Electric Service Territories (IURC) - Shows the Electric Service Territory (EST) boundaries in Indiana, maintained by personnel of the Indiana Utility Regulatory Commission (IURC). This layer is "live" and synchronized to automatically update whenever IURC personnel establish new boundaries.The layer was created to visually represent, as accurately as possible, the electric service territories served by the regulated electric service providers in the state of Indiana, pursuant to Cause Number 42868 (Indiana Utility Regulatory Commission) to establish an online GIS mapping environment to house, edit, and display visual interpretations or electric service territory rulings filed before and ruled by the Indiana Utility Regulatory Commission. The data represented in this layer is strictly a visual aide and a best interpretation of the legally approved Electric Service Territories as ruled by the Indiana Utility Regulatory Commission (IURC). These data are not legally binding or necessarily fully representative of the legal rulings.The following is excerpted from metadata provided by the IURC: "IN THE MATTER OF THE JOINT PETITION OF ELECTRICITY SUPPLIERS FOR (1) THE ESTABLISHMENT OF THE PROCEDURES TO APPROVE SERVICE AREA BOUNDARY AGREEMENTS UNDER IC 8-1-2.3-6(2) AND SERVICE CONSENTS UNDER IC 8-1-2.3-4(A), AND (2) MODIFICATION OF THE FORM AND MAINTENANCE OF MAPS OF ASSIGNED SERVICE AREAS ESTABLISHED PURSUANT TO IC 8-1-2.3-1, ET SEQ. AND THE COMMISSION'S FEBRUARY 19, 1981 ORDER IN CAUSE NO. 36299"

Map of the electric utility service areas in California.

This dataset shows electric utility service area boundaries for the State of Minnesota. The original source data were lines hand-drawn on county highway maps. The maps were scanned and georeferenced to serve as a background for on-screen digitizing. The utilities were then given an opportunity to review and correct the service areas. Changes filed with the Public Utilities Commission (eDockets) were also reviewed to update the areas.

This data provides graphic representation of electric company territories of New Jersey. Data was compiled using Electric Utility paper maps, all greater than 1:500,000. It is anticipated that electric company territorial boundaries will remain stable.

Metadata record for the Wyoming Public Service Commission's map of electric utilities; link to map in record.

This feature class/shapefile represents electric power retail service territories. These are areas serviced by electric power utilities responsible for the retail sale of electric power to local customers, whether residential, industrial, or commercial. The following updates have been made since the previous release: 4 features added.

This feature class represents electric power retail service territories. These are areas serviced by electric power utilities responsible for the retail sale of electric power to local customers, whether residential, industrial, or commercial. The following updates have been made since the previous release: 7 features added, numerous geometries improved, and geographic coverage expanded to include American Samoa, Guam, Northern Mariana Islands, and Virgin Islands.

Map of California electric utility service territories and balancing authorities.

Map of the six electric investor owned utility (IOU) areas in California:- Bear Valley Electric Service- Liberty Utilities- PacifiCorp- PG&E: Pacific Gas & Electric Company- SDG&E: San Diego Gas & Electric Company- SCE: Southern California Edison

Major electric utility lines covering the City of Raleigh jurisdiction. Features are derived from annual aerial photography updates. This layer is updated for a quarter of the city every year and is not a depiction of current conditions.Update Frequency: AnnuallyTime Period: Current as of last flight (see update date on individual features)

Explore the burgeoning Underground Utilities Mapping Services market, driven by infrastructure growth and advanced technologies. Discover market size, CAGR, key drivers, trends, restraints, and regional insights.

Underground Utility Mapping Market Outlook

According to our latest research, the global underground utility mapping market size in 2024 stands at USD 1.92 billion, driven by increasing infrastructure investments, stringent safety regulations, and rapid urbanization. The market is growing at a robust CAGR of 10.6% and is projected to reach USD 5.22 billion by 2033. The primary growth factor is the rising demand for accurate subsurface data to prevent utility strikes and optimize construction workflows.

One of the key drivers fueling the underground utility mapping market is the escalating complexity of urban infrastructure. As cities expand and modernize, the density of underground utilities such as water pipes, gas lines, electrical cables, and telecommunication networks increases significantly. This complexity heightens the risk of accidental utility strikes during excavation, which can lead to costly project delays, property damage, and even severe injuries. Consequently, there is a growing emphasis on deploying advanced underground utility mapping solutions that leverage technologies like ground penetrating radar (GPR), electromagnetic location, and acoustic pipe location. These tools provide precise, real-time data on subsurface utilities, enabling construction and maintenance teams to plan and execute projects with greater accuracy and safety, thereby reducing the risk of disruptions and regulatory penalties.

Another significant growth factor for the underground utility mapping market is the enforcement of stringent government regulations and standards regarding utility detection and safety. Regulatory bodies across North America, Europe, and Asia Pacific have introduced mandates that require comprehensive utility mapping before any excavation or construction activity. These regulations aim to minimize public safety hazards and environmental damage caused by accidental utility strikes. As a result, both public and private sector stakeholders are increasingly investing in sophisticated hardware, software, and service offerings for underground utility mapping. The integration of these solutions with Geographic Information Systems (GIS) and Building Information Modeling (BIM) further enhances their value, enabling seamless data sharing and collaboration among project teams, regulatory authorities, and utility owners.

Technological advancements also play a pivotal role in propelling the underground utility mapping market forward. The advent of high-resolution sensors, artificial intelligence (AI)-powered data analytics, and cloud-based mapping platforms has revolutionized the way subsurface utilities are detected, visualized, and managed. Modern mapping systems can process vast amounts of data in real time, generate detailed 3D models, and provide predictive insights for asset maintenance and risk assessment. These innovations not only improve mapping accuracy but also reduce operational costs and project timelines. The growing adoption of digital twins for infrastructure management is further catalyzing market growth, as stakeholders seek to create comprehensive digital representations of both aboveground and underground assets for lifecycle management and smart city initiatives.

The increasing reliance on GPR Equipment for Utilities is a testament to the growing sophistication of underground utility mapping technologies. Ground Penetrating Radar (GPR) systems are particularly valued for their ability to detect both metallic and non-metallic utilities, providing a comprehensive view of subsurface conditions. This capability is crucial for utilities that involve a mix of materials, such as water and sewage systems, where accurate mapping can prevent costly service disruptions and enhance maintenance strategies. The integration of GPR with other technologies, like electromagnetic locators and acoustic sensors, offers a multi-faceted approach to utility detection, ensuring that all potential obstacles are identified before excavation begins. This technological synergy is driving increased adoption across sectors, from municipal infrastructure projects to private construction endeavors.

From a regional perspective, North America currently dominates the underground utility mapping market, accounting for the largest share in 2024, followed by Europe and Asia Pacific. The United States and Canada benef

Electromagnetic Utility Mapping Systems Market Outlook

According to our latest research, the global electromagnetic utility mapping systems market size reached USD 1.42 billion in 2024, with a robust growth trajectory driven by increasing infrastructure development and the need for accurate underground utility detection. The market is poised to expand at a CAGR of 8.1% from 2025 to 2033, reaching an estimated value of USD 2.76 billion by 2033. This growth is underpinned by the rising adoption of advanced mapping technologies across construction, utility, and municipal sectors, as well as heightened regulatory emphasis on safe excavation practices and asset management.

One of the primary growth drivers for the electromagnetic utility mapping systems market is the global surge in infrastructure projects, particularly in urban centers where the complexity and density of underground utilities are increasing. As cities expand and modernize, the demand for precise and non-invasive utility mapping solutions becomes critical to avoid costly damages, project delays, and safety hazards. These systems, leveraging technologies such as ground penetrating radar (GPR) and electromagnetic induction, enable stakeholders to accurately locate and map utilities like water pipes, gas lines, and electrical cables. This not only enhances operational efficiency but also aligns with stringent governmental regulations mandating the prevention of accidental utility strikes during excavation and construction activities.

Another significant factor fueling the market’s expansion is the rapid technological advancement in hardware and software components of utility mapping systems. Manufacturers are investing heavily in R&D to develop more sensitive, user-friendly, and integrated solutions that can seamlessly interface with geographic information systems (GIS) and building information modeling (BIM) platforms. The integration of AI-driven analytics, cloud-based data storage, and real-time visualization tools has further amplified the value proposition of these systems, making them indispensable for utility companies, construction firms, and surveyors. Moreover, the growing awareness of the long-term cost savings and risk mitigation offered by electromagnetic utility mapping systems is encouraging widespread adoption across both developed and emerging economies.

The market is also witnessing a shift in procurement patterns, with service-based models gaining traction alongside traditional hardware and software sales. Many organizations are opting for outsourced utility mapping services to access the latest technologies and expert operators without the burden of capital investment and maintenance. This trend is particularly pronounced among municipalities and small-to-medium construction firms, which benefit from flexible, scalable solutions tailored to specific project requirements. Furthermore, the increasing digitization of utility networks and the push towards smart city initiatives are expected to create new avenues for market growth, as accurate subsurface data becomes essential for urban planning, asset management, and disaster response strategies.

Regionally, North America continues to dominate the electromagnetic utility mapping systems market, accounting for over 35% of global revenue in 2024, followed by Europe and Asia Pacific. The United States leads in adoption due to its well-established regulatory framework, high infrastructure spending, and technological innovation. Meanwhile, Asia Pacific is emerging as the fastest-growing region, fueled by large-scale urbanization, government investments in smart infrastructure, and the increasing complexity of utility networks in countries like China, India, and Japan. Europe maintains a strong presence, driven by stringent safety standards and the modernization of aging utility infrastructures. The Middle East & Africa and Latin America are also exhibiting steady growth, supported by infrastructure development and the gradual implementation of advanced utility management practices.

Component Analysis

The component segment of the electromagnetic utility mapping systems market is broadly categorized into hardware, software, and services, each playing a distinct role in the value chain. Hardware remains the backbone of the industry, encompassing ground penetrating radars, electromagnetic sensors, and magnetic locators. The demand for adv

Electric utility service boundaries in NYS.

The Underground Utility Mapping market is projected to be valued at $1.2 billion in 2024, driven by factors such as increasing consumer awareness and the rising prevalence of industry-specific trends. The market is expected to grow at a CAGR of 8.5%, reaching approximately $2.5 billion by 2034.

The Underground Utility Mapping market is experiencing robust growth, projected to reach a value exceeding $1.32 billion by 2025 and exhibiting a Compound Annual Growth Rate (CAGR) of over 9.61% from 2025 to 2033. This expansion is fueled by several key drivers. Increasing urbanization and infrastructure development necessitate accurate and efficient utility mapping to prevent costly damages during excavation projects. Stringent safety regulations mandating utility mapping before construction activities further bolster market demand. Technological advancements, particularly in Ground Penetrating Radar (GPR) and electromagnetic locators, are enhancing the accuracy and speed of mapping, driving market adoption. The growing adoption of sophisticated data analytics and GIS integration also contributes significantly to market growth. Furthermore, the rising prevalence of smart city initiatives globally underscores the importance of precise utility data management, creating substantial opportunities for market players. The market is segmented by component type (solutions, encompassing GPR, electromagnetic locators, and other technologies; and services), and by end-user industry (public safety, oil and gas, building and construction, telecommunication, electricity, and others). The solutions segment is likely to dominate owing to continuous technological innovation and the need for high-precision mapping. Geographically, North America and Europe currently hold significant market share due to established infrastructure and advanced technological adoption. However, Asia-Pacific is projected to witness the fastest growth during the forecast period, driven by rapid urbanization and infrastructure development in emerging economies. Key market restraints include the high initial investment costs associated with advanced mapping technologies and the need for skilled professionals to operate and interpret the data. Despite these challenges, the long-term outlook for the Underground Utility Mapping market remains highly positive, with consistent growth anticipated throughout the forecast period. This comprehensive report provides an in-depth analysis of the global Underground Utility Mapping market, offering valuable insights for stakeholders across the value chain. The study period covers 2019-2033, with 2025 serving as the base and estimated year, and the forecast period spanning 2025-2033. The report meticulously examines market dynamics, key players, technological advancements, and future growth prospects, leveraging data from the historical period (2019-2024). This detailed analysis will equip businesses with the knowledge needed to navigate this rapidly evolving market and make informed strategic decisions. The market is segmented by component type (Ground Penetrating Radar, Electromagnetic Locators, Other Solutions), services, and end-user industry (Public Safety, Oil and Gas, Building and Construction, Telecommunication, Electricity, Other End-user Industries). Recent developments include: March 2024: WSB LLC (“WSB”), one of the nation’s fastest-growing infrastructure engineering and consulting firms, partnered with 4M Analytics, the nation’s leading subsurface utility AI mapping and analytics solution. This partnership is intended to support infrastructure projects across the United States, focusing on data integrity and real-time digital delivery. Leveraging artificial intelligence, computer vision, and change detection techniques, 4M Analytics synthesizes, digitizes, and geo-locates millions of utility data sources into a single platform and visually validates each line using vertical and horizontal imagery dating back to the 1940s. This enables ‘real-time’ access to the utility landscape for infrastructure projects through an intuitive user interface. The mapping resources will decrease the time it takes to locate underground utilities for owners, civil engineering firms, general contractors, subsurface utility engineering firms, and many other utility stakeholders., February 2024: Exodigo announced that it would offer the accurate and complete subsurface maps needed to improve undergrounding processes for power lines as part of the Grid Overhaul with Proactive, High-speed Undergrounding for Reliability, Resilience, and Security (GOPHURRS) program led by the US Department of Energy’s Advanced Research Projects Agency-Energy (ARPA-E).. Key drivers for this market are: Emerging Technologies Combined With Utility Maps to Improve the Exploration Activities, Increasing Availability of Detecting Applications and Increased Return on Marketing Spending. Potential restraints include: High Initial Investment Cost To Hinder Market Growth. Notable trends are: Ground Penetrating Radar is Expected to be the Largest Component Type Solution.

Underground Utility Mapping Robots Market Outlook

According to our latest research, the global underground utility mapping robots market size reached USD 1.43 billion in 2024, with a robust compound annual growth rate (CAGR) of 15.7% anticipated through the forecast period. By 2033, the market is projected to attain a value of USD 5.45 billion. This substantial growth trajectory is driven by the escalating demand for precise, efficient, and safe mapping of subsurface utilities amid rapid urbanization and infrastructure development worldwide. The integration of advanced robotics and sensor technologies has significantly enhanced the accuracy and efficiency of underground utility mapping, fueling market expansion as per our latest research findings.

The primary growth factor for the underground utility mapping robots market is the increasing complexity of urban infrastructure and the critical need to avoid utility strikes during excavation and construction activities. As cities expand and the density of underground utilities such as water pipes, gas lines, electrical cables, and telecommunications networks increases, the risk of accidental damage during construction rises. This not only leads to financial losses but also poses significant safety hazards. Consequently, there is a growing reliance on advanced robotic systems equipped with technologies like ground penetrating radar (GPR), LiDAR, and electromagnetic locators to provide accurate, non-invasive mapping solutions. These robots streamline the mapping process, minimize human intervention in hazardous environments, and reduce the likelihood of costly errors, thus driving widespread adoption across various sectors.

Another key driver of market growth is the surge in government regulations and industry standards mandating the precise mapping and documentation of underground utilities. Regulatory bodies in developed and emerging economies are increasingly enforcing stringent guidelines to ensure public safety and prevent utility damages during infrastructure projects. This regulatory pressure compels utility companies, municipalities, and construction firms to invest in state-of-the-art mapping solutions. The adoption of underground utility mapping robots not only ensures compliance with these regulations but also enhances operational efficiency by providing real-time, high-resolution data. This, in turn, accelerates project timelines and reduces overall costs, making these robots an indispensable asset for stakeholders in the construction and utilities sectors.

Technological advancements in robotics and sensor integration are further propelling the underground utility mapping robots market. The development of autonomous and semi-autonomous robots capable of navigating complex underground environments has revolutionized the utility mapping landscape. These robots leverage artificial intelligence, machine learning, and advanced data analytics to deliver precise mapping results with minimal human oversight. The integration of multiple sensing technologies, such as GPR, LiDAR, and electromagnetic locators, enables comprehensive subsurface analysis, providing a holistic view of underground utilities. As a result, end-users benefit from enhanced data accuracy, improved safety, and reduced operational risks, which are key factors contributing to the sustained growth of the market.

The adoption of Electromagnetic Utility Mapping Systems is becoming increasingly significant in the underground utility mapping robots market. These systems utilize electromagnetic fields to detect and map metallic utilities such as pipelines and cables with high precision. The integration of electromagnetic systems with robotic platforms enhances the efficiency and accuracy of utility mapping, particularly in urban areas with dense utility networks. As cities continue to expand and infrastructure becomes more complex, the demand for electromagnetic mapping solutions is expected to rise. These systems provide a non-invasive method of locating utilities, reducing the risk of accidental strikes and ensuring the safety of construction and maintenance activities. The ongoing advancements in sensor technology and data processing capabilities are further driving the adoption of electromagnetic utility mapping systems across various sectors.

From a regional p

In 2012, the CPUC ordered the development of a statewide map that is designed specifically for the purpose of identifying areas where there is an increased risk for utility associated wildfires. The development of the CPUC -sponsored fire-threat map, herein "CPUC Fire-Threat Map," started in R.08-11-005 and continued in R.15-05-006.

A multistep process was used to develop the statewide CPUC Fire-Threat Map. The first step was to develop Fire Map 1 (FM 1), an agnostic map which depicts areas of California where there is an elevated hazard for the ignition and rapid spread of powerline fires due to strong winds, abundant dry vegetation, and other environmental conditions. These are the environmental conditions associated with the catastrophic powerline fires that burned 334 square miles of Southern California in October 2007. FM 1 was developed by CAL FIRE and adopted by the CPUC in Decision 16-05-036.

FM 1 served as the foundation for the development of the final CPUC Fire-Threat Map. The CPUC Fire-Threat Map delineates, in part, the boundaries of a new High Fire-Threat District (HFTD) where utility infrastructure and operations will be subject to stricter fire‑safety regulations. Importantly, the CPUC Fire-Threat Map (1) incorporates the fire hazards associated with historical powerline wildfires besides the October 2007 fires in Southern California (e.g., the Butte Fire that burned 71,000 acres in Amador and Calaveras Counties in September 2015), and (2) ranks fire-threat areas based on the risks that utility-associated wildfires pose to people and property.

Primary responsibility for the development of the CPUC Fire-Threat Map was delegated to a group of utility mapping experts known as the Peer Development Panel (PDP), with oversight from a team of independent experts known as the Independent Review Team (IRT). The members of the IRT were selected by CAL FIRE and CAL FIRE served as the Chair of the IRT. The development of CPUC Fire-Threat Map includes input from many stakeholders, including investor-owned and publicly owned electric utilities, communications infrastructure providers, public interest groups, and local public safety agencies.

The PDP served a draft statewide CPUC Fire-Threat Map on July 31, 2017, which was subsequently reviewed by the IRT. On October 2 and October 5, 2017, the PDP filed an Initial CPUC Fire-Threat Map that reflected the results of the IRT's review through September 25, 2017. The final IRT-approved CPUC Fire-Threat Map was filed on November 17, 2017. On November 21, 2017, SED filed on behalf of the IRT a summary report detailing the production of the CPUC Fire-Threat Map(referenced at the time as Fire Map 2). Interested parties were provided opportunity to submit alternate maps, written comments on the IRT-approved map and alternate maps (if any), and motions for Evidentiary Hearings. No motions for Evidentiary Hearings or alternate map proposals were received. As such, on January 19, 2018 the CPUC adopted, via Safety and Enforcement Division's (SED) disposition of a Tier 1 Advice Letter, the final CPUC Fire-Threat Map.

Additional information can be found here.

Locations of electric utility substations in Vermont. The definition for substation varies, but it is typically thought of as a facility that includes a transformer to step voltage down from transmission or subtransmission voltage to distribution voltage, and also includes other ancillary facilities (such as voltage regulators and switches). This dataset was developed through inquiries of electric utilities,and each site was reviewed on the E-911 viewer for confirmation. PSD staff worked with the Vermont E-911 Board to correct information in the the E-911 ESITE address points layer The final data is an extract selection from the E-911 ESITE address points layer based on the Substation sitetype.DISCLAIMERVCGI and the State of VT make no representations of any kind, including but not limited to the warranties of merchantability or fitness for a particular use, nor are any such warranties to be implied with respect to the data.