NASA's surface biology and geology designated observable: A perspective on surface imaging algorithms

The 2017–2027 National Academies' Decadal Survey, Thriving on Our Changing Planet, recommended Surface Biology and Geology (SBG) as a “Designated Targeted Observable” (DO). The SBG DO is based on the need for capabilities to acquire global, high spatial resolution, visible to shortwave infrared (VSWIR; 380–2500 nm; ~30 m pixel resolution) hyperspectral (imaging spectroscopy) and multispectral midwave and thermal infrared (MWIR: 3–5 μm; TIR: 8–12 μm; ~60 m pixel resolution) measurements with sub-monthly temporal revisits over terrestrial, freshwater, and coastal marine habitats. To address the various mission design needs, an SBG Algorithms Working Group of multidisciplinary researchers has been formed to review and evaluate the algorithms applicable to the SBG DO across a wide range of Earth science disciplines, including terrestrial and aquatic ecology, atmospheric science, geology, and hydrology. Here, we summarize current state-of-the-practice VSWIR and TIR algorithms that use airborne or orbital spectral imaging observations to address the SBG DO priorities identified by the Decadal Survey: (i) terrestrial vegetation physiology, functional traits, and health; (ii) inland and coastal aquatic ecosystems physiology, functional traits, and health; (iii) snow and ice accumulation, melting, and albedo; (iv) active surface composition (eruptions, landslides, evolving landscapes, hazard risks); (v) effects of changing land use on surface energy, water, momentum, and carbon fluxes; and (vi) managing agriculture, natural habitats, water use/quality, and urban development. We review existing algorithms in the following categories: snow/ice, aquatic environments, geology, and terrestrial vegetation, and summarize the community-state-of-practice in each category. This effort synthesizes the findings of more than 130 scientists

Robust hyperspectral image reconstruction for scene simulation applications

This thesis presents the development of a spectral reconstruction method for multispectral (MSI) and hyperspectral (HSI) applications through an enhanced dictionary learning and spectral unmixing methodologies. Earth observation/surveillance is largely undertaken by MSI sensing such as that given by the Landsat, WorldView, Sentinel etc, however, the practical usefulness of the MSI data set is very limited. This is mainly because of the very limited number of wave bands that can be provided by the MSI imagery. One means to remedy this major shortcoming is to extend the MSI into HSI without the need of involving expensive hardware investment. Specifically, spectral reconstruction has been one of the most critical elements in applications such as Hyperspectral scene simulation. Hyperspectral scene simulation has been an important technique particularly for defence applications. Scene simulation creates a virtual scene such that modelling of the materials in the scene can be tailored freely to allow certain parameters of the model to be studied. In the defence sector this is the most cost-effective technique to allow the vulnerability of the soldiers/vehicles to be evaluated before they are deployed to a foreign ground. The simulation of a hyperspectral scene requires the details of materials in the scene, which is normally not available. Current state-of-the-art technology is trying to make use of the MSI satellite data, and to transform it into HSI for the hyperspectral scene simulation. One way to achieve this is through a reconstruction algorithm, commonly known as spectral reconstruction, which turns the MSI into HSI using an optimisation approach. The methodology that has been adopted in this thesis is the development of a robust dictionary learning to estimate the endmember (EM) robustly. Once the EM is found the abundance of materials in the scene can be subsequently estimated through a linear unmixing approach. Conventional approaches to the material allocation of most Hyperspectral scene simulator has been using the Texture Material Mapper (TMM) algorithm, which allocates materials from a spectral library (a collection of pre-compiled endmember iii iv materials) database according to the minimum spectral Euclidean distance difference to a candidate pixel of the scene. This approach has been shown (in this work) to be highly inaccurate with large scene reconstruction error. This research attempts to use a dictionary learning technique for material allocation, solving it as an optimisation problem with the objective of: (i) to reconstruct the scene as closely as possible to the ground truth with a fraction of error as that given by the TMM method, and (ii) to learn materials which are trace (2-3 times the number of species (i.e. intrinsic dimension) in the scene) cluster to ensure all material species in the scene is included for the scene reconstruction. Furthermore, two approaches complementing the goals of the learned dictionary through a rapid orthogonal matching pursuit (r-OMP) which enhances the performance of the orthogonal matching pursuit algorithm; and secondly a semi-blind approximation of the irradiance of all pixels in the scene including those in the shaded regions, have been proposed in this work. The main result of this research is the demonstration of the effectiveness of the proposed algorithms using real data set. The SCD-SOMP has been shown capable to learn both the background and trace materials even for a dictionary with small number of atoms (≈10). Also, the KMSCD method is found to be the more versatile with overcomplete (non-orthogonal) dictionary capable to learn trace materials with high scene reconstruction accuracy (2x of accuracy enhancement over that simulated using the TMM method. Although this work has achieved an incremental improvement in spectral reconstruction, however, the need of dictionary training using hyperspectral data set in this thesis has been identified as one limitation which is needed to be removed for the future direction of research

MS FT-2-2 7 Orthogonal polynomials and quadrature: Theory, computation, and applications

Quadrature rules find many applications in science and engineering. Their analysis is a classical area of applied mathematics and continues to attract considerable attention. This seminar brings together speakers with expertise in a large variety of quadrature rules. It is the aim of the seminar to provide an overview of recent developments in the analysis of quadrature rules. The computation of error estimates and novel applications also are described

Generalized averaged Gaussian quadrature and applications

A simple numerical method for constructing the optimal generalized averaged Gaussian quadrature formulas will be presented. These formulas exist in many cases in which real positive GaussKronrod formulas do not exist, and can be used as an adequate alternative in order to estimate the error of a Gaussian rule. We also investigate the conditions under which the optimal averaged Gaussian quadrature formulas and their truncated variants are internal