Dark signal correction for a lukecold frame-transfer CCD

Hochedez, J.‐F.; Timmermans, Catherine; Hauchecorne, Alain; Meftah, Mustapha

doi:10.1051/0004-6361/201321607

Cited by 4 publications

(3 citation statements)

References 42 publications

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“…The image data of the SODISM II solar telescope require dark-signal corrections (Hochedez et al 2014). SODISM II dark-current images have been performed every day and with an exposure time of 1.4 s. All images have been corrected for dark-current.…”

Section: Sodism II Radiometric Calibrationsmentioning

confidence: 99%

Ground-based measurements of the solar diameter during the rising phase of solar cycle 24

Meftah

Corbard

Irbah

et al. 2014

A&A

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Context. For the past thirty years, modern ground-based time-series of the solar radius have shown different apparent variations according to different instruments. The origins of these variations may result from the observer, the instrument, the atmosphere, or the Sun. Solar radius measurements have been made for a very long time and in different ways. Yet we see inconsistencies in the measurements. Numerous studies of solar radius variation appear in the literature, but with conflicting results. These measurement differences are certainly related to instrumental effects or atmospheric effects. Use of different methods (determination of the solar radius), instruments, and effects of Earth's atmosphere could explain the lack of consistency on the past measurements. A survey of the solar radius has been initiated in 1975 by Francis Laclare, at the Calern site of the Observatoire de la Côte d'Azur (OCA). Several efforts are currently made from space missions to obtain accurate solar astrometric measurements, for example, to probe the long-term variations of solar radius, their link with solar irradiance variations, and their influence on the Earth climate. Aims. The Picard program includes a ground-based observatory consisting of different instruments based at the Calern site (OCA, France). This set of instruments has been named "Picard Sol" and consists of a Ritchey-Chrétien telescope providing full-disk images of the Sun in five narrow-wavelength bandpasses (centered on 393.37, 535.7, 607.1, 782.2, and 1025.0 nm), a Sun-photometer that measures the properties of atmospheric aerosol, a pyranometer for estimating a global sky-quality index, a wide-field camera that detects the location of clouds, and a generalized daytime seeing monitor allowing us to measure the spatio-temporal parameters of the local turbulence. Picard Sol is meant to perpetuate valuable historical series of the solar radius and to initiate new time-series, in particular during solar cycle 24. Methods. We defined the solar radius by the inflection-point position of the solar-limb profiles taken at different angular positions of the image. Our results were corrected for the effects of refraction and turbulence by numerical methods. Results. From a dataset of more than 20 000 observations carried out between 2011 and 2013, we find a solar radius of 959.78 ± 0.19 arcsec (696 113 ± 138 km) at 535.7 nm after making all necessary corrections. For the other wavelengths in the solar continuum, we derive very similar results. The solar radius observed with the Solar Diameter Imager and Surface Mapper II during the period 2011-2013 shows variations shorter than 50 milli-arcsec that are out of phase with solar activity.

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Section: Sodism II Radiometric Calibrationsmentioning

confidence: 99%

Ground-based measurements of the solar diameter during the rising phase of solar cycle 24

Meftah

Corbard

Irbah

et al. 2014

A&A

Self Cite

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“…Self-heating is a determining factor for the magnitude of the various temperature-dependent sources of interference in image sensors, which in turn degrade the image quality [45,51,52]. In principle, it is possible to read the temperature data of both the image sensor (CCD) and the electronics (PCB) of the OWL 640 mini camera module.…”

Section: Thermal Management and Dark Noisementioning

confidence: 99%

Development of a VNIR/SWIR Multispectral Imaging System for Vegetation Monitoring with Unmanned Aerial Vehicles

Alexander

Bareth

Bolten

et al. 2019

Sensors

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Short-wave infrared (SWIR) imaging systems with unmanned aerial vehicles (UAVs) are rarely used for remote sensing applications, like for vegetation monitoring. The reasons are that in the past, sensor systems covering the SWIR range were too expensive, too heavy, or not performing well enough, as, in contrast, it is the case in the visible and near-infrared range (VNIR). Therefore, our main objective is the development of a novel modular two-channel multispectral imaging system with a broad spectral sensitivity from the visible to the short-wave infrared spectrum (approx. 400 nm to 1700 nm) that is compact, lightweight and energy-efficient enough for UAV-based remote sensing applications. Various established vegetation indices (VIs) for mapping vegetation traits can then be set up by selecting any suitable filter combination. The study describes the selection of the individual components, starting with suitable camera modules, the optical as well as the control and storage parts. Special bandpass filters are used to select the desired wavelengths to be captured. A unique flange system has been developed, which also allows the filters to be interchanged quickly in order to adapt the system to a new application in a short time. The characterization of the system was performed in the laboratory with an integrating sphere and a climatic chamber. Finally, the integration of the novel modular VNIR/SWIR imaging system into a UAV and a subsequent first outdoor test flight, in which the functionality was tested, are described.

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“…The Solar radius determination [10][11][12][13][14][15][16][17][18][19] On 5 to 6 June, 2012 the transit of Venus provided a rare opportunity to determine the radius of the Sun using solar imagers observing a well-defined object, namely the planet and its atmosphere, occulting partially the Sun. A method to determine the solar radius has been developed; it is based on the estimation of the spectral solar radiance decrease in a region around the contact between the planet and the Sun at the beginning of the ingress and at the end of the egress.…”

Section: Solar Diameter and Its Evolution During The Rising Phasementioning

confidence: 99%

The PICARD Scientific Mission: status of the program

Rouzé

Hauchecorne

Hochedez

et al. 2014

SpaceOps 2014 Conference

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PICARD is an investigation dedicated to the simultaneous measurement of the absolute total and spectral solar irradiance, the diameter and solar shape, and to the Sun's interior probing by the helioseismology method. The spacecraft was successfully launched into a Sun-synchronous dawn-dusk orbit on 15 June 2010 by a DNEPR-1 launcher for a life expectancy of 2 years; its operational mission ended in March, 2014.The payload consists of the SODISM imager (SOlar Diameter Imager and Surface Mapper) and of two radiometers, SOVAP (SOlar VAriability PICARD) and PREMOS (PREcision MOnitoring Sensor), which measure Total Solar Irradiance. Filter radiometers on PREMOS monitor the Solar Spectral Irradiance in six selected bands in the near UV, visible, and near IR wavelength regions. The SODISM telescope monitors continuously solar activity from the middle ultraviolet (UV) to the near infrared (IR) spectral domains.We shall give an overview of the mission, as well as the behaviour of the instruments in orbit, and the scientific results.

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Dark signal correction for a lukecold frame-transfer CCD

Cited by 4 publications

References 42 publications

Ground-based measurements of the solar diameter during the rising phase of solar cycle 24

Ground-based measurements of the solar diameter during the rising phase of solar cycle 24

Development of a VNIR/SWIR Multispectral Imaging System for Vegetation Monitoring with Unmanned Aerial Vehicles

The PICARD Scientific Mission: status of the program

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