The National Pipeline Mapping System (NPMS) Public Viewer enables the user to view NPMS pipeline, liquefied natural gas (LNG) plant and breakout tank data one county at a time, including attributes and pipeline operator contact information. The user can also view gas transmission and hazardous liquid pipeline accidents and incidents going back to 2002 for the entire US. NPMS pipeline data consists of gas transmission pipelines and hazardous liquid pipelines jurisdictional to the Pipeline and Hazardous Materials Safety Administration (PHMSA). It does not contain gas gathering or distribution pipelines, such as lines which deliver gas to a customer 's home. Therefore, not all pipelines in an area will be visible in the Public Viewer. As well, the breakout tank data is not complete as submission of that data is not a requirement. All NPMS data is for reference purposes only. It should never be used as a substitute for contacting a one-call center prior to excavation activities. Please call 811 before any digging occurs.

This data is a graphic representation of natural gas pipelines. The file has not been certified by a Professional Surveyor. This data is not suitable for legal purposes. The purpose of this data is to provide a generalized statewide view of natural gas pipelines.

This dataset is a compilation of available oil and gas pipeline data and is maintained by BSEE. Pipelines are used to transport and monitor oil and/or gas from wells within the outer continental shelf (OCS) to resource collection locations. Currently, pipelines managed by BSEE are found in Gulf of Mexico and southern California waters.

© MarineCadastre.gov This layer is a component of BOEMRE Layers.

This Map Service contains many of the primary data types created by both the Bureau of Ocean Energy Management (BOEM) and the Bureau of Safety and Environmental Enforcement (BSEE) within the Department of Interior (DOI) for the purpose of managing offshore federal real estate leases for oil, gas, minerals, renewable energy, sand and gravel. These data layers are being made available as REST mapping services for the purpose of web viewing and map overlay viewing in GIS systems. Due to re-projection issues which occur when converting multiple UTM zone data to a single national or regional projected space, and line type changes that occur when converting from UTM to geographic projections, these data layers should not be used for official or legal purposes. Only the original data found within BOEM/BSEE’s official internal database, federal register notices or official paper or pdf map products may be considered as the official information or mapping products used by BOEM or BSEE. A variety of data layers are represented within this REST service are described further below. These and other cadastre information the BOEM and BSEE produces are generated in accordance with 30 Code of Federal Regulations (CFR) 256.8 to support Federal land ownership and mineral resource management.

For more information – Contact: Branch Chief, Mapping and Boundary Branch, BOEM, 381 Elden Street, Herndon, VA 20170. Telephone (703) 787-1312; Email: mapping.boundary.branch@boem.gov

The REST services for National Level Data can be found here: http://gis.boemre.gov/arcgis/rest/services/BOEM_BSEE/MMC_Layers/MapServer

REST services for regional level data can be found by clicking on the region of interest from the following URL: http://gis.boemre.gov/arcgis/rest/services/BOEM_BSEE

Individual Regional Data or in depth metadata for download can be obtained in ESRI Shape file format by clicking on the region of interest from the following URL: http://www.boem.gov/Oil-and-Gas-Energy-Program/Mapping-and-Data/Index.aspx

Currently the following layers are available from this REST location:

OCS Drilling Platforms -Locations of structures at and beneath the water surface used for the purpose of exploration and resource extraction. Only platforms in federal Outer Continental Shelf (OCS) waters are included. A database of platforms and rigs is maintained by BSEE.

OCS Oil and Natural Gas Wells -Existing wells drilled for exploration or extraction of oil and/or gas products. Additional information includes the lease number, well name, spud date, the well class, surface area/block number, and statistics on well status summary. Only wells found in federal Outer Continental Shelf (OCS) waters are included. Wells information is updated daily. Additional files are available on well completions and well tests. A database of wells is maintained by BSEE.

OCS Oil & Gas Pipelines -This dataset is a compilation of available oil and gas pipeline data and is maintained by BSEE. Pipelines are used to transport and monitor oil and/or gas from wells within the outer continental shelf (OCS) to resource collection locations. Currently, pipelines managed by BSEE are found in Gulf of Mexico and southern California waters.

Unofficial State Lateral Boundaries - The approximate location of the boundary between two states seaward of the coastline and terminating at the Submerged Lands Act Boundary. Because most State boundary locations have not been officially described beyond the coast, are disputed between states or in some cases the coastal land boundary description is not available, these lines serve as an approximation that was used to determine a starting point for creation of BOEM’s OCS Administrative Boundaries. GIS files are not available for this layer due to its unofficial status.

BOEM OCS Administrative Boundaries - Outer Continental Shelf (OCS) Administrative Boundaries Extending from the Submerged Lands Act Boundary seaward to the Limit of the United States OCS (The U.S. 200 nautical mile Limit, or other marine boundary)For additional details please see the January 3, 2006 Federal Register Notice.

BOEM Limit of OCSLA ‘8(g)’ zone - The Outer Continental Shelf Lands Act '8(g) Zone' lies between the Submerged Lands Act (SLA) boundary line and a line projected 3 nautical miles seaward of the SLA boundary line. Within this zone, oil and gas revenues are shared with the coastal state(s). The official version of the ‘8(g)’ Boundaries can only be found on the BOEM Official Protraction Diagrams (OPDs) or Supplemental Official Protraction described below.

Submerged Lands Act Boundary - The SLA boundary defines the seaward limit of a state's submerged lands and the landward boundary of federally managed OCS lands. The official version of the SLA Boundaries can only be found on the BOEM Official Protraction Diagrams (OPDs) or Supplemental Official Protraction Diagrams described below.

Atlantic Wildlife Survey Tracklines(2005-2012) - These data depict tracklines of wildlife surveys conducted in the Mid-Atlantic region since 2005. The tracklines are comprised of aerial and shipboard surveys. These data are intended to be used as a working compendium to inform the diverse number of groups that conduct surveys in the Mid-Atlantic region.The tracklines as depicted in this dataset have been derived from source tracklines and transects. The tracklines have been simplified (modified from their original form) due to the large size of the Mid-Atlantic region and the limited ability to map all areas simultaneously.The tracklines are to be used as a general reference and should not be considered definitive or authoritative. This data can be downloaded from http://www.boem.gov/uploadedFiles/BOEM/Renewable_Energy_Program/Mapping_and_Data/ATL_WILDLIFE_SURVEYS.zip

BOEM OCS Protraction Diagrams & Leasing Maps - This data set contains a national scale spatial footprint of the outer boundaries of the Bureau of Ocean Energy Management’s (BOEM’s) Official Protraction Diagrams (OPDs) and Leasing Maps (LMs). It is updated as needed. OPDs and LMs are mapping products produced and used by the BOEM to delimit areas available for potential offshore mineral leases, determine the State/Federal offshore boundaries, and determine the limits of revenue sharing and other boundaries to be considered for leasing offshore waters. This dataset shows only the outline of the maps that are available from BOEM.Only the most recently published paper or pdf versions of the OPDs or LMs should be used for official or legal purposes. The pdf maps can be found by going to the following link and selecting the appropriate region of interest. http://www.boem.gov/Oil-and-Gas-Energy-Program/Mapping-and-Data/Index.aspx Both OPDs and LMs are further subdivided into individual Outer Continental Shelf(OCS) blocks which are available as a separate layer. Some OCS blocks that also contain other boundary information are known as Supplemental Official Block Diagrams (SOBDs.) Further information on the historic development of OPD's can be found in OCS Report MMS 99-0006: Boundary Development on the Outer Continental Shelf: http://www.boemre.gov/itd/pubs/1999/99-0006.PDF Also see the metadata for each of the individual GIS data layers available for download. The Official Protraction Diagrams (OPDs) and Supplemental Official Block Diagrams (SOBDs), serve as the legal definition for BOEM offshore boundary coordinates and area descriptions.

BOEM OCS Lease Blocks - Outer Continental Shelf (OCS) lease blocks serve as the legal definition for BOEM offshore boundary coordinates used to define small geographic areas within an Official Protraction Diagram (OPD) for leasing and administrative purposes. OCS blocks relate back to individual Official Protraction Diagrams and are not uniquely numbered. Only the most recently published paper or pdf

This geographic information system combines detailed information and location coordinates for oil wells, gas wells, and pipelines from the Commission's files with base map data captured from U.S. Geological Survey 7.5 minute quadrangle maps. These interactive maps were developed using Environmental Systems Research Institute, Inc. (ESRI) ArcIMS software, and interface with the Commission's Production Data Query and Drilling Permit Query applications.

This data depicts infrastructure locations for pipelines in Alaska as digitized primarily from 1:24,000, 1:63,360, and 1:250,000 USGS quadrangles. The source document that represented the newest information and best geographic location was used to capture the data. All infrastructure from the primary source document was digitized and then supplemented with the information from other source documents for additional or updated infrastructure or attributes.

The Crude Oil Pipelines dataset was updated on October 21, 2020 from the Energy Information Administration (EIA), with attribute data from the end of calendar year 2024 and is part of the U.S. Department of Transportation (USDOT)/Bureau of Transportation Statistics (BTS) National Transportation Atlas Database (NTAD). Major crude oil pipelines in the United States and selected crude oil pipelines in Canada as of January 2020. Layer includes interstate trunk lines and selected intrastate lines but excludes gathering lines. Based on publicly available data from a variety of sources with varying scales and levels of accuracy. This dataset is not intended to be viewed beyond 1:1,000,000 scale. A data dictionary, or other source of attribute information, is accessible at https://doi.org/10.21949/1520731

The Intermodal Freight Facilities Pipeline Terminals dataset was compiled on February 02, 2021 and was updated on April 21, 2021 from the Bureau of Transportation Statistics (BTS) and is part of the U.S. Department of Transportation (USDOT)/Bureau of Transportation Statistics (BTS) National Transportation Atlas Database (NTAD). Pipeline terminals interface between pipeline mode and other transportation modes. They have the ability to receive or deliver freight commodities via pipeline and truck/rail/water. The data consists of location information, truck/rail/water mode connections, storage capacity, and a list of commodities handled at the terminal. Geographical coverage includes the United States and U.S. territories. This dataset is one of several layers in the Bureau of Transportation Statistics (BTS) Intermodal Freight Facility Database. A data dictionary, or other source of attribute information, is accessible at https://doi.org/10.21949/1529033

Advanced Pipeline GIS Risk Visualization Market Outlook

According to our latest research, the global Advanced Pipeline GIS Risk Visualization market size reached USD 1.26 billion in 2024, reflecting the rapid adoption of GIS technologies for pipeline risk management. The market is poised for robust growth, with a projected CAGR of 12.7% from 2025 to 2033. By the end of the forecast period in 2033, the market is expected to achieve a value of USD 3.71 billion. This expansion is primarily driven by increasing regulatory demands, heightened safety awareness, and the integration of advanced analytics and AI into GIS platforms, which are transforming how pipeline operators visualize, assess, and mitigate risks across diverse infrastructure networks.

Growth in the Advanced Pipeline GIS Risk Visualization market is significantly fueled by the escalating need for real-time pipeline monitoring and risk management. As global energy demands rise and pipeline networks age, operators are under immense pressure to ensure the integrity and safety of critical assets. Advanced GIS visualization tools enable comprehensive mapping, spatial analytics, and predictive modeling, allowing pipeline operators to proactively identify potential threats such as corrosion, leaks, and unauthorized encroachments. The integration of IoT sensors, satellite imagery, and AI-driven analytics further enhances the accuracy and timeliness of risk detection, leading to a substantial reduction in incidents and operational downtime. This technological evolution is compelling industry stakeholders to invest heavily in modern GIS platforms, thereby driving sustained market growth.

Another pivotal growth factor is the tightening regulatory environment across key regions. Governments and industry bodies in North America, Europe, and Asia Pacific are mandating stringent compliance standards for pipeline safety and environmental protection. These regulations require pipeline operators to maintain detailed records, conduct regular risk assessments, and implement advanced monitoring systems. GIS-based risk visualization solutions are uniquely positioned to address these requirements by offering high-resolution data visualization, automated compliance reporting, and seamless integration with regulatory databases. As a result, regulatory compliance is not only a challenge but also a catalyst for digital transformation within the pipeline sector, accelerating the adoption of advanced GIS risk visualization tools.

The market is also benefiting from the growing trend of digital transformation and asset optimization within the oil & gas, water utilities, and chemical industries. Organizations are increasingly leveraging digital twins, cloud-based GIS platforms, and big data analytics to optimize asset performance, extend pipeline lifecycles, and minimize unplanned maintenance. The ability to visualize risk in a geospatial context empowers decision-makers to prioritize investments, allocate resources more effectively, and enhance overall operational resilience. This strategic shift toward data-driven asset management is expected to further amplify demand for advanced pipeline GIS risk visualization solutions in the coming years.

Regionally, North America continues to dominate the Advanced Pipeline GIS Risk Visualization market, accounting for the largest share in 2024, owing to its extensive pipeline infrastructure and proactive regulatory framework. However, Asia Pacific is emerging as the fastest-growing region, driven by rapid industrialization, expanding energy networks, and increasing investments in smart infrastructure. Europe, with its focus on environmental sustainability and pipeline modernization, also presents significant growth opportunities. Meanwhile, the Middle East & Africa and Latin America are gradually adopting advanced GIS solutions, supported by ongoing infrastructure development and the need for enhanced risk management in resource-rich regions.

Component Analysis

The Component segment of the Advanced Pipeline GIS Risk Visualization market is categorized into Software, Hardware, and Services. Software solutions represent the core of this market, encompassing GIS platforms, data analytics tools, and risk visualization applications. These platforms are increasingly leveraging artificial intelligence, machine learning, and real-time data integration to prov

The National Pipeline Mapping System (NPMS) is a geographic information system (GIS) created by the U.S. Department of Transportation, Pipeline and Hazardous Materials Safety Administration (PHMSA), Office of Pipeline Safety (OPS) in cooperation with other federal and state governmental agencies and the pipeline industry. The NPMS consists of geospatial data, attribute data, public contact information, and metadata pertaining to the interstate and intrastate hazardous liquid trunklines and hazardous liquid low-stress lines as well as gas transmission pipelines, liquefied natural gas (LNG) plants, and hazardous liquid breakout tanks jurisdictional to PHMSA.

Mobile GIS for Pipeline Field Crews Market Outlook

According to our latest research, the global Mobile GIS for Pipeline Field Crews market size reached USD 1.54 billion in 2024 and is projected to grow at a robust CAGR of 13.7% from 2025 to 2033, reaching a forecasted market size of USD 4.49 billion by 2033. This growth is primarily driven by the increasing adoption of digital technologies for real-time pipeline monitoring, the rising demand for efficient asset management, and stringent regulatory requirements for pipeline safety and environmental compliance across the globe.

One of the most significant growth factors in the Mobile GIS for Pipeline Field Crews market is the accelerating digital transformation initiatives within the oil and gas sector. Pipeline operators are increasingly leveraging mobile GIS solutions to enhance field productivity, reduce operational downtime, and improve data accuracy. The integration of advanced geospatial analytics, real-time mapping, and cloud-based data sharing has revolutionized how field crews manage inspection, maintenance, and emergency response activities. These technologies allow for seamless communication between field and office teams, ensuring that critical information is updated and accessible instantly. Furthermore, the growing prevalence of Internet of Things (IoT) sensors and unmanned aerial vehicles (UAVs) is complementing mobile GIS platforms, providing comprehensive situational awareness and enabling predictive maintenance strategies that minimize costly disruptions.

Another pivotal driver is the increasing regulatory scrutiny and emphasis on pipeline safety and environmental protection. Governments and regulatory bodies worldwide are imposing stricter compliance standards, mandating pipeline operators to maintain accurate records, conduct regular inspections, and promptly address potential leaks or hazards. Mobile GIS solutions empower field crews to efficiently document inspection results, capture geotagged images, and instantly report anomalies, thereby streamlining compliance reporting and audit processes. This not only mitigates operational risks but also enhances the reputation of pipeline operators by demonstrating a proactive approach to safety and sustainability. The adoption of mobile GIS is further accelerated by the need to manage aging pipeline infrastructure, where rapid identification and remediation of vulnerabilities are critical to preventing environmental incidents and ensuring uninterrupted energy supply.

The increasing complexity and scale of pipeline networks, coupled with mounting pressure to optimize operational efficiency, are also fueling the demand for mobile GIS solutions. As pipeline assets span vast and often remote geographical areas, traditional paper-based methods and manual data entry are proving inadequate and error-prone. Mobile GIS platforms enable field crews to access, update, and synchronize asset data in real time, regardless of their location. This capability not only reduces administrative overhead but also empowers organizations to make data-driven decisions, prioritize maintenance activities, and allocate resources more effectively. The rise of cloud-based deployment models has further democratized access to sophisticated GIS tools, allowing organizations of all sizes to leverage advanced analytics, improve collaboration, and scale their operations without significant upfront investments in IT infrastructure.

Regionally, North America continues to lead the Mobile GIS for Pipeline Field Crews market, driven by extensive pipeline infrastructure, high technology adoption rates, and stringent regulatory frameworks. However, rapid industrialization and expanding energy networks in Asia Pacific and the Middle East are expected to drive significant market growth in these regions over the next decade. Europe is also witnessing steady adoption, supported by ongoing modernization of utility infrastructure and a growing focus on environmental sustainability. Latin America and Africa are emerging as promising markets, albeit at a slower pace, as governments and industry players gradually embrace digital transformation to improve pipeline management and safety outcomes.

Contains the locations of existing residential buildings as well as known proposed and projected buildings (the pipeline). Projected numnber of units come from a number of sources, including first hand knowledge, newspaper articles and CoStar Property Information. Locations of buildings are tracked by the Downtown Detroit Partnership and updated with public announcements, building permits and other sources.

This is the metadata record for the Wyoming Pipeline Authority interactive pipeline map. You must be a current subscriber to the WPA in order to access this map.

Pipeline GIS Software Market Outlook

According to our latest research, the global Pipeline GIS Software market size reached USD 1.54 billion in 2024, reflecting the increasing integration of advanced geospatial technologies in pipeline management across various industries. The market is projected to grow at a robust CAGR of 11.2% from 2025 to 2033, ultimately reaching a value of USD 4.11 billion by 2033. This significant expansion is primarily driven by the rising demand for efficient pipeline monitoring, regulatory compliance, and asset management, as well as the increasing adoption of cloud-based solutions and digital transformation initiatives in the utilities, oil & gas, and water & wastewater sectors.

The primary growth factor for the Pipeline GIS Software market is the escalating need for real-time pipeline monitoring and management solutions. With the expansion of pipeline infrastructure globally, operators are increasingly seeking advanced Geographic Information System (GIS) software to enhance pipeline safety, minimize operational risks, and ensure regulatory compliance. The ability of GIS solutions to provide spatial visualization, remote monitoring, and predictive analytics significantly improves asset management and decision-making processes. As pipeline networks become more complex and geographically dispersed, the demand for robust GIS software capable of integrating with IoT sensors, SCADA systems, and other digital platforms continues to surge, further fueling market growth.

Another key driver is the rapid digital transformation occurring within the oil & gas, water & wastewater, and utilities sectors. Organizations in these industries are investing heavily in digital tools to optimize operations, reduce costs, and enhance sustainability. Pipeline GIS Software plays a crucial role in this transformation by enabling seamless data integration, real-time mapping, and automated inspection and maintenance scheduling. The shift towards predictive maintenance and data-driven asset management is prompting organizations to upgrade from legacy systems to advanced GIS platforms, thereby accelerating market expansion. Furthermore, the increasing focus on environmental stewardship and the need to mitigate pipeline leaks and failures are compelling operators to adopt sophisticated GIS solutions for proactive risk management.

The market is also benefiting from favorable regulatory frameworks and government initiatives aimed at improving pipeline safety and infrastructure resilience. Regulatory bodies across North America, Europe, and Asia Pacific are mandating stringent compliance standards for pipeline operators, including comprehensive mapping, inspection, and reporting requirements. These regulations are driving the adoption of Pipeline GIS Software as operators seek to streamline compliance processes, ensure accurate documentation, and facilitate transparent communication with stakeholders. Additionally, the advent of cloud-based GIS solutions is making advanced pipeline management tools more accessible to small and medium-sized enterprises, further broadening the market base and accelerating global adoption.

Regionally, North America continues to dominate the Pipeline GIS Software market due to its extensive pipeline infrastructure, early adoption of digital technologies, and stringent regulatory environment. However, the Asia Pacific region is emerging as the fastest-growing market, supported by rapid urbanization, expanding energy demand, and significant investments in pipeline construction and modernization. Europe also holds a substantial market share, driven by ongoing infrastructure upgrades and a strong emphasis on sustainability and environmental protection. Latin America and the Middle East & Africa are witnessing steady growth, fueled by increasing oil & gas exploration activities and government-led initiatives to enhance water and utility networks.

Component Analysis

The Component segment of the Pipeline GIS Software market is bifurcated into software and services, each playing a pivotal role in the overall ecosystem. The software component comprises the core GIS platforms that enable pipeline mapping, asset management, inspection, and regulatory compliance. These platforms are designed to integrate seamlessly with existing enterprise systems, IoT devices, and data analytics tools, providing a centralized hub for managing spatial and operational data. The demand for

In advance of design, permitting, and construction of a pipeline to deliver North Slope natural gas to out-of-state customers and Alaska communities, the Division of Geological & Geophysical Surveys (DGGS) has acquired lidar (light detection and ranging) data along proposed pipeline routes, nearby areas of infrastructure, and regions where significant geologic hazards have been identified. Lidar data will serve multiple purposes, but have primarily been collected to (1) evaluate active faulting, slope instability, thaw settlement, erosion, and other engineering constraints along proposed pipeline routes, and (2) provide a base layer for the state-federal GIS database that will be used to evaluate permit applications and construction plans. The digital surface model represents percent canopy cover (between 0 and 1). Cover metric was computed in Fusion (McGaughey 2007), which assesses the percentage of total first returns within each cell that were returned from the canopy. For more specifics on Fusion Gridmetric outputs see the fusion manual (page 56).

The route of the Trans-Alaska Pipeline was received from Alyeska Pipeline Service Company via the State Pipeline Coordinator's Office. The original projection was Transverse Mercator. Annotation for the pipeline was added by DNR via the annotation sub class 'PIPE'.

Written permission to include these data as part of the ADNR digital base map has been received from the Alyeska Pipeline Service Company.

Spatial distribution map of roads, railways and pipelines in China Mongolia Russia economic corridor from 1990 to 2020 1) Spatial data of highway, railway and pipeline in 1990; Spatial data of roads, railways and pipelines in China Mongolia Russia economic corridor in 2015; Spatial data of roads, railways and pipelines in China Mongolia Russia economic corridor in 2020; 2) Download the remote sensing images within the China Mongolia Russia economic corridor on NASA website and use arcgis10 2 software manual interpretation and extraction of highway and railway; Map elements are marked with the help of Russian atlas; The pipeline data shall be manually marked with reference to relevant maps; 3) The scale of the atlas is 1:2500000, which clearly reflects the changes of traffic and pipelines in the China Mongolia Russia economic corridor in recent 30 years,; 4) The data shows in detail the changes of traffic and pipelines in the China Mongolia Russia economic corridor in recent 30 years, which provides a data basis for the later study of the impact of traffic and pipeline construction on the change of ecological environment.

The National Pipeline Mapping System (NPMS) includes a geographic information system (GIS) dataset containing the location and selected attributes of gas transmission and hazardous liquid pipelines, liquefied natural gas (LNG) plants and breakout tanks (BOT) under jurisdiction of the Pipeline and Hazardous Materials Safety Administration (PHMSA). Effective October 1, 2015, pipeline and LNG plant data is collected annually from pipeline operators as required by 49 CFR §§ 191.29 and 195.61. This metadata is for the national pipeline dataset. There is NPMS pipeline data for all 50 states as well as the District of Columbia and Puerto Rico. The NPMS pipeline dataset contains gas transmission and hazardous liquid pipelines subject to regulations from PHMSA. The NPMS pipeline dataset does not contain gas gathering, gas distribution, or hazardous liquid lines not subject to 49 CFR § 195.61 and can never be used in place of contacting a one call center prior to digging. Distribution of NPMS data in GIS format is handled for PHMSA by the National Repository and is limited to pipeline operators and local, state, tribal, and federal government officials and is subject to data access limitations and agreements. Fulfillments of data requests will include data only for the area of jurisdiction of the person requesting the data (data requests are fulfilled per county/counties, state, or the entire U.S.). Instructions for requesting NPMS data in a GIS format are outlined on the NPMS website at www.npms.phmsa.dot.gov.

The Long Island Sound Submerged Cable and Pipeline Areas layer is a polygon feature-based layer that includes the location of submerged cable and/or pipeline areas in Long Island Sound. These can include, but are not necessarily limited to: electric transmission lines, telephone and/or fiber optic cables, natural gas and/or petroleum pipelines, etc. The layer is based on information from the 2002 edition of digital National Oceanic & Atmospheric Administration (NOAA) nautical charts provided by Maptech, Inc., a field survey completed by Ocean Surveys Inc (OSI) in 2002, and the proposed location of a pipeline from plans provided by Broadwater Energy in 2005. The Long Island Sound Submerged Cable and Pipeline Areas layer was originally created during the summer of 2002. The layer represents conditions at particular points in time. The layer includes representations of areas of underwater cables and/or pipelines. It does not include cable and/or pipeline areas landward of mean high water, nor does it include all possible submerged cables, pipelines, or other similar features. Features are polygon locations that represent the approximate or assumed location of cables and/or pipelines for the purpose of cartographic representation and general planning. Attribute information is comprised of codes to uniquely identify individual features, encode cable/pipeline type of information, and cartographically represent (symbolize) cable/pipeline features on a map. Data is compiled at 1:20,000 and 1:24,000 scale. This data is not planned for regular updates. Last updated 10/4/2005

Advanced Pipeline GIS Risk Visualization Market Outlook

As per our latest research, the global market size for the Advanced Pipeline GIS Risk Visualization Market reached USD 2.1 billion in 2024, reflecting robust momentum driven by the increasing demand for infrastructure safety and regulatory compliance. The market is expected to grow at a CAGR of 10.6% from 2025 to 2033, reaching a forecasted value of USD 5.2 billion by 2033. This growth is primarily propelled by the rising adoption of Geographic Information System (GIS) technologies in the pipeline sector, the need for proactive risk management, and stringent safety regulations across key industries.

The primary growth driver for the Advanced Pipeline GIS Risk Visualization Market is the escalating need for enhanced pipeline safety and risk management. With the expansion of oil & gas, water, and utility infrastructures globally, operators are under increasing pressure to ensure the integrity of their assets. GIS-based risk visualization solutions empower operators to monitor, analyze, and mitigate potential threats in real time, reducing the likelihood of catastrophic failures. The integration of advanced analytics, machine learning, and IoT sensors with GIS platforms has further amplified the accuracy and predictive capabilities of these solutions, enabling more informed decision-making and strategic planning for asset management.

Another significant factor fueling market growth is the tightening regulatory environment across multiple regions. Governments and regulatory agencies have imposed stringent guidelines and standards for pipeline monitoring, leak detection, and environmental protection. Compliance with such frameworks necessitates the deployment of sophisticated GIS risk visualization tools capable of providing comprehensive data integration, spatial analysis, and real-time reporting. As a result, pipeline operators are increasingly investing in these advanced technologies to avoid penalties, ensure operational continuity, and enhance public trust. Furthermore, the growing emphasis on environmental sustainability and the transition towards smart infrastructure are accelerating the adoption of GIS-based risk management solutions.

Technological advancements in GIS software and hardware have also played a pivotal role in market expansion. The evolution of cloud computing, the proliferation of mobile devices, and the advent of AI-powered analytics have transformed the capabilities of GIS risk visualization platforms. These innovations have made it possible for organizations to access and analyze vast amounts of spatial data from anywhere, facilitating collaboration among stakeholders and improving emergency response times. Additionally, the integration of 3D visualization, augmented reality, and remote sensing technologies is enhancing the user experience and providing deeper insights into pipeline risk scenarios. Such technological progress is expected to continue driving the market forward over the forecast period.

Regionally, North America remains the dominant market for Advanced Pipeline GIS Risk Visualization, accounting for a significant share of global revenue in 2024. This leadership is attributed to the region's mature pipeline infrastructure, high regulatory standards, and early adoption of digital technologies. However, Asia Pacific is emerging as a high-growth region, propelled by rapid industrialization, urbanization, and substantial investments in new pipeline projects. Europe follows closely, driven by modernization initiatives and a strong focus on environmental safety. Meanwhile, Latin America and the Middle East & Africa are witnessing gradual adoption, supported by infrastructure development and increasing awareness of pipeline safety. This regional diversification is expected to create new opportunities and intensify competition among solution providers.

Component Analysis

The Component segment of the Advanced Pipeline GIS Risk Visualization Market is

Abstract The Oil and Gas Pipelines Database contains known spatial locations of onshore and offshore pipelines or pipeline corridors used to transport natural gas, oil and other liquids within Australia’s mainland and territorial waters. Onshore pipelines are represented as polylines for Qld, NSW, Vic, Tas, and SA, and polygons/corridors for WA and NT. Offshore pipelines are represented as polylines for WA, NT and Vic. Pipeline data has been provided by Petrosys GPinfo as of 24 August 2022. More information available at www.gpinfo.com.au. No effort was made to revise, value add and/or spatially improve the datasets. For the purposes of this dataset a Pipeline is defined as: A linked series of pipes, with pumps and valves, used for the conveyance of gas, oil and liquids. For the purposes of this dataset a Corridor is defined as: A passage of land in which a pipeline and the facilities of a pipeline operator have the potential to transverse, including rights-of-way and easements over and through public or private property. Currency Date modified: 12 December 2022 Modification frequency: As needed The next revision of this database will be determined by Geoscience Australia’s work program. This timeframe will range between 3 and 5 years; this is also dependent upon available resources and other priorities. Data extent Spatial extent North: -9° South: -44° East: 154° West: 112° Temporal extent From 1 January 1970 to Present Source information The primary sources of information/data used to construct and validate entries within the Version 3 database were: Direct data download was captured on the 24 of August 2022 under the licencing agreement between Geoscience Australia (GA) and Petrosys GPinfo Catalog entry: Oil and Gas Pipelines Lineage statement Using pipeline datasets acquired from the States, Territories and NOPTA, the data was uploaded into an ArcSDE environment using Feature Manipulation Engine (FME). The process included the extraction of the themed (gas pipeline and oil pipeline) features, and the translation of the data into a schema created by, National Location Information Branch, Geoscience Australia (GA). Data download: Mar 2015: - Public release of GAs Onshore Gas Pipelines Database Version 1 - Public release of GAs Onshore Oil Pipelines Database Version 1 Mar 2017: - Public release of GAs Gas and Oil Pipelines Database Version 2 Aug 2022: - Public release of GA’s Oil and Gas Pipelines Database – Version 3 Web Service: Feb 2015: - Public release of GA’s Onshore Gas Pipelines web service – Version 1 - Public release of GA’s Onshore Oil Pipelines web service – Version 1 Feb 2016: - Public release of GA’s National Oil and Gas Infrastructure web service – Version 1 Dec 2022: - Public release of GA’s Onshore Oil Pipelines web service – Version 3 Data dictionary All layers

Attribute name Description

NAME The name of each individual feature

DATE_DOWNLOADED The date when the data was downloaded as part of the licencing agreement

FEATURE_TYPE A description of this feature’s type (Pipeline, Corridor)

LENGTH Total length of pipeline - kilometres

LICENSE The licence type in which data can be used

OPERATIONAL_STATUS The operational status as define by GP INFO

SOURCE The source of the data of whom the licencing agreement is with

SPATIAL_CONFIDENCE A confidence value (5 = high to 0 = low) of the feature’s spatial location as assigned by the spatial professional

STATE State or Territory where pipeline segment is located

Contact Geoscience Australia, clientservices@ga.gov.au