Hexagon AB, which offers sensor, software and autonomous solutions, has signed an agreement to acquire Volume Graphics, a specialist in industrial computed tomography (CT) software.
Volume Graphics brings more than 20 years of experience in non-destructive inspection and testing software development. The company’s high-end analysis and visualization CT software enables manufacturers to produce three-dimensional external and internal representations of scanned objects.
Using CT, they’re able to “see” inside the complicated structures of components, otherwise inaccessible with traditional inspection methods. This allows hidden or hard to reach internal features to be measured and inspected for dimensional deviations and flaws without destroying the parts and compromising the integrity of the data in the process.
“Volume Graphics offers an invaluable toolset for leveraging CT data across many use cases — from flaw detection and failure analysis to reverse engineering applications,” said Hexagon President and CEO Ola Rollén. “We look forward to merging our capabilities so that customers can ensure the highest product quality throughout product development and production. Additionally, industrial CT scanning is fast becoming a critical asset to manufacturers as more and more industries embrace additive manufacturing. The addition of CT software capabilities strengthens our portfolio in this growth area.”
Today, a broad range of global customers from the automotive, aerospace and electronics industries use Volume Graphics software for quality assurance.
Founded in 1997 and headquartered in Heidelberg, Germany, Volume Graphics employs around 160 people worldwide. Subsidiaries in Japan, Singapore, China and the U.S., supplemented by an extensive reseller network, deliver its software to customers in more than 50 countries.
Volume Graphics will operate as part of Hexagon’s Manufacturing Intelligence division. Completion of the transaction (closing) is subject to regulatory approvals. 2018 sales amounted to 25 MEUR.
The funding enables continuation of a national effort by state government geospatial information officers and coordinators to work with other state agencies, local elections officials and state elections offices, national GIS (geographic information system) and elections organizations, and federal partners to identify opportunities to leverage this powerful technology to strengthen elections management and citizen engagement.
“As an organization made up of GIS leaders in state government, NSGIC is uniquely positioned to leverage the innovative work of states to use GIS for elections data,” said Molly Schar, NSGIC executive director. “We have enlisted those innovators to contribute and advise throughout the project. Collaboration has been key to the success of the project. Relationships built in the first phase of the project will be invaluable to the work of the second phase as the project seeks to increase engagement and, ultimately, impact.”
Two more years. The Geo-Enabled Elections project was launched in October 2017 and will now continue for an additional two years. The project aims to help strengthen electoral systems by supporting states in the adoption of GIS.
In practical terms, this means encouraging state governments to replace non-spatial address-file systems with election precinct and voter data in a GIS format, leveraging that format’s inherent visual and analytical advantages.
With its second phase, the project turns to focus on working hands-on with up to 10 more states through the pilot program, developing a curriculum for elections officials on foundations of GIS in elections, increasing awareness of the benefits of geo-enabling elections systems among elections stakeholders, and developing policy guidance and advocacy tools to support integration of GIS in elections.
“Accurate boundary lines and efficient voter placement are the building blocks of our elections and are tantamount to the integrity of the democratic process,” said Tammy Patrick, senior advisor at Democracy Fund Voice. “Democracy Fund Voice is a proud sponsor of efforts such as NSGIC Geo-Enabled Elections as a way to further ensure that the American electorate is well served.”
A report of the work done in the first phase of the project is now available.
Accomplishments in the first two years include:
developing an inventory of state implementations of GIS-based elections systems
giving workshops and presentations at national conferences
publishing detailed reports sharing the state of GIS in elections from the perspective of election officials and state GIS leaders
five pilot and case studies
development of a best-practices guide (both in detail and brief versions) was developed
Also, an inaugural Elections GeoSummit in August convened stakeholders from the national, state, and local levels to discuss best practices for geo-enabling elections in the United States.
These documents and other important resources can be found in a PDF format on the NSGIC website.
Pointfuse has developed smart software that automates the identification and classification of objects for facilities management applications using data from mobile mapping systems like the new Leica BLK2GO.
Pointfuse software converts the millions of individual measurements captured by laser scanning and photogrammetry into useable 3D mesh models. The unique ability to classify objects within Pointfuse, both automatically and manually, has already had a huge impact on how as-built data is used within design and construction. It can now realize real time records for space utilization and optimization projects, reducing costs and speeding workflows within facilities management.
The Leica BLK2GO. (Photo: Leica Geosystems)
Pointfuse Simple BIM (sBIM) leverages the core functionality of Pointfuse — the segmented mesh model; automatically converting classified mesh models into “family” groups, such as walls, floors, doors, windows, etc. for use with popular downstream BIM and FM software. Pointfuse sBIM data can then be exported as IFC (Industry Foundation Class) parametrized objects and 2D floors plans and space management reports easily derived. Pointfuse sBIM also automatically calculates quantities, areas and dimensions in an easy to read PDF report.
“This ability to convert classified objects into family place holders has a huge impact on how as-built data is used within a Scan2BIM workflow with the potential for a real return on investment for facilities and space management applications,” said Mark Senior, regional sales director at Pointfuse. “The combination of ease and speed of data capture, as offered by modern hand-held indoor mapping systems like the newly launched Leica BLK2GO, with the automation of Pointfuse processing will release the potential of laser scanning across this sector.”
Pointfuse sBIM was developed in response to a large scale client opportunity that saw the scanning of millions of square feet of facilities with the final deployment of data in Archibus facilities management software using Autodesk Revit as a bridge. Early testing identified that 3D was as quick to create as traditional 2D workflows and exported data is in the region of hundreds of Kbs compared to the Gb volumes of the original point cloud. Taking the process one step further Pointfuse provides an accurate record of the as-built scene by allowing users to create Hybrid meshes combining Pointfuse models with the sBIM IFC container.
Pointfuse will be showcasing the sBIM functionality at the Autodesk University (AU) Expo which takes place Nov. 19-21 at the Sand Expo Convention Centre in Las Vegas, Nevada.
Pyramids of Giza taken from the International Space Station. (Image: NASA)
The Great Pyramids still cast their long shadow upon history. It’s been said that even Time kneels before them. They are monuments to the state-of-the-art technology of the builders using their most advanced astronomy, engineering, mathematics and trigonometry as a testament to their understanding of the world.
They are monuments to the builder’s state-of-the-art technology at the time using their most advanced astronomy, engineering, mathematics, and trigonometry as a testament to their advanced understanding of the world.
The pyramids’ corners align perfectly to the four cardinal points. Shafts on the north slope point towards the circumpolar stars, the so-called “Imperishable Ones” because they never set beneath the horizon. The Great Sphinx, eternal companion of the pyramids, is perfectly aligned to face the rising Sun on the morning of the summer solstice.
These constructs defined the physical framework of their cosmogony — ancient Egypt’s center of the world — their prime meridian and equator. References of place were in terms of direction and distance from the pyramids.
The word meridian is a Latin derivative of meridiem, as in a.m. and p.m., meaning midday. The moment is marked by the sundials’ shadow being neither to the west nor to the east and is directly in the middle. It marks an imaginary line running from north to south. The Prime Meridian is synonymous with Greenwich Mean Time (GMT), Universal Time Coordinate (UTC), or the military time zone Zulu.
In Mesopotamia in 600 B.C. is a map carved into a clay tablet depicting Babylon in the center surrounded by a circular ocean marking the edge of the known world. Beyond the ocean are eight projections emanating like sunrays. Four of them point to the cardinal directions and the other four towards celestial bodies with mythological significance.
This map, called the Bitter Waters, the name of the circular ocean, is considered the oldest in the world; and thus, the first official cartographer forged together the geography of the physical world with that of the cosmos.
Early maps had few frames of reference. If you wanted to know your whereabouts, you had to already know where you were, otherwise, you’d need the expertise of a seasoned guide.
Celestial bodies were the primary means for finding one’s way, the main one being the Sun, especially at daybreak. In fact, for thousands of years the importance of the sunrise was so essential to getting oneself pointed in the right direction that to this day it remains the principle word for that action.
Consider the following. The way a map is pointed is how it is oriented. If someone is lost, physically or consciously, that person is disoriented. The skill of traversing overland is orienteering. These all stem from the Latin word for east, orientalis; hence, the civilizations beyond Byzantium were considered the Orient, and likewise, the word Asia comes from the Phoenician word for sunrise, Asu. Thus, setting out on a journey required waking up with the sunrise and marking the direction of the shadow and then dead reckon along that line due west, or opposite the line due east.
In fact, many ancient maps were oriented toward the east such as the Mappa Mundi mentioned later in this article. At night, the North Star and knowledge of the constellations were used for travel; but during the day, north was just a general direction. North was derived by drawing a right angle perpendicular to the line between the two points of sunrise and sunset. The term for North under Roman rule was pars caeli septentrionalis, which translated means, The part of the sky towards the seven stars, referring to Ursa Major and Minor. North was not of much use during the day until the invention of the magnetic compass.
The Early Superpowers and the Great Sea Race
The trade routes along the Silk Road collapsed after the fall of Byzantium in 1453, and where there is chaos there is also opportunity. Reestablishing dependable trade with the east was worth billions. Finding a sea route to become Europe’s source of spices and goods was too alluring. The “Sea Race” of nations had begun.
Cantino Planisphere. (1502) (Image: public domain)
Portugal won the first round of the Sea Race claiming islands to use for trade routes rounding the Cape of Good Hope in 1488 and reaching India in 1498. Columbus, sailing under the Spanish flag discovered the Americas in 1492. The Mappa Mundi by Spanish explorer Juan de la Cosa in 1500 is the first map to show the Americas.
Navigational maps were closely guarded national secrets; so much so, the Duke of Ferrara hired a spy, Albert Cantino, to steal a Portuguese nautical map, which is now named in his honor, the Cantino Planisphere, and it shows the emerging knowledge of the newly discovered world. It also marks the evolution of travel using celestial navigation. America, unnamed at the time, was a closely guarded secret by the Spanish and of top national interest.
Portugal and Spain dominated the oceans for most of the 15th and 16th centuries to the point that the world was divided between the two along a meridian known as the Tordesillas Line splitting the world between the two superpowers.
Technology Ignites the Golden Age of Sailing Ships
Thanks to early navigation of the Portuguese and the Spanish, the magnetic compass and the sextant came into use, allowing more precise calculations of latitude improving navigation. Cartography and surveying improved as a result. Ingenious approaches for telling time at sea were invented. One method used Jupiter’s four primary moons as a clock.
England, over 100 years late to the global expansion entered the Age of Sail in 1600 when Queen Elizabeth signed the charter establishing the East India Company (EIC). Contrary to both the Portuguese and Spanish models which were funded by their monarchies, the English created a profit-sharing corporate model, which would ultimately account for half of all the world’s trade.
The EIC remains the most profitable company in history (inflation adjusted), but the costs of running such a vast enterprise were also great. The EIC lost nearly 220 ships. Every ship lost was the loss of a captain, the crew, the cargo, and the ship itself. Shipping was a costly venture. Not counting pirates, storms and war, the primary cause of shipwrecks was incorrect location. Distances could be off by hundreds of miles, enough to end up in the shallows or the rocks.
The problem wasn’t latitude. That could be determined with a great degree of certainty using angular measurements of the sun and celestial bodies above the horizon. Longitude was the culprit. Knowing position on an east west axis proved much more difficult. Longitude was thought to be an astronomical problem, and in order to solve it King Charles II established the Royal Observatory in Greenwich, England in 1675, which happened to be at the height of Europe’s scientific revolution, the primary scientist at the time being Isaac Newton.
However, as many of the greatest minds attempted to solve the problem, none were able to do so. Thirty years’ later the Royal Society presented the challenge to the public offering a reward of £20,000, which is equivalent to approximately $3.1 million in 2019. It was known as the Longitude Act of 1714. The solution finally came in 1736.
John Harrison, a clockmaker, understood that space and time are inextricably connected. Longitude was solved by having two chronometers, which literally means an instrument to measure time. One chronometer was set to local time each day at noon. The other was set to Greenwich Mean Time. The difference in hours between the two pinpointed the time zone and the corresponding longitude. The original time zones were not the political ones represented today. There were 24 of them around the circumference of the earth and each time zone corresponded to a different letter of the alphabet.
Time zones traverse in increments of -1 hour to the west and towards the east +1 hour for 12 hours in each direction totaling 24 in all. The Greenwich Observatory lies within time zone 0 which is the military time zone Z. In the military phonetic alphabet Z is Zebra but it used to be Zulu.. The more precise time could be measured, the more accurate the position, thus, location coordinates are measured in degrees, minutes and seconds.
Today, the world’s primary chronometer is called the Master Clock and is housed at the United States Naval Observatory (USNO) in Washington, D.C. The USNO’s primary mission is position, navigation and timing (PNT). The grounds of the USNO is the home of the Vice President indicating the importance time is to commerce and the welfare of a nation.
GPS satellites set their internal clocks to the USNO Master Clock. PNT is so precise location can be determined down to the sub-millimeter level. Every smartphone’s geolocation is tied into this network. The U.S. Naval Observatory Master Clock has a phone number, (202)762-1401, and every 15 seconds the voice of Time proclaims the exact moment, translating the decay of cesium-133 into the same language of the pyramids, the Sphinx and Stonehenge.
A final thought. Heraclitus said we cannot step into the same river twice. The river changes by the flow of itself. But, Time itself is a river and with each passing moment our lives forever change. Look back. It is the past — the place of regret and glory. Look forward. It is the future where hope and fear reside. Look at the present. It is the only place we are.
Letter signed to advance role of geospatial knowledge infrastructure in global society and economy
Geospatial Media & Communications has signed a letter of cooperation with the United Nations Statistics Division (UNSD) to work together to advance the role of geospatial knowledge infrastructure in global society and economy.
Consistent with their respective mandates, the UNSD and Geospatial Media will collaborate to carry out activities related to their common objective of demonstrating the value of global geospatial knowledge, the data ecosystem, public-private partnerships, and their contribution towards building Geospatial Knowledge Infrastructure and the Global Development Agendas.
The agreement was signed by Stefan Schweinfest, director, UNSD, Department of Economic and Social Affairs, and Sanjay Kumar, CEO, Geospatial Media, in New York on Oct. 31.
“The United Nations 2030 Sustainable Development Agenda is ambitious and requires countries to have solid national information systems to successfully stir the process of implementation. It is a central task of my office, the United Nations Statistics Division, to support countries in building the necessary national information capacities, both in the area of statistics and geospatial information. For this challenging task we need the cooperation of the private sector through well established public-private partnerships. Geospatial Media & Communications is a unique partner in this respect, due to its global reach and its in-depth knowledge and understanding of country needs. I am, therefore, delighted to cooperate with them closely in the coming years,” said Mr. Schweinfest.
“Pursuing its vision to make a difference through geospatial knowledge in world economy nad society, Geospatial Media has been evangelizing geospatial industry globally for over two decades through research, advocacy, media and knowledge exchange platforms. It has contributed in the formation and strengthening of several institutions, including the Association of Geospatial Industries (AGI), World Geospatial Industry Council (WGIC), UNGGIM Private Sector Network and the National Think Tank on Geospatial Strategy for New India. Through this collaboration, our intent is to further our vision to showcase high level value of geospatial knowledge in global development agenda and facilitate alignment and evolution of geospatial stakeholders with emerging socio-economic development models in the fourth Industrial age,” said Mr. Sanjay Kumar.
The intended collaboration will focus on a number of common objectives at national, regional and global levels which will include:
Working together to create joint programs and projects to develop geospatial knowledge infrastructure, networks and human resource capacities;
Assessment of the prospective role of geospatial knowledge infrastructure in global society and economy;
Collaboratively developing broader methods, guidelines, architectures and policy frameworks for the adoption, utilisation and benefits of geospatial knowledge infrastructure;
Develop documents, training modules and other resources to assist National Geospatial Information Agencies in their transformation and modernization aspirations in alignment with the national to global vision of the Integrated Geospatial Information Framework;
Facilitate a collaborative knowledge exchange and engagement atmosphere between the commercial geospatial industry, national geospatial agencies, and the broader user industries and civil society, towards developing public-private partnership models for co-creating geospatial knowledge infrastructure and strengthening of industry and institutional capacities; and
Advocate, communicate and promote the value and utility of geospatial information and enabling technologies for sustainable development.
Touch GIS has released the Touch GIS app for iPhone and iPad. Users can explore the app’s features with a free 14-day trial.
Touch GIS offers professional-grade field data collection and visualization. It takes advantage of devices already used by many people, making field data collection easy and convenient, the company said.
Features include:
an intuitive interface
offline capabilities
map caching
robust file support
customizable attribute forms
preloaded feature class templates
Users can collect point, line and polygon features, as well as create custom feature classes.
File types supported include Shapefile, KML/KMZ, GeoJSON, GPX and CSV (Export).
Custom Forms:
– Description
– Date & Time
– Photo
– List Of Values
– Checkbox
– Address
– Number
– Website
– Phone Number
Preloaded Feature Classes:
– Forestry
– Geology
– Real Estate
– Stream Surveys
– Water Infrastructure
– Wetlands
– Create Your Own!
The Library of Congress will celebrate GIS (Geographic Information Science) Day on Nov. 13. GIS Day, which is held during Geography Awareness Week (Nov. 12-18), is an annual, global celebration of GIS and mapping technology. Formally started in 1999, GIS Day aims to provide a forum to promote the benefits of GIS research, demonstrate real-world applications of GIS, and foster open idea sharing and growth in the GIS community.
The 2019 event will include an all-day series of talks on the use of GIS technology and 3D mapping in cultural heritage preservation and disaster response. The discussions will be held from 8:30 a.m. to 3:30 p.m. in LJ-119 on the first floor of the Thomas Jefferson Building, located at 10 First St. SE in Washington, D.C.
The morning session of the event will open with a keynote speech by Sen. John Boozman of Arkansas, co-chair of the Congressional French Caucus focusing on Cultural Heritage Preservation Mapping and Congressional Policy. The morning will also feature takes about the Notre Dame Cathedral fire and the use of GIS and computer vision in disaster response planning and cultural heritage preservation.
The afternoon session will concentrate on on applications of the technology with case studies on historic building and engineering archives in cultural preservation, advanced spatial analysis and 3D mapping of UNESCO World Heritage sites.
There will also be an open house in the Geography and Map Division from 3:30-4:30 p.m.
Epson has launched the Epson SureColor T3170x 24-inch wide-format wireless printer. Engineered to enhance workflow, the new model in the SureColor T-Series product line offers cartridge-free printing in a clean, space-saving design.
The new, easy-to-fill, refillable ink tanks eliminate time spent purchasing and changing ink cartridges. Ideal for low-cost POP and education posters, as well as blueprints and line drawings up to 24 inches, the SureColor T3170x produces accurate, A1/D-size prints in 34 seconds.
“This SureColor T3170x joins the popular T-Series line that delivers powerful printing solutions for many industries, including architecture, engineering, construction, creative professionals and graphic design,” said Matt Kochanowski, product manager, professional imaging, Epson America. “The new refillable ink tank design provides greater flexibility and productivity for workgroups — taking away the worry of changing ink cartridges and lowering running costs — while also delivering the advanced features and space-saving design our customers expect.”
The SureColor T3170x leverages an Epson PrecisionCore MicroTFP printhead with Precision Droplet Control to produce output with crisp lines and outstanding clarity. Whether printing from a roll or the Auto Sheet Feeder, the 4.3-inch color LCD touchscreen makes tasks simple and intuitive, and integrated wireless and Wi-Fi Direct connectivity, allows users to easily print from virtually anywhere in the office using a tablet or smartphone.
Additional product features include:
Cartridge-free printing – High-capacity ink bottles with auto-stop for easy, mess-free filling
Ultra-fast print speeds – A1/D-size prints in as fast as 34 seconds
Low running costs – Ink included in the box can print a substantial number of posters or technical drawings
Easy to operate – Large, intuitive 4.3-inch color LCD screen simplifies print tasks
Compact, clean design – Ultra-small footprint,4 and sleek, minimal design enhances workspaces; easily fits on a desktop or on its own with optional stand, sold separately
Print from virtually anywhere in the office – Easily print from tablets, smartphones and more with integrated wireless plus router-free Wi-Fi Direct printing
Outstanding image quality – PrecisionCore MicroTFP printhead with Precision Droplet Control for outstanding clarity, plus commercial-grade reliability with Nozzle Verification Technology
Versatile media handling – Accommodates rolls up to 24-inch wide and sheets up to 11”x17” through the auto sheet feeder
Precise, sharp details – Print posters, blueprints, line drawings, and more up to 2400 dpi
Easy setup – Get up and running out of the box in as quickly as 30 minutes
Availability
The SureColor T3170x 24-inch wireless printer will be available through authorized Epson Professional Imaging resellers in December 2019. The SureColor T3170x offers a standard Epson PreferredSM Limited Warranty, a one-year program that includes toll-free advanced telephone access Monday through Friday. The Epson SureColor T3170x is designed to work exclusively with Epson ink. For additional information, visit www.proimaging.epson.com.
Satellite imagery company Soar is now allowing public access to its satellites that provide near-real time imagery all across Earth at 10-meter resolution per pixel.
Both the public and the media will now be able to see high-definition aerial views of anywhere on Earth to observe events as they happen. This includes but is not limited to environmental disasters such as wildfires, tsunamis, hurricanes and drought.
Governments will also be able to monitor activities such as the protests in Hong Kong, or illegal mining or deforestation.
Developed by geospatial experts, the map sources satellite images from the European Space Agency’s Sentinel, NASA’s Landsat feeds and the SuperView and Gaofen satellites.
As well as satellite content, the super-map will integrate imagery sourced from drone owners (drone pilots) around the world, who can earn passive income as the value of their imagery becomes realized. They can thus become a one-stop-shop for the collection, distribution, and monetization of mapping imagery from different sensors.
“The problem Soar is solving is that almost 80 percent of all mapping imagery is currently accessed through just one channel, which is, for the most part, reserved mostly for niche commercial use,” said Soar founder and CEO Amir Farhand. “In many cases, the general public only has access to resources that are not updated as frequently. Soar addresses these limitations by generating dynamic, ever-changing data on our platform.”
“Imagery taken by a drone user can be uploaded to social media, and may attract a few likes, or will sit idle on a hard drive,” Farhand said. “The same image uploaded to Soar contributes content to the seeding of the super-map, providing value to a global community, as well as generating income for the drone pilot.”
Soar’s Head of Growth, Tim Glover added, “Imagine if we could re-use that imagery in a way that was totally authentic, collaborative and most importantly, accessible to all. Soar allows anyone to view the Earth from above, meaning it’s easy to observe things like environmental changes, including drought, melting ice caps, industrial growth, natural disasters like volcano eruptions, just to name a few uses. The aim of Soar is to enable anyone to explore and discover our ever-changing world.”
With almost 10 petabytes of data already acquired, Soar is planning additional imagery as part of their growth strategy. Soar has already received several partnership requests from multinational organizations with excess satellite, aerial and drone content from across the globe.
In the near future, the platform will also feature additional data streams from higher resolution satellites, aerial imagery providers and both commercial and recreational drone operators globally.
The use of Soar is suitable for a wide range of industries and applications including agriculture, environmental, logistics, mining and insurance. However, since its beta launch in late 2018, the largest area of growth has been news and social media as users share imagery of landscape events from around the world.
Soar was founded in 2017 by Amir Farhand, an entrepreneur with more than 15 years of geospatial expertise. The Soar leadership team is headed by Chairman Guy Perkins, former co-founder of aerial imaging companies NearMap and Spookfish. Other key managers come from a wide range of industry sectors with varying backgrounds, including the Australian Special Forces, United States Air Force, Lockheed Martin, Rio Tinto, NBCUniversal and Amblin Entertainment.
Esri has launched its first major advertising campaign with a slogan Esri President Jack Dangermond introduced at the Esri User Conference in July.
“Unlike anyone else on this planet, you and your fellow GIS colleagues truly ‘See What Others Can’t.’ My sense is, it’s now time to share this perspective with the rest of the world,” Dangermond said.
The campaign includes broadcast commercials, industry magazines and newspapers, at airports, on billboards and on websites.
“We are inviting the public to join us in understanding how we see the world and how we want them to see the world,” Dangermond said. “We are hopeful this will help expand the understanding and appreciation of what our users do. We ultimately want to bring more people into our community — sharing information, working together, and finding new ways to solve the greatest challenges of today and the future.”
New app gives field crews a fast, easy way to record information while mobile
Esri has released ArcGIS QuickCapture, a mobile app designed for rapid and at-speed field data-collection workflows.
Data can be collected from a moving vehicle with the touch of a button and sent back to the office for real-time analysis, leading to faster and more effective decision-making. The new app is designed for road inspections, aerial surveys, monitoring vegetation encroachment and more.
ArcGIS QuickCapture allows users to configure a customized interface that suits their specific project requirements, eliminating unnecessary features and options. This personalization helps users take advantage of the single-tap, big-button system to capture details and photos as they go. The app is intuitive and user-friendly, eliminating the need for extensive crew training.
The new app integrates with the user’s existing IT infrastructure and ArcGIS platform, which simplifies implementation. It uses the existing GPS and camera on smartphones and tablets, and it is compatible with iOS, Android and Windows devices.
For high-accuracy data collection workflows, QuickCapture is also compatible with external GNSS receivers.
“ArcGIS QuickCapture builds upon and enhances our existing field data collection offerings in ArcGIS,” said Ismael Chivite, senior product manager at Esri. “Field crews are demanding user experiences that are tailored to the way they work. QuickCapture is designed to capture GIS data with the tap of a button, while on the go. At-speed road asset inventories and quick damage assessments are examples of workflows where QuickCapture excels.”
EOS has partnered with four high-resolution imagery providers — Airbus Defense and Space, SI Imaging Services, SpaceWill and 21AT — so users can purchase the latest images directly from LandViewer, the official high-resolution data reseller, or view the images of an area of interest in high resolution on the map.
LandViewer collects the latest up-to-date satellite imagery from commercial satellite providers and incorporates it into an easy-to-use platform. The collection is constantly being improved with new sensors.
LandViewer offers two data sources of commercial imagery:
High-resolution imagery (for analytics), to find and purchase high-resolution images for further in-depth analysis. In this case, the price is based on the size of the area of intersection between the selected image and your area of interest (AOI).
Image from Landviewer for analytics. (Image: EOS)
High-resolution imagery (view only) to view high-resolution images for your area of interest (AOI). In this case, the price is based on the number of tiles within your AOI. The view only option is designed as a stand-alone data source for the everyday business user.
Image from Landviewer (view only). (Image: EOS)
The EOS platform uses commercial imagery from LandViewer with a resolution between 0.3 meter and 1.5 meters, enabling a close look at assets of interest, anywhere in the world.