Multispectral High Dynamic Range Polarimetric Imaging applied to scene segmentation and object classification
Metadatos
Afficher la notice complèteEditorial
Universidad de Granada
Departamento
Universidad de Granada. Programa Oficial de Doctorado en Física y Ciencias del EspacioMateria
Sistemas de imágenes Procesamiento de imágenes Clasificación Imágenes espectroscópicas Detectores ópticos Imágenes multiespectrales Imagénes polarimétricas
Materia UDC
535 66 (043.2) 2512
Date
2017Fecha lectura
2017-03-28Referencia bibliográfica
Martínez Domingo, M.A. Multispectral High Dynamic Range Polarimetric Imaging applied to scene segmentation and object classification. Granada: Universidad de Granada, 2017. [http://hdl.handle.net/10481/47628]
Patrocinador
Tesis Univ. Granada. Programa Oficial de Doctorado en Física y Ciencias del EspacioRésumé
Different advanced techniques of digital imaging such as multispectral imaging,
high dynamic range (HDR) imaging, polarimetric imaging or Near-Infra-Red
imaging, have been developed and applied separately for years. Researchers are
trying to merge some of these techniques together into a single integrated
system. However this integration is rather challenging, specially if we are
dealing with general purpose applications, such as capturing outdoor urban or
natural scenes.
This dissertation proposes capturing system designs, as well as algorithms and
processing techniques for improving and simplifying the systems currently
present in the state of the art of these different imaging techniques. This way,
high dynamic range multispectral polarimetric images in the visible and near
infrared can be captured and processed for many applications such as image
segmentation, objects or materials classification, vegetation monitoring, food
inspection, remote sensing, surveillance, etc.
A new multispectral image capturing system is proposed, based on a novel
generation of sensors which are still under development. Based on simulations,
this work takes advantage of the spectral tunability of these sensors, and
combines it with color filter arrays, to propose an imaging system with 36
spectral channels, achieving very good colorimetric and spectral performance
for spectral reflectance estimation.
Besides, a new algorithm for the automatic capture of HDR images is proposed,
called Adaptive Exposure Estimation (AEE). It can be implemented in any
digital imaging system, and it works online, as the capturing is ongoing. It is
adaptive to scene content without the need of any prior knowledge about the
scene being captured. The proposed method allows the user to tune the performance of the algorithm, keeping the balance between exposure time and
signal-to-noise ratio, by just adjusting two free parameters. It can also capture
the full dynamic range of the scene (or region of interest), or just a part of it.
The proposed AEE algorithm is also adapted to multispectral polarimetric
image capture. Based on a previous work which uses a Liquid Crystal Tunable
Filter, a new full framework for capturing and processing 31-channels
MultiSpectral HDR Polarimetric (MSHDRPol) images is proposed. New
techniques for segmentation and classification of objects present in indoors
scenes are proposed and tested. The results show that the algorithm outperforms
other methods proposed in previous studies.
As an additional contribution, the whole capturing workflow is adapted to an 8-
channels filter-wheel-based imaging system covering the visible and NIR
ranges up to 1000 nm. Therefore a system and a framework able to
automatically capture MultiSpectral HDR Polarimetric Visible and Near Infra-
Red (MSHDRPolVISNIR) images of outdoor scenes are proposed.
A set of 8 outdoors scenes have been captured using the proposed system and
methods and they will be made publicly available after the defense of this
doctoral thesis.
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