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.

The Geographic Information System (GIS) industry is experiencing robust growth, projected to maintain a Compound Annual Growth Rate (CAGR) of 10.80% from 2025 to 2033. This expansion is driven by increasing adoption across diverse sectors, including agriculture, utilities, mining, construction, transportation, and oil and gas. The rising need for precise location-based data for efficient operations, optimized resource management, and informed decision-making fuels this market growth. Advancements in hardware, such as high-resolution sensors and drones, coupled with sophisticated software capabilities like advanced spatial analytics and cloud-based GIS solutions, are key contributors. Furthermore, the proliferation of location-based services (LBS) and the growing adoption of telematics and navigation systems are expanding the applications of GIS technology. While data security concerns and the need for skilled professionals present some challenges, the overall market outlook remains positive. The segmentation of the GIS market reveals a strong demand across various components (hardware and software) and functionalities (mapping, surveying, telematics and navigation, and location-based services). North America currently holds a significant market share due to early adoption and technological advancements, but regions like Asia are exhibiting rapid growth fueled by infrastructure development and increasing digitalization. Leading companies like Bentley Systems, Esri, Trimble, and Hexagon AB are at the forefront of innovation, continuously developing and implementing advanced GIS solutions to meet the evolving needs of different industries. The forecast for the next decade points to further market consolidation, with leading players investing heavily in research and development to enhance their product offerings and expand their market reach. The continued integration of GIS with other technologies such as AI and IoT will further drive market expansion and create new opportunities for growth. Comprehensive Coverage GIS Industry Report (2019-2033) This in-depth report provides a comprehensive analysis of the Geographic Information System (GIS) industry, projecting robust growth from $XXX million in 2025 to $YYY million by 2033. The study covers the historical period (2019-2024), base year (2025), and forecast period (2025-2033), offering invaluable insights for businesses, investors, and policymakers. Keywords: GIS market, GIS software, GIS hardware, GIS solutions, geospatial technology, location intelligence, mapping software, surveying equipment, spatial analysis, geospatial analytics. Recent developments include: November 2022 : The new Geodata Portal and broadband maps for the state will be accessible starting on November 18, 2022, according to a statement from the Connecticut Office of Policy and Management (OPM). This announcement was made on GIS Day 2022, which encourages people to learn about geography and the practical uses of GIS that can improve society., November 2022 : The lt. governor of the Indian state, Jammu and Kashmir, launched a GIS-based system in the region. It highlights the significance of GIS technology in addressing new challenges and exploring new opportunities and its real-world applications, accelerating growth in business, government, and society.. Key drivers for this market are: Growing role of GIS in smart cities ecosystem, Integration of location-based mapping systems with business intelligence systems. Potential restraints include: Integration issues with traditional systems, Data quality and accuracy issues. Notable trends are: The Rising Smart Cities Development and Urban Planning to Drive the Market Growth.

This submission contains an ESRI map package (.mpk) with an embedded geodatabase for GIS resources used or derived in the Nevada Machine Learning project, meant to accompany the final report. The package includes layer descriptions, layer grouping, and symbology. Layer groups include: new/revised datasets (paleo-geothermal features, geochemistry, geophysics, heat flow, slip and dilation, potential structures, geothermal power plants, positive and negative test sites), machine learning model input grids, machine learning models (Artificial Neural Network (ANN), Extreme Learning Machine (ELM), Bayesian Neural Network (BNN), Principal Component Analysis (PCA/PCAk), Non-negative Matrix Factorization (NMF/NMFk) - supervised and unsupervised), original NV Play Fairway data and models, and NV cultural/reference data. See layer descriptions for additional metadata. Smaller GIS resource packages (by category) can be found in the related datasets section of this submission. A submission linking the full codebase for generating machine learning output models is available through the "Related Datasets" link on this page, and contains results beyond the top picks present in this compilation.

The global GIS Data Collector market is experiencing robust growth, driven by increasing adoption of precision agriculture, expanding infrastructure development projects, and the rising need for accurate land surveying and mapping in various sectors. The market, currently valued at approximately $2.5 billion in 2025, is projected to exhibit a Compound Annual Growth Rate (CAGR) of 8% from 2025 to 2033. This growth is fueled by advancements in technology, such as the integration of high-resolution sensors, GPS capabilities, and cloud-based data management systems into these collectors. The high-precision segment is expected to witness significant growth due to its enhanced accuracy and ability to support complex applications like autonomous driving and environmental monitoring. Key applications include agriculture, where precise data collection improves crop yields and resource management, industrial sectors relying on accurate site surveys, and forestry management for sustainable logging practices. Geographic expansion is another significant driver. While North America currently holds a substantial market share due to early adoption and technological advancements, rapid economic growth and increasing infrastructure investments in Asia-Pacific, particularly in China and India, are expected to propel substantial market expansion in these regions. The market faces certain restraints, including the high initial investment cost of GIS data collectors and the need for specialized training for effective operation and data interpretation. However, the long-term benefits of improved efficiency, accuracy, and data-driven decision-making are overcoming these challenges, leading to sustained market growth. The presence of established players like Garmin, Trimble, and Hexagon, alongside emerging regional companies, fosters competition and innovation, contributing to the market’s dynamic landscape.

This project focuses on developing a machine learning-driven system to classify hospital claims and treatment outcomes, offering a second opinion on healthcare costs and decision-making for insurance claims and treatment efficacy.Key Features and Tools:Machine Learning Algorithms: Leveraging Python (pandas, numpy, scikit-learn) for predictive modeling to assess claim validity and treatment outcomes.APIs Integration: Used Google Maps API to retrieve and map the locations of private hospitals in Malaysia.GIS Mapping Dashboard: Created a GIS-enabled dashboard in Microsoft Power BI to visualize private hospital distribution across Malaysia, aiding healthcare planning and analysis.Advanced Analytics Tools: Integrated Microsoft Excel, Python, and Google Collab for data processing and automation workflows.

Seattle Parks and Recreation ARCGIS park feature map layer web services are hosted on Seattle Public Utilities' ARCGIS server. This web services URL provides a live read only data connection to the Seattle Parks and Recreations Adult Fitness Equipment dataset.

description: Seattle Parks and Recreation GIS Map Layer Shapefile - Adult Fitness Equipment Shapefile - This Seattle Parks and Recreation ARCGIS park feature map layer was exported from SPU ARCGIS and converted to a shapefile then manually uploaded to data.seattle.gov via Socrata. OR Web Services - Live "read only" data connection ESRI web services URL: http://gisrevprxy.seattle.gov/arcgis/rest/services/DPR_EXT/ParksExternalWebsite/MapServer/0; abstract: Seattle Parks and Recreation GIS Map Layer Shapefile - Adult Fitness Equipment Shapefile - This Seattle Parks and Recreation ARCGIS park feature map layer was exported from SPU ARCGIS and converted to a shapefile then manually uploaded to data.seattle.gov via Socrata. OR Web Services - Live "read only" data connection ESRI web services URL: http://gisrevprxy.seattle.gov/arcgis/rest/services/DPR_EXT/ParksExternalWebsite/MapServer/0

The 3D Land Surveying System market is experiencing robust growth, projected to reach a market size of $650.3 million in 2025 and exhibiting a Compound Annual Growth Rate (CAGR) of 15.2% from 2025 to 2033. This expansion is driven by several key factors. The increasing demand for precise and efficient land surveying in infrastructure development, particularly in burgeoning construction and urban planning projects globally, is a major catalyst. Furthermore, technological advancements in sensor technology, GPS integration, and data processing capabilities are leading to more accurate, faster, and cost-effective surveying solutions. The shift towards digitalization within the surveying industry, coupled with the rising adoption of Building Information Modeling (BIM) and Geographic Information Systems (GIS), is further fueling market growth. Segmentation reveals strong demand across both fixed and mobile surveying systems, with applications spanning survey and mapping, construction, and other sectors like mining and agriculture. North America and Europe currently hold significant market shares, but the Asia-Pacific region is expected to witness substantial growth driven by rapid urbanization and infrastructure development in countries like China and India. The market's growth trajectory is expected to continue, propelled by ongoing technological innovation and increasing government investments in infrastructure projects worldwide. The integration of artificial intelligence (AI) and machine learning (ML) into 3D land surveying systems promises to enhance data analysis and automation, driving further efficiency gains. However, potential restraints include the high initial investment costs associated with advanced 3D surveying equipment and the need for skilled professionals to operate and interpret the data generated. Nevertheless, the overall outlook remains positive, with the market poised for considerable expansion throughout the forecast period due to the undeniable advantages of 3D surveying over traditional methods in terms of accuracy, speed, and data richness.

Cadastral Mapping Market Outlook

The global cadastral mapping market size was valued at approximately USD 4.2 billion in 2023 and is projected to reach around USD 7.9 billion by 2032, growing at a compound annual growth rate (CAGR) of 7.2% during the forecast period. This market growth can be attributed to increasing urbanization, rapid advancements in geospatial technologies, and the growing need for efficient land management systems across various regions.

The expansion of urban areas and the corresponding increase in the need for effective land management infrastructure are significant growth factors driving the cadastral mapping market. As urbanization accelerates globally, local governments and planning agencies require sophisticated tools to manage and record land ownership, boundaries, and property information. Enhanced geospatial technologies, including Geographic Information Systems (GIS) and remote sensing, are pivotal in facilitating accurate and efficient cadastral mapping, thus contributing to market growth.

Another key growth factor is the rising demand for infrastructure development. As nations invest in large-scale infrastructure projects such as roads, railways, and smart cities, there is an increased need for precise land data to ensure the proper allocation of resources and to avoid legal disputes. Cadastral mapping provides the critical data needed for these projects, hence its demand is surging. Additionally, governments worldwide are increasingly adopting digital platforms to streamline land administration processes, further propelling the market.

Furthermore, the agricultural sector is also significantly contributing to the growth of the cadastral mapping market. Modern agriculture relies heavily on accurate land parcel information for planning and optimizing crop production. By integrating cadastral maps with other geospatial data, farmers can improve land use efficiency, monitor crop health, and enhance yield predictions. This integration is particularly valuable in precision farming, which is becoming more prevalent as the world's population grows and the demand for food increases.

Regionally, Asia Pacific is expected to witness the highest growth in the cadastral mapping market. Factors such as rapid urbanization, extensive infrastructure development projects, and the need for improved land management are driving the demand in this region. Moreover, governments in countries like India and China are investing heavily in creating digital land records and implementing smart city initiatives, which further boosts the market. The North American and European markets are also substantial, driven by the advanced technological infrastructure and well-established land administration systems.

Component Analysis

The cadastral mapping market can be segmented by component into software, hardware, and services. The software segment holds a significant share in this market, driven by the increasing adoption of advanced GIS and mapping software solutions. These software solutions enable accurate land parcel mapping, data analysis, and integration with other geospatial data systems, making them indispensable tools for cadastral mapping. Companies are continuously innovating to provide more intuitive and comprehensive software solutions, which is expected to fuel growth in this segment.

Hardware components, including GPS devices, drones, and other surveying equipment, are also critical to the cadastral mapping market. The hardware segment is expected to grow steadily as technological advancements improve the accuracy and efficiency of these devices. Innovations such as high-resolution aerial imaging and LIDAR technology are enhancing the capabilities of cadastral mapping hardware, allowing for more detailed and precise data collection. This segment is particularly essential for field surveying and data acquisition, forming the backbone of cadastral mapping projects.

The services segment encompasses a wide range of offerings, including consulting, implementation, and maintenance services. Professional services are vital for the successful deployment and operation of cadastral mapping systems. Governments and private sector organizations often rely on specialized service providers to implement these systems, train personnel, and ensure ongoing support. As the complexity of cadastral mapping projects increases, the demand for expert services is also expected to rise, contributing to the growth of this segment.

Integration services are another critical component within the

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.

This map image layer represents the U.S. Department of Health and Human Services (HHS) emPOWER Program, a partnership between ASPR and the Centers for Medicare and Medicaid Services, provides dynamic data and mapping tools to help communities protect the health of more than 4.1 million Medicare beneficiaries who live independently and rely on electricity-dependent medical equipment and health care servicesASPR, in partnership with the Centers for Medicare and Medicaid Services (CMS), provide de-identified and aggregated Medicare beneficiary claims data at the state/territory, county, and ZIP code levels in the HHS emPOWER Map and this public HHS emPOWER REST Service. The REST Service includes aggregated data from the Medicare Fee-For-Service (Parts A&B) and Medicare Advantage (Part C) Programs for beneficiaries who rely on electricity-dependent durable medical equipment (DME) and cardiac implantable devices. Data includes the following DME and devices: cardiac devices (left, right, and bi-ventricular assistive devices (LVAD, RVAD, BIVAD) and total artificial hearts (TAH)), ventilators (invasive, non-invasive and oscillating vests), bi-level positive airway pressure device (BiPAP), oxygen concentrator, enteral feeding tube, intravenous (IV) infusion pump, suction pump, end-stage renal disease (ESRD) at-home dialysis, motorized wheelchair or scooter, and electric bed. Purpose: Over 2.5 million Medicare beneficiaries rely on electricity-dependent medical equipment, such as ventilators, to live independently in their homes. Severe weather and other emergencies, especially those with long power outages, can be life-threatening for these individuals. The HHS emPOWER Map and public REST Service give every public health official, emergency manager, hospital, first responder, electric company, and community member the power to discover the electricity-dependent Medicare population in their state/territory, county, and ZIP Code. Data Source: The REST Service’s data is developed from Medicare Fee-For-Service (Part A & B) (>33M 65+, blind, ESRD [dialysis], dual-eligible, disabled [adults and children]) and Medicare Advantage (Part C) (>21M 65+, blind, ESRD [dialysis], dual-eligible, disabled [adults and children]) beneficiary administrative claims data. This data does not include individuals that are only enrolled in a State Medicaid Program. Note that Medicare DME are subject to insurance claim reimbursement caps (e.g. rental caps) that differ by type, so the DME may have different “look-back” periods (e.g. ventilators are 13 months and oxygen concentrators are 36 months). ZIP Code Aggregation: Some ZIP Codes do not have specific geospatial boundary data (e.g., P.O. Box ZIP Codes). To capture the complete population data, the HHS emPOWER Program identified the larger boundary ZIP Code (Parent) within which the non-boundary ZIP Code (Child) resides. The totals are added together and displayed under the parent ZIP Code. Approved Data Uses: The public HHS emPOWER REST Service is approved for use by all partners and is intended to be used to help inform and support emergency preparedness, response, recovery, and mitigation activities in all communities. Privacy Protections: Protecting the privacy of Medicare beneficiaries is an essential priority for the HHS emPOWER Program. Therefore, all personally identifiable information are removed from the data and numerous de-identification methods are applied to significantly minimize, if not completely mitigate, any potential for deduction of small cells or re-identification risk. For example, any cell size found between the range of 1 and 10 is masked and shown as 11.HHS emPOWER Program Executive SummaryHHS emPOWER Program Informational Power Point.

The RTK (Real-Time Kinematic) Survey Systems market, valued at $783 million in 2025, is poised for robust growth, exhibiting a Compound Annual Growth Rate (CAGR) of 5.9% from 2025 to 2033. This expansion is driven by several key factors. Firstly, the increasing adoption of precise positioning technologies across various sectors, including land and resources management, urban planning and construction, and mineral resource exploration, fuels demand. The rising complexity of infrastructure projects and the need for accurate data for efficient planning and execution further contribute to market growth. Technological advancements, such as the development of more accurate and reliable dual-frequency RTK systems, are also significantly impacting the market. Furthermore, the increasing integration of RTK systems with other technologies like GIS (Geographic Information Systems) and drones enhances their functionality and appeal across various applications. Governments' increasing focus on infrastructure development and smart city initiatives in developing economies like those in Asia-Pacific creates significant growth opportunities. However, market growth may be somewhat tempered by certain restraining factors. The high initial investment cost associated with RTK equipment and the requirement for skilled personnel to operate the systems could limit wider adoption, especially among small and medium-sized enterprises (SMEs). Furthermore, the potential impact of economic downturns on infrastructure spending could also temporarily slow market growth. Nonetheless, the long-term outlook for the RTK Survey Systems market remains positive, driven by continuous technological advancements and expanding applications across various industries. The market segmentation by application (Land and Resources Management, Urban Planning and Construction, Roads and Bridges, Mineral Resources, Others) and type (Single-Frequency RTK, Dual-Frequency RTK) provides further insights into market dynamics and allows for tailored strategies to penetrate specific niche markets. Competition amongst established players like Leica (Hexagon), Trimble, and FARO, as well as emerging companies from China, is expected to remain intense, driving innovation and pricing pressures. This in-depth report provides a comprehensive analysis of the global RTK Survey Systems market, projecting a multi-million-unit market by 2033. We delve into market dynamics, competitive landscapes, and future growth trajectories, offering invaluable insights for stakeholders across the industry. The study covers the historical period (2019-2024), base year (2025), and forecast period (2025-2033), leveraging extensive data analysis to deliver actionable intelligence. Keywords: RTK GPS, Real-Time Kinematic, GNSS Surveying, Surveying Equipment, Land Surveying, GIS, Mapping, Positioning Systems, Precision Agriculture.

GIS Data Collector Market Outlook

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.

Component Analysis

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

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 GNSS RTK Rover market is experiencing robust growth, driven by increasing demand across diverse sectors like agriculture, architecture, and surveying. Technological advancements, such as improved accuracy and integration with other technologies like drones and GIS software, are fueling market expansion. The market's size in 2025 is estimated at $1.5 billion, exhibiting a Compound Annual Growth Rate (CAGR) of 8% from 2025 to 2033. This growth is propelled by the rising adoption of precision agriculture techniques requiring high-accuracy positioning, alongside the expanding construction and infrastructure development globally. The multi-frequency segment holds a significant market share due to its enhanced accuracy and ability to overcome signal interference. Geographically, North America and Europe currently dominate the market, but the Asia-Pacific region is projected to witness the fastest growth due to rapid urbanization and infrastructure projects. However, challenges remain. The high initial investment cost of RTK Rover systems can be a barrier to entry for smaller businesses. Furthermore, the dependence on satellite signals can be affected by atmospheric conditions and signal blockage in urban canyons. Despite these limitations, ongoing technological innovations, including the development of more affordable and user-friendly devices, alongside government initiatives promoting precision technologies, are expected to mitigate these constraints and drive continued market growth over the forecast period. The increasing availability of cloud-based data processing and analysis solutions further enhances the overall value proposition of GNSS RTK Rovers, making them more accessible and effective for a wider range of applications.

Locations of street devices in Arlington County used for assisting traffic or segregating areas from traffic. This includes bollards, curb stops, planters, and other such devices. The data is maintained in the Cartegraph asset management system.Contact: Department of Environmental ServicesData Accessibility: Publicly AvailableUpdate Frequency: DailyDocumentation Last Revision Date: 2/26/2024Documentation Creation Date: 2/26/2024Feature Dataset Name: OMS_TrafficLayer Name: DES_TEO_Street_Devices_pnt

The land surveying instrument market, valued at $6107 million in 2025, is projected to experience robust growth, driven by increasing infrastructure development globally and the rising adoption of advanced technologies like robotic total stations and GNSS receivers. The market's Compound Annual Growth Rate (CAGR) of 5.8% from 2025 to 2033 indicates a significant expansion, fueled by the growing demand for precise and efficient surveying solutions across various sectors. Key application areas like construction and survey & mapping are primary growth drivers, benefiting from urbanization and the need for detailed spatial data. Technological advancements, including improved accuracy, automation, and data integration capabilities of instruments, further contribute to market expansion. While challenges such as high initial investment costs for advanced equipment and the need for skilled professionals might act as restraints, the overall market outlook remains positive due to consistent technological innovation and rising government investments in infrastructure projects worldwide. The market segmentation reveals a diverse landscape. Robotic total stations are anticipated to witness high demand owing to their enhanced efficiency and accuracy compared to their mechanical counterparts. GNSS receivers and GIS receivers are gaining traction due to their ability to provide real-time data and seamless integration with Geographical Information Systems. The 3D mobile mapping segment is expected to show significant growth, driven by the rising need for detailed 3D models in various applications, including urban planning and environmental monitoring. Geographically, North America and Europe currently hold significant market shares, but the Asia-Pacific region is projected to exhibit considerable growth potential in the coming years, driven by rapid urbanization and infrastructure development in countries like China and India. Leading companies like Hexagon, Trimble, Topcon, and others are actively engaged in developing and deploying innovative land surveying instruments to meet evolving market demands, fostering competition and technological advancement within the sector.

Infrastructure point features related to parking area in Easton, Massachusetts. Compiled from 2017 vector mapping project conducted by WSP. The aerial photographic mission was carried out on April 12, 2017. The vector data was collected at scale of 1"= 40'.

The global Mobile Real Time Kinematic (mRTK) machine market is experiencing robust growth, driven by increasing demand across diverse sectors. Let's assume a 2025 market size of $2.5 billion and a Compound Annual Growth Rate (CAGR) of 8% for the forecast period 2025-2033. This growth is fueled by several key factors. The construction industry's heavy reliance on precise positioning for infrastructure projects, coupled with advancements in automation and the Internet of Things (IoT), is a significant contributor. Furthermore, the agriculture sector is adopting mRTK technology for precision farming, enhancing efficiency and yield. The burgeoning need for high-accuracy surveying and mapping in the military and environmental monitoring sectors also contributes significantly to market expansion. Technological improvements, such as the integration of advanced sensors and improved software capabilities, leading to enhanced accuracy, efficiency, and user-friendliness are further accelerating market adoption. The increasing availability of affordable and user-friendly mRTK solutions is also driving wider market penetration. However, certain restraints exist. High initial investment costs, the need for specialized expertise for operation and maintenance, and the potential impact of adverse weather conditions on accuracy can hinder growth. Despite these challenges, the long-term prospects for the mRTK market remain positive, particularly with ongoing research and development leading to more robust, cost-effective solutions. The market is segmented by application (industrial, commercial, military, others) and geographically dispersed, with North America, Europe, and Asia Pacific representing major regions. Key players in the market include Trimble Navigation, Topcon, Leica Geosystems, Novatel, and several others, continually innovating and competing to capture market share. The predicted CAGR of 8% indicates a substantial market expansion over the next decade, making mRTK technology a vital tool across various industries.

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.