Analysis of Viewshed Accuracy with Variable Resolution LIDAR Digital Surface Models and Photogrammetrically-Derived Digital Elevation Models

Miller, Matthew Lowell

20 December 2011

The analysis of visibility between two points on the earth's terrain is a common use of GIS software. Most commercial GIS software packages include the ability to generate a viewshed, or a map of terrain surrounding a particular location that would be visible to an observer. Viewsheds are often generated using "bare-earth" Digital Elevation Models (DEMs) derived from the process of photogrammetry. More detailed models, known as Digital Surface Models (DSMs), are often generated using Light Detection and Ranging (LIDAR) which uses an airborne laser to scan the terrain. In addition to having greater accuracy than photogrammetric DEMs, LIDAR DSMs include surface features such as buildings and trees. This project used a visibility algorithm to predict visibility between observer and target locations using both photogrammetric DEMs and LIDAR DSMs of varying resolution. A field survey of the locations was conducted to determine the accuracy of the visibility predictions and to gauge the extent to which the presence of surface features in the DSMs affected the accuracy. The use of different resolution terrain models allowed for the analysis of the relationship between accuracy and optimal grid size. Additionally, a series of visibility predictions were made using Monte Carlo methods to add random error to the terrain elevation to estimate the probability of a target's being visible. Finally, the LIDAR DSMs were used to determine the linear distance of terrain along the lines-of-sight between the observer and targets that were obscured by trees or bushes. A logistic regression was performed between that distance and the visibility of the target to determine the extent to which a greater amount of vegetation along the line-of-sight impacted the target's visibility. / Master of Science

visibility

digital elevation model

digital surface model

viewshed

LIDAR

Automatic digital surface model generation using graphics processing unit

Van der Merwe, Dirk Jacobus

05 June 2012

M. Ing. / Digital Surface Models (DSM) are widely used in the earth sciences for research, visu- alizations, construction etc. In order to generate a DSM for a speci c area, specialized equipment and personnel are always required which leads to a costly and time consuming exercise. Image processing has become a viable processing technique to generate terrain models since the improvements of hardware provided adequate processing power to complete such a task. Digital Surface Models (DSM) can be generated from stereo imagery, usually obtained from a remote sensing platform. The core component of a DSM generating system is the image matching algorithm. Even though there are a variety of algorithms to date which can generate DSMs, it is a computationally complex calculation and does tend to take some time to complete. In order to achieve faster DSMs, an investigation into an alternative processing platform for the generation of terrain models has been done. The Graphics Processing Unit (GPU) is usually used in the gaming industry to manipulate display data and then render it to a computer screen. The architecture is designed to manipulate large amounts of oating point data. The scientic community has begun using the GPU processing power available for technical computing, hence the term, General Purpose computing on a Graphics Processing Unit (GPGPU). The GPU is investigated as alternative processing platform for the image matching procedure since the processing capability of the GPU is so much higher than the CPU but only for a conditioned set of input data. A matching algorithm, derived from the GC3 algorithm has been implemented on both a CPU platform and a GPU platform in order to investigate the viability of a GPU processing alternative. The algorithm makes use of a Normalized Cross Correlation similarity measurement and the geometry of the image acquisition contained in the sensor model to obtain conjugate point matches in the two source images. The results of the investigation indicated an improvement of up to 70% on the processing time required to generate a DSM. The improvements varied from 70% to some cases where the GPU has taken longer to generate the DSM. The accuracy of the automatic DSM generating system could not be clearly determined since only poor quality reference data was available. It is however shown the DSMs generated using both the CPU and GPU platforms relate to the reference data and correlate to each other. The discrepancies between the CPU and the GPU results are low enough to prove the GPU processing is bene cial with neglible drawbacks in terms of accuracy. The GPU will definitely provide superior processing capabilites for DSM generation above a CPU implementation if a matching algorithm is speci cally designed to cater for the bene ts and limitations of the GPU.

Digital surface model

Digital elevation model

Graphics processing unit

Sensor model theory

A NeRF for All Seasons

Michael Donald Gableman (16632723)

08 August 2023

<p> </p> <p>As a result of Shadow NeRF and Sat-NeRF, it is possible to take the solar angle into account in a NeRF-based framework for rendering a scene from a novel viewpoint using satellite images for training. Our work extends those contributions and shows how one can make the renderings season-specific. Our main challenge was creating a Neural Radiance Field (NeRF) that could render seasonal features independently of viewing angle and solar angle</p> <p>while still being able to render shadows. We teach our network to render seasonal features by introducing one more input variable — time of the year. However, the small training datasets typical of satellite imagery can introduce ambiguities in cases where shadows are present in the same location for every image of a particular season. We add additional terms to the loss function to discourage the network from using seasonal features for accounting for shadows. We show the performance of our network on eight Areas of Interest containing images captured by the Maxar WorldView-3 satellite. This evaluation includes tests measuring the ability of our framework to accurately render novel views, generate height maps, predict shadows, and specify seasonal features independently from shadows. Our ablation</p> <p>studies justify the choices made for network design parameters. Also included in this work is a novel approach to space carving which merges multiple features and consistency metrics</p> <p>at different spatial scales to create higher quality digital surface map than is possible using standard RGB features.</p>

Computer vision

Satelite data

Digital Surface Model (DSM)

Neural Radiance Fields

seasonal variabilities

Space carving

A GIS MODEL TO ESTIMATE SNOW DEPTH USING DIFFERENTIAL GPS AND HIGH-RESOLUTION DIGITAL ELEVATION DATA

HURD, JOHN K., JR.

09 July 2007

No description available.

Geography

GIS

Geographic Information System

Model

GPS

Arctic

Cryosphere

Snow

Digital Surface Model

Remote Sensing

Utvärdering av lägesosäkerheter i ortofoton framtagna med hjälp av DJI Phantom 4 RTK / Evaluation of position uncertainties in orthophotos developed with a DJI Phantom 4 RTK

Larsson, Johan, Stark, Marcus

January 2019

Flygfotografering med Unmanned Aircraft System (UAS) är i jämförelse med traditionell fotogrammetri effektivare, billigare och säkrare vilket har medfört att denna teknik föredras av många aktörer. Ett tidskrävande arbete som varit svårt att kringgå är att etablera flygsignaler på marken som används för att georeferera och kontrollera flygbilderna med. Under 2018 presenterade UAS-tillverkaren DJI sin nya quadcopter med integrerad Real-Time Kinematic (RTK)-modul. I samband med detta kan kontinuerliga och noggranna positioner levereras via Nätverks-RTK (NRTK) och behovet av markstödpunkter reduceras. I denna studie undersöktes lägesosäkerheterna i plan för ortofoton som framställdes med hjälp av en DJI Phantom 4 RTK där flygbilderna georefererades med begränsat antal eller utan markstödpunkter. Lägesosäkerheterna beräknades och kontrollerades enligt Handbok i mät- och kartfrågor (HMK) – Ortofoto, vilket är ett stöddokument inom ämnet. Vid framställning av ett ortofoto krävs även en digital terrängmodell (DTM) eller en digital ytmodell (Digital Surface Model, DSM) och kvaliteten av denna har stor inverkan på ortofotots kvalitet. I denna studie kontrollerades och utvärderades därför en del av den DSM som användes vid ortofotoframställning för respektive uppsättning enligt den tekniska specifikationen SIS-TS 21144:2016. Resultatet från studien visar att ett ortofoto går att framställas utan markstödpunkter och samtidigt klara kraven på specificerad lägesosäkerhet enligt HMK-standardnivå 3. Den sammanlagda lägesosäkerheten beräknades till 0,029 m vilket är 5 mm högre i jämförelse med ett ortofoto som baserats på traditionell georefereringsmetod, dvs. med markstödpunkter. Kravet på kvalitet i höjddata uppfylldes också för ortofotoframställning trots att en systematisk effekt i höjd uppkom. Denna effekt påverkade inte ortofotots koordinater i plan då standardosäkerheterna i höjd var låga. Resultatet visade att om två markstödpunkter adderades i vardera änden av området, kunde de systematiska effekterna i höjd minimeras och det var då möjligt att skapa en DSM som uppfyller kraven för detaljprojektering (noggrannhetsklass 1–3) enligt SIS-TS 21144:2016. / Aerial photography with UAS is in comparison with traditional photogrammetry more efficient, cheaper and safer which has led to this technology being preferred by many performers. A time-consuming job that has been difficult to avoid is to establish signals at the ground that are used for georeferencing and evaluate the results. In 2018, the UAS manufacturer DJI presented its new quadcopter with integrated Real-Time Kinematic (RTK) module. This allows continuous and accurate positions delivered via Network RTK (NRTK) and the need of ground control points can be reduced. In this study, investigations of the position uncertainties in orthophotos produced using a DJI Phantom 4 RTK carried out where the aerial images were georeferenced with limited numbers or without ground control points. The position uncertainties were calculated and controlled according to the Swedish HMK – Ortofoto (Orthophoto) which is a document within the subject. When producing an orthophoto, a digital terrain model (DTM) or a digital surface model (DSM) is also required and the quality of this has a great impact on the result. Therefore, a part of the DSM used for orthophoto production for each set was checked and evaluated according to the Swedish technical specification, SIS-TS 21144:2016. The result of the study shows that an orthophoto can be produced without ground control points and at the same time meet the requirements for specified position uncertainty according to HMK standard level 3. The total position uncertainty was calculated to be 0,029 m, which is 5 mm higher compared to the orthophoto based on the traditional georeferencing method, i.e. with ground control points. The requirement for quality in height data was also met for orthophoto production even though a systematic effect in height occurred. This effect did not affect the plane coordinates in the orthophoto because of the low standard uncertainties in height. The result showed that if two ground control points were added at each end of the area, the systematic effects were minimized, and it was possible to produce a DSM that fulfils the requirements for accuracy class 1-3 according to SIS-TS 21144:2016.

Unmanned Aircraft System (UAS)

DJI Phantom 4 RTK

Orthophoto

Digital Surface Model (DSM)

Agisoft PhotoScan

Unmanned Aircraft System (UAS)

DJI Phantom 4 RTK

Ortofoto

Digital Surface Model (DSM)

Agisoft PhotoScan

Other Civil Engineering

Annan samhällsbyggnadsteknik

Avaliação de qualidade cartográfica e extração de bordas de objetos não pertencentes ao terreno em produtos gerados pelo sistema de varredura a laser aerotransportado. / Map quality evaluation and edge extraction of off-terrain objects on airbone laser scanner products.

Souza, André Luiz Neves de

26 May 2009

O sistema de varredura a LASER aerotransportado é uma tecnologia competitiva para levantamentos que visam à geração de modelos digitais de superfície (MDS) e modelos digitais de terreno (MDT). Esta tecnologia sofreu certa resistência por parte das empresas de aerolevantamento e de alguns usuários, porém vem conquistando o mercado, graças à grande quantidade de trabalhos recentemente publicados. Uma das limitações associadas ao levantamento a LASER é a correta detecção de objetos não pertencentes ao terreno como árvores e edificações. Esses objetos, quando devidamente identificados, são essenciais para várias aplicações como cadastro e avaliação da qualidade cartográfica. Este trabalho propõe uma metodologia de identificação de edificações através da detecção de suas bordas, em uma rede triangular (TIN) construída sobre a nuvem de pontos. A utilização da TIN preserva os valores originais da amostra e, representa o universo real com melhor fidelidade que os modelos matriciais. A detecção é realizada calculando-se as declividades para todos os triângulos da TIN. Após esta etapa, são segmentados todos os triângulos que possuem valor de declividade acima de um limiar, pois representam variações abruptas no terreno, condizentes com edificações. A definição do limiar depende da resolução da nuvem de pontos, padrão de varredura e natureza do terreno. O trabalho apresenta ferramentas preliminares para automatizar a vetorização das bordas detectadas. As edificações extraídas pela metodologia e ferramentas apresentadas, podem ser utilizadas para avaliação da qualidade cartográfica do MDS/MDT. Para isso, compara-se o MDS a um documento cartográfico de referência, e realizam-se testes para: detecção e eliminação de erros grosseiros, detecção de tendências e minimização de erros sistemáticos, testes de precisão e de atendimento ao Padrão de Exatidão Cartográfico (PEC). Após análises, conclui-se que a metodologia de detecção de bordas propostas é eficiente, porém as ferramentas de automatização precisam ser aperfeiçoadas. Conclui-se também que o MDS oriundo do levantamento a LASER tem qualidade cartográfica compatível com o produto cartográfico de referência. Recomenda-se aplicação das metodologias propostas em outros conjuntos de dados. / The airborne LASER scanner is competitive technology for surveys that generates digital surface models (DSM) and Digital Terrain Models (DTM). This technology suffered some resistance by the aerosurvey enterprise (and some users), but is conquering its market share due the amount of papers recently published in this field. A limitation associated with this technique is the correct detection of the offterrain objects, like trees and buildings. These objects, when well identified, are essential to a sort of applications like cadastre e map quality evaluation. This dissertation proposes a methodology to identify buildings by the edge detection of a triangular irregular net (TIN) built over the point cloud. The utilization of TIN preserves the original values, representing the real 3D universe with fidelity despite the raster models. The detection is done calculating the slopes for all triangles of the TIN. After that, the triangles with slope values above a threshold are segmented. The Threshold definition depends on resolution of the point cloud, scan pattern and target behavior. Triangles with high slope values represent hard variation and may mean buildings. This work shows preliminary tools to automate the vectorization of the detected edges. The extracted buildings may be used for map quality evaluation of the DSM/DTM, by comparing it with a reference map. This means: test for detection e elimination of bundles, test for detection and minimization of systematic errors, precision tests and evaluate the meeting the Brazilian cartographic accuracy standard (PEC). Theses analysis concludes that the proposed methodology of edge detection is efficient but the developed tools of automation may be sharpened. Also, concludes that the DSM built with LASER scanner survey is compatible with reference map. Its recommended the application of the methodology on other collections of data.

Cartografia

Controle da qualidade

Detecção de bordas

Digital surface model

Dispositivos de varredura (topografia)

Edge detetcion

LASER scan

Modelagem de dados

Digital Surface Models From Spaceborne Images Without Ground Control

Ataseven, Yoldas

01 September 2012

Generation of Digital Surface Models (DSMs) from stereo satellite (spaceborne) images is classically performed by Ground Control Points (GCPs) which require site visits and precise measurement equipment. However, collection of GCPs is not always possible and such requirement limits the usage of spaceborne imagery. This study aims at developing a fast, fully automatic, GCP-free workflow for DSM generation. The problems caused by GCP-free workflow are overcome using freely-available, low resolution static DSMs (LR-DSM). LR-DSM is registered to the reference satellite image and the registered LR-DSM is used for i) correspondence generation and ii) initial estimate generation for 3-D reconstruction. Novel methods are developed for bias removal for LR-DSM registration and bias equalization for projection functions of satellite imaging. The LR-DSM registration is also shown to be useful for computing the parameters of simple, piecewise empirical projective models. Recent computer vision approaches on stereo correspondence generation and dense depth estimation are tested and adopted for spaceborne DSM generation. The study also presents a complete, fully automatic scheme for GCPfree DSM generation and demonstrates that GCP-free DSM generation is possible and can be performed in much faster time on computers. The resulting DSM can be used in various remote sensing applications including building extraction, disaster monitoring and change detection.

Avaliação de qualidade cartográfica e extração de bordas de objetos não pertencentes ao terreno em produtos gerados pelo sistema de varredura a laser aerotransportado. / Map quality evaluation and edge extraction of off-terrain objects on airbone laser scanner products.

André Luiz Neves de Souza

26 May 2009

O sistema de varredura a LASER aerotransportado é uma tecnologia competitiva para levantamentos que visam à geração de modelos digitais de superfície (MDS) e modelos digitais de terreno (MDT). Esta tecnologia sofreu certa resistência por parte das empresas de aerolevantamento e de alguns usuários, porém vem conquistando o mercado, graças à grande quantidade de trabalhos recentemente publicados. Uma das limitações associadas ao levantamento a LASER é a correta detecção de objetos não pertencentes ao terreno como árvores e edificações. Esses objetos, quando devidamente identificados, são essenciais para várias aplicações como cadastro e avaliação da qualidade cartográfica. Este trabalho propõe uma metodologia de identificação de edificações através da detecção de suas bordas, em uma rede triangular (TIN) construída sobre a nuvem de pontos. A utilização da TIN preserva os valores originais da amostra e, representa o universo real com melhor fidelidade que os modelos matriciais. A detecção é realizada calculando-se as declividades para todos os triângulos da TIN. Após esta etapa, são segmentados todos os triângulos que possuem valor de declividade acima de um limiar, pois representam variações abruptas no terreno, condizentes com edificações. A definição do limiar depende da resolução da nuvem de pontos, padrão de varredura e natureza do terreno. O trabalho apresenta ferramentas preliminares para automatizar a vetorização das bordas detectadas. As edificações extraídas pela metodologia e ferramentas apresentadas, podem ser utilizadas para avaliação da qualidade cartográfica do MDS/MDT. Para isso, compara-se o MDS a um documento cartográfico de referência, e realizam-se testes para: detecção e eliminação de erros grosseiros, detecção de tendências e minimização de erros sistemáticos, testes de precisão e de atendimento ao Padrão de Exatidão Cartográfico (PEC). Após análises, conclui-se que a metodologia de detecção de bordas propostas é eficiente, porém as ferramentas de automatização precisam ser aperfeiçoadas. Conclui-se também que o MDS oriundo do levantamento a LASER tem qualidade cartográfica compatível com o produto cartográfico de referência. Recomenda-se aplicação das metodologias propostas em outros conjuntos de dados. / The airborne LASER scanner is competitive technology for surveys that generates digital surface models (DSM) and Digital Terrain Models (DTM). This technology suffered some resistance by the aerosurvey enterprise (and some users), but is conquering its market share due the amount of papers recently published in this field. A limitation associated with this technique is the correct detection of the offterrain objects, like trees and buildings. These objects, when well identified, are essential to a sort of applications like cadastre e map quality evaluation. This dissertation proposes a methodology to identify buildings by the edge detection of a triangular irregular net (TIN) built over the point cloud. The utilization of TIN preserves the original values, representing the real 3D universe with fidelity despite the raster models. The detection is done calculating the slopes for all triangles of the TIN. After that, the triangles with slope values above a threshold are segmented. The Threshold definition depends on resolution of the point cloud, scan pattern and target behavior. Triangles with high slope values represent hard variation and may mean buildings. This work shows preliminary tools to automate the vectorization of the detected edges. The extracted buildings may be used for map quality evaluation of the DSM/DTM, by comparing it with a reference map. This means: test for detection e elimination of bundles, test for detection and minimization of systematic errors, precision tests and evaluate the meeting the Brazilian cartographic accuracy standard (PEC). Theses analysis concludes that the proposed methodology of edge detection is efficient but the developed tools of automation may be sharpened. Also, concludes that the DSM built with LASER scanner survey is compatible with reference map. Its recommended the application of the methodology on other collections of data.

Cartografia

Controle da qualidade

Detecção de bordas

Dispositivos de varredura (topografia)

Modelagem de dados

Digital surface model

Edge detetcion

LASER scan

Spatial, Temporal, and Geometric Fusion for Remote Sensing Images

Albanwan, Hessah

01 September 2022

No description available.

Civil Engineering

Remote Sensing

Generation of hyperspectral digital surface model in forest areas using hyperspectral 2D frame camera onboard RPAS / Geração de modelo digital de superfície hiperespectral, em áreas de floresta utilizando câmara hiperespectral de quadro embarcada em VANT

Oliveira, Raquel Alves de [UNESP]

29 June 2017

Submitted by Raquel Alves de Oliveira (raquel88@gmail.com) on 2017-12-07T10:06:49Z No. of bitstreams: 1 Oliveira_2017_TESE.pdf: 10400710 bytes, checksum: 4c4e6b235bd849c0d16074edea702847 (MD5) / Approved for entry into archive by ALESSANDRA KUBA OSHIRO null (alessandra@fct.unesp.br) on 2017-12-07T11:22:22Z (GMT) No. of bitstreams: 1 oliveira_ra_dr_prud.pdf: 10400710 bytes, checksum: 4c4e6b235bd849c0d16074edea702847 (MD5) / Made available in DSpace on 2017-12-07T11:22:23Z (GMT). No. of bitstreams: 1 oliveira_ra_dr_prud.pdf: 10400710 bytes, checksum: 4c4e6b235bd849c0d16074edea702847 (MD5) Previous issue date: 2017-06-29 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) / Recentemente, os sensores hiperespectrais miniaturizados entraram no mercado e alguns modelos adquirem bandas hiperespectrais com geometria de quadro, com a vantagem de serem também operados em veículos aéreos remotamente pilotados (VARP). As imagens deste tipo de câmara podem ser utilizadas para a geração de modelos digitais de superfície hiperespectral (MDSHs) de alta resolução, usando o VARP, sem a necessidade do registro de dados de diferentes sensores ou diferente datas de aquisição. MDSHs aumentam o conhecimento sobre os alvos, uma vez que permitem modelar a reflectância do alvo utilizando dados provenientes de diferentes direções. Neste trabalho, a câmara hiperespectral de quadro utilizada não adquire todas as bandas instantaneamente, causando um deslocamento entre as bandas devido ao movimento da plataforma. Os principais objetivos deste projeto foram estudar e desenvolver técnicas para a geração de MDSHs em áreas de florestas, investigando e avaliando as principais etapas para o processamento das imagens da câmara hiperespectral de quadro até a geração do MSDH. Considerando que a tecnologia da câmara baseia-se em filtros ajustáveis, o estudo avaliou: a auto-calibração da câmara, verificando o comportamento dos parâmetros de orientação interior em diferentes bandas espectrais; o corregistro das bandas através de transformações geométricas 2D; e a estimativa dos parâmetros de orientação exterior. Em relação à geração do MDS, uma abordagem baseada em correspondência de imagem no espaço do objeto foi desenvolvida, adaptando o método de busca em linha vertical (VLL) para a geração MDSH e foi nomeado como VLL hiperespectral (HVLL). Adicionalmente, o uso de imagens classificadas para a adaptação dos parâmetros de correspondência foi avaliado com o objetivo de melhorar o processo de correspondência para diferentes objetos (HVLLC). Posteriormente, foram utilizadas múltiplas bandas no processo de correspondência de imagens, dados como múltiplos ângulos de visada e informação espectral foram calculados simultaneamente ao processo de correspondência de imagens. A avaliação da qualidade foi realizada comparando-se os MDSs gerados com os produzidos por um software comercial e por dados Airborne Laser Scanning (ALS). Esta investigação demonstrou que a técnica proposta pode ser usada para a geração de modelos 3D integrados aos dados hiperespectrais multiangulares da câmara hiperespectral de quadro. A avaliação de todas as etapas demonstrou que esta tecnologia pode fornecer dados geométricos e espectrais precisos e os MDSHs resultantes possuem potencial para várias aplicações de sensoriamento remoto. / Recently, miniaturized hyperspectral sensors, operable from small Remotely Piloted Aerial Systems (RPAS), have entered the market and some of these sensors acquire hyperspectral bands in frame geometry. Images of the lightweight hyperspectral 2D frame camera can be used to generate high-resolution hyperspectral digital surface models (HDSMs), without the registration of data from different sensors or different dates of acquisition. HSDMs increase the knowledge about the targets since it allows modeling the target reflectance using data coming from different directions. In this study, the hyperspectral 2D frame camera used does not acquire all bands instantaneously, causing band misalignment due to the platform motion. The main aims of this project were to study and develop techniques for the generation of HDSMs in forest areas, studying and assessing the main steps to process the hyperspectral 2D frame camera images until the HDSM generation. Considering that the camera technology is based on tunable filters, the study have assessed the orientation and DSM generation steps: the self-calibrating bundle adjustment to verify the behaviour of the interior orientation parameters using different spectral bands; the co-registration of the bands using 2D geometric transformation; the exterior orientation parameter estimation. Regarding to the DSM generation, an approach based on object space image matching was developed, adapting the vertical line locus (VLL) method for HDSM generation, and was named as hyperspectral VLL (HVLL). Additionally, the use of image classification data was investigated in order to adapt the image matching parameters and improve the process of image matching for different objects (hyperspectral VLL classes - HVLLC). Further, multiple bands were used and the spectral and multiangular viewing geometry were computed simultaneously to the image matching method. Quality assessment was performed by comparing to DSMs generated to those produced by commercial software and also by Airborne Laser Scanning (ALS) data. This investigation demonstrated that the proposed technique can be used to generate integrated 3D information and multiangular hyperspectral data from hyperspectral 2D frame camera. The assessment of all steps showed that the hyperspectral 2D frame technology can provide accurate geometric and spectral data and the resulting HDSMs have potential for several remote sensing applications. / FAPESP: 2013/17787-3 / FAPESP: 2013/14444-0 / FAPESP: 2014/24844-6

Correspondência de imagens

Câmara hiperespectral de quadro

Nuvem de pontos de floresta

Image matching

Hyperspectral digital surface model

Hyperspectral frame camera

Forest point cloud