Snapshot img

GIS In Utility Industry Market Size 2025-2029

The gis in utility industry market size is forecast to increase by USD 3.55 billion, at a CAGR of 19.8% between 2024 and 2029.

The utility industry's growing adoption of Geographic Information Systems (GIS) is driven by the increasing need for efficient and effective infrastructure management. GIS solutions enable utility companies to visualize, analyze, and manage their assets and networks more effectively, leading to improved operational efficiency and customer service. A notable trend in this market is the expanding application of GIS for water management, as utilities seek to optimize water distribution and reduce non-revenue water losses. However, the utility GIS market faces challenges from open-source GIS software, which can offer cost-effective alternatives to proprietary solutions. These open-source options may limit the functionality and support available to users, necessitating careful consideration when choosing a GIS solution. To capitalize on market opportunities and navigate these challenges, utility companies must assess their specific needs and evaluate the trade-offs between cost, functionality, and support when selecting a GIS provider. Effective strategic planning and operational execution will be crucial for success in this dynamic market.

What will be the Size of the GIS In Utility Industry Market during the forecast period?

Explore in-depth regional segment analysis with market size data - historical 2019-2023 and forecasts 2025-2029 - in the full report.
Request Free SampleThe Global Utilities Industry Market for Geographic Information Systems (GIS) continues to evolve, driven by the increasing demand for advanced data management and analysis solutions. GIS services play a crucial role in utility infrastructure management, enabling asset management, data integration, project management, demand forecasting, data modeling, data analytics, grid modernization, data security, field data capture, outage management, and spatial analysis. These applications are not static but rather continuously unfolding, with new patterns emerging in areas such as energy efficiency, smart grid technologies, renewable energy integration, network optimization, and transmission lines. Spatial statistics, data privacy, geospatial databases, and remote sensing are integral components of this evolving landscape, ensuring the effective management of utility infrastructure. Moreover, the adoption of mobile GIS, infrastructure planning, customer service, asset lifecycle management, metering systems, regulatory compliance, GIS data management, route planning, environmental impact assessment, mapping software, GIS consulting, GIS training, smart metering, workforce management, location intelligence, aerial imagery, construction management, data visualization, operations and maintenance, GIS implementation, and IoT sensors is transforming the industry. The integration of these technologies and services facilitates efficient utility infrastructure management, enhancing network performance, improving customer service, and ensuring regulatory compliance. The ongoing evolution of the utilities industry market for GIS reflects the dynamic nature of the sector, with continuous innovation and adaptation to meet the changing needs of utility providers and consumers.

How is this GIS In Utility Industry Industry segmented?

The gis in utility industry industry research report provides comprehensive data (region-wise segment analysis), with forecasts and estimates in 'USD million' for the period 2025-2029, as well as historical data from 2019-2023 for the following segments. ProductSoftwareDataServicesDeploymentOn-premisesCloudGeographyNorth AmericaUSCanadaEuropeFranceGermanyRussiaMiddle East and AfricaUAEAPACChinaIndiaJapanSouth AmericaBrazilRest of World (ROW).

By Product Insights

The software segment is estimated to witness significant growth during the forecast period.In the utility industry, Geographic Information Systems (GIS) play a pivotal role in optimizing operations and managing infrastructure. Utilities, including electricity, gas, water, and telecommunications providers, utilize GIS software for asset management, infrastructure planning, network performance monitoring, and informed decision-making. The GIS software segment in the utility industry encompasses various solutions, starting with fundamental GIS software that manages and analyzes geographical data. Additionally, utility companies leverage specialized software for field data collection, energy efficiency, smart grid technologies, distribution grid design, renewable energy integration, network optimization, transmission lines, spatial statistics, data privacy, geospatial databases, GIS services, project management, demand forecasting, data modeling, data analytics, grid modernization, data security, field data capture, outage ma

The GIS in Utility Industry market is experiencing robust growth, projected to reach $2.42 billion in 2025 and maintain a Compound Annual Growth Rate (CAGR) of 19.8% from 2025 to 2033. This expansion is fueled by several key drivers. Increasing demand for improved operational efficiency and asset management within utility companies is a primary factor. GIS technologies provide utilities with powerful tools to optimize grid management, streamline maintenance operations, and enhance service delivery. Furthermore, the growing adoption of cloud-based GIS solutions offers enhanced scalability, accessibility, and cost-effectiveness, accelerating market penetration. The integration of advanced technologies such as IoT sensors, AI, and machine learning into GIS platforms further improves data analysis capabilities, enabling predictive maintenance and proactive risk mitigation. While the initial investment in GIS infrastructure can be a restraint for some smaller utility providers, the long-term cost savings and improved operational efficiency are compelling arguments for adoption. Market segmentation reveals a significant demand for software solutions, followed by data and services components. Cloud deployment models are rapidly gaining popularity, surpassing on-premises deployments due to their inherent advantages. Geographically, North America and Europe currently hold significant market share, driven by advanced technological infrastructure and high adoption rates. However, rapidly developing economies in APAC, particularly China and India, are expected to show substantial growth in the coming years, presenting attractive opportunities for market expansion. The competitive landscape is populated by a mix of established players and emerging technology providers, leading to innovation and competitive pricing. The diverse range of GIS solutions available caters to specific utility needs, including electric power, water, gas, and telecom. Software solutions form the core of the market, providing the tools for data visualization, analysis, and management. Data services, including high-resolution imagery and spatial data analytics, are crucial for effective decision-making. The market's future trajectory is positive, propelled by ongoing technological advancements and the urgent need for efficient and resilient utility infrastructure. The increasing focus on sustainability and renewable energy further amplifies the demand for GIS solutions that support grid modernization and the integration of distributed energy resources. The industry's focus will shift towards integrating GIS with other technologies to enhance decision-making processes and operational efficiency, and continued innovation in data analytics and AI will further refine GIS capabilities within the sector.

Programmatically generated Data Dictionary document detailing the Energy Sector Corridors service.

    The PDF contains service metadata and a complete list of data fields.
    For any questions or issues related to the document, please contact the data owner of the service identified in the PDF and Credits of this portal item.


  Related Links
  Energy Sector Corridors Service URL
  Energy Sector Corridors Portal Item

The European Gas Insulated Switchgear (GIS) market is experiencing robust growth, projected to reach €4.19 billion in 2025 and maintain a Compound Annual Growth Rate (CAGR) of 7.62% from 2025 to 2033. This expansion is driven by several key factors. The increasing demand for reliable and efficient power transmission and distribution infrastructure across Europe, particularly in the rapidly growing renewable energy sector, is a major catalyst. Stringent regulations aimed at improving grid stability and safety are further propelling the adoption of GIS technology, which offers superior performance compared to traditional air-insulated switchgear. Furthermore, the ongoing modernization and expansion of existing power grids, coupled with urbanization and industrialization across major European economies like Germany, France, and the UK, are contributing to significant market growth. The market is segmented by voltage level (low, medium, high), end-user (commercial & residential, power utilities, industrial), and geography, with Germany, France, the UK, and other key Nordic countries representing the largest market shares. Competition is fierce among established players such as Hitachi ABB, Schneider Electric, General Electric, Eaton, and Siemens, prompting continuous innovation in GIS technology and service offerings. Growth within specific segments is influenced by regional variations in energy policy and infrastructure development. For example, countries with ambitious renewable energy targets are witnessing faster adoption of GIS solutions for integrating renewable energy sources into the grid. The industrial sector, particularly in manufacturing and process industries, presents a significant growth opportunity due to the need for reliable and safe power distribution within their facilities. While challenges remain, such as the high initial investment costs associated with GIS installation, the long-term benefits in terms of reliability, safety, and reduced maintenance costs are increasingly outweighing these concerns. The forecast period (2025-2033) anticipates continued strong growth, driven by sustained investments in grid modernization and the ongoing expansion of renewable energy capacity across Europe. Recent developments include: October 2023: Nuventura and Iberapa, a Spanish manufacturer of high-voltage (HV) and medium-voltage (MV) substations have announced the signing of a strategic partnership agreement. This exciting collaboration will enable Iberapa to incorporate Nuventura's cutting-edge SF6-free MV GIS into their MV substation offerings., March 2023: Siemens Energy announced an investment of USD 32.5 million in the extension of its manufacturing plant for gas-insulated medium voltage switchgear in Frankfurt-Fechenheim, Germany. A smart, completely automated high-speed warehouse and a 1,200-square-meter extension to an existing hall are being built on the 160,000-square-meter site. For years, the plant has been encountering continued gain in incoming orders and is working at its capacity limitation. The supplemental production area will help a third assembly line for switchgear.. Key drivers for this market are: 4., Increasing Investments in Transmission and Distribution Infrastructure. Potential restraints include: 4., Increasing Investments in Transmission and Distribution Infrastructure. Notable trends are: High Voltage Level Segment Expected to Dominate the Market.

This data layer contains geothermal resource areas and their technical potential used in long-term electric system modeling for Integrated Resource Planning and SB 100. Geothermal resource areas are delineated by Known Geothermal Resource Areas (KGRAs) (Geothermal Map of California, 2002), other geothermal fields (CalGEM Field Admin Boundaries, 2020), and Bureau of Land Management (BLM) Geothermal Leasing Areas (California BLM State Office GIS Department, 2010). The fields that are considered in our assessment have enough information known about the geothermal reservoir that an electric generation potential was estimated by USGS (Williams et al. 2008) or estimated by a BLM Environmental Impact Statement (El Centro Field Office, 2007). For the USGS identified geothermal systems, any point that lies within 2 km of a field is summed to represent the total mean electrical generation potential from the entire field.

Geothermal field boundaries are constructed for identified geothermal systems that lie outside of an established geothermal field. A circular footprint is assumed with a radius determined by the area needed to support the mean resource potential estimate, assuming a 10 MW/km² power density.

Several geothermal fields have power plants that are currently generating electricity from the geothermal source. The total production for each geothermal field is estimated by the CA Energy Commission’s Quarterly Fuel and Energy Report that tracks all power plants greater than 1 MW. The nameplate capacity of all generators in operation as of 2021 were used to inform how much of the geothermal fields are currently in use. This source yields inconsistent results for the power plants in the Geysers. Instead, an estimate from the net energy generation from those power plants is used. Using these estimates, the net undeveloped geothermal resource potential can be calculated.

Finally, we apply the protected area layer for geothermal to screen out those geothermal fields that lie entirely within a protected area. The protected area layer is compiled from public and private lands that have special designations prohibiting or not aligning with energy development.

This layer is featured in the CEC 2023 Land-Use Screens for Electric System Planning data viewer.

For more information about this layer and its use in electric system planning, please refer to the Land Use Screens Staff Report in the CEC Energy Planning Library.

Change Log:

Version 1.1 (January 18, 2024)

• ProtectedArea_Exclusion field was updated to correct for the changes to the Protected Area Layer. A Development Focus Area on Bureau of Land Management (BLM) land that overlays the Coso Hot Springs allows its resource potential to be considered in the statewide estimate.

Data Dictionary:

Total_MWe_Mean: The estimated resource potential from each geothermal field. All geothermal fields, except for Truckhaven, was given an estimate by Williams et al. 2008. If more than one point resource intersects (within 2km of) the field, the sum of the individual geothermal systems was used to estimate the magnitude of the resource coming from the entire geothermal field. Estimates are given in MW.

Total_QFER_NameplateCapacity: The total nameplate capacities of all generators in operation as of 2021 that intersects (within 2 km of) a geothermal field. The resource potential already in use for the Geysers is determined by Lovekin et al. 2004. Estimates are given in MW.

ProtectedArea_Exclusion: Binary value representing whether a field is excluded by the land-use screen or not. Fields that are excluded have a value of 1; those that aren’t have a value of 0.

NetUndevelopedRP: The net undeveloped resource potential for each geothermal field. This field is determined by subtracting the total resource potential in use (Total_QFER_NameplateCapacity) from the total estimated resource potential (Total_MWe_Mean). Estimates are given in MW.

Acres_GeothermalField: This is the geodesic acreage of each geothermal field. Values are reported in International Acres using a NAD 1983 California (Teale) Albers (Meters) projection.

References:

1. Geothermal Map of California, S-11. California Department of Conservation, 2002. https://www.conservation.ca.gov/calgem/geothermal/maps/Pages/index.aspx
2. CalGEM Field Admin Boundaries, 2020. https://gis.conservation.ca.gov/server/rest/services/CalGEM/Admin_Bounds/MapServer
   
3. California BLM State Office GIS Department, California BLM Verified and Potential Geothermal Leases in California, 2010. https://databasin.org/datasets/5ec77a1438ab4402bf09ef9bfd7f04d9/
   
4. Williams, Colin F., Reed, Marshall J., Mariner, Robert H., DeAngelo, Jacob, Galanis, S. Peter, Jr. 2008. "Assessment of moderate- and high-temperature geothermal resources of the United States: U.S. Geological Survey Fact Sheet 2008-3082." 4 p. https://certmapper.cr.usgs.gov/server/rest/services/geothermal/westus_favoribility_systems/MapServer/0
5. El Centro Field Office, Bureau of Land Management (2007). Final Environmental Impact Statement for the Truckhaven Geothermal Leasing Area (Publication Index Number: BLM/CA/ES-2007-017+3200). United States Department of the Interior Bureau of Land Management.
6. Lovekin, James W., Subir K. Sanyal, Christopher W. Klein. 2004. “New Geothermal Site Identification and Qualification.” Richmond, California:

Solar Insolation Mapping Service Market Outlook

As per the latest research conducted in 2025, the global Solar Insolation Mapping Service market size stands at USD 1.45 billion in 2024, reflecting robust growth momentum driven by the accelerating adoption of solar energy solutions worldwide. The market is exhibiting a strong compound annual growth rate (CAGR) of 11.2% and is forecasted to reach USD 3.61 billion by 2033. The surge in demand for efficient site assessment and optimization for solar projects, combined with the proliferation of advanced mapping technologies, is a primary growth factor fueling this market’s expansion.

One of the principal growth drivers for the Solar Insolation Mapping Service market is the escalating global commitment to renewable energy targets and the urgent need to mitigate climate change. Governments and private sector entities are increasingly investing in solar power infrastructure, necessitating precise and reliable insolation data to maximize the efficiency and viability of solar installations. The integration of advanced mapping services, such as satellite-based and GIS-enabled solutions, allows stakeholders to identify optimal locations, assess potential yield, and minimize project risks. This data-driven approach is critical for both large-scale utility projects and distributed solar applications, significantly enhancing project bankability and operational outcomes.

Technological advancements are further propelling the Solar Insolation Mapping Service market. The evolution of satellite imagery, remote sensing, and sophisticated data analytics has revolutionized the way solar resources are measured and mapped. The advent of high-resolution geospatial data and real-time monitoring capabilities enables more accurate and granular assessments of solar potential across diverse geographies. Moreover, the integration of artificial intelligence and machine learning algorithms is improving the predictive accuracy of insolation mapping, supporting better decision-making for developers, utilities, and policymakers. These innovations are making solar project development more efficient, cost-effective, and scalable, thereby accelerating market growth.

Another significant factor contributing to market expansion is the growing adoption of solar energy in emerging economies, particularly in regions with high solar irradiation. Countries in Asia Pacific, Latin America, and Africa are witnessing a surge in solar installations, driven by favorable government policies, declining solar technology costs, and increasing electricity demand. Solar insolation mapping services play a crucial role in these markets by enabling precise site selection and resource assessment, which are essential for attracting investment and ensuring project success. As more regions embrace solar power, the demand for accurate and reliable insolation mapping will continue to rise, further strengthening the market’s outlook.

Regionally, the Asia Pacific market is leading the global Solar Insolation Mapping Service industry, accounting for a substantial share of total revenue in 2024. This dominance is underpinned by aggressive solar energy targets in countries such as China, India, and Japan, along with significant investments in solar infrastructure. North America and Europe are also key markets, benefiting from mature solar industries and advanced technological capabilities. Meanwhile, Latin America and the Middle East & Africa are emerging as high-growth regions, supported by abundant solar resources and increasing policy support for renewable energy development. This regional diversity ensures a broad and resilient growth trajectory for the global market.

Service Type Analysis

The Solar Insolation Mapping Service market is segmented by service type into Satellite-Based Mapping, Ground-Based Mapping, and Hybrid Mapping. Satellite-based mapping services have emerged as the dominant segment, owing to their ability to provide comprehensive, high-resolution, and continuous data coverage across vast geographica

The global aerial survey services market, valued at $16.09 billion in 2025, is projected to experience robust growth, exhibiting a compound annual growth rate (CAGR) of 4.0% from 2025 to 2033. This expansion is driven by several key factors. Increasing demand for precise and efficient data acquisition across diverse sectors, including construction, agriculture, and environmental monitoring, fuels market growth. Technological advancements in drone technology, sensor capabilities, and data processing software are enabling higher resolution imagery, faster processing times, and more detailed analysis, further bolstering market adoption. The rising need for infrastructure development, particularly in emerging economies, coupled with stricter environmental regulations mandating comprehensive surveys, significantly contributes to market expansion. Furthermore, the integration of AI and machine learning in data analysis enhances the accuracy and efficiency of aerial surveys, further driving demand. Segmentation analysis reveals a strong presence across various applications. Forestry and agriculture benefit significantly from aerial surveys for precision farming and land management. Similarly, the construction industry leverages aerial data for site planning, progress monitoring, and infrastructure inspections. The energy sector utilizes aerial surveys for pipeline monitoring, power line inspections, and resource exploration. Environmental studies rely heavily on this technology for monitoring deforestation, pollution levels, and ecosystem changes. While aircraft remain the dominant platform, the increasing adoption of drones and satellites indicates a shifting technological landscape. Competitive analysis indicates a diverse range of companies operating in this market, representing a blend of established players and innovative startups, indicative of a dynamic and competitive market environment. The geographical distribution of market activity mirrors global infrastructure development and economic activity, with North America and Europe currently holding significant market share, while Asia-Pacific presents a substantial growth opportunity.

The global utility coordination services market is experiencing robust growth, driven by increasing urbanization, expanding infrastructure projects, and stringent regulations aimed at minimizing disruptions during utility work. The market's size in 2025 is estimated at $15 billion, reflecting a compound annual growth rate (CAGR) of approximately 7% from 2019 to 2024. This growth is fueled by several key factors. Firstly, the rising complexity of underground and above-ground utility networks necessitates sophisticated coordination to prevent costly damages and service interruptions. Secondly, governments worldwide are increasingly mandating utility coordination to ensure public safety and efficient project delivery. This regulatory push is particularly evident in North America and Europe, regions that currently hold significant market share. Finally, technological advancements, such as GIS mapping and digital collaboration platforms, are improving efficiency and reducing the risk of errors in utility coordination. The Water and Wastewater, and Electric Power application segments are expected to lead the market growth, followed by Oil and Gas and Transportation sectors due to their extensive utility networks. The market is segmented by application (Water and Wastewater, Electric Power, Transportation, Oil and Gas, Telecommunications, Others) and type (Underground Utility, Above Ground Utility). While North America and Europe currently dominate the market, Asia-Pacific is poised for significant growth, driven by rapid infrastructure development in countries like China and India. However, factors like high initial investment costs for technology adoption and a potential shortage of skilled professionals could restrain market growth to some extent. The competitive landscape is characterized by a mix of large multinational firms and specialized regional players. Companies are focusing on strategic partnerships, technological innovations, and expansion into new geographic markets to maintain a competitive edge. The forecast period (2025-2033) anticipates continued market expansion, with the CAGR potentially increasing slightly as technology adoption accelerates and infrastructure development continues globally. This positive outlook makes the utility coordination services market an attractive sector for investment and expansion.

The global satellite imagery and image processing services market is experiencing robust growth, driven by increasing demand across diverse sectors. The market, estimated at $15 billion in 2025, is projected to expand at a Compound Annual Growth Rate (CAGR) of 7% from 2025 to 2033, reaching approximately $25 billion by 2033. This expansion is fueled by several key factors. Firstly, advancements in satellite technology are providing higher-resolution imagery with improved accuracy and faster processing times, enabling more detailed analysis for various applications. Secondly, the rising adoption of cloud-based platforms for image processing and analytics is streamlining workflows and reducing costs for users. This is particularly crucial for smaller businesses and organizations that previously lacked access to sophisticated image processing capabilities. Thirdly, the growing need for precise geographical information across diverse sectors, including environmental monitoring, precision agriculture, urban planning, and disaster response, fuels market demand. The defense and security sector remains a significant contributor, with increasing reliance on satellite imagery for intelligence gathering and surveillance. Market segmentation reveals significant opportunities within specific application areas. The environmental sector, utilizing satellite imagery for deforestation monitoring, climate change analysis, and pollution detection, is a rapidly growing segment. Similarly, the energy and power sector leverages satellite imagery for pipeline monitoring, renewable energy resource assessment, and infrastructure management. Within image processing types, the demand for advanced data analytics is soaring, with growing adoption of artificial intelligence and machine learning for automated feature extraction and predictive analysis. While regulatory hurdles and the high initial investment cost of satellite technologies pose some challenges, the overall market outlook remains positive, driven by technological advancements, increasing data accessibility, and rising demand for location-based intelligence. Competition is intensifying amongst established players and new entrants, leading to innovation and affordability in the market.

Asia-Pacific GIS Market is Segmented by Component (Hardware, Software, and Services), Deployment Mode (On-Premise, Cloud, and Hybrid), Function (Mapping, Spatial Analysis and Modelling, Surveying and Positioning, and More), End-User Industry (Government and Defence, Utilities and Energy, Transportation and Logistics, and More), and Country. The Market Forecasts are Provided in Terms of Value (USD).

The size of the India Satellite Imagery Services market was valued at USD XXX Million in 2023 and is projected to reach USD XXX Million by 2032, with an expected CAGR of 17.43% during the forecast period.The satellite image services primarily include acquisition, processing, analysis, and interpretation to extract useful information. This high-resolution information obtained and captured from Earth-orbiting satellites indicates aspects pertaining to land use and development in urban areas, agriculture, natural resources, and climate change.Indian satellite image services are achieving an exponential growth rate as they meet the increasing demand of various sectors. These sat data are increasingly being used by governments for urban planning, disaster management, and border surveillance. Agriculture uses satellite data to monitor crop growth, estimate yields, and carry out precision farming, while resource exploration and environmental impact assessments are common applications of satellite imagery in the mining and energy sectors. Telecommunications and the GIS industries depend on satellite imagery to plan networks and map areas.The growth of the Indian market is due to the focus of the Indian government on space technology and its initiatives to encourage the use of satellite data. There is vast potential and promising applications of satellite imagery services in the country of India, as there has been a rising advancement in technology along with sophistication of techniques in data analysis. Recent developments include: January 2023: The Indian Space Research Organization's National Remote Sensing Center released satellite images of Joshimath, a town in Uttarakhand that is slowly sinking due to land subsidence, and the images show that a rapid subsidence of 5.4 cm was observed in a span of twelve days between December last week and January first week., June 2022: Pataa Navigations, an India-based software firm, and Indian National Space Promotion and Authorisation Centre (IN-SPACe) signed an MoU to enable access to ISRO's Geospatial Services and APIs for the creation of an addressing system during the opening of the In-Space headquarters. The company would launch an addressing revolution in India by providing access to satellite image-based digital addresses. Through this MoU, the partnership would be for the ISRO portals Bhuvan, VEDAS, and MOSDAC services.. Key drivers for this market are: Government Initiatives to Foster the Growth of Satellite Imagery Services in India, Increasing Importance on Disaster Management and Mitigation Efforts. Potential restraints include: Affordability and Accessibility might restrain the Market Growth, Limited Standardization and Interoperability. Notable trends are: Government Initiatives to Foster the Growth of Satellite Imagery Services in India.

Electricity, natural gas, stationary diesel, and propane used for heating, cooling, and general building operations account for 64% (2,610,223 mt CO2e) of Boulder Counties total emissions. Within specific communities, the number varies but typically still dominates their total emissions.Within this sector, electricity and natural gas make up the majority of emissions at 59% and 37% respectively. If you include the emissions created from the transmission and distribution losses (the loss of electricity from the sources of supply and points of distribution) the emissions from electricity usage jump to 62%. Natural gas also experiences losses in distribution (1% of building sector emissions are caused by natural gas leakage). See below.

The global aerial survey market, valued at $7,454 million in 2025, is projected to experience steady growth, driven by increasing demand across diverse sectors. The Compound Annual Growth Rate (CAGR) of 3.1% from 2025 to 2033 indicates a consistent expansion, fueled by several key factors. Technological advancements in drone technology and sensor capabilities are making aerial surveys more efficient, cost-effective, and accessible. This is particularly impactful in sectors like forestry and agriculture, where precision mapping and monitoring are crucial for optimizing resource management and yield. Furthermore, the growing need for infrastructure development in construction and the expanding energy sector (oil & gas, power & energy) are creating significant opportunities for aerial surveys. The rise of environmental studies and the need for precise land use monitoring are also contributing factors. While data limitations prevent precise segmentation breakdown, the relatively even distribution across application segments suggests a balanced market with no single dominant application area. The presence of established players like Kokusai Kogyo and Zenrin alongside smaller specialized firms suggests a competitive landscape that fosters innovation and growth. The geographic distribution is expected to see continued strong performance in North America and Asia Pacific, driven by robust infrastructure projects and technological adoption rates. However, emerging economies in other regions also hold substantial untapped potential. The market's growth trajectory is expected to remain relatively consistent throughout the forecast period, with a gradual increase in market size year-on-year. While some regional markets might experience more rapid growth than others due to varying levels of economic development and technological adoption, the overall market is poised for steady expansion. The continued development of sophisticated data analytics capabilities paired with aerial survey data will further enhance the value proposition of these services, broadening their appeal across various industries. This includes applications in urban planning, disaster management, and precision farming, all of which contribute to the overall market growth. However, regulatory hurdles and concerns about data privacy may present some challenges. Nevertheless, the overall outlook for the aerial survey market remains positive, presenting substantial opportunities for both established players and new entrants.

The Unmanned Aerial Survey (UAS) service market, valued at $4263 million in 2025, is projected to experience robust growth, driven by a Compound Annual Growth Rate (CAGR) of 5.1% from 2025 to 2033. This expansion is fueled by several key factors. Firstly, the increasing adoption of UAS technology across diverse sectors like forestry, agriculture, construction, and oil & gas is significantly boosting demand. Precision agriculture, infrastructure inspection, and environmental monitoring are prime examples of applications where UAS provide cost-effective and efficient solutions, leading to higher accuracy and faster turnaround times compared to traditional methods. Furthermore, advancements in drone technology, including improved sensor capabilities, longer flight times, and enhanced data processing software, are continuously expanding the capabilities and applications of UAS surveys. The growing availability of skilled professionals and specialized service providers further contributes to market growth. Government initiatives promoting the use of drones for various purposes and a rise in private sector investment in UAS technology are also expected to contribute to the market's expansion. However, market growth may face some restraints. Regulatory hurdles and safety concerns surrounding drone operations remain a challenge in some regions. High initial investment costs for advanced UAS systems and the need for skilled operators may limit adoption among smaller companies. Data security and privacy issues related to the collection and storage of sensitive geographical information also pose concerns. Despite these challenges, the overall market outlook remains positive, driven by the aforementioned growth factors and the ongoing technological advancements within the UAS industry. The market is segmented by application (forestry & agriculture, construction, power & energy, oil & gas, environmental studies, others) and type (drone, satellite, others). North America and Europe currently hold significant market shares, but Asia-Pacific is projected to witness substantial growth in the coming years due to increasing infrastructure development and government investments in drone technology.

The global UAV Aerial Survey Services market is experiencing robust growth, driven by increasing demand across diverse sectors. Technological advancements in drone technology, offering higher resolution imagery and improved data processing capabilities, are significantly contributing to this expansion. The market's versatility, providing cost-effective and efficient solutions for various applications, further fuels its growth. Specific sectors like construction, agriculture, and energy are key drivers, utilizing UAV surveys for site mapping, precision agriculture, pipeline inspections, and environmental monitoring. While regulatory hurdles and data security concerns present challenges, the market is overcoming these limitations through the development of standardized operating procedures and robust data encryption techniques. Assuming a conservative CAGR of 15% (a reasonable estimate given the rapid technological advancements and increasing adoption rates in this sector), and a 2025 market size of $2 billion, the market is projected to reach approximately $4.2 Billion by 2033. This substantial growth is further fueled by the increasing affordability and accessibility of UAV technology, enabling more businesses to leverage aerial survey services. The segmentation of the UAV Aerial Survey Services market reveals that orthophoto and oblique image services are widely utilized, catering to diverse application needs. Forestry and agriculture are dominant sectors, with construction, power and energy, and oil & gas industries rapidly adopting this technology. Regional analysis highlights strong growth in North America and Asia-Pacific, driven by significant investments in infrastructure development and agricultural modernization. Europe follows closely, spurred by government initiatives promoting sustainable development and environmental monitoring. The competitive landscape includes both established players like Kokusai Kogyo and Zenrin, and emerging specialized companies, indicating a dynamic and competitive market with potential for further consolidation and innovation. The continued development of advanced data analytics capabilities, integrated with UAV imagery, will create new opportunities and drive market expansion.

The global aquatic mapping services market is experiencing robust growth, driven by increasing demand for accurate and detailed underwater and lake mapping data across various sectors. The market's expansion is fueled by several key factors. Firstly, the rising need for efficient resource management in maritime and inland water bodies is propelling the adoption of aquatic mapping technologies. Governments and enterprises are increasingly investing in these services for applications such as infrastructure development, environmental monitoring, and navigation safety. Secondly, advancements in technologies like LiDAR, sonar, and satellite imagery are enhancing the precision and efficiency of aquatic mapping, leading to cost reductions and improved data quality. Finally, stricter environmental regulations and the growing awareness of aquatic ecosystem preservation are further boosting market growth. While data on specific market size and CAGR is absent, a conservative estimate based on similar geospatial data markets suggests a 2025 market size around $1.5 billion, growing at a compound annual growth rate (CAGR) of 8-10% over the forecast period (2025-2033). Segmentation reveals strong growth across multiple application areas. The enterprise sector, encompassing oil & gas, aquaculture, and renewable energy companies, is a significant driver, relying on aquatic mapping for exploration, development, and operational efficiency. Government agencies utilize the data for coastal zone management, water resource assessment, and national security purposes. Similarly, lake mapping is a fast-growing segment, supported by increasing interest in lake health monitoring and recreational activities. Geographic variations in market size are likely to reflect the distribution of water bodies and economic activity. North America and Europe are expected to hold significant market shares due to high levels of technological adoption and investment in infrastructure projects. However, the Asia-Pacific region is predicted to witness significant growth potential, driven by rapid urbanization, economic development, and increasing investment in water resource management.

The global switchgear market, valued at $122.24 billion in 2025, is projected to experience robust growth, driven by the increasing demand for reliable power distribution across residential, commercial, and industrial sectors. The market's Compound Annual Growth Rate (CAGR) of 6.10% from 2019 to 2024 suggests a consistent upward trajectory, anticipated to continue throughout the forecast period (2025-2033). Key drivers include the expanding global infrastructure development, particularly in emerging economies, coupled with rising urbanization and industrialization. The growing adoption of renewable energy sources and smart grids further fuels market expansion. Technological advancements, such as the development of advanced gas-insulated switchgear (GIS) and the integration of digital technologies for improved monitoring and control, are shaping market trends. However, high initial investment costs associated with switchgear installation and maintenance, along with stringent safety regulations, pose potential restraints. Segmentation analysis reveals significant growth across various types, including high-voltage switchgear, driven by the needs of large-scale industrial and utility applications. The preference for gas-insulated switchgear over air-insulated switchgear, due to its superior performance and compact design, is another notable trend. Geographic distribution indicates strong market presence in North America and Europe, while Asia-Pacific is anticipated to exhibit the highest growth rate due to rapid economic development and infrastructure investments in countries like India and China. Leading players such as Schneider Electric, Siemens, ABB, and Eaton are strategically investing in research and development, acquisitions, and partnerships to maintain their competitive edge and capitalize on emerging market opportunities. The switchgear market's future prospects remain positive, driven by long-term trends in energy consumption and infrastructure development. While challenges related to cost and regulation persist, innovative solutions and strategic partnerships are paving the way for continued expansion. The diversification across end-user industries ensures a relatively resilient market, even amidst economic fluctuations. The forecast period will likely see a continued shift towards more efficient, reliable, and technologically advanced switchgear solutions, aligning with global sustainability goals and the demand for improved power grid management. Specific growth within segments will be influenced by regional policies supporting renewable energy integration and industrial automation initiatives. The competitive landscape is expected to remain dynamic, with ongoing consolidation and expansion by major players. Recent developments include: February 2024: Schneider Electric introduced a new product called SureSeT Medium Voltage (MV) switchgear for the Canadian market. This innovative solution, which features the EvoPacT circuit breaker, aims to provide a more efficient and advanced option for primary switchgear applications that can handle digital operations effectively. SureSeT thoroughly monitors thermal, environmental, and circuit breaker health and is durable and compact. SureSeT can minimize downtime and enable faster detection of problems for quicker repairs by offering features like remote control and digital services utilizing real-time data., October 2023: Siemens Smart Infrastructure broadened its selection of eco-friendly and digital medium-voltage switchgear to aid in decarbonizing power grids. The latest blue GIS primary switchgear, free of F-gases, allows for an early shift toward sustainable grids before regulation. Siemens introduced the 8DAB 24 and enhanced the NXPLUS C 24, focusing on industrialized and high-end ratings up to 24 kV and 2500 A. It was created using the Robust Eco Design principle. The 8DAB 24 guarantees a decreased carbon footprint throughout its lifecycle. This makes it a perfect option for supporting a sustainable shift toward renewable energy.. Key drivers for this market are: Growth of Smart Electricity Grid Infrastructure, Growing Focus on Infrastructure and Renewable Energy Sources; Increased Investment in Industrial Production. Potential restraints include: Growth of Smart Electricity Grid Infrastructure, Growing Focus on Infrastructure and Renewable Energy Sources; Increased Investment in Industrial Production. Notable trends are: The Residential Segment to Witness a Significant Growth.

Summary

Geojson files used to visualize geospatial layers relevant to identifying and assessing trucking fleet decarbonization opportunities with the MIT Climate & Sustainability Consortium's Geospatial Trucking Industry Decarbonization Explorer (Geo-TIDE) tool.

Relevant Links

Link to the online version of the tool (requires creation of a free user account).

Link to GitHub repo with source code to produce this dataset and deploy the Geo-TIDE tool locally.

Funding

This dataset was produced with support from the MIT Climate & Sustainability Consortium.

Original Data Sources

These geojson files draw from and synthesize a number of different datasets and tools. The original data sources and tools are described below:

Filename(s) Description of Original Data Source(s) Link(s) to Download Original Data License and Attribution for Original Data Source(s)

faf5_freight_flows/*.geojson

trucking_energy_demand.geojson

highway_assignment_links_*.geojson

infrastructure_pooling_thought_experiment/*.geojson

Regional and highway-level freight flow data obtained from the Freight Analysis Framework Version 5. Shapefiles for FAF5 region boundaries and highway links are obtained from the National Transportation Atlas Database. Emissions attributes are evaluated by incorporating data from the 2002 Vehicle Inventory and Use Survey and the GREET lifecycle emissions tool maintained by Argonne National Lab.

Shapefile for FAF5 Regions

Shapefile for FAF5 Highway Network Links

FAF5 2022 Origin-Destination Freight Flow database

FAF5 2022 Highway Assignment Results

Attribution for Shapefiles: United States Department of Transportation Bureau of Transportation Statistics National Transportation Atlas Database (NTAD). Available at: https://geodata.bts.gov/search?collection=Dataset.

License for Shapefiles: This NTAD dataset is a work of the United States government as defined in 17 U.S.C. § 101 and as such are not protected by any U.S. copyrights. This work is available for unrestricted public use.

Attribution for Origin-Destination Freight Flow database: National Transportation Research Center in the Oak Ridge National Laboratory with funding from the Bureau of Transportation Statistics and the Federal Highway Administration. Freight Analysis Framework Version 5: Origin-Destination Data. Available from: https://faf.ornl.gov/faf5/Default.aspx. Obtained on Aug 5, 2024. In the public domain.

Attribution for the 2022 Vehicle Inventory and Use Survey Data: United States Department of Transportation Bureau of Transportation Statistics. Vehicle Inventory and Use Survey (VIUS) 2002 [supporting datasets]. 2024. https://doi.org/10.21949/1506070

Attribution for the GREET tool (original publication): Argonne National Laboratory Energy Systems Division Center for Transportation Research. GREET Life-cycle Model. 2014. Available from this link.

Attribution for the GREET tool (2022 updates): Wang, Michael, et al. Summary of Expansions and Updates in GREET® 2022. United States. https://doi.org/10.2172/1891644

grid_emission_intensity/*.geojson

Emission intensity data is obtained from the eGRID database maintained by the United States Environmental Protection Agency.

eGRID subregion boundaries are obtained as a shapefile from the eGRID Mapping Files database.

eGRID database

Shapefile with eGRID subregion boundaries

Attribution for eGRID data: United States Environmental Protection Agency: eGRID with 2022 data. Available from https://www.epa.gov/egrid/download-data. In the public domain.

Attribution for shapefile: United States Environmental Protection Agency: eGRID Mapping Files. Available from https://www.epa.gov/egrid/egrid-mapping-files. In the public domain.

US_elec.geojson

US_hy.geojson

US_lng.geojson

US_cng.geojson

US_lpg.geojson

Locations of direct current fast chargers and refueling stations for alternative fuels along U.S. highways. Obtained directly from the Station Data for Alternative Fuel Corridors in the Alternative Fuels Data Center maintained by the United States Department of Energy Office of Energy Efficiency and Renewable Energy.

US_elec.geojson

US_hy.geojson

US_lng.geojson

US_cng.geojson

US_lpg.geojson

Attribution: U.S. Department of Energy, Energy Efficiency and Renewable Energy. Alternative Fueling Station Corridors. 2024. Available from: https://afdc.energy.gov/corridors. In the public domain.

These data and software code ("Data") are provided by the National Renewable Energy Laboratory ("NREL"), which is operated by the Alliance for Sustainable Energy, LLC ("Alliance"), for the U.S. Department of Energy ("DOE"), and may be used for any purpose whatsoever.

daily_grid_emission_profiles/*.geojson

Hourly emission intensity data obtained from ElectricityMaps.

Original data can be downloaded as csv files from the ElectricityMaps United States of America database

Shapefile with region boundaries used by ElectricityMaps

License: Open Database License (ODbL). Details here: https://www.electricitymaps.com/data-portal

Attribution for csv files: Electricity Maps (2024). United States of America 2022-23 Hourly Carbon Intensity Data (Version January 17, 2024). Electricity Maps Data Portal. https://www.electricitymaps.com/data-portal.

Attribution for shapefile with region boundaries: ElectricityMaps contributors (2024). electricitymaps-contrib (Version v1.155.0) [Computer software]. https://github.com/electricitymaps/electricitymaps-contrib.

gen_cap_2022_state_merged.geojson

trucking_energy_demand.geojson

Grid electricity generation and net summer power capacity data is obtained from the state-level electricity database maintained by the United States Energy Information Administration.

U.S. state boundaries obtained from this United States Department of the Interior U.S. Geological Survey ScienceBase-Catalog.

Annual electricity generation by state

Net summer capacity by state

Shapefile with U.S. state boundaries

Attribution for electricity generation and capacity data: U.S. Energy Information Administration (Aug 2024). Available from: https://www.eia.gov/electricity/data/state/. In the public domain.

electricity_rates_by_state_merged.geojson

Commercial electricity prices are obtained from the Electricity database maintained by the United States Energy Information Administration.

Electricity rate by state

Attribution: U.S. Energy Information Administration (Aug 2024). Available from: https://www.eia.gov/electricity/data.php. In the public domain.

demand_charges_merged.geojson

demand_charges_by_state.geojson

Maximum historical demand charges for each state and zip code are derived from a dataset compiled by the National Renewable Energy Laboratory in this this Data Catalog.

Historical demand charge dataset

The original dataset is compiled by the National Renewable Energy Laboratory (NREL), the U.S. Department of Energy (DOE), and the Alliance for Sustainable Energy, LLC ('Alliance').

Attribution: McLaren, Joyce, Pieter Gagnon, Daniel Zimny-Schmitt, Michael DeMinco, and Eric Wilson. 2017. 'Maximum demand charge rates for commercial and industrial electricity tariffs in the United States.' NREL Data Catalog. Golden, CO: National Renewable Energy Laboratory. Last updated: July 24, 2024. DOI: 10.7799/1392982.

eastcoast.geojson

midwest.geojson

la_i710.geojson

h2la.geojson

bayarea.geojson

saltlake.geojson

northeast.geojson

Highway corridors and regions targeted for heavy duty vehicle infrastructure projects are derived from a public announcement on February 15, 2023 by the United States Department of Energy.

The shapefile with Bay area boundaries is obtained from this Berkeley Library dataset.

The shapefile with Utah county boundaries is obtained from this dataset from the Utah Geospatial Resource Center.

Shapefile for Bay Area country boundaries

Shapefile for counties in Utah

Attribution for public announcement: United States Department of Energy. Biden-Harris Administration Announces Funding for Zero-Emission Medium- and Heavy-Duty Vehicle Corridors, Expansion of EV Charging in Underserved Communities (2023). Available from https://www.energy.gov/articles/biden-harris-administration-announces-funding-zero-emission-medium-and-heavy-duty-vehicle.

Attribution for Bay area boundaries: San Francisco (Calif.). Department Of Telecommunications and Information Services. Bay Area Counties. 2006. In the public domain.

Attribution for Utah boundaries: Utah Geospatial Resource Center & Lieutenant Governor's Office. Utah County Boundaries (2023). Available from https://gis.utah.gov/products/sgid/boundaries/county/.

License for Utah boundaries: Creative Commons 4.0 International License.

incentives_and_regulations/*.geojson

State-level incentives and regulations targeting heavy duty vehicles are collected from the State Laws and Incentives database maintained by the United States Department of Energy's Alternative Fuels Data Center.

Data was collected manually from the State Laws and Incentives database.

Attribution: U.S. Department of Energy, Energy Efficiency and Renewable Energy, Alternative Fuels Data Center. State Laws and Incentives. Accessed on Aug 5, 2024 from: https://afdc.energy.gov/laws/state. In the public domain.

These data and software code ("Data") are provided by the National Renewable Energy Laboratory ("NREL"), which is operated by the Alliance for Sustainable Energy, LLC ("Alliance"), for the U.S. Department of Energy ("DOE"), and may be used for any purpose whatsoever.

costs_and_emissions/*.geojson

diesel_price_by_state.geojson

trucking_energy_demand.geojson

Lifecycle costs and emissions of electric and diesel trucking are evaluated by adapting the model developed by Moreno Sader et al., and calibrated to the Run on Less dataset for the Tesla Semi collected from the 2023 PepsiCo Semi pilot by the North American Council for Freight Efficiency.

In

Cloud GIS Market size is expected to reach USD 3,303.1 Million by 2033, projected at a CAGR of 14% during forecast period.