GPS World

Tag: GIS

  • Rugged Trimble Pro Series GNSS Receivers Provide Flexibility for GIS and Mobile Mapping

    Pro20Series20Cover20View Trimble
    Trimble

    Trimble introduced today the next-generation of its Trimble GPS Pathfinder family — the Trimble Pro 6H and Pro 6T receivers for GIS and mobile mapping. The Trimble Pro series with advanced features allows mobile workers to configure a solution for a wide range of applications, delivering flexibility in professional GIS data collection, Trimble said. The series offers a new streamlined form-factor and dramatic productivity improvements in difficult GNSS environments with Trimble Floodlight technology.

    The modular Trimble Pro series receiver gives users the flexibility to choose their setup configurations:

    • Optimized for use with Trimble data collection devices such as the Trimble Juno or Nomad G series handhelds, or Yuma tablet computer, the Trimble Pro series can also be used with other tablets and handhelds with NMEA output.
    • Real-time or postprocessed GIS workflows.
    • The receiver can be deployed in a backpack, on a pole or mounted on a vehicle.
    • Two models are available: the Trimble Pro 6H delivers decimeter accuracy, while the Pro 6T is the submeter model for standard GIS applications.

    With the availability of the new Pro series receivers, data collection professionals now have access to the productivity-enhancements of Floodlight technology in both integrated and modular configurations,” said Daniel Wallace, general manager of Trimble’s GIS Data Collection Division. “While some prefer the convenience of an integrated, all-in-one handheld, others will appreciate the Pro series’ flexibility to choose from a range of data collection devices such as a high-resolution tablet or lightweight Trimble Juno.”

    Trimble Floodlight technology allows users to collect decimeter accuracy data in tough GNSS environments, Trimble said. Buildings and trees can cause satellite shadow and limit the environments where high-accuracy GNSS data collection can be performed. Trimble Floodlight technology combines a range of techniques to increase the availability of positions and boost accuracy in areas affected by satellite shadow. Using Floodlight technology, the Pro series can keep teams productive without compromising on accuracy. Users can work with fewer disruptions and ensure better data, faster data collection and higher field efficiency.

    Trimble Pro series receivers are rugged and built to withstand the rigors of long hours in tough outdoor conditions, yet optimized for high-accuracy GIS data collection workflows, Trimble said. For applications such as utilities inspections and timber stand valuations, Trimble Pro receivers provide long battery life and tough construction for dependable service over the course of rigorous data-collection projects.

    With its IP65 rating, the receivers offer reliable operation, even after prolonged exposure to water and dust, Trimble said. An integrated antenna reduces the complexity of the system for fast setup and swift data collection campaigns. Field workers can be up and running with minimal training, saving time and money. Combined with a Trimble handheld solution and Trimble TerraSync software, the complete system provides dedicated field workflows to simplify data collection and improve integration with the GIS for total workflow improvements.

    The new Trimble Pro 6H and 6T receivers are available from Trimble’s worldwide Mapping & GIS authorized distribution channel.

  • King County GIS Reports Significant Return on Investment

    King County announced that twenty years ago geographic information services were in the proposal and planning stage in King County, Washington. Today King County’s geographic information system (GIS) includes integrated spatial databases, mapping and analysis software, information technology, and professional GIS staff. King County’s GIS was developed to meet the business needs of county users, and it also provides free data and online mapping capability to the public.

     

    According to announcement, in March 2012 a return-on-investment (ROI) report issued by Professor Richard Zerbe and Associates showed that use of the King County Geographic Information System has resulted in at least $775 million in net benefits to the county over the eighteen-year period from 1992 to 2010. While ROI estimates are often developed as part of a proposal to develop a geographic information system, it is believed that this is the first study by independent economic consultants to examine and measure the actual benefits realized by a city or county from the internal agency use of GIS.

    King County reported that the study methodology looked at the cost to perform county agency business functions both with and without GIS. For example, county permit technicians were asked how much time it takes to pull together all the maps and spatial data needed to assist a permit applicant now with GIS, versus the time it would take the technician to perform the same business function without GIS tools and data. The methodology included detailed interviews of 30 key county staff and then an online survey to county GIS users that was completed by 175 respondents. Interview and survey responses were analyzed to compare both with-GIS and without-GIS level of effort. The results were then compiled and monetized by output type and agency to measure cost savings and productivity benefits.

    The total cost for King County GIS, including capital development, central GIS operations and maintenance, and agency GIS end-user costs from 1992 to 2010 is over $201 million. In 2010 alone these county GIS costs were $14.6 million, but for the same year the Zerbe report measured benefits from GIS of $180 million, with a lower estimate of $87 million. So the benefits over a single year far outweigh the costs for the year, and if repeated for 2011 and 2012, the benefits realized over just two years could eclipse the costs of the previous twenty.

    This project was partly funded by the Oregon Department of Administrative Services, Geospatial Enterprise Office.

    Dr. Richard O. Zerbe, Jr. is the Daniel J. Evans Professor of Public Affairs at the University of Washington, where he is Director of the Center for Benefit-Cost Analysis.

     

    The King County GIS Center is a part of King County Information Technology, chartered as an internal service fund to provide GIS services to county agencies and external customers. The King County GIS Center operates King County’s enterprise GIS and provides data, services, and training to help put GIS to work. For more information, contact Greg Babinski at the King County GIS Center (206-263-3753).

  • Blue Marble Releases 13.1 Update to Global Mapper Software Developer Toolkit

    Blue Marble Geographics announced the release of Global Mapper Software Developer Toolkit version 13.1. This update features many new drawing and analysis tools along with enhanced geospatial PDF and LAS 1.4 support.

     

    According to the announcement, Global Mapper SDK 13.1 syncs up the software developer toolkit with Global Mapper desktop software releases. This will enable a more consistent release cycle ensuring the software developers are able to work with the latest and greatest feature/functions introduced to the desktop version of the software. The 13.1 release introduces many new drawing tools such as drawing map layout items, including elevation legend, distance scale, map feature legend, and north arrow. The update also introduces powerful new analysis tools like the function for creating density/heat grids from loaded point features, the function for creating roughness length grids from a land cover layer and the method for easily calculating a watershed with stream paths and drainage basins from loaded terrain layers. The ability to add custom online data sources is introduced along with improved Geospatial PDF support, new LandXML, LASzip and LAS 1.4, I.H.S. Well Data point files, GeoJSON, and Digital Bathe Bathymetric Database Variable Resolution (DBDB-V) files and much more.

    “Blue Marble has been directly supporting hundreds of geospatial software developers implement cutting edge technology for years,” stated Blue Marble President Patrick Cunningham. “The Global Mapper SDK is a great tool to add to a suite of libraries and we are excited to work directly with our developer community with this new display and translation api. Syncing up the SDK kits with the desktop releases will help us provide the latest features and functionality to our existing users as well as new customers for future releases.”

    Blue Marble’s geospatial data manipulation, visualization, and conversion solutions are used worldwide by thousands of GIS analysts at software, oil and gas, mining, civil engineering, surveying, and technology companies, as well as governmental and university organizations.

  • Telogis Acquires Maptuit Assets

    Telogis, Inc. announces the acquisition of the assets of Maptuit, a leading provider of connected navigation for commercial fleets. This acquisition — the company’s fifth in three years — expands Telogis’ services as the market increases adoption of location-based Software-as-a-Service (SaaS) solutions. Maptuit’s commercial navigation technologies further enhance the Telogis enterprise platform of SaaS solutions, which includes fleet management, navigation, multi-vehicle route optimization and planning, work order management and mobile integration.

     

    “This acquisition adds a new dimension to our platform,” said Newth Morris, president, Telogis Route and Telogis Mobile. “With these advances, Telogis further differentiates itself in the market by providing the most comprehensive suite of location intelligence solutions on a single platform.”   

    According to the announcement, the enhancements to the Telogis platform resulting from this acquisition include an advanced location-based service (LBS) engine that receives feedback from the field on road conditions and physical restrictions that may not be captured by commercial and open source map data. These capabilities are critical not only to the commercial navigation markets where Maptuit has been successful, but also to industries such as mining, and oil and gas, which operate in remote regions where map data coverage is limited.

    Maptuit’s technologies also allow companies to specify “known-good” routes and yard-approaches. These capabilities help companies improve the safety of route operations and are increasingly important in international markets where bonded routes exist.

    Telogis reports it will integrate Maptuit’s technologies directly into its enterprise platform, thereby expanding the Telogis customer base by more than 100,000 subscribers.

    “The commercial navigation technologies that Maptuit has revolutionized will enhance all of the applications on our platform — route planning, navigation, execution analytics — and position our company to best handle the growing location intelligence needs of companies worldwide,” said Morris. “This acquisition complements the Telogis platform with a unique set of high-value capabilities that allow companies to dramatically transform their operations, improve safety and lower operating costs.”

  • Geospatial Mapping Enhances Arlington National Cemetery Management

    Officials at Arlington National Cemetery will use an Army-designed geospatial mapping system to manage cemetery operations, said the executive director of the Army National Cemeteries Program.

     

    Kathryn A. Condon testified before the House Veterans Affairs Committee's disability assistance and memorial affairs subcommitee to provide an update on the progress made in rectifying long-standing management problems at Arlington National Cemetery.

    Source: Arlington National Cemetary

    "Arlington is no longer a paper-based operation. By producing a single electronic map of Arlington, the staff will assign, manage and track gravesites with an authoritative digital map," Condon said. "It will allow us to synchronize in real time our burial operations at Arlington."

    The geospatial mapping system allows officials to synchronize burial operations with other daily operations, such as public ceremonies, infrastructure repair, grounds upkeep and public safety activities, Condon explained. The system is linked to Arlington's interment scheduling system, which allows schedulers to assign gravesites and assign procession routes. It also alerts Arlington staff of other activities in the area, she said.

    Arlington is the first national cemetery to use this technology, Condon told the panel.

    The geospatial mapping system will use the information collected and validated as part of the Army's gravesite accountability study. The gravesite accountability effort resulted in the first review, analysis and coordination of records kept in various ways at Arlington over the cemetery's history, Condon said.

    The Gravesite Accountability Task Force physically examined and photographed 259,978 gravesites, niches and markers using a custom-built smartphone application and matched each photo with records in a database. Arlington officials are 84 percent complete in validating records, officials said, and are on track to finish this summer.

    Once complete, Arlington's accountability effort will create a single, verifiable and authoritative database of all those laid to rest at Arlington, officials added, and it will be linked with Arlington's geospatial mapping system.

  • Blue Marble Releases 13.1 Update to Global Mapper

    Blue Marble Geographics announced the release of Global Mapper version 13.1. This update features new network licensing, enhanced geospatial PDF support and much more. Blue Marble’s geospatial data manipulation, visualization and conversion solutions are used worldwide by thousands of GIS analysts at software, oil and gas, mining, civil engineering, surveying, and technology companies, as well as governmental and university organizations.

    According to the announcement, Global Mapper 13.1 introduces Flex LM licensing to the software which provides multi-seat users with a flexible network licensing function. This efficient checkout or borrowing process allows easier access to the software across entire organizations, paving the way for new enterprise features in coming releases. The 13.1 update also introduces new geospatial PDF functionality such as the ability to import and export to 64-bit versions, the ability to select which layer to load from a geospatial PDF and the ability to load multi-page PDFs with geo-positioning. Additional enhancements include support for LAS version 1.4 and LASzip files, GeoJSON formatted data, Digital Bathymetric Database Variable Resolution (DBDB-V), LandXML files and over fifteen additional new formats. Version 13.1 also includes significant speed increases to the depression filling step when generating watersheds/drainage areas, added built-in access to land cover datasets and generation of grids from layers, significant enhancements to the Digitizer tool as well as many other minor enhancements and updates throughout the software.

    "For a minor version release, this update is quite comprehensive," stated Blue Marble President Patrick Cunningham. "We are just starting to bring the support of our development team to assisting lead product developer, Mike Childs and we’re already seeing some great gains. Look for many more great enhancements over the next year."

  • GPS for GIS Data Collection – 101: Webinar Follow-up

    Thank you for making “GPS for GIS Data Collection – 101” one of the most well-attended webinars we’ve done. It’s the first that was co-hosted by GPS World magazine and Geospatial Solutions online. If you don’t subscribe to my Geospatial Solutions Weekly newsletter, you might want to consider it as I venture into GIS and broader issues that I don’t have the space to cover in this newsletter. Also, the webinar had a record number of sponsors. Thanks to Hemisphere GPS, Laser Technology, and First American. Those folks make it possible for us to bring these webinars to you free of charge.

    As customary, the newsletter after the webinar is dedicated to addressing some of the questions and posting the results from the polls I took during the webinar.

    Poll Results

    I conducted three polls during the webinar. I received some feedback that we aren’t giving folks enough time to respond to the polls. We’ll pay more attention to that in future webinars and allow more time. Following are the results:

    Poll #1: Do you currently use GPS for collecting GIS data?

    Yes:     68.5%
    No:     31.5%

    Total votes: 165

    Poll #2: What accuracy do you require in a GPS mapping system?

    cm-level:     28.4%
    One foot:     10.8%
    Sub-meter:    33.1%
    1-3 meters:    22.3%
    3-5 meters:    4.1%
    5+ meters:     1.4%

    Total votes: 148

    Poll #3: Select the three most important items to you in a GPS mapping system.

    Collect attribute data:    88.1%
    Cost:                71.4%
    Ergonomics:            7.9%
    Photo-geotagging:        19.8%
    Accuracy:            87.3%
    Laser offset points:        22.2%

    Total votes: 126

    Question #1: How many satellites are transmitting and how many are just for replacement purposes?

    Gakstatter: There are 30 operational GPS satellites. Currently, they are configured in a 24-satellite configuration so six of them are orbiting as “back-ups.” There are also three satellites, I believe, that are in inactive reserve that could be brought back into service if required.

    However, as covered in my last three newsletters, the DoD is transitioning the GPS constellation to a 27-satellite configuration to improve satellite visibility to users. The process of transitioning started in January will take up to two years to complete. Please see the following articles for details on the 24+3 configuration:

    The New GPS 24+3 Constellation: What Does it Mean to the Surveying and GIS User?

    GPS 24+3 Configuration: A Closer Look

    The Best and Final Look at the GPS 24+3 Configuration

     

    Question #2: I do have a question, but it will take too long right now. How do I contact you later?

    Gakstatter: Please feel free to e-mail me with questions any time…[email protected]. I learn a lot from your questions.

     

    Question #3: What about use of iPhones or Blackberries with GPS embedded in the device?

    Gakstatter: As smartphones become more powerful and prevalent, I think the use of them for GIS data collection will increase. I have two comments on this:

     

    • To this point, the ability to run GIS data collection software is hit or miss. Some smartphones just don’t have the resources (memory, processing speed) to handle running the more powerful data-collection software on the market. Of course, with technology advancing that may not be as much of an issue in the future, and it’s possible that GIS software manufacturers will write streamlined software specifically for smartphones.
    • The accuracy of GPS receivers built into smartphones will always be pretty rough. I’d put it in the 5+ meter category and I don’t think it will get much better, so adjust your expectation accordingly. However, using Bluetooth you might be able to “tether” the smartphone to a higher performance external GPS receiver.

     

    Question #4: Is there a place for consumer-grade receivers in GIS data collection?

    Gakstatter: Yes, I wrote an article on this last year. You can read it here…

    Consumer-Grade GPS Receivers for GIS Data Collection

    Please don’t hesitate to e-mail me more questions about this that may not be answered in the referenced article. I’ve been thinking about a follow-up article on this subject.
    Question #5: What accuracy would you expect to record from a GPS handheld unit?

    Gakstatter: There are high-performance handheld GPS receivers that can deliver centimeter-level positions and there are consumer-type handheld GPS receivers that delivery 5+ meter accuracy. This is typically a direct relationship between accuracy and cost (you’re not going to get sub-meter accuracy from a $200 receiver).

    The best way to approach this is to decide what accuracy you require (cm-level, one foot, sub-meter, 1-3 meters, 3-5 meters, 5+ meters) and look at the budget you have available. You might want to take a look at the webinar I conducted last year titled “A Buyer’s Guide to GPS/GIS Mapping Equipment” and a newsletter article I wrote around the same time titled GPS Receivers for GIS Data Collection.

     

     

    Question #6: We have a Topcon GMS-2 unit using an exteral antenna on a range pole similiar to one of the pictures you had in the presentation. How does the height of the range pole with the external antenna affect the X-Y position? Or does it? Thanks.

    Gakstatter: The value of the range pole is that it gives the GPS antenna a clear view of the sky (above your head and other local obstructions). It can only improve your X-Y position. I don’t know how many times I’ve seen users hold a handheld GPS receiver up against their chest, effectively eliminating the use (and degrading accuracy) of GPS satellites behind them.

     

    Question #7: For area determination which is preferred: static or dynamic?

    Gakstatter: Personally, I would use dynamic unless you’re talking about a very small parcel of land (less than an acre). I’ve seen a number of reports on this and I believe all of them used dynamic data collec
    tion with pretty reasonable results. In other words, I don’t think static buys you much in terms of acreage precision. However, I’ve been in circumstances where I used a combination of both such as when I know there’s a reasonably straight line between two vertices, but it would be very difficult to walk a direct line between them. In that case, I might use static for that leg of the traverse.

     

    Question #8: I thought that PDOP was Positional Dilution of Precision.

    Gakstatter: Several of you busted me on this. I mis-typed the presentation slide. I wrote Precision Dilution of Precision, which doesn’t make any sense. It should have been Position Dilution of Precision (PDOP). The horizontal component of PDOP is HDOP (Horizontal Dilution of Precision). The vertical component of PDOP is VDOP (Vertical Dilution of Precision).

    Click here for a Wikipedia link that provides a little more information on GPS DOPs.

     

    Question #9: Explain limitations of what type of project you cannot do if not a licensed surveyor.

    Gakstatter: Because local laws vary widely, it really depends on where you are working. Even within a country like the U.S., each state has its own statutes that define the roles of the land surveyor.

    In some areas, activities as simple as GIS data collection must be supervised by a licensed surveyor. In other areas, high-liability activities such as construction staking can be done by virtually anyone.

     

     

    Question #10: Could the steel plate in my head cause multipath or obstruct signals when I use the integrated antenna?

    Gakstatter: I can safely say (tongue in cheek) that in 20 years of GPS product development, conducting workshops/seminars, attending conferences, and performing GPS fieldwork, I’ve never heard this question. I’m speechless.  :-)

     

    Question #11: A presumption that we should avoid is that by default “GIS data collection” implies low accuracy. This is simply not true. Position accuracy is independent of GIS. GIS can handle any level of accuracy the user desires. There is no such thing as a “GIS-grade” or “GIS-accuracy” survey. What relationship does GIS have with accuracy?

    Gakstatter: I think Guest Commentator Craig Greenwald and I covered this well in the webinar, but it’s good to reinforce the point. I cringe when I hear someone say GIS stands for Get It Surveyed because it implies that the quality of a GIS is dependent on accuracy. It’s not. In some cases, +/- 500 feet. accuracy is perfectly fine for analysis in a GIS. The accuracy required by a GIS totally depends on the type of analysis you are conducting. Many surveyors typically think of GIS in terms of a land record (parcel) mapping system, but GIS is used for so much more than that. You don’t need cm-level accuracy to find the optimal location for the next McDonald’s restaurant within a city.

     

    Question #12: Do you plan on conducting a webinar that will discuss strictly GPS, i.e., RTK vs. static, data reduction, post processing, etc.

    Gakstatter: Yes, if you’re not subscribed to the Survey Scene newsletter, please sign up for that here as well as the Geospatial Solutions Weekly newsletter on the same sign-up page. The price is right…free. You can also look at the webinar archives where I have covered some of these subjects before. I’m also scheduled to conduct at least three more webinars this year (next one in May/June – topic not yet determined).

     

    There were many other questions and I’ll continue including answers to them in the mid-March Survey Scene newsletter. Also, I suggest you sign up for my Geospatial Solutions Weekly newsletter (GSS Weekly) as mentioned above as I tackle GPS/GIS-related issues there, too. Next week, in the GSS Weekly, I’ll continue my discussion on the roles of the surveyor and GIS professional.

     

    Thanks, and see you next time.

    Follow me on Twitter at http://twitter.com/GPSGIS_Eric

     

     

     

  • LizardTech MrSID Generation 4 Files Now Supported in Global Mapper

    LizardTech announced the integration of its MrSID Generation 4 (MG4) SDK into Global Mapper version 11.01. Until recently, Global Mapper’s customers were not able to load point cloud datasets that were compressed to MrSID Generation 4 using LiDAR Compressor into Global Mapper. However, with the addition of support for MG4 in Global Mapper version 11.01 users can load point cloud datasets compressed to MrSID Generation 4 for use in volumetric analysis, contour generation, and visualization.

    “Adding MG4 integration to the latest version of Global Mapper is just another step to ensure that our customers have as many mapping tools possible at their fingertips,” said Mike Childs, Global Mapper Software LLC. “Based on user feedback, we believe this integration with LizardTech will bring added value to our customers.”

    “LizardTech’s goal is to give customers tools for using their point cloud data compressed with LiDAR Compressor in the applications they use every day,” said Jon Skiffington, LizardTech’s director of marketing. “Many of our customers use Global Mapper, but were not able to use it with MrSID files created in LiDAR Compressor. Now our customers can easily load point cloud datasets compressed to MrSID Generation 4
    into Global Mapper.”

  • ABB Selects Intergraph for North African Gas Pipeline Project

    ABB has selected Intergraph for the development of an oil and gas pipeline network and relevant facilities in North Africa. The pipeline network will be built in the El Merk field, a remote, harsh desert location in Algeria.

    According to Intergraph, geospatial-based pipeline infrastructure management solutions will enable ABB to more effectively design, construct and maintain pipelines and assets and demonstrate a comprehensive pipeline integrity program while reducing the cost of maintaining records. By storing records in a central geographic information system (GIS), the solution makes information readily available for a variety of applications, improving record keeping productivity while assuring compliance with regulatory requirements.

    “An accurate, up-to-date view of all critical assets at any given time is a crucial component of any pipeline implementation project,” said Sergio Casati, ABB Project Manager. “Especially in such challenging terrain conditions, we need to keep our pulse on the status of all assets in near real-time. The strength of Intergraph technology and its more than 40 years of experience in the utilities sector, as well as market leadership in enterprise engineering software, were key factors in our decision to partner with the company on this project. Intergraph’s open, flexible technology platform was also desirable for an initiative like the El Merk project, which involves a consortium of multiple vendors.”

    The announcement said that geospatial technology from Intergraph will play a significant role in the design and installation of the pipeline, field gathering stations, gas distribution manifolds, flow and trunk lines and water and gas re-injection facilities in El Merk. The technology will support the Pipeline Open Data Standard (PODS) model, the most widely implemented pipeline data model in the industry, and all data will be stored in an Oracle Spatial database. The implementation will also include a portal component for the seamless distribution of data to all parties, including field and remote users.

    “The collaboration of Intergraph with ABB Italy on this project marks a significant milestone in Intergraph’s involvement in the oil and gas pipeline industry,” said Maximilian Weber, Utilities & Communications manager for Intergraph in EMEA. “Intergraph has worked with leading pipeline providers around the world including Spectra Energy and Northwest Energy in the U.S., E.ON Ruhrgas in Germany and Chongqing Gas in China. Additionally, our Process, Power & Marine division is the world’s leading provider of enterprise engineering software for the design, construction and operation of plants, pipelines, ships and offshore facilities. We are pleased that ABB has recognized our strength in this industry and has chosen us to ensure the accurate, efficient management of assets, as well as play a key role in protecting this infrastructure.”

  • Apogee Offers Mapping, Geospatial Product Licenses for Educational Use

    Apogee Mapping has released amLibrary, a spatial data bundle that includes the company’s four flagship products and is packaged exclusively for use by higher education institutions.

    The bundle includes Apogee’s amElevation, amHillshade, amContour, and amWater. AmElevation is a national dataset of 1-arc second digital elevation data (DEM); amHillshade comprises nationwide 40, 200, and 1,000 foot contours in a smoothed vector format; amHillshade is a national set of tiled raster topography offered in both grayscale and full-color; and amWater is a premium vector hydrography dataset derived from information generated by the U.S. Environmental Protection Agency. AmLibrary also includes 50 data layers depicting environmental, climactic, and geologic data. Bundled together, this information provides GIS users with comprehensive and detailed terrain data that can be used as a basis upon which to conduct research and perform complex spatial analyses, according to Apogee Mapping.

    AmLibrary is offered exclusively to colleges and universities in either MapInfo TAB format or ESRI Shapefile format. Full product documentation, layer, and metadata are provided with the product.

  • ESRI Con: LizardTech Unveils MrSID Compression for Raw LiDAR Data

    LizardTech’s LiDAR Compressor can convert cloud data into MrSID files that retain 100 percent of the original raw data at just 25 percent of the file size, according to the company.

    Derivatives can be extracted repeatedly from LiDAR files compressed to MrSID, LizardTech said. It can also reportedly reduce LiDAR file sizes by up 90 percent with no perceptible loss. The company introduced the LiDAR Compressor at the 2009 ESRI International User Conference in San Diego this week.

    LizardTech also unveiled an improved version of the MrSID format called MrSID Generation 4 (MG4). MG4 MrSID files support the compression of LiDAR data, which will allow users to view and access their LiDAR data faster, LizardTech said.

    LizardTech LiDAR Compressor is available for purchase now directly from LizardTech’s website or by contacting one of LizardTech’s sales representatives.

  • GPS Receivers for GIS Data Collection

    In my last issue, I proclaimed the start of GPS/GIS month, with a focus on the subject in three of my newsletters. This is the second in that series. The first column can be read here. Also, I’m hosting a webinar June 30 to discuss using GPS receivers and technology for GIS data collection. In my last newsletter I discussed the use of consumer GPS receivers for GIS data collection. Remember the analogy I used…a Volkswagen Beetle wasn’t designed to run in a Formula One race? This column is going to focus on the Formula One cars, not the Volkswagen Beetles. In other words, it will focus on the GPS receivers on the market that are designed for GIS data collection. I will refer to them as GPS/GIS receivers.

    What differentiates a GPS/GIS receiver from any other GPS receiver?

    The number-one differentiator is that GPS/GIS receivers are designed do a better job of optimizing tracking and accuracy in areas where GIS data collection is performed. The operative term is “are designed.” Specifically, engineers who designed GPS/GIS receivers do so with different design criteria than engineers who design consumer GPS receivers and even survey GPS receivers. For example, a GPS/GIS receiver must be designed to operate where GIS data is collected and with reasonable accuracy. On the other hand, consumer GPS receivers are designed to track in tough conditions, but at the expense of accuracy. Furthermore, survey GPS receivers hold accuracy as the number-one priority so they sacrifice the ability to track in many environments.

    The following matrix illustrates my point (1 = Highest priority design consideration, 5 = Lowest priority design consideration):

    There are thousands of designers of consumer GPS receivers (Garmin, TomTom, Magellan, etc.) and probably only 10 designers of GPS receivers for surveying (Trimble, Leica/NovAtel, Topcon, Magellan Professional, Septentrio, JAVAD GNSS, NavCom, etc.). There are even fewer designers of GPS/GIS receivers — less than 10 (Trimble, Magellan Professional, Topcon, Geneq, Sokkia, Hemisphere, JAVAD GNSS, ViaSat).

    The market for GPS/GIS receivers is a complicated one. That’s the primary reason why there are only a few manufacturers. Here are some of the reasons why it is complex:

    • Users require a GPS receiver that will work effectively in many different and challenging environments such as under trees, in mountainous areas and near buildings. There is not one product on the market that will meet every user’s requirements.
    • Users have various needs for the type of GIS data collected. For example, some only need two or three attributes for a utility pole and others may need to collect dynamic line segments such as speed zones and road lane types.
    • There is not an effective way for manufacturers to distribute such products. The traditional survey instrument dealers (not all) are not typically trained or experienced in GPS/GIS technology. Since there is not an effective distribution channel, the alternative is to create a grass-roots distribution channel, which is very time-consuming.

    There are many factors to consider when attempting to determine what sort of GPS/GIS data collection system best fits a user’s requirements. Here are some in order of priority:

    1. Budget. One could argue that data collection requirements should be #1. Maybe, but that depends on what stage of planning you’re in. If you are in the budget planning phase and are able to influence it, then I agree that user requirements should be the first priority. However, the vast majority of people I encounter are given an established budget to work within. In that case, budget should be #1 because it’s a waste of time to consider solutions outside of the budget constraint.
    2. Accuracy. When I ask a potential GPS/GIS user what their accuracy requirement is, the typical answer is “as accurate as I can get”. Of course, you can imagine the ensuing conversation…Me: Well, Ok, you can achieve results around a centimeter.
      Them: That’s great. A centimeter is perfect.
      Me: Ok, here are the cost and training requirements.
      Them: Wow, why is it so expensive???????
      Me: There is a direct relationship between accuracy and cost. The more accurate you want, the more expensive it’s going to be.
      Them: Well, Ok, we reeeeally only need to be within about three feet.
      Me: Do you need elevation values within three feet?
      Them (now leery of the response to their answers): Will those cost more?
      Me: Yes, probably quite a bit more.
      Them: No, we don’t need elevations.
    3. Data collection requirements. Essentially, consumer GPS receivers and survey GPS systems “think” in terms of points. More specifically, consumer GPS receivers operate in terms of waypoints and survey GPS systems operate in terms of point averaging.
      Some of the more sophisticated survey GPS systems offer Field-to-Finish (F2F) capability whereas points are automatically connected to form a line back in the office such as with curbs and property lines.GIS data collection systems are different. GIS “sees” the world in one of three ways; points, lines (or polylines) and areas (or polygons). All have some level of database information attached. For example, a fire hydrant is a point on a map but there is also information in the GIS about that fire hydrant such as condition, last inspection date, etc. A parcel is a polygon on a map but there is also information in the GIS about that parcel such as ownership, tax id, etc.
      Additionally, there are several methods to record all three.For example, a wetland biologist may be mapping the perimeter of a wetland area but wants to “take points” on certain habitat nests he/she sees while walking the perimeter. Some of the more powerful GIS data collection software is built so the biologist can temporarily suspend mapping the perimeter and be allowed to map the next site and resume mapping the perimeter when point recording is finished.

      Using the proper data collection software that matches the user requirements can save a significant amount of time and energy.

       

    4. Data collection conditions. This is the biggest “gotcha” for GPS/GIS receivers. A certain GPS receiver designed for GIS data collection may perform flawlessly in the open-sky and works perfectly well for uses such as agriculture or other open-sky environments. However, most uses consist of some or all work done in “less-than-ideal” GPS conditions. Tree canopy is the biggest culprit. In that scenario, receiver performance can differ significantly. Some won’t track at all in those environments and some will track very well, but accept excessively noisy satellite measurements (which significantly degrades accuracy). The best ones are designed with a keen balance of satellite tracking and accuracy – with settings the user can change depending on the environment.

    Why are GPS/GIS receivers so much more expensive than consumer GPS receivers?

    Part of the reason that consumer GPS receivers are adapted to GPS/GIS data collection is the significant difference in cost. A consumer GPS receive
    r can be purchased for well under US$200. The entry level price for a GPS receiver with comparable accuracy, but with GIS data collection features is four times that. Furthermore, the entry level price for a GPS/GIS receiver capable of sub-meter accuracy is about $2,000.

    There are several specific and justifiable reasons for the price difference, but suffice to say that significantly more design engineering, technical support and sales effort is involved with GPS/GIS receivers. Furthermore, the volume of GPS/GIS receivers is miniscule compared to consumer receivers. If there were tens of millions of GPS/GIS receivers manufactured and sold every year, the price would be under US$200 each. But the GIS market just isn’t that large. Therefore, GPS/GIS manufacturers have to charge more per unit to account for engineering, technical support and sales overhead.

    Lastly, as mentioned above, there are not very many manufacturers of GPS/GIS receivers. Lack of competition usually results in higher prices to the end user.

    What sources of GPS corrections are available?

    Autonomous (no differential correction applied) GPS is pretty accurate these days…on the order of a few meters. For this reason, consumer GPS receiver manufacturers tend to leave out information on GPS corrections in their specifications. Their rationale is that consumers don’t really care as long as they can navigate effectively.

    However, the GPS/GIS receiver market is much more concerned with accuracy. Therefore, some sort of GPS correction source is highly recommended and necessary to achieve the desired accuracy.

    There are essentially two types of GPS corrections: real-time and post-processing.

    Throughout the 1980s and 1990s, post-processing was the dominant method of correcting GPS data. Even then, 2-5 meter accuracy was the norm for GPS/GIS receivers after post-processing was applied. Sub-meter GPS technology (using GPS/GIS receivers) only became possible towards the end of the 1990’s. Users were accustomed to going through the post-processing exercise (downloading base station data, QAing post-processed data, etc.). At that time, the only option for using real-time corrections were commercial services such as OmniSTAR.

    In the mid-1990s, the U.S. Coast Guard (USCG) established the DGPS system that broadcast real-time GPS corrections free of charge along the US coastlines and major waterways. The user only needed to purchase equipment (beacon receiver) to receive the signal. The success of that program lead to the U.S. Department of Transportation (DOT) to expand the program to cover inland regions that were out of the USCG domain. That was the GPS/GIS user’s first taste of free DGPS corrections…and they liked it because it eliminated the time-consuming (and sometimes painful) process of post-processing.

    The break-out milestone for real-time corrections came in 2003 when the Federal Aviation Administration (FAA) declared the Wide Area Augmentation System (WAAS) operational. WAAS took real-time GPS corrections to another level of simplicity. Not only is WAAS free of charge to users, but unlike the USCG DGPS and commercial DGPS services, it’s broadcast on the same frequency as GPS. This means that no extra antenna or receiver is required to utilize the signal. Furthermore, it’s broadcast nation-wide in the US where ever the WAAS satellites are visible to the user. Due to the success of WAAS, several other regions in the world have deployed similar systems; EGNOS in Western Europe, MSAS in Japan/Korea and GAGAN in India.

    Finally, in the early part of this decade, local networks of reference stations began springing up. These are called RTK Networks. While built primarily for users of survey GPS receivers who require cm-level accuracy, there is a growing population of GPS/GIS users who are connecting their GPS/GIS receivers to these networks to obtain GPS corrections. However, the costs can be expensive. Some network operators charge a fee to access their network and the user must also have a data subscription with a wireless provider (GSM or CDMA) which has a monthly fee associated with it — similar to a mobile phone.

    The Future is Clear

    The trend is clearly towards using real-time GPS corrections no matter which source is used. The time consumed by post-processing and the expense of maintaining software and training requirements adds too much overhead in most applications for organizations to consider it.Although not the dominate correction technology any longer, post-processing in the GPS/GIS segment still has a niche – the so-called “sub-foot” niche. While the majority of GIS applications are satisfied with “sub-meter” (or even 1-3 meter) accuracy, there are certain applications where “sub-foot” accuracy is required. With these receivers, the users must post-process against several reference stations or tie into an RTK Network.

    Integrated “All-in-one” GPS/GIS receiver or separate stand-alone receiver?

    In the GPS/GIS receiver market, there are clearly two types of systems. The “All-in-one” receivers have the GPS receiver, antenna and data collector built into a hand-held format. These are products such as the Trimble GeoXT/XH, Magellan Mobile Mapper CX/6 and Topcon GMS-2.

    The “stand-alone” receivers are a “black box” which houses only the GPS receiver, GPS antenna and optionally a battery. Other devices such as PDAs, tablet computers and notebook computers receive GPS data from these stand-alone receivers typically via Bluetooth interface or cable connection. These are products such as the Trimble ProXT/XH, Geneq SX Blue, Sokkia GIR1600, Hemisphere A100 and Javad GISMore.

    There are advantages and disadvantages to both.

    “All-in-one” receivers house everything one needs in a single hand-held unit. The advantage is that the data collector, GPS receiver, antenna, battery system, etc. are all designed by one company to work together. On the other hand, designing all of these components into a single hand-held can make for a somewhat heavier unit. Also, PDA technology is evolving rapidly. “All-in-one” receivers aren’t updated nearly as fast as PDA technology so an “All-in-one” unit may have an out-dated operating system and/or processor if the design is a few years old.

    “Stand-alone” receivers are separate receivers that send GPS data to a PDA, tablet computer or notebook computer via wireless Bluetooth or cable connectio
    n. The advantage of these systems is flexibility. On one project, they can be interfaced to a PDA. On the next project, they can be interfaced to a notebook computer running different mapping software. They aren’t affected by the advancement of PDA, operating system or computer processor technology.

    The Final Analysis — GPS/GIS Receivers for GIS Data Collection

    There a myriad of GPS receiver technologies being used for GIS data collection. It’s a complex industry. Some receivers being used are purpose-built and others have been adapted from other industries like consumer GPS.

    There is no magic formula to determine which GPS receiver will work best because it really depends on the user’s requirements and in GIS, the user requirement vary greatly. “Try before you buy” is the best advice to follow when going through the equipment/software selection process.

     

    If you have time, I’m conducting a GPS/GIS receiver webinar on June 30 (next Tuesday) at 10:00 a.m. Pacific time. I will continue the discussion of GPS/GIS receiver selection. Register for the webinar here.