GPS World

Tag: remote sensing

  • Ground system ready for Joint Polar Satellite launch

    The northernmost Joint Polar Satellite System Common Ground System station in Svalbard, Norway. (Photo: Raytheon)
    The northernmost Joint Polar Satellite System Common Ground System station in Svalbard, Norway. (Photo: Raytheon)

    Newest version of Raytheon’s Joint Polar Satellite System Common Ground System is now operational

    Raytheon’s next-generation Common Ground System for the Joint Polar Satellite System (JPSS CGS 2.0) is now operational, supporting 11 polar-orbiting satellites and delivering observations to NOAA’s National Weather Service almost 50 percent faster than before.

    Svalbard, Norway, is the location of the northernmost Joint Polar Satellite System Common Ground System station.

    JPSS CGS 2.0 was designed to support the upcoming NASA launch of NOAA’s JPSS-1 satellite on Nov. 14.

    “The new ground system significantly improves the mission capabilities of the JPSS program,” said Matt Gilligan, vice president of Raytheon’s Navigation and Environmental Solutions. “It can handle even more data from the full constellation of satellites now and in the future.”

    Developed by NASA for NOAA, the JPSS CGS collects and disseminates observations from polar-orbiting weather satellites from the United States, Europe and Japan.

    The polar orbiters provide critical weather and environmental data to ensure meteorologists and forecasters have robust, reliable information to make timely and accurate weather predictions that help save lives, protect property and decrease the devastating economic impact caused by severe weather.

  • Phase One innovates four-band aerial imaging

    Phase-One-4-Band-W

    Phase One Industrial has introduced its Phase One 4-Band Solution, which incorporates an innovative batch-processing tool that automates and simplifies the four-band aerial image generation process.

    Adding a fourth band of near infrared (NIR) image data to three-band color (RGB) image data yields multispectral information useful in vegetation studies — in applications ranging from crop metrics for optimization, to vegetation health, environmental contamination and city observations for green site monitoring.

    Synchronized Phase One metric aerial cameras.
    Synchronized Phase One metric aerial cameras.

    The solution is composed of two synchronized Phase One metric aerial cameras mounted side by side on a specially designed base plate, a Phase One iX Controller and Phase One iX Capture software.

    Images are captured in NIR and RGB bands simultaneously, and processed automatically to generate distortion-free images and perform fine co-registration of the pixels from NIR to the RGB images — including processing different image sizes — with seven different output options, including multispectral CIR images.

    Complementing the solution’s software functionality, the use of two separate cameras to support higher system sensitivity permits operators to separately control capture settings so that they can operate under a wider range of lighting conditions.

    “We very easily installed the cameras into the gyro mount, and all power and communications were automatically configured with the iX-Controller,” said Peter Bochmann, operator of Aerial SurveyS GmbH. “The output four-band images were incredible, showing an area of forest vegetation straight-away that needed attention; we would not have seen this detail with RGB images alone. The flexibility of the solution is also great, since you can combine any two Phase One metric medium-format cameras and accomplish multiple jobs without changing the setup.”

    The Phase One 4-Band Solution offers a variety of benefits:

    • 100MP sensors for RGB and NIR images, no NIR up scaling is needed;
    • CMOS sensors for maximum sensitivity;
    • Post processing is automatic, using the solutions’ iX Controller along with iX Capture;
    • Automatic individual aperture control and auto exposure mode is available for both cameras;
    • Direct connection to GNSS/IMU systems; coordinates are stored inside the EXIF data of each image to speed later post-processing;
    • Also available with 80MP RGB and 60MP Achromatic Sensors.

  • New ArcGIS Full Motion Video release gives faster access

    Esri’s latest version of ArcGIS Full Motion Video (FMV) presents new capabilities to improve the way analysts and managers interact with videos.

    ArcGIS FMV allows users to view, organize and analyze video from drones and other collection platforms.

    The new release includes a performance boost in playback and panning, and in zooming the video during playback. It offers full support for JP2, and TIFF support for video mosaics including full image transformations for better accuracy. A new search tool makes it easier to find video segments based on location, time, and selected features.

    “ArcGIS FMV expands the capabilities of ArcGIS as a complete, professional platform for managing, sharing, and extracting value from geospatial data,” said Gerald Kinn, Esri’s lead product engineer for imagery. “Imagery from video is one of the most important sources of data in ArcGIS.”

    The previous version of ArcGIS FMV included a multiplexer tool that allowed users to transform non-MISB format videos, such as from UAVs or drones, into MISB-compliant videos compatible with the FMV add-in.

    “ArcGIS FMV tools add a dimension to our remote sensing analysis not previously possible,” said Verne LaClair, general manager for Vertex Geo, an Esri partner that specializes in civilian, municipal, defense and intelligence initiatives. “The ability to map FMV content will play an important role in search-and-rescue operations, wildlife tracking and monitoring, and cinematography projects.”

    For specific and technical details about this and the latest version, visit Esri.com/FMV.

  • USGIF Partners with the Centre for Spatial Law and Policy

    The United States Geospatial Intelligence Foundation and the Centre for Spatial Law and Policy have entered into a memorandum of agreement under which USGIF and the Centre will educate the geospatial community on the unique legal and policy issues that impact the collection, use, storage and distribution of geospatial information.

    Under the agreement, USGIF and the Centre have created a Geospatial and Remote Sensing Law Working Group. The group will develop training and education materials for GEOINT practitioners, host workshops, and further the GEOINT Community’s understanding of geospatial and remote sensing law.

    “The Centre is pleased to be working with USGIF to educate the geospatial community on these important issues,” said Kevin Pomfret, executive director of the Centre for Spatial Law and Policy. “This is also an opportunity for the geospatial community to educate lawyers on where GEOINT is taking the law.”

    “As we embark upon the GEOINT revolution, the myriad technological advances related to location and remote sensing are significantly outpacing the development of associated law and policy,” said USGIF CEO Keith Masback. “Decisions are being made daily at all levels of government — in the U.S. and abroad — as courts set precedents gavel drop by gavel drop. This partnership will play a crucial role in organizing a more coherent way forward.”

    Next month, the Geospatial and Remote Sensing Law Working Group will host a half-day workshop on legal matters critical to the GEOINT Community as part of USGIF’s 2015 GEOINT Community Week.

    The program will include three panels: Government Contracts and Organizational Conflicts of Interest: Conflicts in an Increasingly Conflicted World; Government Contracts and Intellectual Property: Playing a Critical Role in Geospatial Contracting; and Developments in Licensing of Commercial Remote Sensing Satellites. The event will take place Nov. 18 at General Dynamics Information Technology in Springfield, Va. Click here for more information or to register.

  • Night-Time Satellite Images Show ISIS-Controlled Regions

    ISIS-remote-sensing-city-lights
    Figure 1. Suomi NPP/VIIRS night-time light images for Iraq: (a) May 2014, (b) December 2014.

    A new paper published in the academic journal International Journal of Remote Sensing analyzed city night lights in Northern Iraq during 2014, suggesting a major loss of electrical power supply within the Iraqi cities seized by ISIS.

    The territory controlled by the Islamic State of Iraq and Syria (ISIS) has grown rapidly since the start of the Syrian Civil War, and in 2014 ISIS expanded its control into Northern Iraq. While there are many media reports on violence and geopolitical issues surrounding the takeover of these areas, the impact on everyday life, such as access to electricity for people living in ISIS-controlled regions, is less clear.

    In the study, Xi Li and Deren Li (Wuhan University, China) and Rui Zhang and Chengquan Huang (University of Maryland) analyzed city lights as a proxy for the power supply in ISIS-controlled regions between May 2014 and December 2014. The city light data were acquired from the Visible Infrared Imaging Radiometer Suite (VIIRS) sensor on the NASA/NOAA Suomi National Polar-orbiting Partnership (NPP) satellite.

    The analysis indicates that most of the ISIS-controlled cities, including Mosul and Tikrit, experienced a decrease of more than 90 percent in city light after being seized by ISIS, while the loss of light in cities controlled by the Iraqi security forces (ISF) was very limited. However, the city lights in Ar Raqqa, Syria, ISIS’ de facto capital, did not show a decline after that region was seized by ISIS.

    These comparisons suggest that the conflict in Northern Iraq has resulted in a major loss of electrical power supply within the Iraqi cities seized by ISIS, and that this loss is most likely due to lack of access to the Iraqi power grid, rather than a deliberate ISIS strategy of limiting night-time light.

    The insurgency in Northern Iraq since 2014 has led to a severe humanitarian crisis, the study authors say. It is widely known that it is extremely dangerous to collect information from ISIS-controlled regions; therefore, the use of remotely sensed night-time light images such as these offer humanitarian agencies and NGOs a low-risk indicator of socioeconomic conditions in war-torn countries like Iraq.

    The paper is “Detecting 2014 Northern Iraq Insurgency using night-time light imagery,” by Xi Li, Rui Zhang, Chengquan Huang and Deren Li, International Journal of Remote Sensing, 2015, published by Taylor & Francis Group.

  • Trimble Provides Software Enhancements for GIS, Remote Sensing

    Trimble has announced a series of new software enhancements that enable photogrammetry, GIS, geospatial and remote sensing professionals to streamline workflows, achieve faster results and gain increased value from highly accurate geospatial data. Enhancements include the Trimble Inpho version 6.1 photogrammetric suite, UASMaster version 6.1 and UASMaster Lite for Unmanned Aircraft System (UAS) applications, and eCognition  version 9.1 and eCognition Essentials version 1.1 image analysis software.

    The announcement was made at the Imaging and Geospatial Technology Forum (IGTF), formerly ASPRS, held May 4-8 in Tampa, Fla.

    “Optimizing software workflows for our customers to gain value from imaging data is critical for the success of geospatial professionals and a continued focus of Trimble Geospatial,” said Alain Samaha, business area director of GIS and Geospatial Software Solutions for Trimble’s Geospatial Division. “The new enhancements will enable customers to streamline processes and increase their efficiency and productivity, which translates to increased cost savings and decreased operational expenditures.”

    Photogrammetry professionals generating high-quality deliverables, with Trimble’s Inpho software, such as 3D CAD line work, GIS layers and DTMs, can now reduce production time by days through optimized geo-referencing capabilities and new tools for CAD object creation. The Inpho version 6.1 enhancement allows snapping-to-elevation and draping lines-to-elevation models—for greater efficiency in creating CAD data layers—while maintaining the highest level of accuracy.

    The UASMaster version 6.1 software enhancement offers greater productivity through new support for precise GNSS data that allows users to reduce the number of ground control points required without compromising accuracy. For professionals new to the UAS market, UASMaster is now also available in an entry-level “Lite” edition. The new UASMaster Lite edition allows users to quickly extract high quality deliverables within a simplified workflow, while obtaining the same industry-leading quality offered with Inpho software.

    Inpho version 6.1 and UASMaster version 6.1 now also include a direct interface connection to Trimble’s eCognition analysis software, making it easier to obtain actionable and valuable information from imagery data in land classification maps, GIS layers and change analysis.

    eCognition version 9.1, an object-based image analysis software, now includes enhanced multi-core processing, allowing GIS, geospatial and remote sensing professionals to extract valuable information from satellite and aerial based data faster than before. New GIS-based analytic tools and improved tools for packaging applications make it easier to create customer solutions.

    eCognition Essentials version 1.1 provides up to 50-percent faster processing than previously, including improved flexibility and control of classification workflows for professionals generating land-cover mapping deliverables.

    The new versions are available now.

  • Report Examines Geospatial Analysis for Defense, Security

    A new report by Visiongain examines geospatial data analysis for defense and homeland security — a world market worth $9.7 billion in 2014. The report, “Governmental Geospatial Intelligence (GEOINT) Solutions Market 2014-2024: Digital Mapping, Geographic Information Systems (GIS), Cloud-Based Geo-Analytics & Geo-Data Exploitation for Defence & Homeland Security” is being offered by Reportbuyer.com.

    Advances in technologies such as cloud and 3D modeling — together with increased availability of high-quality, high-accuracy geospatial data, especially from space-based remote sensing satellites — are propelling the market for governmental GEOINT solutions, Reportbuyer.com said.

    “The coming decade will see governments around the world scrambling to acquire GEOINT capabilities on increasingly higher scales, to ensure they stay on top in the ‘information superiority’ race,”  Reportbuyer.com said in a press release. “At the moment, outside the U.S. this is a relatively young market, at the very beginning of a period of large international expansion over the next ten years.”

    According to Reportbuyer.com, geospatial information exploitation technology is one of the vital enablers and defining aspects of 21st century defense, intelligence and homeland security capabilities and operations. In a digital age where the vast majority of data has a location and time, GIS and GEOINT systems provide the means to reference it geographically.

    “In this visual context, complex dynamics, patterns and relationships can be revealed, analyzed and understood in a completely new way,” Reportbuyer.com said. “This takes ‘situational awareness’ to an entirely different level, and enables an unprecedented and powerful new type of analysis: geospatial analysis. A key part of this overall capability is a new generation of tools for advanced digital mapping and modeling, which extend the applications of GIS beyond intelligence, C2 (command and control) and the achievement of information superiority into areas like resource management, mission simulation, and down to individual soldiers.”

    The 300-page report provides market forecasts and analysis for GEOINT solutions, 2014-2024, and sales value projections of the market with essential information on the technologies, GEOINT organizations and competitors. The report is available at Reportbuyer.com.

  • ASPRS Releases New Accuracy Standards for Digital Geospatial Data

    The American Society for Photogrammetry and Remote Sensing (ASPRS) has released new Positional Accuracy Standards for Digital Geospatial Data. The PDF is available here.

    The new ASPRS accuracy standards fill a critical need for map users and map makers alike. For centuries, map scale and contour interval have been used as an indication of map accuracy. Users want to know how accurately they can measure different things on a map, and map makers want to know how accurate maps need to be in order to satisfy user requirements. Those contracting for new maps depend on some form of map accuracy standard to evaluate the tradeoff between the accuracy required vs. how much time and expense are justified in achieving it, and then to describe the accuracy of the result in a uniform way that is reliable, defensible, and repeatable, ASPRS explains in a statement.

    The new ASPRS standards address recent innovations in digital imaging and non-imaging sensors, airborne GPS, inertial measurement units (IMU) and aerial triangulation (AT) technologies. Unlike prior standards, the new standards are independent of scale and contour interval, they address higher levels of accuracies achievable by the latest technologies (such as unmanned aerial systems and LiDAR mobile mapping systems), and they provide enough flexibility to be applicable to future technologies as they are developed. Finally, the new standards provide cross references to older standards, as well as detailed guidance for a wide range of potential applications.

    No prior U.S. accuracy standard comprehensively addresses the current state of mapping technology, which is why the new ASPRS standards were developed. The National Map Accuracy Standards (NMAS), developed in 1947, are still used because they are simple, but there is no scientific correlation between those standards and current mapping methodologies.

    The ASPRS 1990 Standards were an improvement over NMAS; however, they did not do well in representing the capabilities of LiDAR, orthoimagery, digital mapping cameras or other current technologies in wide-spread use today.

    The National Standard for Spatial Data Accuracy (NSSDA) is a reporting standard that references the old ASPRS 1990 standards and is cross-referenced in the new ASPRS standards.  NSSDA provides no accuracy thresholds and does not by itself provide any new or updated guidance on how to select or specify an appropriate accuracy for intended applications.

    The new ASPRS standards were developed by the ASPRS Map Accuracy Standards Working Group, a joint committee under the Photogrammetric Applications Division, Primary Data Acquisition Division and LiDAR Division, which was formed for the purpose of reviewing and updating ASPRS map accuracy standards to reflect current technologies. A subcommittee of this group, consisting of Qassim Abdullah, David Maune, Doug Smith, and Hans Karl Heidemann, was responsible for drafting the document.

    Draft versions of the standard underwent extensive review, both within ASPRS as well as through public review by other key geospatial mapping organizations, prior to final approval by the ASPRS Board of Directors on November 17, 2014.

  • TerraGo Partners with RazorTek on TerraGo Edge

    TerraGo is partnering with RazorTek, a GIS and remote-sensing consulting firm specializing in design, development and automation of complex systems for spatial data display and analysis. RazorTek will deploy TerraGo Edge for customers looking to replace GPS handhelds with a mobile app that integrates directly with Esri’s ArcGIS.

    “We see a great opportunity to help our customers utilize TerraGo Edge for field data collection on their smartphones and tablets,” said Dan Rodriguez, CEO, RazorTek. “The nice thing about TerraGo Edge is that it replaces proprietary GPS handhelds with a simple mobile solution at a fraction of the cost, and it works seamlessly with Esri ArcGIS out of the box.”

    “RazorTek is an industry expert for deploying advanced remote sensing and GIS solutions,” said John Timar, vice president,  TerraGo. “TerraGo Edge gives the RazorTek team a cost-effective mobile solution that can deliver cm-level accuracy or whatever the RazorTek customer needs, while leveraging their existing ArcGIS investment.”

    RazorTek is an authorized reseller of TerraGo products and also offers a range of geospatial technology software and services including GIS services, aerial photography, satellite imagery and LiDAR.

  • Hexagon Geospatial Tech Measures Tallest Mountain in New Zealand

    Topography of Mount Cook, New Zealand's tallest peak, changed following a rock avalanche. (Photo Wikipedia Commons, C.M. Lynch)
    Topography of Mount Cook, New Zealand’s tallest peak, changed following a rock avalanche. (Photo Wikipedia Commons, C.M. Lynch)

    The National School of Surveying, University of Otago, implemented Hexagon Geospatial technologies provided by Intergraph in its quest to measure the summit of Mount Cook, the tallest mountain in New Zealand and a UNESCO World Heritage Site. The University of Otago is New Zealand’s oldest university.

    The university turned to Hexagon Geospatial’s ERDAS IMAGINE and IMAGINE Photogrammetry (formerly LPS) to help measure the height of Mount Cook, also called Aoraki, following a large rock avalanche that changed the peak’s topography and height in 1991. For many years, the university has benefited from Hexagon Geospatial’s education licenses through Intergraph, and chose these technologies for the project because of  their image processing and photogrammetric capabilities, as well as integrated workflows.

    “ERDAS IMAGINE is the cornerstone of the project. It started from there,” said Pascal Sirguey, senior lecturer at National School of Surveying and project leader. “Using the photogrammetric capability, we were led to look more closely at what the model was telling us. The software gave us the right answer in the end.”

    Following the avalanche, a resurvey found the mountain to be 3,754 meters high — down from the surveying estimate of 3,764 meters in 1881. The university undertook the unique challenge of validating the new elevation. Photogrammetry and remote sensing were the only viable methods for measuring the summit as it is considered sacred by the Maori tribe of Ngāi Tahu and standing on it is prohibited.

    Using Hexagon Geospatial’s software, along with Global Navigation Satellite System receivers, the university determined the actual height of Mount Cook is 3,724 meters. For the university’s remarkable efforts, Sirguey received the top award from the New Zealand Institute of Surveyors in 2014 for teaching and education and the New Zealand Spatial Excellence Award 2014 in the Education and Professional Development category.

    The University of Otago was founded in 1869 by an ordinance of the Otago Provincial Council. Its School of Surveying offers the only academic qualification leading to professional recognition as a professional land surveyor in New Zealand, following a period of post-graduation training and examination by the New Zealand Institute of Surveyors. The courses offer a broad range of disciplines — surveying, land planning and development, survey measurement and Geographic Information Systems — that equip graduates for a professional career.

    Provided through Intergraph, Hexagon Geospatial’s education program provides the university with a complete geospatial software portfolio that offers support and tools for academic research projects and teaching.

  • Proteus Discusses Satellite-Derived Forest Inventory in Webinar

    Proteus FZC, a provider of satellite-derived mapping and classification services, will discuss its use of high-resolution WorldView-2 imagery to derive accurate forest inventory and tree classification maps in Abu Dhabi during a free webinar with DigitalGlobe.

    “Vegetation Analysis in the Desert Using Satellite Imagery,” part of the ongoing DigitalGlobe LEAD Webinar Series, will be held September 24 at 12:30 p.m. BST (7:30 a.m. U.S. EDT). Register by clicking here.

    The webinar is aimed at managers and technical analysts from forestry, agriculture, remote sensing and GIS organizations in private and public sectors. The webinar will cover:

    • How very high-resolution satellite remote sensing technology is being deployed commercially for tree inventory and condition analysis.
    • Tools that are available now to help agriculture, forestry and environmental decision makers in areas with sparse water resources.
    • How to use satellite data in support of environmental planning and policy creation.

    Richard Flemmings, Proteus project manager, will offer insight into a recent 20-million tree mapping and classification project performed by Proteus FZC in Abu Dhabi. As an extension to an Emirate-wide habitat and land use/land cover project, Proteus applied advanced processing algorithms to the multispectral and panchromatic WorldView-2 image data to differentiate many tree species and assess the condition of individual trees, critical for irrigation management.

    “This project demonstrates the viability of using very high-resolution satellite imagery to quickly and cost effectively create baseline vegetative inventories within diverse land-use areas,” said Flemmings. “The mapping technique used in Abu Dhabi can be applied to create forest and vegetation inventories of other species anywhere in the world.”

    Since 2011, Proteus has been delivering solutions for mapping and classification projects using multispectral satellite imagery. These mapping projects have been delivered for environmental, oil & gas, engineering and other coastal zone applications in Europe, USA, the Middle East and Caribbean.

    For more information on Proteus products, see www.proteusgeo.com  or email [email protected] for further details or to discuss individual requirements.