In this paper, the instrument setup is first described, and then a series of test measurements, aimed to the characterization of the main subsystems, are reported. In particular, laboratory tests have been performed concerning (i) the radiation sources, (ii) the reference targets, and (iii) linearity of detector response; the instrumental imaging artifacts have also been investigated.

Published

2015