Your search keyword '"multi-spectral"' showing total 444 results

101. Wildfire Smoke Particle Properties and Evolution, from Space-Based Multi-Angle Imaging

Author

Katherine Junghenn Noyes, Ralph Kahn, Arthur Sedlacek, Lawrence Kleinman, James Limbacher, and Zhanqing Li

Subjects

biomass burning, remote sensing, misr, smoke plumes, aerosol particle properties, aerosols, bbop, multi-angle, multi-spectral, wildfire, Science

Abstract

Emitted smoke composition is determined by properties of the biomass burning source and ambient ecosystem. However, conditions that mediate the partitioning of black carbon (BC) and brown carbon (BrC) formation, as well as the spatial and temporal factors that drive particle evolution, are not understood adequately for many climate and air-quality related modeling applications. In situ observations provide considerable detail about aerosol microphysical and chemical properties, although sampling is extremely limited. Satellites offer the frequent global coverage that would allow for statistical characterization of emitted and evolved smoke, but generally lack microphysical detail. However, once properly validated, data from the National Aeronautics and Space Administration (NASA) Earth Observing System’s Multi-Angle Imaging Spectroradiometer (MISR) instrument can create at least a partial picture of smoke particle properties and plume evolution. We use in situ data from the Department of Energy’s Biomass Burning Observation Project (BBOP) field campaign to assess the strengths and limitations of smoke particle retrieval results from the MISR Research Aerosol (RA) retrieval algorithm. We then use MISR to characterize wildfire smoke particle properties and to identify the relevant aging factors in several cases, to the extent possible. The RA successfully maps qualitative changes in effective particle size, light absorption, and its spectral dependence, when compared to in situ observations. By observing the entire plume uniformly, the satellite data can be interpreted in terms of smoke plume evolution, including size-selective deposition, new-particle formation, and locations within the plume where BC or BrC dominates.

Published

2020

102. Detection of Aquatic Plants Using Multispectral UAV Imagery and Vegetation Index

Author

Bonggeun Song and Kyunghun Park

Subjects

unmanned aircraft vehicle, remote sensing, vegetation index, aquatic plants, gis, multi-spectral, Science

Abstract

In this study, aquatic plants in a small reservoir were detected using multispectral UAV (Unmanned Aerial Vehicle) imagery and various vegetation indices. A Firefly UAV, which has both fixed-wing and rotary-wing flight modes, was flown over the study site four times. A RedEdge camera was mounted on the UAV to acquire multispectral images. These images were used to analyze the NDVI (Normalized Difference Vegetation Index), ENDVI (Enhance Normalized Difference Vegetation Index), NDREI (Normalized Difference RedEdge Index), NGRDI (Normalized Green-Red Difference Index), and GNDVI (Green Normalized Difference Vegetation Index). As for multispectral characteristics, waterside plants showed the highest reflectance in Rnir, while floating plants had a higher reflectance in Rre. During the hottest season (on 25 June), the vegetation indices were the highest, and the habitat expanded near the edge of the reservoir. Among the vegetation indices, NDVI was the highest and NGRDI was the lowest. In particular, NGRDI had a higher value on the water surface and was not useful for detecting aquatic plants. NDVI and GNDVI, which showed the clearest difference between aquatic plants and water surface, were determined to be the most effective vegetation indices for detecting aquatic plants. Accordingly, the vegetation indices using multispectral UAV imagery turned out to be effective for detecting aquatic plants. A further study will be accompanied by a field survey in order to acquire and analyze more accurate imagery information.

Published

2020

103. Assessing a novel modelling approach with high resolution UAV imagery for monitoring health status in priority riparian forests

Author

Patricia María Rodríguez-González, Juan Gabriel Ávarez-González, Juan Guerra-Hernández, and Ramón Alberto Díaz-Varela

Subjects

texture variables, multi-spectral, RPAS, Multispectral image, Alder, Normalized Difference Vegetation Index, Riparian forest, Ecology, Evolution, Behavior and Systematics, QH540-549.5, Nature and Landscape Conservation, geography, geography.geographical_feature_category, defoliation, biology, Ecology, Texture variables, Multi-spectral, Confusion matrix, Forestry, Vegetation, biology.organism_classification, Random forest, 3D point cloud, Alnus glutinosa, tree health monitoring, Defoliation, Environmental science, Cartography

Abstract

Research Background: Black alder (Alnus glutinosa) forests are in severe decline across their area of distribution due to a disease caused by the soil-borne pathogenic Phytophthora alni species complex (class Oomycetes), “alder Phytopththora”. Mapping of the different types of damages caused by the disease is challenging in high density ecosystems in which spectral variability is high due to canopy heterogeneity. Data obtained by unmanned aerial vehicles (UAVs) may be particularly useful for such tasks due to the high resolution, flexibility of acquisition and cost efficiency of this type of data. In this study, A. glutinosa decline was assessed by considering four categories of tree health status in the field: asymptomatic, dead and defoliation above and below a 50% threshold. A combination of multispectral Parrot Sequoia and UAV unmanned aerial vehicles -red green blue (RGB) data were analysed using classical random forest (RF) and a simple and robust three-step logistic modelling approaches to identify the most important forest health indicators while adhering to the principle of parsimony. A total of 34 remote sensing variables were considered, including a set of vegetation indices, texture features from the normalized difference vegetation index (NDVI) and a digital surface model (DSM), topographic and digital aerial photogrammetry-derived structural data from the DSM at crown level. Results: The four categories identified by the RF yielded an overall accuracy of 67%, while aggregation of the legend to three classes (asymptomatic, defoliated, dead) and to two classes (alive, dead) improved the overall accuracy to 72% and 91% respectively. On the other hand, the confusion matrix, computed from the three logistic models by using the leave-out cross-validation method yielded overall accuracies of 75%, 80% and 94% for four-, three- and two-level classifications, respectively. Discussion: The study findings provide forest managers with an alternative robust classification method for the rapid, effective assessment of areas affected and non-affected by the disease, thus enabling them to identify hotspots for conservation and plan control and restoration measures aimed at preserving black alder forests info:eu-repo/semantics/publishedVersion

Published

2021

104. Assessment of Surface Soil Moisture Using High-Resolution Multi-Spectral Imagery and Artificial Neural Networks

Author

Leila Hassan-Esfahani, Alfonso Torres-Rua, Austin Jensen, and Mac McKee

Subjects

remote sensing, high-resolution, multi-spectral, soil moisture, Artificial Neural Network, UAV, Science

Abstract

Many crop production management decisions can be informed using data from high-resolution aerial images that provide information about crop health as influenced by soil fertility and moisture. Surface soil moisture is a key component of soil water balance, which addresses water and energy exchanges at the surface/atmosphere interface; however, high-resolution remotely sensed data is rarely used to acquire soil moisture values. In this study, an artificial neural network (ANN) model was developed to quantify the effectiveness of using spectral images to estimate surface soil moisture. The model produces acceptable estimations of surface soil moisture (root mean square error (RMSE) = 2.0, mean absolute error (MAE) = 1.8, coefficient of correlation (r) = 0.88, coefficient of performance (e) = 0.75 and coefficient of determination (R2) = 0.77) by combining field measurements with inexpensive and readily available remotely sensed inputs. The spatial data (visual spectrum, near infrared, infrared/thermal) are produced by the AggieAir™ platform, which includes an unmanned aerial vehicle (UAV) that enables users to gather aerial imagery at a low price and high spatial and temporal resolutions. This study reports the development of an ANN model that translates AggieAir™ imagery into estimates of surface soil moisture for a large field irrigated by a center pivot sprinkler system.

Published

2015

105. Aerosol retrieval algorithm based on adaptive land–atmospheric decoupling for polarized remote sensing over land surfaces.

Author

Wang, Han, Sun, Xiaobing, Yang, Leiku, Zhao, Meiru, Lui, Pei, and Du, Weibing

Subjects

*ATMOSPHERIC aerosols, *ALGORITHMS, *REMOTE sensing, *SOLAR radiation, *LAND surface temperature

Abstract

Highlights • Land surface reflected solar radiation is disturbance in aerosol remote sensing. • Solve the problem of land–atmosphere decoupling from polarized measurements more accurately. • Retrieved the global AOD from PARASOL measurements and distinguished the error sources. • AOD value has the greatest effect on the precision of the retrieval results. • The Angstrom exponent and NDVI values had only minor effects on the accuracy. Abstract Land–atmospheric decoupling is important for the retrieval accuracy in atmospheric remote sensing. In this study, we developed an algorithm that adaptively decouples the land surface and atmosphere reflected solar radiation and retrieves the aerosol properties (adaptive land–atmospheric decoupling algorithm, ALAD). The ALAD algorithm allows precise global aerosol optical depth (AOD) retrievals. The four sub-procedures in ALAD comprise estimating a first guess for surface properties, aerosol property retrieval, atmospheric correction, and assessing the results. The ALAD algorithm was applied to PARASOL (Polarization & Anisotropy of Reflectances for Atmospheric Sciences coupled with Observations from a Lidar) and the retrieved AODs were compared with the AOD products from the Moderate resolution Imaging Spectroradiometer (MODIS) and AErosol RObotic NETwork (AERONET). ALAD and MODIS retrieved AOD values were with good consistency in terms of their spatial distribution, regardless of the region or the global distribution. The correlation coefficient between the global ALAD and AERONET AOD was 0.875, and about 60.7% of the AODs retrieved by ALAD were within the expected error range of ±(15% AOD + 0.05). The results obtained using ALAD agreed well with the AERONET values. We also investigated the aerosol and land surface properties that might introduce errors into the AOD values retrieved by ALAD. It was found that the value of AOD had the greatest effect on the accuracy of the retrieval results. The errors introduced by the Angstrom exponent and Normalized Difference Vegetation Index varied slightly but they made no significant contributions. [ABSTRACT FROM AUTHOR]

Published

2018

106. Imaging spectrometer emulates Landsat: A case study with Airborne Visible Infrared Imaging Spectrometer (AVIRIS) and Operational Land Imager (OLI) data.

Author

Seidel, Felix C., Stavros, E. Natasha, Cable, Morgan L., Green, Robert, and Freeman, Anthony

Subjects

*ARTIFICIAL satellites, *REMOTE sensing, *LANDSAT satellites, *SPECTRAL imaging, *AIRBORNE Visible/Infrared Imaging Spectrometer (AVIRIS), *INFRARED spectroscopy, *INFRARED imaging

Abstract

Remote sensing data are most useful if they are available with sufficient precision, accuracy, spatiotemporal and spectral sampling, as well as continuity across decades. The Landsat and Sentinel series, as well other satellites are currently covering significant parts of this observational trade space. It can be expected that growing demands and budget constraints will require new capabilities in orbit that can address as many observables as possible with a single instrument. Recent optical performance improvements of imaging spectrometers make them true alternatives to traditional multispectral imagers. However, they are much more adaptable to a wide range of Earth observation needs due to the combination of continuous high spectral sampling with spatial sampling consistent with previous sensors (e.g., Landsat). Unfortunately, there is a knowledge gap in demonstrating that imaging spectroscopy data can substitute for multi-spectral data while sustaining the long-term record. Thus, the objective of this analysis is to test the hypothesis that imaging spectroscopy data compare radiometrically with multi-spectral data to within 5%. Using a coincident Airborne Visible/Infrared Imaging Spectrometer (AVIRIS) flight with over-passing Operational Land Imager (OLI) data on Landsat 8, we document a procedure for simulating OLI multi-spectral bands from AVIRIS data, evaluate influencing factors on the observed radiance, and assess the difference in top-of-atmosphere radiance as compared to OLI. The procedure for simulating OLI data include spectral convolution, accounting for the minimal atmospheric effects between the two sensors, and spatial resampling. The remaining differences between the simulated and the real OLI data result mainly from differences in sensor calibration, surface bi-directional reflectance, and spatial sampling. The median relative radiometric difference for each band ranges from −8.3% to 0.6%. After bias-correction to minimize potential calibration discrepancies, we find no more than a 1.2% relative difference. This analysis therefore successfully demonstrates that imaging spectrometer data can contribute to Landsat-type or other multi-spectral data records. It also shows that cross-calibration from a spectrometer to a radiometer can be easily performed as a result of the imaging spectrometer high spectral sampling and its ability to recreate multi-spectral response functions. [ABSTRACT FROM AUTHOR]

Published

2018

107. Grain yield prediction using multi-temporal UAV-based multispectral vegetation indices and endmember abundance in rice.

Author

Su, Xi, Wang, Jiacheng, Ding, Lu, Lu, Jingshan, Zhang, Jiawen, Yao, Xia, Cheng, Tao, Zhu, Yan, Cao, Weixing, and Tian, Yongchao

Subjects

*GRAIN yields, *MULTISPECTRAL imaging, *DRONE aircraft, *PADDY fields, *GRAIN trade, *REMOTE sensing

Abstract

Timely and accurately predicting grain yield before harvest is of great importance for rice production management and grain trade. Numerous methods based on remote sensing (RS) technology have explored to estimate rice grain yield. However, in most cases, these methods are negatively affected by the mixed pixels of RS images due to the effect of background and panicles. To resolve such issues, the abundance information of leaves, soil and water background and rice panicles were extracted from the multispectral images of unmanned aerial vehicle (UAV) for the multiple endmember spectral mixture analysis (MESMA) method. Based on the analysis of contribution of vegetation index (VI) and abundance (ABD) to rice grain yield, a rice grain yield prediction model was developed by combining multi-stage time-series, ABD and VI. Results showed that MESMA can mitigate endmember variability in the estimation of rice yield, and achieve higher accuracy than conventional spectral mixture analysis (SMA). The NDRE and the sum of leaf and panicle abundance (ABD L+P) can be well correlated to grain yield before heading stage (R2 = 0.75) and at heading stage (R2 = 0.72), respectively. In comparison to them, the multi-stage time-series model consisted of VI and ABD [∑(VI&ABD)] produces the highest correlation (R2 = 0.80). It could also resolve the issues about the underestimation of yield using different datasets from various multi-spectral camera in comparison to the single-parameter models ∑VI and ∑ABD, and produce the good validation accuracy with R2 = 0.73, RRMSE= 0.22 and R2 = 0.75, RRMSE= 0.15, respectively. This study suggests that the combination of UAV multi-temporal VI and ABD data can achieve accurate prediction of rice grain yield. This method effectively utilizes the optical information of leaves and rice panicles and reduces background effects, which provides a new idea for accurate rice yield prediction. • A multi-stage time-series GY prediction model combining VI and EM abundance. • MESMA method solves the problem of spectral variability in rice fields. • GY response is contributed by both leaves and panicles. • The model used NDRE at booting and ABD from heading to initial filling can give the best results. [ABSTRACT FROM AUTHOR]

Published

2023

108. Compression and Multi-Spectral Sensing for Video Based Physiological Monitoring

Author

Steinhauser, Carl Frederick and Steinhauser, Carl Frederick

Abstract

Remote physiological monitoring is an active area of research that extends monitoring capabilities traditionally found in a clinical setting towards the home, telehealth, and beyond. In particular, there is interest in leveraging consumer electronic devices for sensing physiological characteristics such as heart rate, heart rate variability, and blood oxygen saturation. This thesis focuses on enhancing the understanding and usage of the sensing component for these applications to improve the performance and quality of cardio-physiological monitoring. First, a close relationship between the color spaces used for video compression and the color projection planes commonly used for heart rate estimation is identified. % that results in higher compression of the physiological signal. The study demonstrates the impact of this observation on real and synthetic data to provide a foundation to guide future video coding to optimize its configurations to better preserve the heart rate signal for health related applications. Second, an investigation with a commercial-off-the-shelf (COTS) multi-spectral sensor is presented with key observations related to the sampling rate, exposure settings, and multi-channel processing. These observations will enable better usage of the sensor for future studies and data collections that leverage the more precise spectral measurements from the multi-spectral sensor compared to standard RGB cameras.

Published

2022

109. SEN23E: A Cloudless Geo-Referenced Multi-Spectral Sentinel-2/Sentinel-3 Dataset for Data Fusion Analysis

Author

Ibáñez Fernández, Damián, Fernandez-Beltran, Ruben, and Pla, Filiberto

Subjects

data fusion, remote sensing, multi-spectral, sentinel-3 (S3), dataset, sentinel-2 (S2)

Abstract

Ponència presentada en el IEEE International Symposium on Geoscience and Remote Sensing (IGARSS 2022) The availability of geo-referenced coupled data of dif-ferent platforms is essential to train remote sensing (RS) multi-modal classification and bio-phyiscal parameter esti-mation learning methods. To properly develop a general-izing model different scenes and topographies are required. For this purpose, different multi-modal datasets have been published for the last years. Nevertheless, to our knowl-edge there is not any dataset composed of Sentinel-2 (S2) and Sentinel-3 (S3) geo-referenced images. In this paper we present SEN23, a dataset composed of 100 complete multi-spectral S2 and S3 paired images of different locations along Europe from the 2021 summer. The coupled images were obtained with a time difference of three or less days, containing less than a 1 % of cloud coverage and have a resolution difference of × 15. SEN23E is expected to help with the development of new multi-spectral, multi-resolution and multi-modal models for complex tasks which need con-text and complete images. SEN23E will be available at https://github.com/ibanezdf/SEN23E.

Published

2022

110. Improving Estimation Accuracy of Growing Stock by Multi-Frequency SAR and Multi-Spectral Data over Iran’s Heterogeneously-Structured Broadleaf Hyrcanian Forests

Author

Mohammad Sadegh Ataee, Yasser Maghsoudi, Hooman Latifi, and Farhad Fadaie

Subjects

GSV, nu SVR, uneven-aged mountainous, polarimetery, multi-spectral, optimization, Plant ecology, QK900-989

Abstract

Via providing various ecosystem services, the old-growth Hyrcanian forests play a crucial role in the environment and anthropogenic aspects of Iran and beyond. The amount of growing stock volume (GSV) is a forest biophysical parameter with great importance in issues like economy, environmental protection, and adaptation to climate change. Thus, accurate and unbiased estimation of GSV is also crucial to be pursued across the Hyrcanian. Our goal was to investigate the potential of ALOS-2 and Sentinel-1’s polarimetric features in combination with Sentinel-2 multi-spectral features for the GSV estimation in a portion of heterogeneously-structured and mountainous Hyrcanian forests. We used five different kernels by the support vector regression (nu-SVR) for the GSV estimation. Because each kernel differently models the parameters, we separately selected features for each kernel by a binary genetic algorithm (GA). We simultaneously optimized R2 and RMSE in a suggested GA fitness function. We calculated R2, RMSE to evaluate the models. We additionally calculated the standard deviation of validation metrics to estimate the model’s stability. Also for models over-fitting or under-fitting analysis, we used mean difference (MD) index. The results suggested the use of polynomial kernel as the final model. Despite multiple methodical challenges raised from the composition and structure of the study site, we conclude that the combined use of polarimetric features (both dual and full) with spectral bands and indices can improve the GSV estimation over mixed broadleaf forests. This was partially supported by the use of proposed evaluation criterion within the GA, which helped to avoid the curse of dimensionality for the applied SVR and lowest over estimation or under estimation.

Published

2019

111. Multi-Temporal Agricultural Land-Cover Mapping Using Single-Year and Multi-Year Models Based on Landsat Imagery and IACS Data

Author

Isaac Kyere, Thomas Astor, Rüdiger Graß, and Michael Wachendorf

Subjects

agricultural land-cover, multi-spectral, generalized model, machine learning, crop type mapping, Integrated Administration and Control System, remote sensing, Agriculture

Abstract

The spatial distribution and location of crops are necessary information for agricultural planning. The free availability of optical satellites such as Landsat offers an opportunity to obtain this key information. Crop type mapping using satellite data is challenged by its reliance on ground truth data. The Integrated Administration and Control System (IACS) data, submitted by farmers in Europe for subsidy payments, provide a solution to the issue of periodic field data collection. The present study tested the performance of the IACS data in the development of a generalized predictive crop type model, which is independent of the calibration year. Using the IACS polygons as objects, the mean spectral information based on four different vegetation indices and six Landsat bands were extracted for each crop type and used as predictors in a random forest model. Two modelling methods called single-year (SY) and multiple-year (MY) calibration were tested to find out their performance in the prediction of grassland, maize, summer, and winter crops. The independent validation of SY and MY resulted in a mean overall accuracy of 71.5% and 77.3%, respectively. The field-based approach of calibration used in this study dealt with the ‘salt and pepper’ effects of the pixel-based approach.

Published

2019

112. Detection of oil spills in inland lake using multi-spectral satellite images

Author

Mantsis, Damianos Florin, Bakratsas, Marios, Vlachos, Konstantinos, Moumtzidou, Anastasia, Gialampoukidis, Ilias, Vrochidis, Stefanos, and Kompatsiaris, Ioannis

Subjects

multi-spectral, inland water, oil spill, deep neural network, Sentinel-2

Abstract

Satellite images play a crucial role in monitoring Earth’s oceans, especially when it comes to oil spills. Traditionally, detection methods use Synthetic Aperture Radar (SAR) images that allow the detection of oil spills independent of clouds or daylight. However, SAR based methods are limited by wind conditions, as well as, look-alikes. Multispectral satellite images are perfect tools to fill this gap given that they allow the detection of pollution when weak or strong winds do not allow the use of SAR images. For this, a case of oil spill contamination is investigated in an inland lake in northern Greece using Sentinel-2 and PlanetScope multi-spectral images. This case is characterized by a small sample of known oil spills, making this study even more challenging. First, we implement different atmospheric corrections to acquire the remote sensing reflectance for the multispectral bands. Our sensitivity analysis shows that the detection capability for oil spills in not constrained only to the visible (VIS) part of the spectrum, but also extends to the Near Infrared (NIR), as well as, the Short Wavelength Infrared (SWIR). Among these, the NIR (833 nm) and Narrow NIR (865 nm) seem to have the largest sensitivity to fresh water oil spills. Additionally, the oil spills investigated tend to enhance the remote sensing reflectance for the NIR and SWIR part of the spectrum, but reduce it for the VIS bands, with the exception of Red (665 nm), which has a more ambiguous behavior. Given the reduced known oil spill cases (just two) for this study a pixel based machine learning approach is implemented instead of an object based one. Furthermore, the size of the oil spills will determine the choice of the bands, given that low resolution bands tend to reduce the pixel sample, and high resolution bands are limited by their availability (only four are available). Finally, the chosen bands are feed into a Deep Neural Network with two hidden layers for processing and the optimal hyperparameters are investigated. Despite the limited oil spill sample, the results are encouraging, showing a good detection capability.

Published

2022

113. Design and fabrication of a multi-spectral near-infrared fundus camera with a patterned interference filter for light scattering detection

Author

Wang, Ze

Subjects

patterned interference filter, multi-spectral, human health care, near-infrared, fundus camera, scattering detection

Published

2022

114. Dimension Reduction of Multi-Spectral Satellite Image Time Series to Improve Deforestation Monitoring.

Author

Meng Lu, Hamunyela, Eliakim, Verbesselt, Jan, and Pebesma, Edzer

Subjects

*DEFORESTATION, *MULTISPECTRAL imaging, *REMOTE-sensing images, *TIME series analysis, *COINTEGRATION

Abstract

In recent years, sequential tests for detecting structural changes in time series have been adapted for deforestation monitoring using satellite data. The input time series of such sequential tests is typically a vegetation index (e.g., NDVI), which uses two or three bands and ignores all other bands. Being limited to a vegetation index will not benefit from the richer spectral information provided by newly launched satellites and will bring two bottle-necks for deforestation monitoring. Firstly, it is hard to select a suitable vegetation index a priori. Secondly, a single vegetation index is typically affected by seasonal signals, noise and other natural dynamics, which decrease its power for deforestation detection. A novel multispectral time series change monitoring method that combines dimension reduction methods with a sequential hypothesis test is proposed to address these limitations. For each location, the proposed method automatically chooses a “suitable” index for deforestation monitoring. To demonstrate our approach, we implemented it in two study areas: a dry tropical forest in Bolivia (time series length: 444) with strong seasonality and a moist tropical forest in Brazil (time series length: 225) with almost no seasonality. Our method significantly improves accuracy in the presence of strong seasonality, in particular the temporal lag between disturbance and its detection. [ABSTRACT FROM AUTHOR]

Published

2017

115. The study of spectrum reconstruction based on fuzzy set full constraint and multiendmember decomposition.

Author

Yanbiao Sun, Yi Lin, Xingbang Hu, Shuaiyang Zhao, Suihua Liu, Qingxi Tong, Dennis, Helder, and Lei Yan

Subjects

FUZZY sets, HYPERSPECTRAL imaging systems, REMOTE sensing

Abstract

Hyperspectral imaging system can obtain spectral and spatial information simultaneously with bandwidth to the level of 10 nm or even less. Therefore, hyperspectral remote sensing has the ability to detect some kinds of objects which can not be detected in wide-band remote sensing, making it becoming one of the hottest spots in remote sensing. In this study, under conditions with a fuzzy set of full constraints, Normalized Multi-Endmember Decomposition Method (NMEDM) for vegetation, water, and soil was proposed to reconstruct hyperspectral data using a large number of high-quality multispectral data and auxiliary spectral library data. This study considered spatial and temporal variation and decreased the calculation time required to reconstruct the hyper-spectral data. The results of spectral reconstruction based on NMEDM showed that the reconstructed data has good qualities and certain applications, which makes it possible to carry out spectral features identification. This method also extends the application of depth and breadth of remote sensing data, helping to explore the law between multispectral and hyperspectral data. [ABSTRACT FROM AUTHOR]

Published

2017

116. DASC: Robust Dense Descriptor for Multi-Modal and Multi-Spectral Correspondence Estimation.

Author

Kim, Seungryong, Min, Dongbo, Ham, Bumsub, Do, Minh N., and Sohn, Kwanghoon

Subjects

*MULTISPECTRAL imaging, *DENSITY, *MODALITY (Theory of knowledge), *STATISTICAL correlation, *PHOTOMETRY, *GEOMETRIC approach

Abstract

Establishing dense correspondences between multiple images is a fundamental task in many applications. However, finding a reliable correspondence between multi-modal or multi-spectral images still remains unsolved due to their challenging photometric and geometric variations. In this paper, we propose a novel dense descriptor, called dense adaptive self-correlation (DASC), to estimate dense multi-modal and multi-spectral correspondences. Based on an observation that self-similarity existing within images is robust to imaging modality variations, we define the descriptor with a series of an adaptive self-correlation similarity measure between patches sampled by a randomized receptive field pooling, in which a sampling pattern is obtained using a discriminative learning. The computational redundancy of dense descriptors is dramatically reduced by applying fast edge-aware filtering. Furthermore, in order to address geometric variations including scale and rotation, we propose a geometry-invariant DASC (GI-DASC) descriptor that effectively leverages the DASC through a superpixel-based representation. For a quantitative evaluation of the GI-DASC, we build a novel multi-modal benchmark as varying photometric and geometric conditions. Experimental results demonstrate the outstanding performance of the DASC and GI-DASC in many cases of dense multi-modal and multi-spectral correspondences. [ABSTRACT FROM AUTHOR]

Published

2017

117. Assessing very high resolution UAV imagery for monitoring forest health during a simulated disease outbreak.

Author

Dash, Jonathan P., Watt, Michael S., Pearse, Grant D., Heaphy, Marie, and Dungey, Heidi S.

Subjects

*HIGH resolution imaging, *FOREST health, *FOREST monitoring, *TREE farms, *REMOTE sensing

Abstract

Research into remote sensing tools for monitoring physiological stress caused by biotic and abiotic factors is critical for maintaining healthy and highly-productive plantation forests. Significant research has focussed on assessing forest health using remotely sensed data from satellites and manned aircraft. Unmanned aerial vehicles (UAVs) may provide new tools for improved forest health monitoring by providing data with very high temporal and spatial resolutions. These platforms also pose unique challenges and methods for health assessments must be validated before use. In this research, we simulated a disease outbreak in mature Pinus radiata D. Don trees using targeted application of herbicide. The objective was to acquire a time-series simulated disease expression dataset to develop methods for monitoring physiological stress from a UAV platform. Time-series multi-spectral imagery was acquired using a UAV flown over a trial at regular intervals. Traditional field-based health assessments of crown health (density) and needle health (discolouration) were carried out simultaneously by experienced forest health experts. Our results showed that multi-spectral imagery collected from a UAV is useful for identifying physiological stress in mature plantation trees even during the early stages of tree stress. We found that physiological stress could be detected earliest in data from the red edge and near infra-red bands. In contrast to previous findings, red edge data did not offer earlier detection of physiological stress than the near infra-red data. A non-parametric approach was used to model physiological stress based on spectral indices and was found to provide good classification accuracy (weighted kappa = 0.694). This model can be used to map physiological stress based on high-resolution multi-spectral data. [ABSTRACT FROM AUTHOR]

Published

2017

118. Discrimination of beef muscle based on visible-near infrared multi-spectral features: Textural and spectral analysis.

Author

Aït-Kaddour, Abderrahmane, Jacquot, Sylvain, Micol, Didier, and Listrat, Anne

Subjects

*BEEF, *ERECTOR spinae muscles, *CATTLE carcasses, *ABDOMINAL muscles, *ANIMAL carcasses

Abstract

The potential of multi-spectral visible-near infrared imaging to discriminate beef meat muscles in relation with their type and animal origin was examined in the present study. Two hundred forty muscles of three types (longissimus thoracis, biceps femoris, andsemimembranosus) were obtained from the carcasses of three types of animals, two late-maturing cattle types of animals (Limousin and Blond d’Aquitaine) that grow slowly and deposit more muscles and less fat, compared to one early-maturing cattle types of animals (Angus) which tends to have muscles richer in collagen and in intramuscular fat. Two hundred forty cube images were collected with nineteen Ligth Emitting Diodes (405 to 1050 nm) using the Videometer Lab2 device. The image cubes were processed in order to extract image mean spectra and image shape features from co-occurrence and difference of histogram matrices. The results of the partial least square discriminant analysis performed on image texture features and spectral data show a maximum ranging from 63.5 to 83% of good classification depending on the muscle and breed considered. This study demonstrated the promising potential of the visible-near infrared multi-spectral imager to characterize beef meat muscles based on muscle type and its animal origin. [ABSTRACT FROM PUBLISHER]

Published

2017

119. 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

120. Mineral Mapping for Exploration: An Australian Journey of Evolving Spectral Sensing Technologies and Industry Collaboration.

Author

Cudahy, Thomas

Subjects

PROSPECTING, MINERAL industries, CARTOGRAPHY, EQUIPMENT & supplies

Abstract

This paper describes selected results from over a dozen collaborative projects led by Commonwealth Scientific and Industrial Research Organisation (CSIRO) in Australia spanning a 30-year history of developments in satellite, airborne, field and drill core sensing technologies and how these can assist explorers to measure and map valuable mineral information. The exploration case histories are largely from Australian test sites and describe how spectral sensing technologies have progressed from early "niche creation" systems, such as the field PIMA-II (Portable Field Mineral Analyzer) and airborne Geoscan, HyMap™ and OARS-TIPS (Operational Airborne Remote Sensing - Thermal Infrared Profiling Spectrometer) systems and drill-core HyLogger™ systems, to the current expanding array of pubic and commercial mineral mapping sensors, including the ASTER (Advanced Spaceborne Thermal Emission and Reflectance Radiometer) satellite system which has acquired imagery spanning the entire Earth's land surface (<83°latitude). These sensors are delivering voluminous spectral data from different parts of the visible to the thermal infrared (400 to 14,000 nm) spectrum at different spectral, radiometric and spatial resolutions. Two critical exploration challenges are central to the case histories, namely: (i) can surface cover, such as vegetation, regolith or transported materials, be characterized and accounted for so that the target geology is accurately revealed; and (ii) does this revealed geology show evidence of alteration footprints to potential economic mineralization. Spectrally measurable minerals important to solving these challenges include white micas, kaolinite and garnets, with measurement of their respective physicochemistries being key. For example, kaolin disorder is useful for mapping transported versus weathered in situ materials, while the chemical substitution in white micas and garnets provide vectors to potential economic mineralization. Importantly, appropriate selection of the optimum sensor/data type for a given geological application depends primarily on the level of detail/accuracy of the mineral information required by the user. A major opportunity is to now harness the many sensor/data types and deliver to users consistent, accurate mineral information products, that is, creation of a number of valuable global mineral product standards. As part of this vision, CSIRO has been developing improved sensor/data calibration processes and information extraction methods that for example, unmix the target mineralogy from green and dry vegetation cover in remote sensing data sets. Emphasis to date has been on generating public spectral-mineral product standards, especially at ASTER's limited but geologically-valuable spectral resolution. The results are showing that scalable, global, three-dimensional (3D) mineral maps are achievable which will only improve our ability to more accurately characterize regolith and geological architecture, increase our understanding of formative processes and assist the discovery of new economic mineral systems. [ABSTRACT FROM AUTHOR]

Published

2016

121. Detection of change in vegetation cover using multi-spectral and multi-temporal information for District Sargodha, Pakistan / Detecção de alteração na cobertura vegetal com uso de informação multiespectral e multitemporal para o Distrito de Sargodha, Paquistão

Author

Farooq Ahmad

Subjects

Change detection, EVI, Landsat, multi-temporal, multi-spectral, NDVI, Pakistan, Environmental sciences, GE1-350, Social sciences (General), H1-99

Abstract

Detection of change is the measure of the distinct data framework and thematic change information that can direct to more tangible insights into underlying process involving land cover and landuse changes. Monitoring the locations and distributions of land cover changes is important for establishing links between policy decisions, regulatory actions and subsequent landuse activities. Change detection is the process that helps in determining the changes associated with landuse and land cover properties with reference to geo-registered multi-temporal remote sensing information. It assists in identifying change between two or more dates that is uncharacterized of normal variation. After image to image registrations, the normalized difference vegetation index (NDVI), the transformed normalized difference vegetation index (TNDVI), the enhanced vegetation index (EVI) and the soil-adjusted vegetation index (SAVI) values were derived from Landsat ETM+ dataset and an image differencing algorithm was applied to detect changes. This paper presents an application of the use of multi-temporal Landsat ETM+ images and multi-spectral MODIS (Terra) EVI/NDVI time-series vegetation phenology metrics for the District Sargodha. The results can be utilized as a temporal landuse change model for Punjab province of Pakistan to quantify the extent and nature of change and assist in future prediction studies. This will support environmental planning to develop sustainable landuse practices.

Published

2012

122. Glacier Monitoring Based on Multi-Spectral and Multi-Temporal Satellite Data: A Case Study for Classification with Respect to Different Snow and Ice Types

Author

Weinmann, Janine Florath, Sina Keller, Rodrigo Abarca-del-Rio, Stefan Hinz, Guido Staub, and Martin

Subjects

remote sensing, glacier monitoring, snow mapping, classification, multi-temporal, multi-spectral, change detection, Sentinel-2

Abstract

Remote sensing techniques are frequently applied for the surveying of remote areas, where the use of conventional surveying techniques remains difficult and impracticable. In this paper, we focus on one of the remote glacier areas, namely the Tyndall Glacier area in the Southern Patagonian Icefield in Chile. Based on optical remote sensing data in the form of multi-spectral Sentinel-2 imagery, we analyze the extent of different snow and ice classes on the surface of the glacier by means of pixel-wise classification. Our study comprises three main steps: (1) Labeled Sentinel-2 compliant data are obtained from theoretical spectral reflectance curves, as there are no training data available for the investigated area; (2) Four different classification approaches are used and compared in their ability to identify the defined five snow and ice types, thereof two unsupervised approaches (k-means clustering and rule-based classification via snow and ice indices) and two supervised approaches (Linear Discriminant Analysis and Random Forest classifier); (3) We first focus on the pixel-wise classification of Sentinel-2 imagery, and we then use the best-performing approach for a multi-temporal analysis of the Tyndall Glacier area. While the achieved classification results reveal that all of the used classification approaches are suitable for detecting different snow and ice classes on the glacier surface, the multi-temporal analysis clearly reveals the seasonal development of the glacier. The change of snow and ice types on the glacier surface is evident, especially between the end of ablation season (April) and the end of accumulation season (September) in Southern Chile.

Published

2022

123. Glacier Monitoring Based on Multi-Spectral and Multi-Temporal Satellite Data: A Case Study for Classification with Respect to Different Snow and Ice Types

Author

Florath, Janine, Keller, Sina, Abarca-Del-Rio, Rodrigo, Hinz, Stefan, Staub, Guido, and Weinmann, Martin

Subjects

remote sensing, multi-spectral, Earth sciences, classification, ddc:550, glacier monitoring, snow mapping, multi-temporal, Sentinel-2, change detection

Abstract

Remote sensing techniques are frequently applied for the surveying of remote areas, where the use of conventional surveying techniques remains difficult and impracticable. In this paper, we focus on one of the remote glacier areas, namely the Tyndall Glacier area in the Southern Patagonian Icefield in Chile. Based on optical remote sensing data in the form of multi-spectral Sentinel-2 imagery, we analyze the extent of different snow and ice classes on the surface of the glacier by means of pixel-wise classification. Our study comprises three main steps: (1) Labeled Sentinel-2 compliant data are obtained from theoretical spectral reflectance curves, as there are no training data available for the investigated area; (2) Four different classification approaches are used and compared in their ability to identify the defined five snow and ice types, thereof two unsupervised approaches (k-means clustering and rule-based classification via snow and ice indices) and two supervised approaches (Linear Discriminant Analysis and Random Forest classifier); (3) We first focus on the pixel-wise classification of Sentinel-2 imagery, and we then use the best-performing approach for a multi-temporal analysis of the Tyndall Glacier area. While the achieved classification results reveal that all of the used classification approaches are suitable for detecting different snow and ice classes on the glacier surface, the multi-temporal analysis clearly reveals the seasonal development of the glacier. The change of snow and ice types on the glacier surface is evident, especially between the end of ablation season (April) and the end of accumulation season (September) in Southern Chile.

Published

2022

124. Multi-source Remote Sensing for Forest Characterization and Monitoring

Author

Zhang, Qi

Subjects

Active fire, Forest height, 401304 Photogrammetry and remote sensing, LiDAR, Burned area, Multi-spectral, PolInSAR

Abstract

As a dominant terrestrial ecosystem of the Earth, forest environments play profound roles in ecology, biodiversity, resource utilization, and management, which highlights the significance of forest characterization and monitoring. Some forest parameters can help track climate change and quantify the global carbon cycle and therefore attract growing attention from various research communities. Compared with traditional in-situ methods with expensive and time-consuming field works involved, airborne and spaceborne remote sensors collect cost-efficient and consistent observations at global or regional scales and have been proven to be an effective way for forest monitoring. With the looming paradigm shift toward data-intensive science and the development of remote sensors, remote sensing data with higher resolution and diversity have been the mainstream in data analysis and processing. However, significant heterogeneities in the multi-source remote sensing data largely restrain its forest applications urging the research community to come up with effective synergistic strategies. The work presented in this thesis contributes to the field by exploring the potential of the Synthetic Aperture Radar (SAR), SAR Polarimetry (PolSAR), SAR Interferometry (InSAR), Polarimetric SAR Interferometry (PolInSAR), Light Detection and Ranging (LiDAR), and multispectral remote sensing in forest characterization and monitoring from three main aspects including forest height estimation, active fire detection, and burned area mapping. First, the forest height inversion is demonstrated using airborne L-band dual-baseline repeat-pass PolInSAR data based on modified versions of the Random Motion over Ground (RMoG) model, where the scattering attenuation and wind-derived random motion are described in conditions of homogeneous and heterogeneous volume layer, respectively. A boreal and a tropical forest test site are involved in the experiment to explore the flexibility of different models over different forest types and based on that, a leveraging strategy is proposed to boost the accuracy of forest height estimation. The accuracy of the model-based forest height inversion is limited by the discrepancy between the theoretical models and actual scenarios and exhibits a strong dependency on the system and scenario parameters. Hence, high vertical accuracy LiDAR samples are employed to assist the PolInSAR-based forest height estimation. This multi-source forest height estimation is reformulated as a pan-sharpening task aiming to generate forest heights with high spatial resolution and vertical accuracy based on the synergy of the sparse LiDAR-derived heights and the information embedded in the PolInSAR data. This process is realized by a specifically designed generative adversarial network (GAN) allowing high accuracy forest height estimation less limited by theoretical models and system parameters. Related experiments are carried out over a boreal and a tropical forest to validate the flexibility of the method. An automated active fire detection framework is proposed for the medium resolution multispectral remote sensing data. The basic part of this framework is a deep-learning-based semantic segmentation model specifically designed for active fire detection. A dataset is constructed with open-access Sentinel-2 imagery for the training and testing of the deep-learning model. The developed framework allows an automated Sentinel-2 data download, processing, and generation of the active fire detection results through time and location information provided by the user. Related performance is evaluated in terms of detection accuracy and processing efficiency. The last part of this thesis explored whether the coarse burned area products can be further improved through the synergy of multispectral, SAR, and InSAR features with higher spatial resolutions. A Siamese Self-Attention (SSA) classification is proposed for the multi-sensor burned area mapping and a multi-source dataset is constructed at the object level for the training and testing. Results are analyzed by different test sites, feature sources, and classification methods to assess the improvements achieved by the proposed method. All developed methods are validated with extensive processing of multi-source data acquired by Uninhabited Aerial Vehicle Synthetic Aperture Radar (UAVSAR), Land, Vegetation, and Ice Sensor (LVIS), PolSARproSim+, Sentinel-1, and Sentinel-2. I hope these studies constitute a substantial contribution to the forest applications of multi-source remote sensing.

Published

2022

125. Fast urban land cover mapping exploiting sentinel-1 and sentinel-2 data

Author

ANDREA VIRGILIO MONTI-GUARNIERI, Naomi Petrushevsky, and Marco Manzoni

Subjects

Science, Multi-spectral, General Earth and Planetary Sciences, Synthetic aperture radar, Data fusion, Machine-learning, synthetic aperture radar, multi-spectral, urban classification, machine-learning, data fusion, Urban classification

Abstract

The rapid change and expansion of human settlements raise the need for precise remote-sensing monitoring tools. While some Land Cover (LC) maps are publicly available, the knowledge of the up-to-date urban extent for a specific instance in time is often missing. The lack of a relevant urban mask, especially in developing countries, increases the burden on Earth Observation (EO) data users or requires them to rely on time-consuming manual classification. This paper explores fast and effective exploitation of Sentinel-1 (S1) and Sentinel-2 (S2) data for the generation of urban LC, which can be frequently updated. The method is based on an Object-Based Image Analysis (OBIA), where one Multi-Spectral (MS) image is used to define clusters of similar pixels through super-pixel segmentation. A short stack (

Published

2022

126. Decision Tree and Texture Analysis for Mapping Debris-Covered Glaciers in the Kangchenjunga Area, Eastern Himalaya

Author

Adina Racoviteanu and Mark W. Williams

Subjects

optical remote sensing, multi-spectral, ASTER, debris-covered glaciers, Sikkim Himalaya, Science

Abstract

In this study we use visible, short-wave infrared and thermal Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER) data validated with high-resolution Quickbird (QB) and Worldview2 (WV2) for mapping debris cover in the eastern Himalaya using two independent approaches: (a) a decision tree algorithm, and (b) texture analysis. The decision tree algorithm was based on multi-spectral and topographic variables, such as band ratios, surface reflectance, kinetic temperature from ASTER bands 10 and 12, slope angle, and elevation. The decision tree algorithm resulted in 64 km2 classified as debris-covered ice, which represents 11% of the glacierized area. Overall, for ten glacier tongues in the Kangchenjunga area, there was an area difference of 16.2 km2 (25%) between the ASTER and the QB areas, with mapping errors mainly due to clouds and shadows. Texture analysis techniques included co-occurrence measures, geostatistics and filtering in spatial/frequency domain. Debris cover had the highest variance of all terrain classes, highest entropy and lowest homogeneity compared to the other classes, for example a mean variance of 15.27 compared to 0 for clouds and 0.06 for clean ice. Results of the texture image for debris-covered areas were comparable with those from the decision tree algorithm, with 8% area difference between the two techniques.

Published

2012

127. Individual Urban Tree Species Classification Using Very High Spatial Resolution Airborne Multi-Spectral Imagery Using Longitudinal Profiles

Author

Baoxin Hu and Kongwen Zhang

Subjects

classification, urban, high spatial resolution, multi-spectral, longitudinal profiles, trees species, decision trees, Science

Abstract

Individual tree species identification is important for urban forest inventory and ecology management. Recent advances in remote sensing technologies facilitate more detailed estimation of individual urban tree characteristics. This study presents an approach to improve the classification of individual tree species via longitudinal profiles from very high spatial resolution airborne imagery. The longitudinal profiles represent the side view tree shape, which play a very important role in individual tree species on-site identification. Decision tree classification was employed to conduct the final classification result. Using this profile approach, six major species (Maple, Ash, Birch, Oak, Spruce, Pine) of trees on the York University (Ontario, Canada) campus were successfully identified. Two decision trees were constructed, one knowledge-based and one derived from gain ratio criteria. The classification accuracy achieved were 84% and 86%, respectively.

Published

2012

128. Robust Pedestrian Detection Based on Multi-Spectral Image Fusion and Convolutional Neural Networks

Author

Xu Chen, Lei Liu, and Xin Tan

Subjects

multi-spectral, TK7800-8360, Computer Networks and Communications, Hardware and Architecture, Control and Systems Engineering, Signal Processing, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, pedestrian detection, image fusion, convolutional neural network, Electronics, Electrical and Electronic Engineering

Abstract

Nowadays, pedestrian detection is widely used in fields such as driving assistance and video surveillance with the progression of technology. However, although the research of single-modal visible pedestrian detection has been very mature, it is still not enough to meet the demand of pedestrian detection at all times. Thus, a multi-spectral pedestrian detection method via image fusion and convolutional neural networks is proposed in this paper. The infrared intensity distribution and visible appearance features are retained with a total variation model based on local structure transfer, and pedestrian detection is realized with the multi-spectral fusion results and the target detection network YOLOv3. The detection performance of the proposed method is evaluated and compared with the detection methods based on the other four pixel-level fusion algorithms and two fusion network architectures. The results attest that our method has superior detection performance, which can detect pedestrian targets robustly even in the case of harsh illumination conditions and cluttered backgrounds.

Published

2021

129. Developing Forest Cover Composites through a Combination of Landsat-8 Optical and Sentinel-1 SAR Data for the Visualization and Extraction of Forested Areas

Author

Ram C. Sharma, Keitarou Hara, and Ryutaro Tateishi

Subjects

forests, multi-spectral, Landsat-8, Sentinel-1, backscattering, composite images, neural networks, Photography, TR1-1050, Computer applications to medicine. Medical informatics, R858-859.7, Electronic computers. Computer science, QA75.5-76.95

Abstract

Mapping the distribution of forested areas and monitoring their spatio-temporal changes are necessary for the conservation and management of forests. This paper presents two new image composites for the visualization and extraction of forest cover. By exploiting the Landsat-8 satellite-based multi-temporal and multi-spectral reflectance datasets, the Forest Cover Composite (FCC) was designed in this research. The FCC is an RGB (red, green, blue) color composite made up of short-wave infrared reflectance and green reflectance, specially selected from the day when the Normalized Difference Vegetation Index (NDVI) is at a maximum, as the red and blue bands, respectively. The annual mean NDVI values are used as the green band. The FCC is designed in such a way that the forested areas appear greener than other vegetation types, such as grasses and shrubs. On the other hand, the croplands and barren lands are usually seen as red and water/snow is seen as blue. However, forests may not necessarily be greener than other perennial vegetation. To cope with this problem, an Enhanced Forest Cover Composite (EFCC) was designed by combining the annual median backscattering intensity of the VH (vertical transmit, horizontal receive) polarization data from the Sentinel-1 satellite with the green term of the FCC to suppress the green component (mean NDVI values) of the FCC over the non-forested vegetative areas. The performances of the FCC and EFCC were evaluated for the discrimination and classification of forested areas all over Japan with the support of reference data. The FCC and EFCC provided promising results, and the high-resolution forest map newly produced in the research provided better accuracy than the extant MODIS (Moderate Resolution Imaging Spectroradiometer) Land Cover Type product (MCD12Q1) in Japan. The composite images proposed in the research are expected to improve forest monitoring activities in other regions as well.

Published

2018

130. Using Multi-Spectral UAV Imagery to Extract Tree Crop Structural Properties and Assess Pruning Effects

Author

Kasper Johansen, Tri Raharjo, and Matthew F. McCabe

Subjects

UAV, multi-spectral, lychee, pruning, tree crop structure, change detection, Science

Abstract

Unmanned aerial vehicles (UAV) provide an unprecedented capacity to monitor the development and dynamics of tree growth and structure through time. It is generally thought that the pruning of tree crops encourages new growth, has a positive effect on fruiting, makes fruit-picking easier, and may increase yield, as it increases light interception and tree crown surface area. To establish the response of pruning in an orchard of lychee trees, an assessment of changes in tree structure, i.e., tree crown perimeter, width, height, area and Plant Projective Cover (PPC), was undertaken using multi-spectral UAV imagery collected before and after a pruning event. While tree crown perimeter, width and area could be derived directly from the delineated tree crowns, height was estimated from a produced canopy height model and PPC was most accurately predicted based on the NIR band. Pre- and post-pruning results showed significant differences in all measured tree structural parameters, including an average decrease in tree crown perimeter of 1.94 m, tree crown width of 0.57 m, tree crown height of 0.62 m, tree crown area of 3.5 m2, and PPC of 14.8%. In order to provide guidance on data collection protocols for orchard management, the impact of flying height variations was also examined, offering some insight into the influence of scale and the scalability of this UAV-based approach for larger orchards. The different flying heights (i.e., 30, 50 and 70 m) produced similar measurements of tree crown width and PPC, while tree crown perimeter, area and height measurements decreased with increasing flying height. Overall, these results illustrate that routine collection of multi-spectral UAV imagery can provide a means of assessing pruning effects on changes in tree structure in commercial orchards, and highlight the importance of collecting imagery with consistent flight configurations, as varying flying heights may cause changes to tree structural measurements.

Published

2018

131. Estimation of Vegetable Crop Parameter by Multi-temporal UAV-Borne Images

Author

Thomas Moeckel, Supriya Dayananda, Rama Rao Nidamanuri, Sunil Nautiyal, Nagaraju Hanumaiah, Andreas Buerkert, and Michael Wachendorf

Subjects

point clouds, biomass, crop height, machine learning, unmanned aerial vehicles, multi-spectral, Science

Abstract

3D point cloud analysis of imagery collected by unmanned aerial vehicles (UAV) has been shown to be a valuable tool for estimation of crop phenotypic traits, such as plant height, in several species. Spatial information about these phenotypic traits can be used to derive information about other important crop characteristics, like fresh biomass yield, which could not be derived directly from the point clouds. Previous approaches have often only considered single date measurements using a single point cloud derived metric for the respective trait. Furthermore, most of the studies focused on plant species with a homogenous canopy surface. The aim of this study was to assess the applicability of UAV imagery for capturing crop height information of three vegetables (crops eggplant, tomato, and cabbage) with a complex vegetation canopy surface during a complete crop growth cycle to infer biomass. Additionally, the effect of crop development stage on the relationship between estimated crop height and field measured crop height was examined. Our study was conducted in an experimental layout at the University of Agricultural Science in Bengaluru, India. For all the crops, the crop height and the biomass was measured at five dates during one crop growth cycle between February and May 2017 (average crop height was 42.5, 35.5, and 16.0 cm for eggplant, tomato, and cabbage). Using a structure from motion approach, a 3D point cloud was created for each crop and sampling date. In total, 14 crop height metrics were extracted from the point clouds. Machine learning methods were used to create prediction models for vegetable crop height. The study demonstrates that the monitoring of crop height using an UAV during an entire growing period results in detailed and precise estimates of crop height and biomass for all three crops (R2 ranging from 0.87 to 0.97, bias ranging from −0.66 to 0.45 cm). The effect of crop development stage on the predicted crop height was found to be substantial (e.g., median deviation increased from 1% to 20% for eggplant) influencing the strength and consistency of the relationship between point cloud metrics and crop height estimates and, thus, should be further investigated. Altogether the results of the study demonstrate that point cloud generated from UAV-based RGB imagery can be used to effectively measure vegetable crop biomass in larger areas (relative error = 17.6%, 19.7%, and 15.2% for eggplant, tomato, and cabbage, respectively) with a similar accuracy as biomass prediction models based on measured crop height (relative error = 21.6, 18.8, and 15.2 for eggplant, tomato, and cabbage).

Published

2018

132. Aerosol Properties from Multi-spectral and Multi-angular Aircraft 4STAR Observations: Expected Advantages and Challenges

Author

Sinyuk, Alexander

Published

2012

133. Using Remote Sensing and an Unmanned Aerial System for Weed Management in Agricultural Crops: A Review

Author

Nik Norasma Che'ya, Zaid Ramli, Muhammad Huzaifah Mohd Roslim, Nursyazyla Sulaiman, Mst. Motmainna, Muhammad Noor Hazwan Abd Manaf, and Abdul Shukor Juraimi

Subjects

multi-spectral, Food security, Computer science, business.industry, Agriculture, Weed control, artificial intelligence, Drone, hyperspectral, Remote sensing (archaeology), Sustainability, Food processing, weeds, weeds management, business, Weed, Agronomy and Crop Science, Remote sensing

Abstract

Weeds are unwanted plants that can reduce crop yields by competing for water, nutrients, light, space, and carbon dioxide, which need to be controlled to meet future food production requirements. The integration of drones, artificial intelligence, and various sensors, which include hyperspectral, multi-spectral, and RGB (red-green-blue), ensure the possibility of a better outcome in managing weed problems. Most of the major or minor challenges caused by weed infestation can be faced by implementing remote sensing systems in various agricultural tasks. It is a multi-disciplinary science that includes spectroscopy, optics, computer, photography, satellite launching, electronics, communication, and several other fields. Future challenges, including food security, sustainability, supply and demand, climate change, and herbicide resistance, can also be overcome by those technologies based on machine learning approaches. This review provides an overview of the potential and practical use of unmanned aerial vehicle and remote sensing techniques in weed management practices and discusses how they overcome future challenges.

Published

2021

134. Image Registration of Satellite Images with Varying Illumination Level Using HOG Descriptor Based SURF.

Author

Patel, Manish I., Thakar, Vishvjit K., and Shah, Shishir K.

Subjects

IMAGE registration, DIGITAL image processing, IMAGE recognition (Computer vision), SIMULATION methods & models, HISTOGRAMS

Abstract

Image registration aligns two images geometrically, which is frequently required in medical, computer vision and remote-sensing field. It is a crucial pre-processing step in change detection or growth monitoring using satellite images. Accuracy of change detection depends on accuracy of image registration. For multi-modal, multi-sensor, multi-spectral satellite images one of the challenges for image registration is varying illumination level according to the sensor characteristics. This challenge is addressed by using Histogram of Oriented Gradient (HOG) along with Speeded-Up Robust Feature (SURF). It is shown that illumination variation gives some incorrect matches with SURF only which degrades image registration. Incorrect matches are reduced by using HOG as descriptor in SURF. Supporting simulation results for satellite images are presented which show the improvement in the correct matching rate. [ABSTRACT FROM AUTHOR]

Published

2016

135. UAS-based soil carbon mapping using VIS-NIR (480–1000 nm) multi-spectral imaging: Potential and limitations.

Author

Aldana-Jague, Emilien, Heckrath, Goswin, Macdonald, Andy, van Wesemael, Bas, and Van Oost, Kristof

Subjects

*SOIL mapping, *CARBON in soils, *SOIL sampling, *SOIL testing, *HIGH resolution imaging, *SUPPORT vector machines

Abstract

Traditional methods to assess the soil organic carbon (SOC) content based on soil sampling and analysis are time consuming and expensive, and the results are influenced by the sampling design. The aim of this study was to investigate the potential of UAS (Unmanned Aerial Systems) multi-spectral imagery (480–1000 nm) for estimating the SOC content in bare cultivated soils at a high spatial resolution (12 cm). We performed UAS analysis on the Hoosfield Spring Barley experiment at Rothamsted (UK) where adjacent plots with distinctly different SOC contents, due to different long-term management practices, provide a valuable resource to evaluate this approach. We acquired images (wavelength: 480–550–670–780–880–1000 nm) at an altitude of 120 m over an area of 2 ha using a multi-spectral camera mounted on an UAS. The high-resolution images captured small-scale variations at the soil surface (e.g. shadows, tillage and wheels marks). After a projection in new dimensions by a PCA, we calibrated a support vector machine regression using observations from conventional soil sampling and SOC measurements. The performance of the calibration had a R 2 of 0.98 and a RMSE of 0.17%C. A cross-validation showed that the model was robust, with an average R 2 of 0.95 and a RMSE of 0.21%. An external validation dataset was used to evaluate the predicted spatial patterns of SOC content and a good fit with an RMSE 0.26%C was obtained. Although this study shows that the methodology has a clear potential for use in precision agriculture or monitoring important soil properties following changes in management, we also identify and discuss its limitations and current shortcomings. [ABSTRACT FROM AUTHOR]

Published

2016

136. GLOBAL LAND COVER CLASSIFICATION USING MODIS SURFACE REFLECTANCE PROSUCTS.

Author

Kiyonari Fukue and Haruhisa Shimoda

Subjects

LAND cover, SOCIAL segmentation, OPTICAL bistability

Abstract

The objective of this study is to develop high accuracy land cover classification algorithm for Global scale by using multi-temporal MODIS land reflectance products. In this study, time-domain co-occurrence matrix was introduced as a classification feature which provides time-series signature of land covers. Further, the non-parametric minimum distance classifier was introduced for time-domain co-occurrence matrix, which performs multi-dimensional pattern matching for time-domain co-occurrence matrices of a classification target pixel and each classification classes. The global land cover classification experiments have been conducted by applying the proposed classification method using 46 multi-temporal(in one year) SR(Surface Reflectance) and NBAR(Nadir BRDF-Adjusted Reflectance) products, respectively. IGBP 17 land cover categories were used in our classification experiments. As the results, SR and NBAR products showed similar classification accuracy of 99%. [ABSTRACT FROM AUTHOR]

Published

2016

137. EVALUATION OF THE MAIN CEOS PSEUDO CALIBRATION SITES USING MODIS BRDF/ALBEDO PRODUCTS.

Author

Kharbouche, Said and Muller, Jan-Peter

Subjects

DRONE aircraft, AERIAL photogrammetry

Abstract

This work describes our findings about an evaluation of the stability and the consistency of twenty primary PICSs (Pseudo-Invariant Calibration Sites). We present an analysis of 13 years of 8-daily MODIS products of BRDF parameters and white-sky-albedos (WSA) over the shortwave band. This time series of WSA and BRDFs shows the variation of the "stability" varies significantly from site to site. Using a 10x10 km window size over all the sites, the change in of WSA stability is around 4% but the isotropicity, which is an important element in inter-satellite calibration, can vary from 75% to 98%. Moreover, some PICS, especially, Libya-4 which is one of the PICS which is most employed, has significant and relatively fast changes in wintertime. PICS observations of BRDF/albedo shows that the Libya-4 PICS has the best performance but it is not too far from some sites such as Libya-1 and Mali. This study also reveals that Niger-3 PICS has the longest continuous period of high stability per year, and Sudan has the most isotropic surface. These observations have important implications for the use of these sites. [ABSTRACT FROM AUTHOR]

Published

2016

138. Early Detection of Summer Crops Using High Spatial Resolution Optical Image Time Series.

Author

Sicre, Claire Marais, Inglada, Jordi, Fieuzal, Rémy, Baup, Frédéric, Valero, Silvia, Cros, Jérôme, Huc, Mireille, and Demarez, Valérie

Subjects

*AGRICULTURAL climatology, *OPTICAL images, *AGRICULTURAL productivity, *CROPS, *NORMALIZED difference vegetation index, *MANAGEMENT

Abstract

In the context of climate change, agricultural managers have the imperative to combine sufficient productivity with durability of the resources. Many studies have shown the interest of recent satellite missions as suitable tools for agricultural surveys. Nevertheless, they are not predictive methods. A system able to detect summer crops as early as possible is important in order to obtain valuable information for a better water management strategy. The detection of summer crops before the beginning of the irrigation period is therefore our objective. The study area is located near Toulouse (southwestern France), and is a region of mixed farming with a wide variety of irrigated and non-irrigated crops. Using the reference data for the years concerned, a set of fixed thresholds are applied to a vegetation index (the Normalized Difference Vegetation Index, NDVI) for each agricultural season of multi-spectral satellite optical imagery acquired at decametric spatial resolutions from 2006 to 2013. The performance (i.e., accuracy) is contrasted according to the agricultural practices, the development states of the different crops and the number of acquisition dates (one to three in the results presented here). The detection of summer crops reaches 64% to 88% with a single date, 80% to 88% with two dates and 90% to 99% with three dates. The robustness of this method is tested for several years (showing an impact of meteorological conditions on the actual choice of images), several sensors and several resolutions. [ABSTRACT FROM AUTHOR]

Published

2016

139. Which wavelength is the best for arterial pulse waveform extraction using laser speckle imaging?

Author

Vaz, Pedro, Pereira, Tânia, Figueiras, Edite, Correia, Carlos, Humeau-Heurtier, Anne, and Cardoso, João

Subjects

SPECKLE interference, WAVELENGTHS, IMAGING phantoms, FAST Fourier transforms, WAVE analysis

Abstract

A multi-wavelengths analysis for pulse waveform extraction using laser speckle is conducted. The proposed system consists of three coherent light sources (532 nm, 635 nm, 850 nm). A bench-test composed of a moving skin-like phantom (silicone membrane) is used to compare the results obtained from different wavelengths. The system is able to identify a skin-like phantom vibration frequency, within physiological values, with a minimum error of 0.5 mHz for the 635 nm and 850 nm wavelengths and a minimum error of 1.3 mHz for the 532 nm light wavelength using a FFT-based algorithm. The phantom velocity profile is estimated with an error ranging from 27% to 9% using a bidimensional correlation coefficient-based algorithm. An in vivo trial is also conducted, using the 532 nm and 635 nm laser sources. The 850 nm light source has not been able to extract the pulse waveform. The heart rate is identified with a minimum error of 0.48 beats per minute for the 532 nm light source and a minimal error of 1.15 beats per minute for the 635 nm light source. Our work reveals that a laser speckle-based system with a 532 nm wavelength is able to give arterial pulse waveform with better results than those given with a 635 nm laser. [ABSTRACT FROM AUTHOR]

Published

2016

140. Visible and infrared multi-spectral illumination concept based on GALILEAN collimation systems. IACATS illumination source

Author

Universidad EAFIT. Departamento de Ciencias Básicas, Óptica Aplicada, Gonzalo, R.Z., Tomás, B.D., Carmen, P.S., René, R.G., Concepción, G.A., Hugo, L.H., Antonio, A.C., Javier, M.R., Heribert, A., Javier, S., Universidad EAFIT. Departamento de Ciencias Básicas, Óptica Aplicada, Gonzalo, R.Z., Tomás, B.D., Carmen, P.S., René, R.G., Concepción, G.A., Hugo, L.H., Antonio, A.C., Javier, M.R., Heribert, A., and Javier, S.

Abstract

A LED based illumination system in which five Galilean collimation systems have been used is reported on. It is part of a turbulence simulator for the evaluation of on ground telescopes instrumentation developed by INTA (optics) and LIDAX (opto-mechanics) for the IAC called IACATS. The illumination requirements (some visible and infrared lines) allow the use of five different LEDs (red, green, blue and two infrareds). In order to optimize the illumination level of each wavelength, a Galilean collimating optical configuration was constructed for each wavelength channel. The IACATS instrument simulates a scene consisting of a set of different binary stars simulating the required angular separation between them, ant their spectral characteristics. As a result, a visible and infrared multi-spectral illumination system has been integrated as a part of the turbulence simulator, and the features (opto-mechanical) and illumination characteristics are described in the following lines. ©2010 SPIE'.

Published

2021

141. Identifying key wavenumbers that improve prediction of amylose in rice samples utilizing advanced wavenumber selection techniques

Author

Mishra, Puneet, Woltering, Ernst J., Mishra, Puneet, and Woltering, Ernst J.

Abstract

This study utilizes advanced wavenumber selection techniques to improve the prediction of amylose content in grounded rice samples with near-infrared spectroscopy. Four different wavenumber selection techniques, i.e. covariate selection (CovSel), variable combination population analysis (VCPA), bootstrapping soft shrinkage (BOSS) and variable combination population analysis-iteratively retains informative variables (VCPA-IRIV), were used for model optimization and key wavenumbers selection. The results of the several wavenumber selection techniques were compared with the predictions reported previously on the same data set. All the four wavenumber selection techniques improved the predictive performance of amylose in rice samples. The best performance was obtained with VCPA, where, with only 11 wavenumbers-based model, the prediction error was reduced by 19% compared to what reported previously on the same data set. The selected wavenumbers can help in development of low-cost multi-spectral sensors for amylose prediction in rice samples.

Published

2021

142. Evaluation of Semantic Segmentation Methods for Land Use with Spectral Imaging Using Sentinel-2 and PNOA Imagery

Author

Darío G. Lema, Ángela Alonso, Rubén Usamentiaga, Daniel F. Garcia, and Oscar D. Pedrayes

Subjects

medicine.medical_specialty, multi-spectral, 010504 meteorology & atmospheric sciences, Computer science, Science, 0211 other engineering and technologies, Inference, convolutional neural network, 02 engineering and technology, computer.software_genre, 01 natural sciences, Convolutional neural network, medicine, Segmentation, Satellite imagery, unet, sentinel, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, pnoa, agriculture, sigpac, deeplab, Ground sample distance, aerial, semantic segmentation, Random forest, Spectral imaging, Software deployment, General Earth and Planetary Sciences, Data mining, computer

Abstract

Land use classification using aerial imagery can be complex. Characteristics such as ground sampling distance, resolution, number of bands and the information these bands convey are the keys to its accuracy. Random Forest is the most widely used approach but better and more modern alternatives do exist. In this paper, state-of-the-art methods are evaluated, consisting of semantic segmentation networks such as UNet and DeepLabV3+. In addition, two datasets based on aircraft and satellite imagery are generated as a new state of the art to test land use classification. These datasets, called UOPNOA and UOS2, are publicly available. In this work, the performance of these networks and the two datasets generated are evaluated. This paper demonstrates that ground sampling distance is the most important factor in obtaining good semantic segmentation results, but a suitable number of bands can be as important. This proves that both aircraft and satellite imagery can produce good results, although for different reasons. Finally, cost performance for an inference prototype is evaluated, comparing various Microsoft Azure architectures. The evaluation concludes that using a GPU is unnecessarily costly for deployment. A GPU need only be used for training.

Published

2021

143. FIRST ASSESSMENTS ON HERITAGE SCIENCE ORIENTED IMAGE-BASED MODELING USING LOW-COST MODIFIED AND MOBILE CAMERAS

Author

Fulvio Rinaudo, Efstathios Adamopoulos, and A. Bovero

Subjects

lcsh:Applied optics. Photonics, Computer science, Real-time computing, Heritage, Modified Camera, lcsh:Technology, 01 natural sciences, Mobile Camera, 010309 optics, Software, Thermal, 11. Sustainability, 0103 physical sciences, Structure-from-Motion, Structure from motion, Instrumentation (computer programming), Image sensor, Multi-Spectral, lcsh:T, business.industry, Low-Cost, 010401 analytical chemistry, Modeling, lcsh:TA1501-1820, 3D modeling, 0104 chemical sciences, Cultural heritage, Photogrammetry, lcsh:TA1-2040, Metric (unit), Heritage, Modeling, Modified Camera, Mobile Camera, Multi-Spectral, Thermal, Low-Cost, Structure-from-Motion, lcsh:Engineering (General). Civil engineering (General), business

Abstract

Three-dimensional modeling of cultural heritage, especially concerning large scale studies, as for example, archaeometry, diagnostics and conservation intervention applications, which usually require high-resolution and multi-spectral analyses, necessitates the use of complicate and often expensive equipment. Recent developments regarding low-cost commercially available spectrally modified digital reflex cameras, smartphones with good quality image sensors, mobile thermal cameras in combination with automated or semi-automated photogrammetric software implementing Structure from Motion (SfM) and Multiview Stereo (MVS) algorithms constitute some cheaper and simpler alternatives. Although, the results of the integration of these types of sensors and techniques are often not evaluated as metric products. The presented research combines the above-mentioned instrumentation and software to implement and evaluate low-cost 3D modeling solutions on heritage science-oriented case studies, but also to perform some first assessments on the resulting models' metric properties, quality of texture and usefulness for further scientific investigations.

Published

2019

144. 3D INTERPRETATION AND FUSION OF MULTIDISCIPLINARY DATA FOR HERITAGE SCIENCE: A REVIEW

Author

Efstathios Adamopoulos and Fulvio Rinaudo

Subjects

lcsh:Applied optics. Photonics, multi-spectral, Computer science, Point cloud, Heritage, data interpretation, modelling, multi-sensor, multi-spectral, data fusion, data interpretation, Heritage, 010502 geochemistry & geophysics, 01 natural sciences, lcsh:Technology, modelling, Documentation, Multidisciplinary approach, multi-sensor, 0105 earth and related environmental sciences, Fusion, data fusion, Information retrieval, lcsh:T, Interpretation (philosophy), 010401 analytical chemistry, lcsh:TA1501-1820, Sensor fusion, 0104 chemical sciences, lcsh:TA1-2040, Raw data, lcsh:Engineering (General). Civil engineering (General)

Abstract

Activities related to the protection of tangible heritage require extensive multidisciplinary documentation. The various raw data that occur have been oftentimes been processed, visualized and evaluated separately leading to aggregations of unassociated information of varying data types. In the direction of adopting complete approaches towards more effective decision making, the interpretation and fusion of these data in three dimensions, inserting topological information is deemed necessary. The present study addresses the achieved level of three-dimensional interpretation and fusion with geometric models of data originating from different fields, by providing an extensive review of the relevant literature. Additionally, it briefly discusses perspectives on techniques that could potentially be integrated with point clouds or models.

Published

2019

145. RIMFRA: Rotation-invariant multi-spectral facial recognition approach by using orthogonal polynomials

Author

Nazife Cevik and Taner Cevik

Subjects

Multi-Spectral, Channel (digital image), Computer Networks and Communications, Computer science, business.industry, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, 020207 software engineering, Pattern recognition, Multi spectral, Astrophysics::Cosmology and Extragalactic Astrophysics, 02 engineering and technology, Facial recognition system, Hardware and Architecture, Computer Science::Computer Vision and Pattern Recognition, Orthogonal polynomials, Rotation Invariant, 0202 electrical engineering, electronic engineering, information engineering, Media Technology, Astrophysics::Solar and Stellar Astrophysics, Artificial intelligence, Invariant (mathematics), business, Facial Recognition, Orthogonal Polynomial, Software

Abstract

Çevik, Nazife (Arel Author), This paper proposes a novel rotation-invariant multi-spectral facial recognition approach (RIMFRA) by using orthogonal polynomials. In the first step, a rotation, illumination and noise invariant local descriptor (RinLd) is proposed to represent the texture patterns of a face image. Color channels of the images embodies non-trivial information about the characteristic of the image. Hence, the local descriptor matrices are extracted among the color channels. The corresponding new descriptor matrices for the red, green and blue channels of the image are extracted. Afterwards, co-occurrence matrices are obtained from the six combinations of the corresponding color channel descriptor matrices, that are red-red, blue-blue, green-green, red-blue, green-blue and red-green. Finally, these matrices are decomposed by using the orthogonal polynomials to achieve a more reliable and characteristic pattern extraction. The coefficients obtained as a result of the decomposition process are used as the ultimate features for the classification of the images. Extensive simulations are conducted over benchmark datasets. As presented by the simulation results, the ultimate features yield very high discriminating performance as well as providing resistance to rotation and illumination variations. © 2019, Springer Science+Business Media, LLC, part of Springer Nature.

Published

2019

146. Multi-Spectral RGB-NIR Image Classification Using Double-Channel CNN

Author

Fen Liu, Xi'an Feng, Yingying Xu, Hui Huang, and Jionghui Jiang

Subjects

General Computer Science, Channel (digital image), Computer science, Multi spectral, 02 engineering and technology, 01 natural sciences, Convolutional neural network, Image (mathematics), 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, RGB-NIR, Artificial neural network, Contextual image classification, business.industry, Multi-spectral, 010401 analytical chemistry, General Engineering, Pattern recognition, 0104 chemical sciences, double-channel CNN, RGB color model, 020201 artificial intelligence & image processing, lcsh:Electrical engineering. Electronics. Nuclear engineering, Enhanced Data Rates for GSM Evolution, Artificial intelligence, business, lcsh:TK1-9971, CNN

Abstract

As 4-sensor line scan camera technology has matured, red (R), green (G), blue (B), and near-infrared (RGB-NIR) datasets have begun to appear in large numbers. The RGB-NIR data contain the rich color features of the RGB image and the sharp edge features of the NIR image. At present, in many studies, the RGB-NIR data are input directly into the processing algorithms for calculation of the 4D data; in these cases, redundant information is included, and the high correlation between the bands results in an inability to fully exploit the characteristics of the RGB-NIR data. In this paper, we propose a double-channel convolutional neural network (CNN) algorithm that takes into account the strong correlation between the R, G, and B bands in aerial images and the weaker correlation between the NIR band and the R, G, and B bands. First, the features of the RGB and NIR bands are calculated in two different CNN networks, and subsequently, feature fusion is performed in the fully connected layer. This is followed by the classification. By combining the two neural networks of RGB-CNN and NIR-CNN, the respective characteristics of the RGB-NIR data are fully exploited.

Published

2019

147. 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

148. Comparative study of two antipsychotic drugs binding to human serum albumin: By multispectroscopic and molecular docking methods.

Author

Huang, Ze-Yue, Li, Xiao-Yun, Hu, Lan-Yi, Bai, Ai-Min, and Hu, Yan-Jun

Subjects

*ANTIPSYCHOTIC agents, *MOLECULAR docking, *SERUM albumin, *TIME-resolved spectroscopy, *FLUORESCENCE spectroscopy, *CIRCULAR dichroism, *ARIPIPRAZOLE, *AMISULPRIDE

Abstract

[Display omitted] • Comparative analysis of the affinity interaction between two typical antipsychotics and HSA. • Combined multispectral and electrochemical methods compared the binding intensity of their interactions. • The two antipsychotics caused significant perturbations to the structure of the HSA. • Molecular docking demonstrated the existence of multiple forces during the interaction. Psychiatric disorders are common diseases with a high prevalence. Currently, increasing focus on the treatment of psychiatric disorders has driven the development and investigation of antipsychotic drugs. In this paper, two classical antipsychotic drugs risperidone (RIP) and paliperidone (PIP) were selected as research subjects to explore their action mechanism with biological macromolecule human serum albumin (HSA). Combined UV spectroscopy and time-resolved fluorescence spectroscopy results showed that the quenching of HSA by RIP/PIP was a static process, and this result was further confirmed by temperature-dependent experiments, while hydrogen bonding, electrostatic forces and hydrophobic forces existed in the above process. Furthermore, synchronous fluorescence spectroscopy, three-dimensional fluorescence spectroscopy and circular dichroism (CD) spectroscopy experiments demonstrated the effect on HSA before and after the addition of RIP/PIP. Electrochemical experiments results determined that K a of HSA and RIP/PIP system was 1.52 × 104 M−1–2.85 × 104 M−1. According to the competition experiments and molecular docking indicating RIP/PIP bound to site I of HSA. Finally, these results provided reliable information for the development of antipsychotic drugs. [ABSTRACT FROM AUTHOR]

Published

2022

149. Using UAV Borne, Multi-Spectral Imaging for the Field Phenotyping of Shoot Biomass, Leaf Area Index and Height of West African Sorghum Varieties under Two Contrasted Water Conditions

Author

Boubacar Gano, Delphine Luquet, Alain Audebert, Joseph Sékou B. Dembele, Grégory Beurier, Adama P. Ndour, Diaga Diouf, Institut Sénégalais de Recherches Agricoles [Dakar] (ISRA), Université Cheikh Anta Diop [Dakar, Sénégal] (UCAD), Amélioration génétique et adaptation des plantes méditerranéennes et tropicales (UMR AGAP), Centre de Coopération Internationale en Recherche Agronomique pour le Développement (Cirad)-Centre international d'études supérieures en sciences agronomiques (Montpellier SupAgro)-Institut national d’études supérieures agronomiques de Montpellier (Montpellier SupAgro), Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro)-Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Département Systèmes Biologiques (Cirad-BIOS), Centre de Coopération Internationale en Recherche Agronomique pour le Développement (Cirad), Deutscher Akademischer Austausch Dienst (DAAD), and sgt terra gates project - Bill and Melinda Gates foundation

Subjects

0106 biological sciences, Tolérance à la sécheresse, 010504 meteorology & atmospheric sciences, UAV platform, Phénotype, unmanned aerial vehicles [EN], drought tolerance, Facteur climatique, RGB cameras, 01 natural sciences, Imagerie multispectrale, Mathematics, 2. Zero hunger, Biomass (ecology), education.field_of_study, biology, Indice de surface foliaire, food and beverages, Agriculture, Vegetation, vegetation indices, multi-spectral, phenotyping, F60 - Physiologie et biochimie végétale, Drought tolerance, Population, Context (language use), Normalized Difference Vegetation Index, West Africa, [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, Leaf area index, education, 0105 earth and related environmental sciences, 15. Life on land, Sorghum, biology.organism_classification, Agronomy, sorghum, U30 - Méthodes de recherche, Agronomy and Crop Science, 010606 plant biology & botany, Index de végétation

Abstract

Meeting food demand for the growing population will require an increase to crop production despite climate changes and, more particularly, severe drought episodes. Sorghum is one of the cereals most adapted to drought that feed millions of people around the world. Valorizing its genetic diversity for crop improvement can benefit from extensive phenotyping. The current methods to evaluate plant biomass, leaves area and plants height involve destructive sampling and are not practical in breeding. Phenotyping relying on drone based imagery is a powerful approach in this context. The objective of this study was to develop and validate a high throughput field phenotyping method of sorghum growth traits under contrasted water conditions relying on drone based imagery. Experiments were conducted in Bambey (Senegal) in 2018 and 2019, to test the ability of multi-spectral sensing technologies on-board a UAV platform to calculate various vegetation indices to estimate plants characteristics. In total, ten (10) contrasted varieties of West African sorghum collection were selected and arranged in a randomized complete block design with three (3) replicates and two (2) water treatments (well-watered and drought stress). This study focused on plant biomass, leaf area index (LAI) and the plant height that were measured weekly from emergence to maturity. Drone flights were performed just before each destructive sampling and images were taken by multi-spectral and visible cameras. UAV-derived vegetation indices exhibited their capacity of estimating LAI and biomass in the 2018 calibration data set, in particular: normalized difference vegetative index (NDVI), corrected transformed vegetation index (CTVI), seconded modified soil-adjusted vegetation index (MSAVI2), green normalize difference vegetation index (GNDVI), and simple ratio (SR) (r2 of 0.8 and 0.6 for LAI and biomass, respectively). Developed models were validated with 2019 data, showing a good performance (r2 of 0.92 and 0.91 for LAI and biomass accordingly). Results were also promising regarding plant height estimation (RMSE = 9.88 cm). Regression plots between the image-based estimation and the measured plant height showed a r2 of 0.83. The validation results were similar between water treatments. This study is the first successful application of drone based imagery for phenotyping sorghum growth and development in a West African context characterized by severe drought occurrence. The developed approach could be used as a decision support tool for breeding programs and as a tool to increase the throughput of sorghum genetic diversity characterization for adaptive traits.

Published

2021

150. Deriving Planform Morphology and Vegetation Coverage From Remote Sensing to Support River Management Applications

Author

Massimo Guerrero, Michael Nones, Richard J. Boothroyd, Boothroyd R.J., Nones M., and Guerrero M.

Subjects

multi-spectral, 010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, 02 engineering and technology, 01 natural sciences, Normalized Difference Vegetation Index, remote sensing, Satellite imagery, GE1-350, 0105 earth and related environmental sciences, General Environmental Science, Riparian zone, Hydrology, geography, Po river, geography.geographical_feature_category, Flood myth, multi-temporal, Vegetation, river science, 020801 environmental engineering, google earth engine, Environmental sciences, Snowmelt, Environmental science, Sediment transport, Channel (geography)

Abstract

With the increasing availability of big geospatial data (e.g., multi-spectral satellite imagery) and access to platforms that support multi-temporal analyses (e.g., cloud-based computing, Geographical Information Systems, GIS), the use of remotely sensed information for monitoring riverine hydro-morpho-biodynamics is growing. Opportunities to map, quantify and detect changes in the wider riverscape (i.e., water, sediment and vegetation) at an unprecedented spatiotemporal resolution can support flood risk and river management applications. Focusing on a reach of the Po River (Italy), satellite imagery from Landsat 5, 7, and 8 for the period 1988–2018 were analyzed in Google Earth Engine (GEE) to investigate changes in river planform morphology and vegetation dynamics associated with transient hydrology. An improved understanding of these correlations can help in managing sediment transport and riparian vegetation to reduce flood risk, where biogeomorphic processes are commonly overlooked in flood risk mapping. In the study, two established indices were analyzed: the Modified Normalized Difference Water Index (MNDWI) for monitoring changes in the wetted river planform morphology, inferring information about sediment dynamics, and the Normalized Difference Vegetation Index (NDVI) for evaluating changes in vegetation coverage. Results suggest that planform changes are highly localized with most parts of the reach remaining stable. Using the wetted channel occurrence as a measure of planform stability, almost two-thirds of the wetted channel extent (total area = 86.4 km2) had an occurrence frequency >90% (indicating stability). A loss of planform complexity coincided with the position of former secondary channels, or zones where the active river channel had narrowed. Time series analysis of vegetation dynamics showed that NDVI maxima were recorded in May/June and coincided with the first peak in the hydrological regime (occurring in late spring and associated with snowmelt). Seasonal variation in vegetation coverage is potentially important for local hydrodynamics, influencing flood risk. We suggest that remotely sensed information can provide river scientists with new insights to support the management of highly anthropized watercourses.

Published

2021