Data Visualization and Analysis with NASA's Mercury Trek Online Portal

2020 ◽  
Author(s):  
Brian Day ◽  
Emily Law ◽  
Keyword(s):  
User Interface ◽  
Solar System ◽  
Data Visualization ◽  
Planetary Science ◽  
Dynamic Surface ◽  
Web Based ◽  
Surface Features ◽  
Analysis Tools ◽  
Initial Release ◽  
Data Products

<p><strong>Introduction:</strong>  In its investigations of the planet Mercury, NASA’s MESSENGER returned an immense amount of data detailing the dynamic surface of our solar system’s innermost planet. As the European and Japanese space agencies prepared for the launch of BepiColombo, the next mission to explore Mercury, BepiColombo’s project science team asked NASA to produce a new portal within the Solar System Treks suite (https://trek.nasa.gov) featuring data returned by MESSENGER from Mercury. This new portal would be used both for mission planning and for public outreach by the BepiColombo mission. While initially populated with Messenger data, the portal is also being designed to facilitate visualization, analysis, and dissemination of data from BepiColombo after it commences science operations in orbit around Mercury. The initial release of the Mercury Trek in 2019 shortly followed the launch of BepiColombo on its journey to Mercury.</p> <p><strong>The Mercury Trek Portal:</strong>  The initial release of Mercury Trek in July 2019 featured data products from the Mercury Dual Imaging System (MDIS) instrument that operated aboard NASA’s MErcury Surface, Space ENvironment, GEochemistry and Ranging (MESSENGER) mission while in orbit around Mercury from 2011 to 2015. These products include the MDIS Global Mosaic, MDIS BDR Global Mosaic, MDIS Color Global Mosaic, MDIS MD3 Color Global Mosaic, MDIS Enhanced Color Global Mosaic, MDIS LOI (low-incidence angle) Global Mosaic, MDIS Global Digital Elevation Model (DEM), and MDIS Color Hillshade Global map derived from the DEM. An updated release in June 2020 featured enhanced search capabilities, an updated user interface, the option to have user interface control labels in either English or Japanese, and the addition of numerous new data products. These include high resolution MDIS mosaics, DEMs, and slope data for selected regions, and gravimetric maps including crustal thickness, gravity anomaly, gravity degree strength, and gravity disturbance. Also included are 1:5M geologic maps for the Beethoven, Discovery, Kuiper, Michaelangelo, Shakespeare, Tolstoj, and Victoria regions.</p> <p>Mercury Trek’s data visualization capabilities make it easy to stack and blend different data layers in order to optimize depictions of a wide variety of surface features. Data products can be viewed in equatorial, or polar projected views, or on an interactive 3D globe. The Trek interface allows the user to maneuver a first-person visualization of “flying” across the surface of the Mercury.</p> <p>Analysis tools make it easy to measure distances (either straight-line or along a user-defined path) and to create elevation profiles for surface features. Users can draw user-defined bounding boxes across Vesta’s terrain to generate STL or OBJ files for 3D printing. They can also draw a freehand path anywhere across the surface and have Vesta Trek return a QR code that can be scanned into a smartphone (Android or iOS). The smartphone can then be placed into a pair of inexpensive cardboard-compatible goggles. The user will then be able to fly their defined path in virtual reality.</p> <p>We intend to continue working with the BepiColombo mission and the greater planetary science community to enhance the new Mercury Trek portal with additional data products, and solicit suggestions from the community.</p> <p><strong>One Component in an Integrated Suite:</strong>  Mercury Trek is one of a growing number of portals in NASA’s Solar System Treks Project, available at https://trek.nasa.gov. NASA's Solar System Trek online portals for lunar and planetary mapping and modeling provide web-based suites of interactive data visualization and analysis tools to enable mission planners, planetary scientists, students, and the general public to access mapped data products from past and current missions for Mercury, the Moon, Mars, Vesta, Ceres, Titan, seven of Saturn’s smaller icy moons (Dione, Enceladus, Iapetus Mimas, Phoebe, Rhea, and Tethys), Ryugu, and Bennu. As web-based toolsets, the portals do not require users to purchase or install any software beyond current web browsers. These portals are being used for site selection and analysis by NASA and a number of its international partners, supporting upcoming missions.</p> <p><strong>Acknowledgements: </strong>The authors would like to thank the Planetary Science Division of NASA’s Science Mission Directorate, the Science Engagement and Partnerships Division of NASA’s Science Mission Directorate, and the Advanced Explorations Systems Program of NASA’s Human Exploration and Operations Mission Directorate for their support and guidance in the development of the Solar System Treks.</p>

Innovative visualization and analysis capabilities to advance scientific discovery

2020 ◽  
Author(s):  
Emily Law ◽  
Brian Day ◽  
Keyword(s):  
Solar System ◽  
Data Science ◽  
Scientific Discovery ◽  
Scientific Research ◽  
Value Added ◽  
Planetary Science ◽  
Analysis Tools ◽  
Wide Range ◽  
Data Products ◽  
Advanced Analysis

<p>NASA’s Solar System Treks program produces a suite of interactive visualization and AI/data science analysis tools. These tools enable mission planners, planetary scientists, and engineers to access geospatial data products derived from big data returned from a wide range of instruments aboard a variety of past and current missions, for a growing number of planetary bodies.</p><p>The portals provide easy-to-use tools for browse, search and the ability to overlay a growing range and large amount of value added data products. Data products can be viewed in 2D and 3D, in VR and can be easily integrated by stacking and blending together rendering optimal visualization. Data sets can be plotted and compared against each other. Standard gaming and 3D mouse controllers allow users to maneuver first-person visualizations of flying across planetary surfaces.</p><p>The portals provide a set of advanced analysis tools that employed AI and data science methods. The tools facilitate measurement and study of terrain including distance, height, and depth of surface features. They allow users to perform analyses such as lighting and local hazard assessments including slope, surface roughness and crater/boulder distribution, rockfall distribution, and surface electrostatic potential. These tools faciliate a wide range of activities including the planning, design, development, test and operations associated with lunar sortie missions; robotic (and potentially crewed) operations on the surface; planning tasks in the areas of landing site evaluation and selection; design and placement of landers and other stationary assets; design of rovers and other mobile assets; developing terrain-relative navigation (TRN) capabilities; deorbit/impact site visualization; and assessment and planning of science traverses. Additional tools useful scientific research are under development such as line of sight calculation.</p><p>Seven portals are publicly available to explore the Moon, Mars, Vesta, Ceres, Titan, IcyMoons, and Mercury with more portals in development and planning stages.</p><p>This presentation will provide an overview of the Solar System Treks and highlight its innovative visualization and analysis capabilities that advance scientific discovery.  The information system and science communities are invited to provide suggestions and requests as the development team continues to expand the portals’ tool suite to maximize scientific research.</p><p>Lastly, the authors would like to thank the Planetary Science Division of NASA’s Science Mission Directorate, NASA’s SMD Science Engagement and Partnerships, the Advanced Explorations Systems Program of NASA’s Human Exploration Operations Directorate, and the Moons to Mars Mission Directorate for their support and guidance in the development of the Solar System Treks.</p>

Web-Based Data Visualization Platform for MATSim

2020 ◽  
Vol 2674 (10) ◽  
pp. 124-133
Author(s):  
Billy Charlton ◽  
Janek Laudan
Keyword(s):  
User Interface ◽  
Open Source ◽  
Data Visualization ◽  
Aggregate Level ◽  
Web Based ◽  
Client Server ◽  
Web Technologies ◽  
Front End ◽  
Advanced User ◽  
Simulation Results

There are many tools available for analyzing MATSim transport simulation results, both open-source and commercial. This research builds a new open-source visualization platform for MATSim outputs that is entirely web-based. After initial experiments with many different web technologies, a client-server platform design emerges which leverages the advanced user interface capabilities of modern browsers on the front-end, and relies on back-end server processing for more processor-intensive tasks. The initial platform is now operational and includes several aggregate-level visualizations including origin–destination flows, transit supply, and emissions levels as well as a fully disaggregate traffic animation visualization. These visualizations are general enough to be useful for various projects. Further work is needed to make them more compelling and the platform more useful for practitioners.

New search capabilities based on observational geometry for Mars Express data in the ESA’s Planetary Science Archive

2020 ◽  
Author(s):  
Emmanuel Grotheer ◽  
Nicolas Manaud ◽  
Keyword(s):  
User Interface ◽  
Planetary Science ◽  
Geometrical Parameters ◽  
Search Interface ◽  
Mars Express ◽  
The Public ◽  
Data Products ◽  
Planetary Missions ◽  
Search Capability ◽  
Archived Data

<div>The European Space Agency’s (ESA) Mars Express (MEX) mission to Mars has been returning valuable scientific data for ~16 years.  This data is available to the public for free via the Planetary Science Archive (PSA), which houses the raw, calibrated, and higher-level data returned by the ESA’s planetary missions, including data provided by the various MEX instrument teams.  Besides an FTP server, there is also a user interface with different search views available for the public to search for archived data.  Development of a map-based search interface is underway.  As a first step towards this, the geometrical parameters of all the data products from a wide variety of instruments had to be computed in a unified manner.  These values will be used to enable searches based on observational geometry via the Table View, and other views as well.   </div><div>1. The PSA user interfaces</div><div>The ESA’s PSA uses the Planetary Data System (PDS) format developed by NASA to store the data from its various planetary missions.  In the case of MEX, the data is stored in the PDS3 format, which primarily uses ASCII files to store and describe the data.  When first searching for new data, users would benefit from using the Table View search interface [1].  Here the user can search using various parameters, such as mission name, target (e.g. Mars), instrument name, processing level, observation times, etc.  The development of the PSA’s search capabilities continues, thus more search parameters will be added over time.  In particular, this presentation will focus on the development of new filter menus within the Table View to allow for searches based on the observational geometry of the data products. </div><div>Also available in the Table View interface is a section for “Free Search”, allowing one to use Contextual Query Language (CQL) to search over additional parameters.  These various search methods rely mainly on the metadata provided by the instrument teams in the labels associated with each of the data products.  In the case of the observational geometry searches, in order to provide a uniform search capability, the GEOGEN tool was developed by SpaceFrog Design to provide the tables of relevant parameters to be queried.</div><div> </div><div>2. Summary and Conclusions</div><div>Thanks to the efforts of the MEX instrument teams, the MEX Science Ground Segment team, and the PSA Archive Scientists and Engineers, over 16 years worth of observational data from Mars orbit are available to the public.  This data can be freely accessed at the ESA’s PSA, at .  There are multiple ways of browsing the archived data, including those from other planetary missions, though in this presentation we will focus on the new observational geometry search capability that will become available soon. </div><div>The development of the PSA’s user interface is an ongoing project, and we welcome feedback from the community for suggestions on new ways to search this wealth of data.  Feedback and suggestions can be sent to .</div>

OpenPlanetaryMap Updates: Planetary Basemaps and Geocoding Web Services

2020 ◽  
Author(s):  
Nicolas Manaud ◽  
Jérôme Gasperi ◽  
Andrea Nass ◽  
Stephan van Gasselt ◽  
Angelo Pio Rossi ◽  
...  
Keyword(s):  
Solar System ◽  
Web Services ◽  
User Interfaces ◽  
General Public ◽  
Planetary Science ◽  
Web Based ◽  
Web Mapping ◽  
Platform Architecture ◽  
Service Oriented ◽  
System 1

<p>OpenPlanetaryMap (OPM) is a collaborative project to build the first Open Planetary Mapping and Social platform for researchers, educators, storytellers, and the general public. We want to make it easy for anyone to create and share maps and locations on any planets or bodies in our Solar System [1].</p><p>Our platform architecture is based on four main service-oriented components: (1) an open repository of geospatial <em>datasets</em>; containing information used to create basemaps and to enable location-based searches, (2) <em>basemaps</em> that are needed to build any types of web mapping applications or geospatial data visualisation, (3) geocoding and geo-referencing <em>APIs/web services</em> to enable location-based searches and crowdsourcing of our datasets repository, (4) Web app, Python module and CLI <em>interfaces</em> to search, add and share places on planetary bodies.</p><p>Since the project started as an initiative funded by Europlanet in 2017, we have consolidated our network of collaborators and we published our first planetary basemaps and design concept [2]. Instructions on how to use our basemaps are available from our new website [3]. External projects have started to use OPM basemaps, for example: PLANMAP Stories [4] and CaSSIS Map Interface [5]. While we continue to improve our basemaps and create new ones, we have been working on providing an open planetary geocoding API/web service and user interfaces.</p><p>The purpose of our planetary geocoding API is to provide a common and consistent way of defining and searching for places on the surface of bodies in the Solar System, including the Earth. We are first implementing our geocoding API as a JavaScript module, along with our first web map interface that demonstrates its use. We will then focus on implementing our geocoding API as a Python module.</p><p>We introduce the project and present recent updates on OPM planetary basemaps, geocoding APIs and user interfaces.</p><p>[1] Manaud et al. (2018). OpenPlanetaryMap: Building the first Open Planetary Mapping and Social platform for researchers, educators, storytellers, and the general public. European Planetary Science Congress 2018, 12, EPSC2018-78. [2] Nass et al. (2019). Towards a new face for Planetary Maps: Design and web- based Implementation of Planetary Basemaps. Adv. Cartogr. GIScience Int. Cartogr. Assoc., 1, 15, 2019. https://doi.org/10.5194/ica-adv-1-15-2019 [3] http://openplanetarymap.org [4] https://stories.planmap.eu/mars/gale [5] http://cassis.halimede.unibe.ch</p>

OpenPlanetaryMap Updates: Planetary Basemaps and Geocoding Web Services

2020 ◽  
Author(s):  
Nicolas Manaud ◽  
Jérome Gasperi ◽  
Andrea Nass ◽  
Stephan van Gasselt ◽  
Angelo Pio Rossi ◽  
...  
Keyword(s):  
Solar System ◽  
Web Services ◽  
User Interfaces ◽  
General Public ◽  
Planetary Science ◽  
Web Based ◽  
Web Mapping ◽  
Platform Architecture ◽  
Service Oriented ◽  
System 1

<p>We introduce the project and present recent updates on OPM planetary basemaps, geocoding APIs and user interfaces.</p> <p>OpenPlanetaryMap (OPM) is a collaborative project to build the first Open Planetary Mapping and Social platform for researchers, educators, storytellers, and the general public. We want to make it easy for anyone to create and share maps and locations on any planets or bodies in our Solar System [1].</p> <p>Our platform architecture is based on four main service-oriented components: (1) an open repository of geospatial <em>datasets</em>; containing information used to create basemaps and to enable location-based searches, (2) <em>basemaps</em> that are needed to build any types of web mapping applications or geospatial data visualisation, (3) geocoding and geo-referencing <em>APIs/web services</em> to enable location-based searches and crowdsourcing of our datasets repository, (4) Web app, Python module and CLI <em>interfaces</em> to search, add and share places on planetary bodies.</p> <p>Since the project started as an initiative funded by Europlanet in 2017, we have consolidated our network of collaborators and we published our first planetary basemaps and design concept [2]. Instructions on how to use our basemaps are available from our new website [3]. External projects have started to use OPM basemaps, for example: PLANMAP Stories [4] and CaSSIS Map Interface [5]. While we continue to improve our basemaps and create new ones, we have been working on providing an open planetary geocoding API/web service and user interfaces.</p> <p>The purpose of our planetary geocoding API is to provide a common and consistent way of defining and searching for places on the surface of bodies in the Solar System, including the Earth. We are first implementing our geocoding API as a JavaScript module, along with our first web map interface that demonstrates its use. We will then focus on implementing our geocoding API as a Python module.</p> <p>[1] Manaud et al. (2018). OpenPlanetaryMap: Building the first Open Planetary Mapping and Social platform for researchers, educators, storytellers, and the general public. European Planetary Science Congress 2018, 12, EPSC2018-78. [2] Nass et al. (2019). Towards a new face for Planetary Maps: Design and web- based Implementation of Planetary Basemaps. Adv. Cartogr. GIScience Int. Cartogr. Assoc., 1, 15, 2019. https://doi.org/10.5194/ica-adv-1-15-2019 [3] http://openplanetarymap.org [4] https://stories.planmap.eu/mars/gale [5] http://cassis.halimede.unibe.ch</p>

scholarly journals Functional Architecture of integrated framework for Facet-based Data Collection and Analysis

2020 ◽  
Vol 9 (2S5) ◽  
pp. 25-27
Keyword(s):  
Data Analysis ◽  
User Interface ◽  
Data Visualization ◽  
Web Crawler ◽  
Text Data ◽  
Web Based ◽  
Integrated Framework ◽  
Text Information ◽  
Text Data Analysis ◽  
The Web

We present in this paper an integrated framework for collection and analysis of Facet-based text data. The integrated framework consists of four components: (1) user interface, (2) web crawler, (3) data analyzer, and (4) database (DB). User interface is used to set input Facet and option values for web crawling and text data analysis using a graphical user interface (GUI). In fact, it offers outcomes of research by data visualization. The web crawler collects text data from articles posted on the web based on input Facets. The data analyzer classifies papers in "relevant articles" (i.e., word sets to be included on such posts) and "nonrelevant articles" with predefined information. It then analyzes the text data of the relevant articles and visualizes the results of the data analysis. Ultimately, the DB holds the generated text information, the predefined user-defined expertise and the outcomes of data analysis and data visualization. We verify the feasibility of an integrated framework by means of proof of concept (PoC) prototyping. The experimental results show that the implemented prototype reliably collects and analyzes the text data of the articles.

scholarly journals Visualization and Analysis of Data from Small-Body Missions with NASA’s Solar System Treks Portals

2020 ◽  
Author(s):  
Brian Day ◽  
Emily Law ◽  
Keyword(s):  
Solar System ◽  
Small Body ◽  
Planetary Science ◽  
Asteroid Belt ◽  
Sample Collection ◽  
Science Division ◽  
Small Bodies ◽  
Sample Site ◽  
Surface Sample ◽  
Data Products

<p>This presentation provides an overview of portals within NASA’s Solar System Treks Project (SSTP) that specifically target small bodies within our Solar System. These, and all of the portals in the suite of Solar System Trek portals, are available at https://trek.nasa.gov.</p> <p>These portals each allow for visualization of different data products in 2D maps with various projections. They also allow users to conduct interactive 3D flyovers. The VR tool allows users to generate their own virtual reality flyovers for any user-defined paths along the bodies’ surfaces. Other tools let users measure distances, generate elevation plots, and create 3D print files for user-defined regions or the entire body.</p> <p>JAXA’s Hayabusa 2 mission recently completed a campaign of reconnaissance, sample collection, and rover deployment at the near-Earth asteroid (162173) Ryugu. JAXA is providing mission data to SSTP, which is incorporating it into the new Ryugu Trek portal (https://trek.nasa.gov/ryugu). The internationalized user interface features controls in both English and Japanese. The portal’s bookmarks feature takes users to particular areas of interest for more detailed looks at specific landforms and sites. On Ryugu, we focus on the surface sample site, impactor and sub-surface sample site, as well as landing sites and traverse paths for the HIBOU, OWL, and MASCOT rovers. We also highlight the first landforms on Ryugu to have been given official IAU names.</p> <p>While Hayabusa2 was exploring Ryugu, NASA’s OSIRIS-REx mission began conducting a detailed examination of the asteroid (101955) Bennu, another near-Earth object. At the request of NASA’s Planetary Science Division and the OSIRIS-REx mission, SSTP began implementation a new portal for the asteroid Bennu, featuring data that is being returned from OSIRIS-REx. The Bennu Trek portal (https://trek.nasa.gov/bennu) reveals Bennu’s top-like shape, a fascinating commonality with Ryugu. It also reveals details of Bennu’s intensely boulder covered terrain. Bookmarked features include Nightingale, Sandpiper, Osprey, and Kingfisher, the top four candidates for sample collection. We also highlight the first landforms on Bennu to have been given official IAU names. Each of these features were singled out as landmarks for OSIRIS-REx’s Natural Feature Tracking (NFT) navigation method that will be used to guide the spacecraft down to its surface sample collection site.</p> <p>In its investigations of Vesta and Ceres, NASA’s Dawn mission has returned spectacular data of the surfaces of these two prominent small bodies within the asteroid belt. This presentation will showcase the use of the Ceres Trek (https://trek.nasa.gov/ceres) and Vesta Trek (https://trek.nasa.gov/vesta) portals and demonstrate how they can be used to visualize and analyze particularly interesting landforms such as the pitted terrain on Vesta and relic cryovolcanoes on Ceres.</p> <p>Under development at this time is a new portal for Mars’ larger Moon, Phobos. This portal will make extensive use of data from ESA’s Mars Express. It is being designed in collaboration with JAXA to support Japan’s upcoming Martian Moons eXploration (MMX) mission. This presentation will provide a preview of a prototype for Phobos Trek.</p> <p>Other Near-Earth asteroids being considered as candidates for future portals include (433) Eros utilizing data gathered by the NEAR Shoemaker mission, and (25143) Itokawa using data from JAXA’s Hayabusa mission. Together, a growing collection of small body Trek portals would enhance capabilities for comparative planetology among this fascinating class of objects. </p> <p>All of these products are efforts in the NASA Solar System Treks Project, available at https://trek.nasa.gov. NASA's Solar System Trek online portals provide web-based suites of interactive data visualization and analysis tools to enable mission planners, planetary scientists, students, and the general public to access mapped data products from past and current missions for a growing number of planetary bodies. These portals are being used for site selection and analysis by NASA and its international partners, supporting upcoming missions. In addition to demonstrating the capabilities of selected portals in this presentation, we will solicit input from the community for ideas for future enhancements.</p> <p>The authors would like to thank the Planetary Science Division of NASA’s Science Mission Directorate, NASA’s SMD Science Engagement and Partnerships, the Advanced Explorations Systems Program of NASA’s Human Exploration Operations Directorate, and the Moon to Mars Directorate for their support and guidance in the development of the Solar System Treks.</p>

Intel® Component Diagnostic Technology: Tools and Education for Intel Component Defect Reduction

2004 ◽  
Author(s):  
Julie S. Doll
Keyword(s):  
User Interface ◽  
Data Management ◽  
Contract Manufacturing ◽  
Defect Reduction ◽  
Web Based ◽  
Technology Tools ◽  
Diagnostic Capability ◽  
Diagnostic Technology

Abstract To enable efficient, accurate debug of Intel architecture components to take place within contract manufacturing sites, and to provide alternatives for the removal of Intel components from, Intel is deploying a diagnostic capability and attendant educational collateral known as to achieve these objectives Intel® Component Diagnostic Technology. This paper will describe details of Intel® Component Diagnostic Technology, including the diagnostic fixture and user interface, diagnostic scripts and analytical coverage, data management and reporting, and on-site and Web-based educational offerings.

A framework for programmatically designing user interfaces in JavaScript

2015 ◽  
Vol 11 (3) ◽  
pp. 254-269
Author(s):  
Henry Larkin
Keyword(s):  
User Interface ◽  
User Interfaces ◽  
Design Methodology ◽  
Rapid Development ◽  
Program Code ◽  
Web Based ◽  
Content Type ◽  
Mobile Web ◽  
Mobile Interfaces ◽  
New Framework

Purpose – The purpose of this paper is to investigate the feasibility of creating a declarative user interface language suitable for rapid prototyping of mobile and Web apps. Moreover, this paper presents a new framework for creating responsive user interfaces using JavaScript. Design/methodology/approach – Very little existing research has been done in JavaScript-specific declarative user interface (UI) languages for mobile Web apps. This paper introduces a new framework, along with several case studies that create modern responsive designs programmatically. Findings – The fully implemented prototype verifies the feasibility of a JavaScript-based declarative user interface library. This paper demonstrates that existing solutions are unwieldy and cumbersome to dynamically create and adjust nodes within a visual syntax of program code. Originality/value – This paper presents the Guix.js platform, a declarative UI library for rapid development of Web-based mobile interfaces in JavaScript.

PLANETARY SCIENCE: How Neptune Pushed the Boundaries of Our Solar System

Science ◽  
2004 ◽  
Vol 306 (5700) ◽  
pp. 1302-1304 ◽  
Author(s):  
A. Morbidelli
Keyword(s):  
Solar System ◽  
Planetary Science
Sign in / Sign up

Export Citation Format

Share Document