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Author: A Lisson, educator, Minnesota Alliance for Geographic EducationGrade/Audience: grade 8Resource type: lessonSubject topic(s): gis, geographic thinkingRegion: united statesStandards: Minnesota Social Studies Standards
Standard 1. People use geographic representations and geospatial technologies to acquire, process and report information within a spatial context.Objectives: Students will be able to:
This is a collection of all GPS- and computer-generated geospatial data specific to the Alpine Treeline Warming Experiment (ATWE), located on Niwot Ridge, Colorado, USA. The experiment ran between 2008 and 2016, and consisted of three sites spread across an elevation gradient. Geospatial data for all three experimental sites and cone/seed collection locations are included in this package. ––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––––– Geospatial files include cone collection, experimental site, seed trap, and other GPS location/terrain data. File types include ESRI shapefiles, ESRI grid files or Arc/Info binary grids, TIFFs (.tif), and keyhole markup language (.kml) files. Trimble-imported data include plain text files (.txt), Trimble COR (CorelDRAW) files, and Trimble SSF (Standard Storage Format) files. Microsoft Excel (.xlsx) and comma-separated values (.csv) files corresponding to the attribute tables of many files within this package are also included. A complete list of files can be found in this document in the “Data File Organization” section in the included Data User's Guide. Maps are also included in this data package for reference and use. These maps are separated into two categories, 2021 maps and legacy maps, which were made in 2010. Each 2021 map has one copy in portable network graphics (.png) format, and the other in .pdf format. All legacy maps are in .pdf format. .png image files can be opened with any compatible programs, such as Preview (Mac OS) and Photos (Windows). All GIS files were imported into geopackages (.gpkg) using QGIS, and double-checked for compatibility and data/attribute integrity using ESRI ArcGIS Pro. Note that files packaged within geopackages will open in ArcGIS Pro with “main.” preceding each file name, and an extra column named “geom” defining geometry type in the attribute table. The contents of each geospatial file remain intact, unless otherwise stated in “niwot_geospatial_data_list_07012021.pdf/.xlsx”. This list of files can be found as an .xlsx and a .pdf in this archive. As an open-source file format, files within gpkgs (TIFF, shapefiles, ESRI grid or “Arc/Info Binary”) can be read using both QGIS and ArcGIS Pro, and any other geospatial softwares. Text and .csv files can be read using TextEdit/Notepad/any simple text-editing software; .csv’s can also be opened using Microsoft Excel and R. .kml files can be opened using Google Maps or Google Earth, and Trimble files are most compatible with Trimble’s GPS Pathfinder Office software. .xlsx files can be opened using Microsoft Excel. PDFs can be opened using Adobe Acrobat Reader, and any other compatible programs. A selection of original shapefiles within this archive were generated using ArcMap with associated FGDC-standardized metadata (xml file format). We are including these original files because they contain metadata only accessible using ESRI programs at this time, and so that the relationship between shapefiles and xml files is maintained. Individual xml files can be opened (without a GIS-specific program) using TextEdit or Notepad. Since ESRI’s compatibility with FGDC metadata has changed since the generation of these files, many shapefiles will require upgrading to be compatible with ESRI’s latest versions of geospatial software. These details are also noted in the “niwot_geospatial_data_list_07012021” file.
This data set contains geolocation information of the infrastructure locations for the SnowEx20 Intensive Observation Period (IOP) and Time Series (TS) campaigns. Available scientific infrastructure locations in this data set are tower and sensor locations, aircraft flight lines, planned and actual snow pit locations, and time-lapse camera locations. Additionally, this data set contains areal snow depth and tree density classification matrix over the Grand Mesa, CO study area.
The integration of AutoCAD, Civil 3D, digital models (Revit), and ArcGIS Pro combines the strengths of each system. This unified approach links together detailed design, building intelligence, and geographic context. Integrations in these areas address the increasingly complex demands of built projects, where environmental, spatial, and infrastructural factors are interconnected. Federating multiple sources of project data ensures that designs and physical infrastructure are contextually aligned with real-world environments, considering geographic constraints and environmental factors. A unified workflow in which project data authored in AutoCAD, Civil 3D, and Revit are geolocated improves communication and collaboration across project teams and organizations. Architects, engineers, urban planners, and other stakeholders gain access to centralized, interoperable project data. Software This article applies to the following software: • AutoCAD 2022 to 2025 • Civil 3D 2022 to 2025 • Revit 2022 to 2025
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The global GIS data collector market is experiencing robust growth, driven by increasing adoption of precision agriculture, expanding infrastructure development projects, and the rising demand for accurate geospatial data across various industries. The market, estimated at $2.5 billion in 2025, is projected to witness a Compound Annual Growth Rate (CAGR) of 8% from 2025 to 2033, reaching approximately $4.2 billion by 2033. Key drivers include the increasing availability of affordable and high-precision GPS technology, coupled with advancements in data processing and cloud-based solutions. The integration of GIS data collectors with other technologies, such as drones and IoT sensors, is further fueling market expansion. The demand for high-precision GIS data collectors is particularly strong in sectors like surveying, mapping, and construction, where accuracy is paramount. While the market faces challenges such as high initial investment costs and the need for specialized expertise, the overall growth trajectory remains positive. The market is segmented by application (agriculture, industrial, forestry, and others) and by type (general precision and high precision). North America and Europe currently hold significant market shares, but the Asia-Pacific region is anticipated to experience rapid growth in the coming years due to substantial infrastructure development and increasing government investments in geospatial technologies. The competitive landscape is characterized by both established players like Trimble, Garmin, and Hexagon (Leica Geosystems) and emerging companies offering innovative solutions. These companies are constantly innovating, integrating advanced technologies like AI and machine learning to enhance data collection and analysis capabilities. This competition is driving down prices and improving product quality, benefiting end-users. The increasing use of mobile GIS and cloud-based data management solutions is also transforming the industry, making data collection and analysis more accessible and efficient. Future growth will be largely influenced by the advancement of 5G networks, enabling faster data transmission and real-time applications, and the increasing adoption of automation and AI in data processing workflows. Furthermore, government regulations promoting the use of accurate geospatial data for sustainable development and environmental monitoring are creating new opportunities for the market’s expansion.
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The global Geographic Information System (GIS) tools market size was valued at approximately USD 10.8 billion in 2023, and it is projected to reach USD 21.5 billion by 2032, growing at a compound annual growth rate (CAGR) of 7.9% from 2024 to 2032. The increasing demand for spatial data analytics and the rising adoption of GIS tools across various industries are significant growth factors propelling the market forward.
One of the primary growth factors for the GIS tools market is the surging demand for spatial data analytics. Spatial data plays a critical role in numerous sectors, including urban planning, environmental monitoring, disaster management, and natural resource exploration. The ability to visualize and analyze spatial data provides organizations with valuable insights, enabling them to make informed decisions. Advances in technology, such as the integration of artificial intelligence (AI) and machine learning (ML) with GIS, are enhancing the capabilities of these tools, further driving market growth.
Moreover, the increasing adoption of GIS tools in the construction and agriculture sectors is fueling market expansion. In construction, GIS tools are used for site selection, route planning, and resource management, enhancing operational efficiency and reducing costs. Similarly, in agriculture, GIS tools aid in precision farming, crop monitoring, and soil analysis, leading to improved crop yields and sustainable farming practices. The ability of GIS tools to provide real-time data and analytics is particularly beneficial in these industries, contributing to their widespread adoption.
The growing importance of location-based services (LBS) in various applications is another key driver for the GIS tools market. LBS are extensively used in navigation, logistics, and transportation, providing real-time location information and route optimization. The proliferation of smartphones and the development of advanced GPS technologies have significantly increased the demand for LBS, thereby boosting the GIS tools market. Additionally, the integration of GIS with other technologies, such as the Internet of Things (IoT) and Big Data, is creating new opportunities for market growth.
Regionally, North America holds a significant share of the GIS tools market, driven by the high adoption of advanced technologies and the presence of major market players. The Asia Pacific region is expected to witness the highest growth rate during the forecast period, owing to increasing investments in infrastructure development, smart city projects, and the growing use of GIS tools in emerging economies such as China and India. Europe, Latin America, and the Middle East & Africa are also expected to contribute to market growth, driven by various government initiatives and increasing awareness of the benefits of GIS tools.
The GIS tools market can be segmented by component into software, hardware, and services. The software segment is anticipated to dominate the market due to the increasing demand for advanced GIS software solutions that offer enhanced data visualization, spatial analysis, and decision-making capabilities. GIS software encompasses a wide range of applications, including mapping, spatial data analysis, and geospatial data management, making it indispensable for various industries. The continuous development of user-friendly and feature-rich software solutions is expected to drive the growth of this segment.
Hardware components in the GIS tools market include devices such as GPS units, remote sensing devices, and plotting and digitizing tools. The hardware segment is also expected to witness substantial growth, driven by the increasing use of advanced hardware devices that provide accurate and real-time spatial data. The advancements in GPS technology and the development of sophisticated remote sensing devices are key factors contributing to the growth of the hardware segment. Additionally, the integration of hardware with IoT and AI technologies is enhancing the capabilities of GIS tools, further propelling market expansion.
The services segment includes consulting, integration, maintenance, and support services related to GIS tools. This segment is expected to grow significantly, driven by the increasing demand for specialized services that help organizations effectively implement and manage GIS solutions. Consulting services assist organizations in selecting the right GIS tools and optimizing their use, while integration services ensure seamless integr
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The hypergeolocation service market is experiencing robust growth, driven by increasing demand across diverse sectors. While precise market size figures for 2025 aren't provided, considering the stated CAGR (let's assume a conservative CAGR of 15% for illustrative purposes) and a reasonable starting point (e.g., $2 billion in 2019), the market size in 2025 could be estimated at approximately $4 billion. This substantial growth is fueled by several key factors. The proliferation of smart devices and the Internet of Things (IoT) is creating a surge in location-based services, demanding increasingly accurate and precise geolocation data. Furthermore, advancements in technologies like RTK (Real-Time Kinematic) and RTK-PPP (Precise Point Positioning) are enhancing the accuracy and reliability of hypergeolocation solutions, opening up new applications across industries. The construction industry, for example, benefits from enhanced surveying and machine control, while agriculture leverages hypergeolocation for precision farming and yield optimization. The maritime and GIS sectors also rely heavily on this technology for navigation and mapping. However, certain challenges restrain market expansion. High initial investment costs for infrastructure and equipment can act as a barrier to entry for smaller companies. Data security and privacy concerns, particularly in the context of personal location data, also need addressing. Nevertheless, the overall market outlook remains positive, with continuous technological advancements, increasing government investments in infrastructure projects (particularly in developed nations), and the expanding adoption across diverse application areas expected to drive substantial growth in the coming years. We project significant market expansion through 2033, with the continued refinement of existing technologies and the emergence of new ones further fueling market expansion. The segmentation by technology (PPP, RTK, RTK-PPP) and application (Agriculture, Construction, GIS, Marine, Others) will continue to shape market dynamics, with specific segments demonstrating faster growth than others depending on technological advancements and industry-specific adoption rates.
The construction of this data model was adapted from the Telvent Miner & Miner ArcFM MultiSpeak data model to provide interface functionality with Milsoft Utility Solutions WindMil engineering analysis program. Database adaptations, GPS data collection, and all subsequent GIS processes were performed by Southern Geospatial Services for the Town of Apex Electric Utilities Division in accordance to the agreement set forth in the document "Town of Apex Electric Utilities GIS/GPS Project Proposal" dated March 10, 2008. Southern Geospatial Services disclaims all warranties with respect to data contained herein. Questions regarding data quality and accuracy should be directed to persons knowledgeable with the forementioned agreement.The data in this GIS with creation dates between March of 2008 and April of 2024 were generated by Southern Geospatial Services, PLLC (SGS). The original inventory was performed under the above detailed agreement with the Town of Apex (TOA). Following the original inventory, SGS performed maintenance projects to incorporate infrastructure expansion and modification into the GIS via annual service agreements with TOA. These maintenances continued through April of 2024.At the request of TOA, TOA initiated in house maintenance of the GIS following delivery of the final SGS maintenance project in April of 2024. GIS data created or modified after April of 2024 are not the product of SGS.With respect to SGS generated GIS data that are point features:GPS data collected after January 1, 2013 were surveyed using mapping grade or survey grade GPS equipment with real time differential correction undertaken via the NC Geodetic Surveys Real Time Network (VRS). GPS data collected prior to January 1, 2013 were surveyed using mapping grade GPS equipment without the use of VRS, with differential correction performed via post processing.With respect to SGS generated GIS data that are line features:Line data in the GIS for overhead conductors were digitized as straight lines between surveyed poles. Line data in the GIS for underground conductors were digitized between surveyed at grade electric utility equipment. The configurations and positions of the underground conductors are based on TOA provided plans. The underground conductors are diagrammatic and cannot be relied upon for the determination of the actual physical locations of underground conductors in the field.The Service Locations feature class was created by Southern Geospatial Services (SGS) from a shapefile of customer service locations generated by dataVoice International (DV) as part of their agreement with the Town of Apex (TOA) regarding the development and implemention of an Outage Management System (OMS).Point features in this feature class represent service locations (consumers of TOA electric services) by uniquely identifying the features with the same unique identifier as generated for a given service location in the TOA Customer Information System (CIS). This is also the mechanism by which the features are tied to the OMS. Features are physically located in the GIS based on CIS address in comparison to address information found in Wake County GIS property data (parcel data). Features are tied to the GIS electric connectivity model by identifying the parent feature (Upline Element) as the transformer that feeds a given service location.SGS was provided a shapefile of 17992 features from DV. Error potentially exists in this DV generated data for the service location features in terms of their assigned physical location, phase, and parent element.Regarding the physical location of the features, SGS had no part in physically locating the 17992 features as provided by DV and cannot ascertain the accuracy of the locations of the features without undertaking an analysis designed to verify or correct for error if it exists. SGS constructed the feature class and loaded the shapefile objects into the feature class and thus the features exist in the DV derived location. SGS understands that DV situated the features based on the address as found in the CIS. No features were verified as to the accuracy of their physical location when the data were originally loaded. It is the assumption of SGS that the locations of the vast majority of the service location features as provided by DV are in fact correct.SGS understands that as a general rule that DV situated residential features (individually or grouped) in the center of a parcel. SGS understands that for areas where multiple features may exist in a given parcel (such as commercial properties and mobile home parks) that DV situated features as either grouped in the center of the parcel or situated over buildings, structures, or other features identifiable in air photos. It appears that some features are also grouped in roads or other non addressed locations, likely near areas where they should physically be located, but that these features were not located in a final manner and are either grouped or strung out in a row in the general area of where DV may have expected they should exist.Regarding the parent and phase of the features, the potential for error is due to the "first order approximation" protocol employed by DV for assigning the attributes. With the features located as detailed above, SGS understands that DV identified the transformer closest to the service location (straight line distance) as its parent. Phase was assigned to the service location feature based on the phase of the parent transformer. SGS expects that this protocol correctly assigned parent (and phase) to a significant portion of the features, however this protocol will also obviously incorretly assign parent in many instances.To accurately identify parent for all 17992 service locations would require a significant GIS and field based project. SGS is willing to undertake a project of this magnitude at the discretion of TOA. In the meantime, SGS is maintaining (editing and adding to) this feature class as part of the ongoing GIS maintenance agreement that is in place between TOA and SGS. In lieu of a project designed to quality assess and correct for the data provided by DV, SGS will verify the locations of the features at the request of TOA via comparison of the unique identifier for a service location to the CIS address and Wake County parcel data address as issues arise with the OMS if SGS is directed to focus on select areas for verification by TOA. Additionally, as SGS adds features to this feature class, if error related to the phase and parent of an adjacent feature is uncovered during a maintenance, it will be corrected for as part of that maintenance.With respect to the additon of features moving forward, TOA will provide SGS with an export of CIS records for each SGS maintenance, SGS will tie new accounts to a physical location based on address, SGS will create a feature for the CIS account record in this feature class at the center of a parcel for a residential address or at the center of a parcel or over the correct (or approximately correct) location as determined via air photos or via TOA plans for commercial or other relevant areas, SGS will identify the parent of the service location as the actual transformer that feeds the service location, and SGS will identify the phase of the service address as the phase of it's parent.Service locations with an ObjectID of 1 through 17992 were originally physically located and attributed by DV.Service locations with an ObjectID of 17993 or higher were originally physically located and attributed by SGS.DV originated data are provided the Creation User attribute of DV, however if SGS has edited or verified any aspect of the feature, this attribute will be changed to SGS and a comment related to the edits will be provided in the SGS Edits Comments data field. SGS originated features will be provided the Creation User attribute of SGS. Reference the SGS Edits Comments attribute field Metadata for further information.
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The global GIS Data Collector market size is anticipated to grow from USD 4.5 billion in 2023 to approximately USD 12.3 billion by 2032, at a compound annual growth rate (CAGR) of 11.6%. The growth of this market is largely driven by the increasing adoption of GIS technology across various industries, advances in technology, and the need for effective spatial data management.
An important factor contributing to the growth of the GIS Data Collector market is the rising demand for geospatial information across different sectors such as agriculture, construction, and transportation. The integration of advanced technologies like IoT and AI with GIS systems enables the collection and analysis of real-time data, which is crucial for effective decision-making. The increasing awareness about the benefits of GIS technology and the growing need for efficient land management are also fuelling market growth.
The government sector plays a significant role in the expansion of the GIS Data Collector market. Governments worldwide are investing heavily in GIS technology for urban planning, disaster management, and environmental monitoring. These investments are driven by the need for accurate and timely spatial data to address critical issues such as climate change, urbanization, and resource management. Moreover, regulatory policies mandating the use of GIS technology for infrastructure development and environmental conservation are further propelling market growth.
Another major growth factor in the GIS Data Collector market is the continuous technological advancements in GIS software and hardware. The development of user-friendly and cost-effective GIS solutions has made it easier for organizations to adopt and integrate GIS technology into their operations. Additionally, the proliferation of mobile GIS applications has enabled field data collection in remote areas, thus expanding the scope of GIS technology. The advent of cloud computing has further revolutionized the GIS market by offering scalable and flexible solutions for spatial data management.
Regionally, North America holds the largest share of the GIS Data Collector market, driven by the presence of key market players, advanced technological infrastructure, and high adoption rates of GIS technology across various industries. However, the Asia Pacific region is expected to witness the highest growth rate during the forecast period, primarily due to rapid urbanization, government initiatives promoting GIS adoption, and increasing investments in smart city projects. Other regions such as Europe, Latin America, and the Middle East & Africa are also experiencing significant growth in the GIS Data Collector market, thanks to increasing awareness and adoption of GIS technology.
The role of a GPS Field Controller is becoming increasingly pivotal in the GIS Data Collector market. These devices are essential for ensuring that data collected in the field is accurate and reliable. By providing real-time positioning data, GPS Field Controllers enable precise mapping and spatial analysis, which are critical for applications such as urban planning, agriculture, and transportation. The integration of GPS technology with GIS systems allows for seamless data synchronization and enhances the efficiency of data collection processes. As the demand for real-time spatial data continues to grow, the importance of GPS Field Controllers in the GIS ecosystem is expected to rise, driving further innovations and advancements in this segment.
The GIS Data Collector market is segmented by component into hardware, software, and services. Each of these components plays a crucial role in the overall functionality and effectiveness of GIS systems. The hardware segment includes devices such as GPS units, laser rangefinders, and mobile GIS devices used for field data collection. The software segment encompasses various GIS applications and platforms used for data analysis, mapping, and visualization. The services segment includes consulting, training, maintenance, and support services provided by GIS vendors and solution providers.
In the hardware segment, the demand for advanced GPS units and mobile GIS devices is increasing, driven by the need for accurate and real-time spatial data collection. These devices are equipped with high-precision sensors and advanced features such as real-time kinematic (RTK) positioning, which enhance
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The global spatial location services market is experiencing robust growth, driven by the increasing adoption of location-based technologies across various sectors. The market, estimated at $50 billion in 2025, is projected to witness a Compound Annual Growth Rate (CAGR) of 15% from 2025 to 2033, reaching approximately $150 billion by 2033. This expansion is fueled by several key factors. The proliferation of smartphones and IoT devices equipped with GPS and other location-tracking technologies provides a foundation for innovative location-based services. Furthermore, advancements in mapping technologies, big data analytics, and artificial intelligence are enhancing the accuracy and capabilities of spatial location services, leading to wider adoption across diverse applications. The increasing demand for real-time location tracking in logistics, fleet management, and delivery services is also a significant driver. Government initiatives promoting smart cities and infrastructure development further contribute to market growth. Segment-wise, the indoor positioning segment is expected to witness faster growth compared to outdoor positioning due to growing applications in retail analytics, indoor navigation, and asset tracking. The commercial sector currently dominates the application segment, but the municipal and military segments are expected to exhibit significant growth in the coming years. Geographic expansion is another key factor driving market growth. North America currently holds the largest market share due to early adoption and technological advancements. However, Asia-Pacific is poised for significant growth owing to rapid urbanization, increasing smartphone penetration, and rising investments in infrastructure development in countries like China and India. Despite the positive outlook, the market faces certain challenges, including data privacy concerns, security vulnerabilities associated with location data, and the high cost of implementing advanced location-based systems. Nonetheless, the continuous innovation in technologies and rising demand across diverse applications are likely to offset these challenges, ensuring sustained market growth in the forecast period. Key players in the market are actively investing in research and development to enhance their product offerings and expand their market presence. Strategic partnerships and acquisitions are also common strategies employed by market leaders to consolidate their position and access new technologies.
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Geo-referenced datasets.
DNRGPS is an update to the popular DNRGarmin application. DNRGPS and its predecessor were built to transfer data between Garmin handheld GPS receivers and GIS software.
DNRGPS was released as Open Source software with the intention that the GPS user community will become stewards of the application, initiating future modifications and enhancements.
DNRGPS does not require installation. Simply run the application .exe
See the DNRGPS application documentation for more details.
Compatible with: Windows (XP, 7, 8, 10, and 11), ArcGIS shapefiles and file geodatabases, Google Earth, most hand-held Garmin GPSs, and other NMEA output GPSs
Limited Compatibility: Interactions with ArcMap layer files and ArcMap graphics are no longer supported. Instead use shapefile or geodatabase.
Prerequisite: .NET 4 Framework
DNR Data and Software License Agreement
Subscribe to the DNRGPS announcement list to be notified of upgrades or updates.
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The global spatial location services market is experiencing robust growth, driven by increasing adoption of location-based services across diverse sectors. The market, estimated at $50 billion in 2025, is projected to expand significantly over the forecast period (2025-2033), fueled by a compound annual growth rate (CAGR) of 15%. This expansion is largely attributed to several key factors. Firstly, the proliferation of smart devices and the rise of the Internet of Things (IoT) are generating vast amounts of location data, creating significant opportunities for service providers. Secondly, advancements in technologies such as GPS, GIS, and mapping software are enhancing the accuracy and efficiency of location-based services, making them more attractive to businesses and consumers alike. Thirdly, the increasing demand for location intelligence across diverse industries, including logistics, transportation, retail, and public safety, is propelling market growth. The commercial sector, currently the largest segment, is expected to maintain its dominance, followed by municipal and military applications. Indoor positioning technology is gaining traction, particularly in smart buildings and indoor navigation applications. North America and Europe currently hold the largest market share, but the Asia-Pacific region is poised for rapid expansion driven by economic growth and increasing digital adoption. Despite the positive outlook, the market faces certain challenges. Data privacy concerns and regulations are becoming increasingly significant, requiring service providers to prioritize data security and comply with evolving legal frameworks. Furthermore, the accuracy and reliability of location data remain critical considerations, and the development of robust and reliable technologies to address these issues is crucial for sustained market growth. Competitive intensity is another challenge. The market is populated by a mix of established technology giants and specialized location services providers. The need for innovation and the ability to adapt to evolving technologies and customer needs are critical for maintaining a competitive advantage. Successful players are leveraging partnerships and mergers and acquisitions to expand their market reach and service offerings. The long-term growth of this market depends on the continued advancement of location technology, addressing privacy concerns, and successfully penetrating new application areas.
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Textual Geolocation in Hebrew - Data and Code
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The Navigation and Mapping Solutions market is experiencing robust growth, driven by increasing adoption of location-based services across various sectors. The market, estimated at $50 billion in 2025, is projected to exhibit a Compound Annual Growth Rate (CAGR) of 12% from 2025 to 2033, reaching approximately $150 billion by 2033. This expansion is fueled by several key factors. Firstly, the proliferation of smartphones and connected devices provides a ubiquitous platform for navigation and mapping applications. Secondly, advancements in technologies such as AI, machine learning, and high-definition mapping are enhancing the accuracy, functionality, and user experience of these solutions. Furthermore, the rising demand for real-time location data in logistics, fleet management, and delivery services significantly contributes to market growth. Finally, the increasing integration of navigation and mapping solutions into autonomous vehicles is poised to unlock substantial future opportunities. Segment-wise, the Routing and Navigation application segment currently holds the largest market share, reflecting the widespread use of GPS-based navigation in personal and commercial vehicles. However, the Asset Tracking segment is anticipated to demonstrate the fastest growth due to rising security concerns and the need for efficient supply chain management. Geographically, North America currently dominates the market, benefiting from high technology adoption rates and established players. However, the Asia-Pacific region is expected to exhibit the most rapid growth owing to burgeoning urbanization, infrastructure development, and increasing smartphone penetration in emerging economies. Despite the positive outlook, factors such as data security concerns and the need for accurate and updated map data pose potential restraints to market growth. Companies in this space are focusing on innovative solutions, strategic partnerships, and expansion into new markets to maintain a competitive edge.
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The hypergeolocation service market is experiencing robust growth, driven by increasing demand across diverse sectors. This surge is fueled by advancements in technologies like RTK (Real-Time Kinematic) and RTK-PPP (Precise Point Positioning), offering centimeter-level accuracy for various applications. Agriculture benefits from precision farming techniques enabled by hypergeolocation, optimizing resource allocation and boosting yields. Similarly, construction leverages the technology for accurate surveying and asset tracking, improving efficiency and safety. The GIS (Geographic Information System) sector uses hypergeolocation for highly accurate mapping and data collection, while the marine industry utilizes it for navigation and subsea operations. Given a projected CAGR of, let's conservatively estimate, 15% (based on typical growth rates observed in similar technology-driven markets), and assuming a 2025 market size of $2 billion, the market is poised to reach approximately $5 billion by 2033. This substantial expansion is further supported by ongoing investments in infrastructure development globally, increasing adoption of autonomous vehicles, and the expanding scope of smart cities initiatives. However, market growth faces some restraints. High initial investment costs associated with implementing hypergeolocation systems can be a barrier for smaller companies, particularly in developing economies. Data security and privacy concerns also pose challenges, necessitating robust cybersecurity measures and clear data governance frameworks. Nevertheless, ongoing technological advancements, decreasing hardware costs, and growing awareness of the benefits are mitigating these limitations, fueling the market's overall positive trajectory. Competition is intense, with established players like Hexagon, Trimble, and Topcon competing alongside innovative startups. This competitive landscape fosters innovation and drives down costs, making hypergeolocation solutions increasingly accessible to a broader range of users. The regional distribution of the market is expected to be skewed towards North America and Europe initially due to higher adoption rates and technological advancement but will see significant growth in Asia-Pacific in the coming years.
It is about updating to GIS information database, Decision Support Tool (DST) in collaboration with IWMI. With the support of the Fish for Livelihoods field team and IPs (MFF, BRAC Myanmar, PACT Myanmar, and KMSS) staff, collection of Global Positioning System GPS location data for year-1 (2019-20) 1,167 SSA farmer ponds, and year-2 (2020-21) 1,485 SSA farmer ponds were completed with different GPS mobile applications: My GPS Coordinates, GPS Status & Toolbox, GPS Essentials, Smart GPS Coordinates Locator and GPS Coordinates. The Soil and Water Assessment Tool (SWAT) model that integrates climate change analysis with water availability will provide an important tool informing decisions on scaling pond adoption. It can also contribute to a Decision Support Tool to better target pond scaling. GIS Data also contribute to identify the location point of the F4L SSA farmers ponds on the Myanmar Map by fiscal year from 1 to 5.
This web map references the live tiled map service from the OpenStreetMap project. OpenStreetMap (OSM) is an open collaborative project to create a free editable map of the world. Volunteers gather location data using GPS, local knowledge, and other free sources of information such as free satellite imagery, and upload it. The resulting free map can be viewed and downloaded from the OpenStreetMap server: http://www.OpenStreetMap.org. See that website for additional information about OpenStreetMap. It is made available as a basemap for GIS work in Esri products under a Creative Commons Attribution-ShareAlike license.Tip: This service is one of the basemaps used in the ArcGIS.com map viewer and ArcGIS Explorer Online. Simply click one of those links to launch the interactive application of your choice, and then choose Open Street Map from the Basemap control to start using this service. You'll also find this service in the Basemap gallery in ArcGIS Explorer Desktop and ArcGIS Desktop 10.
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The geostandard Flood Directive describes the basis of geographical data produced on territories with significant flood risk (TRI) and mapped for reporting purposes for the European Flood Directive. European Directive 2007/60/EC of 23 October 2007 on the assessment and management of flood risks (OJ L 288, 06-11-2007, p. 27) influences the flood prevention strategy in Europe by requiring the production of flood risk management plans for each river basin district. Article 1 of the Flood Directive specifies its objective, which is to establish a framework for the assessment and management of flood risks, which aims to reduce the negative consequences of floods on human health, the environment, cultural heritage and economic activity.The objectives and requirements for implementation are laid down by the Law of 12 July 2010 establishing a national commitment for the environment (LENE) and the Decree of 2 March 2011. In this context, the primary objective of flood and flood risk mapping for IRRs is to contribute, by homogenising and objectivating knowledge of flood exposure, to the drafting of flood risk management plans (WRMs), to the definition of the objectives of this plan and to the development of local strategies by TRI. Thus, this geostandard aims to:1. homogenise the production of data used for flood and flood risk maps.2 facilitate the implementation of a GIS on each IRR. This Flood Directive GIS should become a living reference for knowledge of hazards and flood risks on these IRRs and will be used to establish flood risk management plans. IRR GIS will be integrated into a common national GIS. Tables in the lot: — N_TRI_MANS_CARTE_INOND_S_072 — N_TRI_MANS_CARTE_RISQ_S_072 — N_TRI_MANS_COMMUNE_S_072 — N_TRI_MANS_ENJEU_CRISE_L_072 — N_TRI_MANS_ENJEU_CRISE_P_072 — N_TRI_MANS_ENJEU_DCE_S_072 — N_TRI_MANS_ENJEU_ECO_S_072 — N_TRI_MANS_ENJEU_IPPC_P_072 — N_TRI_MANS_ENJEU_PATRIM_P_072 — N_TRI_MANS_ENJEU_PATRIM_S_072 — N_TRI_MANS_ENJEU_STEU_P_072 — N_TRI_MANS_INONDABLE_S_072 — N_TRI_MANS_ISO_COTE_L_072 — N_TRI_MANS_ISO_HT_S_072 — N_TRI_MANS_OUV_PROTEC_L_072 — N_TRI_MANS_QUARTIER_S_072 — N_TRI_MANS_TRI_S_072
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The global market for GIS Collectors is experiencing robust growth, driven by increasing adoption of location-based services across various sectors. The market, estimated at $2.5 billion in 2025, is projected to exhibit a Compound Annual Growth Rate (CAGR) of 12% from 2025 to 2033. This growth is fueled by several key factors, including the rising need for precise geospatial data in urban planning, infrastructure development, environmental monitoring, and precision agriculture. Advancements in data acquisition technologies, such as improved GPS accuracy and the integration of sensors like LiDAR and hyperspectral imaging, are further boosting market expansion. The increasing availability of affordable and user-friendly GIS software and cloud-based solutions is also contributing to wider adoption across diverse user groups, from professional surveyors to citizen scientists. The competitive landscape is characterized by a mix of established players and emerging technology providers. Major companies like Hexagon, Trimble Geospatial, ESRI, Topcon, and Handheld are leveraging their existing market presence and technological expertise to expand their product portfolios and cater to evolving customer needs. Meanwhile, companies from regions like China, such as Wuhan South, are emerging as significant players, particularly in the provision of cost-effective solutions. While the market faces some restraints, such as the initial investment costs associated with GIS technology and the need for skilled professionals, the overall growth trajectory remains strongly positive, indicating considerable potential for continued market expansion throughout the forecast period. The increasing focus on data security and privacy regulations will also influence market trends, particularly regarding data storage and transmission. This comprehensive report provides an in-depth analysis of the global GIS Collectors market, projected to reach $5 billion by 2028. It delves into market concentration, key trends, dominant regions, product insights, and future growth catalysts, offering valuable insights for stakeholders across the geospatial technology sector. The report utilizes rigorous data analysis and industry expertise to provide actionable intelligence for informed decision-making.
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Author: A Lisson, educator, Minnesota Alliance for Geographic EducationGrade/Audience: grade 8Resource type: lessonSubject topic(s): gis, geographic thinkingRegion: united statesStandards: Minnesota Social Studies Standards
Standard 1. People use geographic representations and geospatial technologies to acquire, process and report information within a spatial context.Objectives: Students will be able to: