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12 results on '"frame camera"'

1. Multimodal Monocular Dense Depth Estimation with Event-Frame Fusion Using Transformer

Author

Xiao, Baihui, Xu, Jingzehua, Zhang, Zekai, Xing, Tianyu, Wang, Jingjing, Ren, Yong, Goos, Gerhard, Series Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Wand, Michael, editor, Malinovská, Kristína, editor, Schmidhuber, Jürgen, editor, and Tetko, Igor V., editor

Published
2024
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2. The Visual Monitoring Camera (VMC) on Mars Express: A new science instrument made from an old webcam orbiting Mars.

Author

Hernández-Bernal, Jorge, Cardesín-Moinelo, Alejandro, Hueso, Ricardo, Ravanis, Eleni, Burgos-Sierra, Abel, Wood, Simon, Costa-Sitja, Marc, Escalante, Alfredo, Grotheer, Emmanuel, Marín-Yaseli de la Parra, Julia, Merrit, Donald, Almeida, Miguel, Breitfellner, Michel, Sierra, Mar, Martin, Patrick, Titov, Dmitri, Wilson, Colin, Larsen, Ethan, del Río-Gaztelurrutia, Teresa, and Sánchez-Lavega, Agustín

Subjects
*SCIENTIFIC apparatus & instruments, *DUST, *ATMOSPHERIC circulation, *TECHNICAL specifications, *CLOUD dynamics, *MARTIAN atmosphere
Abstract

The Visual Monitoring Camera (VMC) is a small imaging instrument onboard Mars Express with a field of view of ∼40°x30°. The camera was initially intended to provide visual confirmation of the separation of the Beagle 2 lander and has similar technical specifications to a typical webcam of the 2000s. In 2007, a few years after the end of its original mission, VMC was turned on again to obtain full-disk images of Mars to be used for outreach purposes. As VMC obtained more images, the scientific potential of the camera became evident, and in 2018 the camera was given an upgraded status of a new scientific instrument, with science goals in the field of Martian atmosphere meteorology. The wide Field of View of the camera combined with the orbit of Mars Express enable the acquisition of full-disk images of the planet showing different local times, which for a long time has been rare among orbital missions around Mars. The small data volume of images also allows videos that show the atmospheric dynamics of dust and cloud systems to be obtained. This paper is intended to be the new reference paper for VMC as a scientific instrument, and thus provides an overview of the updated procedures to plan, command and execute science observations of the Martian atmosphere. These observations produce valuable science data that is calibrated and distributed to the community for scientific use. • The preparation of an engineering camera to be used as a science instrument is described. • Developed procedures enabled this new fully operational science instrument. • Low-cost cameras can expand the science return of current and future space missions. [ABSTRACT FROM AUTHOR]

Published
2024
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3. Geometric calibration of a hyperspectral frame camera with simultaneous determination of sensors misalignment

Author

Lucas D. Santos, Antonio M.G. Tommaselli, Adilson Berveglieri, Nilton N. Imai, Raquel A. Oliveira, and Eija Honkavaara

Subjects
Camera calibration, Hyperspectral imaging, Frame camera, Sensor misalignment, Geography (General), G1-922, Surveying, TA501-625
Abstract

The recent development of lightweight and relatively low-cost hyperspectral sensors has created new perspectives for remote sensing applications. This study aimed to investigate the geometric calibration of a hyperspectral frame camera based on a tuneable Fabry–Pérot interferometer (FPI) and two sensors. The radiation passes through the optics and then through the FPI, where it is redirected to two sensors using a beam-splitting prism. Previous studies have shown significant variations between the interior orientation parameters for the different bands, both between bands of the same sensor and between different sensors, and that these variations are due to the principle of image acquisition. Discrepancies of tens of pixels were obtained by comparing image coordinates measured in different bands. In this research, it was proposed to calibrate this camera in a static mode with changes in the mathematical calibration model. The restriction of obtaining only one set of exterior orientation parameters by hypercube was applied, adding parameters related to the misalignment between the sensors and parameters of a linear function relating the camera principal distance to the wavelength values. The application of the parameters estimated with this approach reduced the discrepancies between image coordinates measured in different bands to values smaller than one pixel. Using the sensor calibration parameters in the mobile UAV operation in an aerial bundle adjustment reduced the root mean square error (RMSE) on checkpoints by approximately 20% compared to the traditional model in which the interior orientation parameters and lens distortions were calibrated for each band separately. Thus, it was possible to obtain accurate results that make the use of this camera more practical since only one set of calibration parameters for all bands is needed.

Published
2022
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5. Mapping Reflectance Anisotropy of a Potato Canopy Using Aerial Images Acquired with an Unmanned Aerial Vehicle.

Author

Roosjen, Peter P. J., Suomalainen, Juha M., Bartholomeus, Harm M., Kooistra, Lammert, and Clevers, Jan G. P. W.

Subjects
*POTATO yields, *AGRICULTURE, *DRONE aircraft, *IMAGE processing, *DISTRIBUTION (Probability theory), *DATA analysis
Abstract

Viewing and illumination geometry has a strong influence on optical measurements of natural surfaces due to their anisotropic reflectance properties. Typically, cameras on-board unmanned aerial vehicles (UAVs) are affected by this because of their relatively large field of view (FOV) and thus large range of viewing angles. In this study, we investigated the magnitude of reflectance anisotropy effects in the 500–900 nm range, captured by a frame camera mounted on a UAV during a standard mapping flight. After orthorectification and georeferencing of the images collected by the camera, we calculated the viewing geometry of all observations of each georeferenced ground pixel, forming a dataset with multi-angular observations. We performed UAV flights on two days during the summer of 2016 over an experimental potato field where different zones in the field received different nitrogen fertilization treatments. These fertilization levels caused variation in potato plant growth and thereby differences in structural properties such as leaf area index (LAI) and canopy cover. We fitted the Rahman–Pinty–Verstraete (RPV) model through the multi-angular observations of each ground pixel to quantify, interpret, and visualize the anisotropy patterns in our study area. The Q parameter of the RPV model, which controls the proportion of forward and backward scattering, showed strong correlation with canopy cover, where in general an increase in canopy cover resulted in a reduction of backward scattering intensity, indicating that reflectance anisotropy contains information on canopy structure. In this paper, we demonstrated that anisotropy data can be extracted from measurements using a frame camera, collected during a typical UAV mapping flight. Future research will focus on how to use the anisotropy signal as a source of information for estimation of physical vegetation properties. [ABSTRACT FROM AUTHOR]

Published
2017
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6. Cross-ratio-based line scan camera calibration using a planar pattern.

Author

Dongdong Li, Gongjian Wen, and Shaohua Qiu

Subjects
*CALIBRATION, *GEOMETRIC modeling, *CAMERAS, *STEREOSCOPIC cameras, *PHOTOGRAMMETRY, *CROSS ratio (Geometry)
Abstract

A flexible new technique is proposed to calibrate the geometric model of line scan cameras. In this technique, the line scan camera is rigidly coupled to a calibrated frame camera to establish a pair of stereo cameras. The linear displacements and rotation angles between the two cameras are fixed but unknown. This technique only requires the pair of stereo cameras to observe a specially designed planar pattern shown at a few (at least two) different orientations. At each orientation, a stereo pair is obtained including a linear array image and a frame image. Radial distortion of the line scan camera is modeled. The calibration scheme includes two stages. First, point correspondences are established from the pattern geometry and the projective invariance of cross-ratio. Second, with a two-step calibration procedure, the intrinsic parameters of the line scan camera are recovered from several stereo pairs together with the rigid transform parameters between the pair of stereo cameras. Both computer simulation and real data experiments are conducted to test the precision and robustness of the calibration algorithm, and very good calibration results have been obtained. Compared with classical techniques which use three-dimensional calibration objects or controllable moving platforms, our technique is affordable and flexible in close-range photogrammetric applications. [ABSTRACT FROM AUTHOR]

Published
2016
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7. Mapping Reflectance Anisotropy of a Potato Canopy Using Aerial Images Acquired with an Unmanned Aerial Vehicle

Author

Peter P. J. Roosjen, Juha M. Suomalainen, Harm M. Bartholomeus, Lammert Kooistra, and Jan G. P. W. Clevers

Subjects
reflectance anisotropy, Bidirectional Reflectance Distribution Function (BRDF), unmanned aerial vehicle, frame camera, multi-spectral, Rahman–Pinty–Verstraete (RPV) model., Science
Abstract

Viewing and illumination geometry has a strong influence on optical measurements of natural surfaces due to their anisotropic reflectance properties. Typically, cameras on-board unmanned aerial vehicles (UAVs) are affected by this because of their relatively large field of view (FOV) and thus large range of viewing angles. In this study, we investigated the magnitude of reflectance anisotropy effects in the 500–900 nm range, captured by a frame camera mounted on a UAV during a standard mapping flight. After orthorectification and georeferencing of the images collected by the camera, we calculated the viewing geometry of all observations of each georeferenced ground pixel, forming a dataset with multi-angular observations. We performed UAV flights on two days during the summer of 2016 over an experimental potato field where different zones in the field received different nitrogen fertilization treatments. These fertilization levels caused variation in potato plant growth and thereby differences in structural properties such as leaf area index (LAI) and canopy cover. We fitted the Rahman–Pinty–Verstraete (RPV) model through the multi-angular observations of each ground pixel to quantify, interpret, and visualize the anisotropy patterns in our study area. The Θ parameter of the RPV model, which controls the proportion of forward and backward scattering, showed strong correlation with canopy cover, where in general an increase in canopy cover resulted in a reduction of backward scattering intensity, indicating that reflectance anisotropy contains information on canopy structure. In this paper, we demonstrated that anisotropy data can be extracted from measurements using a frame camera, collected during a typical UAV mapping flight. Future research will focus on how to use the anisotropy signal as a source of information for estimation of physical vegetation properties.

Published
2017
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8. Process of Surface Flashover in Vacuum Under Nanosecond Pulse.

Author

Junping Tang, Aici Qiu, Li Yang, Wei Jia, Haiyang Wang, and Junna Li

Subjects
*ELECTRIC insulators & insulation, *VACUUM, *PULSED power systems, *ELECTRIC arc, *MAGNETOHYDRODYNAMICS
Abstract

In a wide variety of high-power pulsed devices, vacuum surface flashover plays a key role in the system performance. High-speed electrical measurements with temporal resolution in the nanosecond range were employed to measure the flashover characteristics, and high-speed three-frame photography was used to image the flashover channels at different phases along the insulator surface. From these test results, the flashover under nanosecond pulse would experience a process with three typical phases: initial phase, developing phase, and extinguishing phase. Spectra luminosity of the flashover channel is also discussed for better understanding the mechanism of the flashover process. [ABSTRACT FROM AUTHOR]

Published
2010
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9. Mapping Reflectance Anisotropy of a Potato Canopy Using Aerial Images Acquired with an Unmanned Aerial Vehicle

Author

Juha Suomalainen, P.P.J. Roosjen, Lammert Kooistra, Jan G. P. W. Clevers, and Harm Bartholomeus

Subjects
Canopy, 010504 meteorology & atmospheric sciences, 0211 other engineering and technologies, 02 engineering and technology, 01 natural sciences, Laboratory of Geo-information Science and Remote Sensing, Bidirectional Reflectance Distribution Function (BRDF), Laboratorium voor Geo-informatiekunde en Remote Sensing, Leaf area index, lcsh:Science, Anisotropy, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Remote sensing, Rahman–Pinty–Verstraete (RPV) model, Pixel, Scattering, Multi-spectral, Orthophoto, Vegetation, Unmanned aerial vehicle, PE&RC, Frame camera, Rahman-Pinty-Verstraete (RPV) model, General Earth and Planetary Sciences, lcsh:Q, Reflectance anisotropy, reflectance anisotropy, unmanned aerial vehicle, frame camera, multi-spectral, Focus (optics), Geology
Abstract

Viewing and illumination geometry has a strong influence on optical measurements of natural surfaces due to their anisotropic reflectance properties. Typically, cameras on-board unmanned aerial vehicles (UAVs) are affected by this because of their relatively large field of view (FOV) and thus large range of viewing angles. In this study, we investigated the magnitude of reflectance anisotropy effects in the 500–900 nm range, captured by a frame camera mounted on a UAV during a standard mapping flight. After orthorectification and georeferencing of the images collected by the camera, we calculated the viewing geometry of all observations of each georeferenced ground pixel, forming a dataset with multi-angular observations. We performed UAV flights on two days during the summer of 2016 over an experimental potato field where different zones in the field received different nitrogen fertilization treatments. These fertilization levels caused variation in potato plant growth and thereby differences in structural properties such as leaf area index (LAI) and canopy cover. We fitted the Rahman–Pinty–Verstraete (RPV) model through the multi-angular observations of each ground pixel to quantify, interpret, and visualize the anisotropy patterns in our study area. The Θ parameter of the RPV model, which controls the proportion of forward and backward scattering, showed strong correlation with canopy cover, where in general an increase in canopy cover resulted in a reduction of backward scattering intensity, indicating that reflectance anisotropy contains information on canopy structure. In this paper, we demonstrated that anisotropy data can be extracted from measurements using a frame camera, collected during a typical UAV mapping flight. Future research will focus on how to use the anisotropy signal as a source of information for estimation of physical vegetation properties.

Published
2017
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11. Achievement of the 'benchmark' session - on the use of UAV images for 3D reconstruction: a joint experience among users

Author

Mancini, F., Castagnetti, C., Rossi, P., Guerra, F., Ballarin, M., Visintini, D., Garraffa, A., Stecchi, F., Aicardi, I., Grasso, N., Noardo, F., Luca, V., Ratto Cavagnaro, M., GABRIELLA CAROTI, ANDREA PIEMONTE, Pinto, L., Santise, M., Albano, V., Curuni, M., Cerratti, M., and Abate, G.

Subjects
frame camera, camera self-calibration, action camera, Benchmark session, UAV photogrammetry, camera self-calibration, action camera, frame camera, Benchmark session, UAV photogrammetry
Published
2016

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