272 research outputs found
IoT Applications Computing
The evolution of emerging and innovative technologies based on Industry 4.0 concepts are transforming society and industry into a fully digitized and networked globe. Sensing, communications, and computing embedded with ambient intelligence are at the heart of the Internet of Things (IoT), the Industrial Internet of Things (IIoT), and Industry 4.0 technologies with expanding applications in manufacturing, transportation, health, building automation, agriculture, and the environment. It is expected that the emerging technology clusters of ambient intelligence computing will not only transform modern industry but also advance societal health and wellness, as well as and make the environment more sustainable. This book uses an interdisciplinary approach to explain the complex issue of scientific and technological innovations largely based on intelligent computing
Wireless Sensor Networks
The aim of this book is to present few important issues of WSNs, from the application, design and technology points of view. The book highlights power efficient design issues related to wireless sensor networks, the existing WSN applications, and discusses the research efforts being undertaken in this field which put the reader in good pace to be able to understand more advanced research and make a contribution in this field for themselves. It is believed that this book serves as a comprehensive reference for graduate and undergraduate senior students who seek to learn latest development in wireless sensor networks
Acoustic Event Detection System
HlavnĂm cĂlem tĂ©to práce je vytvoĹ™it systĂ©m schopnĂ˝ detekce, klasifikace a lokalizace stĹ™elby. SystĂ©m se skládá z dedikovanĂ© desky a serverovĂ© aplikace. SystĂ©m detekuje zvukovĂ© události a jako prvnĂ krok vyfiltruje události, kterĂ© nejsou stĹ™elba. NáslednÄ› jsou klĂÄŤovĂ© vlastnosti nahrávky extrahovány pomocĂ Mel-Frequency Cepstral Coefficients. Na vektoru klĂÄŤovĂ˝ch vlastnostĂ je dále provedena klasifikace pouĹľitĂ©ho kalibru zbranÄ›, kterou provádĂ metoda podpĹŻrnĂ˝ch vektorĹŻ (Support-Vector Machine). Lokalizace stĹ™elby je provádÄ›na na zvukovĂ˝ch událostech, ke kterĂ˝m je pĹ™ipojena velmi pĹ™esná ÄŤasová znaÄŤka (timestamp) a pozice měřĂcĂho pĹ™Ăstroje (uzlu). Data shromáždÄ›ná z jednotlivĂ˝ch zaĹ™ĂzenĂ jsou pouĹľita pro Ĺ™ešenĂ lokalizaÄŤnĂho problĂ©mu na základÄ› změřenĂ©ho ÄŤasu zaznamenánĂ (Time of Arrival Localization Problem). Pro jeho Ĺ™ešenĂ jsou popsány dvÄ› rĹŻznĂ© metody, lišĂcĂ se dle poÄŤtu měřĂcĂch zaĹ™ĂzenĂ, kterĂ© danou událost detekovaly. VytvoĹ™ená serverová aplikace je nejen schopna Ĺ™ešit lokalizaÄŤnĂ Ăşlohu popsanou výše, ale takĂ© poskytuje vizualizaci s administracĂ uĹľivatelĹŻ, uzlĹŻ a zpráv uzlĹŻ. NavrĹľená deska je schopna zĂskat svou pozici spolu s pĹ™esnou ÄŤasovou znaÄŤkou události a odeslat všechny potĹ™ebnĂ© informace pomocĂ LoRaWan sĂtÄ› na server. Na desce je naimplementován jak detekÄŤnĂ, tak klasifikaÄŤnĂ algoritmus. NavĂc deska nabĂzĂ rozhranĂ ve formÄ› pĹ™ĂkazovĂ© řádky pro nastavenĂ parametrĹŻ aplikace, jako jsou napĹ™Ăklad koeficienty detekÄŤnĂho algoritmu.The main goal of the thesis is to create a system capable of gunshot detection, classification, and localization. The detection system consists of a specialized board and a server application. At first, the gunshot detection algorithm is executed for filtration of non-gunshot events. Afterwards, the features are extracted by Mel-Frequency Cepstral Coefficients. The feature vector is then passed to the gunshot classification, performed through Support Vector Machine. The localization task is executed on precisely timestamped acoustic events that are coupled with position of the measuring devices (nodes) on the server. The aggregated data are utilized for solving the Time of Arrival Localization Problem. Two different methods are described based on the number of nodes that detected the event. The created server application solves the localization task as mentioned above but also offers visualization and administration of users, nodes, and node’s messages. The proposed board is able to acquire position with precise timestamping and send the required information through LoRaWAN network to the server. The board implements detection and classification algorithms and also offers a command line interface for setting the firmware’s parameters such as detection algorithms’ coefficients
Marshall Space Flight Center Research and Technology Report 2019
Today, our calling to explore is greater than ever before, and here at Marshall Space Flight Centerwe make human deep space exploration possible. A key goal for Artemis is demonstrating and perfecting capabilities on the Moon for technologies needed for humans to get to Mars. This years report features 10 of the Agencys 16 Technology Areas, and I am proud of Marshalls role in creating solutions for so many of these daunting technical challenges. Many of these projects will lead to sustainable in-space architecture for human space exploration that will allow us to travel to the Moon, on to Mars, and beyond. Others are developing new scientific instruments capable of providing an unprecedented glimpse into our universe. NASA has led the charge in space exploration for more than six decades, and through the Artemis program we will help build on our work in low Earth orbit and pave the way to the Moon and Mars. At Marshall, we leverage the skills and interest of the international community to conduct scientific research, develop and demonstrate technology, and train international crews to operate further from Earth for longer periods of time than ever before first at the lunar surface, then on to our next giant leap, human exploration of Mars. While each project in this report seeks to advance new technology and challenge conventions, it is important to recognize the diversity of activities and people supporting our mission. This report not only showcases the Centers capabilities and our partnerships, it also highlights the progress our people have achieved in the past year. These scientists, researchers and innovators are why Marshall and NASA will continue to be a leader in innovation, exploration, and discovery for years to come
NASA Capability Roadmaps Executive Summary
This document is the result of eight months of hard work and dedication from NASA, industry, other government agencies, and academic experts from across the nation. It provides a summary of the capabilities necessary to execute the Vision for Space Exploration and the key architecture decisions that drive the direction for those capabilities. This report is being provided to the Exploration Systems Architecture Study (ESAS) team for consideration in development of an architecture approach and investment strategy to support NASA future mission, programs and budget requests. In addition, it will be an excellent reference for NASA's strategic planning. A more detailed set of roadmaps at the technology and sub-capability levels are available on CD. These detailed products include key driving assumptions, capability maturation assessments, and technology and capability development roadmaps
NASA Tech Briefs, December 2007
Topics include: Ka-Band TWT High-Efficiency Power Combiner for High-Rate Data Transmission; Reusable, Extensible High-Level Data-Distribution Concept; Processing Satellite Imagery To Detect Waste Tire Piles; Monitoring by Use of Clusters of Sensor-Data Vectors; Circuit and Method for Communication Over DC Power Line; Switched Band-Pass Filters for Adaptive Transceivers; Noncoherent DTTLs for Symbol Synchronization; High-Voltage Power Supply With Fast Rise and Fall Times; Waveguide Calibrator for Multi-Element Probe Calibration; Four-Way Ka-Band Power Combiner; Loss-of-Control-Inhibitor Systems for Aircraft; Improved Underwater Excitation-Emission Matrix Fluorometer; Metrology Camera System Using Two-Color Interferometry; Design and Fabrication of High-Efficiency CMOS/CCD Imagers; Foam Core Shielding for Spacecraft CHEM-Based Self-Deploying Planetary Storage Tanks Sequestration of Single-Walled Carbon Nanotubes in a Polymer PPC750 Performance Monitor Application-Program-Installer Builder Using Visual Odometry to Estimate Position and Attitude Design and Data Management System Simple, Script-Based Science Processing Archive Automated Rocket Propulsion Test Management Online Remote Sensing Interface Fusing Image Data for Calculating Position of an Object Implementation of a Point Algorithm for Real-Time Convex Optimization Handling Input and Output for COAMPS Modeling and Grid Generation of Iced Airfoils Automated Identification of Nucleotide Sequences Balloon Design Software Rocket Science 101 Interactive Educational Program Creep Forming of Carbon-Reinforced Ceramic-Matrix Composites Dog-Bone Horns for Piezoelectric Ultrasonic/Sonic Actuators Benchtop Detection of Proteins Recombinant Collagenlike Proteins Remote Sensing of Parasitic Nematodes in Plants Direct Coupling From WGM Resonator Disks to Photodetectors Using Digital Radiography To Image Liquid Nitrogen in Voids Multiple-Parameter, Low-False-Alarm Fire-Detection Systems Mosaic-Detector-Based Fluorescence Spectral Imager Plasmoid Thruster for High Specific-Impulse Propulsion Analysis Method for Quantifying Vehicle Design Goals Improved Tracking of Targets by Cameras on a Mars Rover Sample Caching Subsystem Multistage Passive Cooler for Spaceborne Instruments GVIPS Models and Software Stowable Energy-Absorbing Rocker-Bogie Suspension
2020 NASA Technology Taxonomy
This document is an update (new photos used) of the PDF version of the 2020 NASA Technology Taxonomy that will be available to download on the OCT Public Website. The updated 2020 NASA Technology Taxonomy, or "technology dictionary", uses a technology discipline based approach that realigns like-technologies independent of their application within the NASA mission portfolio. This tool is meant to serve as a common technology discipline-based communication tool across the agency and with its partners in other government agencies, academia, industry, and across the world
Facilitating and Enhancing the Performance of Model Selection for Energy Time Series Forecasting in Cluster Computing Environments
Applying Machine Learning (ML) manually to a given problem setting is a tedious and time-consuming process which brings many challenges with it, especially in the context of Big Data. In such a context, gaining insightful information, finding patterns, and extracting knowledge from large datasets are quite complex tasks. Additionally, the configurations of the underlying Big Data infrastructure introduce more complexity for configuring and running ML tasks. With the growing interest in ML the last few years, particularly people without extensive ML expertise have a high demand for frameworks assisting people in applying the right ML algorithm to their problem setting. This is especially true in the field of smart energy system applications where more and more ML algorithms are used e.g. for time series forecasting. Generally, two groups of non-expert users are distinguished to perform energy time series forecasting. The first one includes the users who are familiar with statistics and ML but are not able to write the necessary programming code for training and evaluating ML models using the well-known trial-and-error approach. Such an approach is time consuming and wastes resources for constructing multiple models. The second group is even more inexperienced in programming and not knowledgeable in statistics and ML but wants to apply given ML solutions to their problem settings.
The goal of this thesis is to scientifically explore, in the context of more concrete use cases in the energy domain, how such non-expert users can be optimally supported in creating and performing ML tasks in practice on cluster computing environments. To support the first group of non-expert users, an easy-to-use modular extendable microservice-based ML solution for instrumenting and evaluating ML algorithms on top of a Big Data technology stack is conceptualized and evaluated. Our proposed solution facilitates applying trial-and-error approach by hiding the low level complexities from the users and introduces the best conditions to efficiently perform ML tasks in cluster computing environments.
To support the second group of non-expert users, the first solution is extended to realize meta learning approaches for automated model selection. We evaluate how meta learning technology can be efficiently applied to the problem space of data analytics for smart energy systems to assist energy system experts which are not data analytics experts in applying the right ML algorithms to their data analytics problems. To enhance the predictive performance of meta learning, an efficient characterization of energy time series datasets is required. To this end, Descriptive Statistics Time based Meta Features (DSTMF), a new kind of meta features, is designed to accurately capture the deep characteristics of energy time series datasets. We find that DSTMF outperforms the other state-of-the-art meta feature sets introduced in the literature to characterize energy time series datasets in terms of the accuracy of meta learning models and the time needed to extract them. Further enhancement in the predictive performance of the meta learning classification model is achieved by training the meta learner on new efficient meta examples. To this end, we proposed two new approaches to generate new energy time series datasets to be used as training meta examples by the meta learner depending on the type of time series dataset (i.e. generation or energy consumption time series). We find that extending the original training sets with new meta examples generated by our approaches outperformed the case in which the original is extended by new simulated energy time series datasets
Commercial lunar propellant architecture : a collaborative study of lunar propellant production
This paper is the result of an examination by industry, government, and academic experts of the approach, challenges, and payoffs of a private business that harvests and processes lunar ice as the foundation of a lunar, cislunar (between the Earth and the Moon), and Earth-orbiting economy. A key assumption of this analysis is that all work--construction, operation, transport, maintenance and repair--is done by robotic systems. No human presence is required.Funded by the United Launch AllianceAuthors: David Kornuta, United Launch Alliance, CisLunar Project Lead [and 29 other authors]Executive Summary -- Introduction -- Prospecting -- Mining Operations -- Propellant Storage -- Power -- Robotic Services -- Robotic Services -- Transportation -- Business Case -- Legal -- Benefits -- Recommendations
- …