Enhancing Gas Pipeline Management with GIS: Key Benefits and Applications

In the energy and utilities sector, gas pipeline management is complex, requiring precision, safety, and a clear strategy for both existing infrastructure and future expansion. Geographic Information Systems (GIS) have revolutionized pipeline management by providing a spatially accurate, data-rich view of assets. From asset management and leak detection to route planning and demand forecasting, GIS is becoming indispensable for gas companies. This blog delves into the ways GIS transforms gas pipeline management, delivering benefits across safety, efficiency, cost-saving, and planning.

How 3D Vector Maps Assist in Managing Large-Scale Infrastructure Projects

The Unseen Backbone: How 3D Vector Maps Assist in Managing Large-Scale Infrastructure Projects

Large-scale infrastructure projects – think new railway lines, sprawling urban developments, extensive utility networks, or critical flood defense systems – are among the most complex undertakings imaginable. They involve colossal budgets, diverse stakeholders, multi-disciplinary teams, and timelines stretching over years, if not decades. Traditionally, managing these behemoths relied on intricate 2D blueprints, complex GIS data, and often, sheer human experience. While effective to a degree, these methods often struggle to convey the holistic picture, leading to communication gaps, potential clashes, and slower decision-making.

In this intricate dance of engineering and planning, 3D Vector Maps have emerged as a revolutionary tool, transforming how infrastructure projects are conceived, managed, and communicated. Far beyond a simple topographical view, these dynamic digital environments provide an unparalleled level of clarity and spatial understanding, making them an indispensable asset for project managers navigating the complexities of modern development.

Know The Visual Power of 3D Vector Maps

What exactly are 3D Vector Maps, and why are they so effective? Unlike raster images (which are pixel-based), vector maps are built from mathematical paths, allowing for infinite scalability without loss of detail. When extruded into the third dimension, these maps bring elevation, existing structures, and proposed designs into a lifelike, interactive environment. This allows for an intuitive understanding of terrain, urban fabric, and how new infrastructure will integrate with the existing world.

The ability to render precise spatial relationships, coupled with the inclusion of environmental data, turns these maps into powerful visualization platforms. A well-executed 3D Map Illustration can highlight not just the proposed road, but also its impact on surrounding buildings, elevation changes, and even potential view obstructions, providing a holistic perspective that 2D plans simply cannot offer.

Enhance Project Planning and Design

The benefits of integrating 3D Vector Maps permeate every phase of a large-scale infrastructure project:

Comprehensive Site Analysis and Environmental Impact: 

Before any ground is broken, understanding the project site is paramount. 3D Vector Maps provide an incredibly detailed digital terrain model, allowing engineers and planners to analyze elevation changes, existing geological features, water bodies, and vegetation. This is crucial for precise excavation planning, identifying potential environmental sensitivities, and ensuring compliance with regulations. The ability to overlay environmental data directly onto the 3D terrain provides immediate insights into how a proposed highway extension, for instance, might affect local hydrology or wildlife habitats. This level of comprehensive pre-visualization significantly reduces unforeseen challenges later on.

Optimized Route and Infrastructure Planning: 

For linear projects like roads, pipelines, or transmission lines, 3D Vector Maps are invaluable for route optimization. Engineers can virtually test multiple alignments, assessing factors like cut-and-fill volumes, bridge requirements, tunneling feasibility, and proximity to existing utilities or properties. This iterative design process within a 3D environment allows for the most efficient and cost-effective solutions to be identified before significant resources are committed.

Precise Clash Detection and Coordination: 

Large infrastructure projects involve multiple layers: underground utilities (water, gas, fiber optics), foundations, structural elements, and above-ground components. 3D Vector Maps can integrate data from various engineering disciplines (BIM models, CAD drawings) to visually identify potential conflicts or overlaps between different elements. This pre-emptive identification of clashes – for example, a new foundation interfering with an existing sewer line – saves immense time, cost, and rework during the construction phase. The visual clarity offered by an Architecture Illustration that highlights these potential conflicts is indispensable.

Bridging Communication Gaps and Fostering Stakeholder Engagement

One of the most significant challenges in large infrastructure projects is communicating complex plans to a diverse audience, many of whom lack technical backgrounds. 3D Vector Maps excel in this area:

Clearer Presentations for Non-Technical Audiences: 

Explaining the intricate details of a new metro line or a large-scale bridge to investors, public officials, or community members can be daunting with only spreadsheets and technical drawings. 3D Vector Maps transform these abstract plans into compelling visual narratives. Stakeholders can literally "fly through" the proposed project, see it integrated into their city, and understand its impact from various perspectives. This clarity fosters trust and makes it easier to secure approvals and funding.

Effective Public Consultation and Engagement: 

Community acceptance is vital for major infrastructure projects. Residents can see how a proposed road widening might affect their neighborhood, visualize changes to park spaces, or understand noise mitigation measures. This transparency, often presented as a clear 3D Map Illustration, allows for more informed feedback from the public, leading to designs that better serve community needs and reduce opposition.

Streamlining Construction, Operations, and Future Asset Management

The utility of 3D Vector Maps extends far beyond the planning and design phases:

Optimized Construction Logistics: 

During construction, the maps can be used for logistical planning, optimizing the placement of heavy machinery, material laydown areas, and temporary access roads. Real-time data from construction progress can be overlaid onto the 3D model, providing project managers with an up-to-the-minute visual of the build, helping to keep projects on schedule and within budget.

Dynamic Asset Management: 

Once constructed, large-scale infrastructure assets require continuous management and maintenance. 3D Vector Maps serve as dynamic "digital twins" of these assets. Information about utility lines, bridge inspection data, maintenance schedules, and even sensor readings (e.g., from smart city infrastructure) can be integrated and visualized on the map. This provides a comprehensive, living record of the infrastructure, vastly improving long-term operational efficiency and emergency response capabilities.

Predictive Analysis and Simulation: 

With rich data integrated into 3D Vector Maps, projects can move into predictive analysis. Engineers can simulate traffic flow on new road networks, model flood scenarios to test defense systems, or analyze the impact of different urban planning decisions over time. This foresight allows for proactive problem-solving and the creation of more resilient, future-proof infrastructure. The visual impact of such simulations through a detailed 3D Map Illustration is unparalleled.

The Role of Specialized Expertise

Creating and managing these sophisticated 3D Vector Maps requires specialized expertise. Companies offering these services leverage advanced GIS software, 3D modeling tools, and often integrate with Building Information Modeling (BIM) data. The process involves meticulous data collection, precision modeling, and skilled Architecture Illustration to ensure both technical accuracy and visual clarity.

Conclusion

In the era of increasingly complex and ambitious infrastructure projects, the demand for tools that foster clarity, efficiency, and seamless collaboration is paramount. 3D Vector Maps are proving to be that essential tool, transforming how projects are conceived, designed, built, and managed. By providing an unparalleled visual understanding of terrain, proposed structures, and integrated data, they empower project managers to make smarter decisions, bridge communication gaps among global teams, and engage stakeholders more effectively. From initial planning and precise 3D Map Illustration to long-term asset management, these digital models are not just a visualization enhancement – they are the unseen backbone ensuring the successful delivery of the infrastructure that shapes our world.

What Does a Surveyor Do for Infrastructure Planning? Key Contributions

Infrastructure planning is a complex and critical process that requires precise and reliable data. What does a surveyor do for infrastructure planning? This question is fundamental to understanding how large-scale projects—from roads and bridges to utilities and urban developments—are successfully designed and executed. Surveyors play a pivotal role in providing accurate measurements, mapping, and spatial information that form the foundation of sound infrastructure development.

Understanding the Role of a Surveyor in Infrastructure Planning

A surveyor is a professional trained in the science of measuring and mapping land, buildings, and natural features. In infrastructure planning, surveyors gather essential data that informs engineers, architects, planners, and contractors, ensuring projects are viable, safe, and compliant with regulations.

Precise Land Measurement and Boundary Identification

One of the most critical tasks surveyors perform is precise land measurement. Knowing the exact dimensions and boundaries of a site is fundamental to planning infrastructure projects. This ensures that developments do not encroach on private property or protected lands and helps avoid costly legal disputes.

Surveyors use advanced tools such as GPS, total stations, and drones to capture high-resolution data. Their work determines property lines, easements, and rights-of-way—information crucial for positioning infrastructure elements like roads, pipelines, and utility networks.

Topographical Surveys and Terrain Analysis

Infrastructure projects often require detailed knowledge of the land’s topography. Surveyors conduct topographical surveys to map the natural and man-made features of the terrain, including elevations, slopes, and existing structures.

This data enables planners to design projects that work with the landscape, minimize environmental impact, and optimize construction methods. For example, road designers use contour data to plan routes that avoid steep grades or flood-prone areas, reducing long-term maintenance costs and enhancing safety.

Subsurface Utility Engineering (SUE)

A lesser-known but vital aspect of a surveyor’s work in infrastructure planning is subsurface utility engineering. This involves locating and mapping underground utilities such as water pipes, electrical cables, gas lines, and telecommunications infrastructure.

Identifying these utilities before construction begins helps prevent accidents, service interruptions, and expensive repairs. It also aids in designing infrastructure layouts that avoid conflicts with existing underground services, ensuring smoother project execution.

Contribution to Regulatory Compliance and Risk Management

Surveyors also play a crucial role in ensuring infrastructure projects meet regulatory standards. Accurate surveying supports compliance with zoning laws, environmental regulations, and building codes.

By providing reliable data, surveyors help project teams assess risks related to land ownership, environmental constraints, and potential hazards. This proactive approach minimizes delays and budget overruns caused by unforeseen issues.

Enhancing Project Planning and Stakeholder Communication

Infrastructure planning involves multiple stakeholders, including government agencies, private developers, and local communities. Surveyors create detailed maps, plans, and reports that facilitate clear communication among these parties.

High-quality surveying data helps stakeholders visualize the project, understand spatial relationships, and make informed decisions. This transparency is essential for gaining approvals, securing funding, and maintaining public trust.

Technological Innovations in Surveying for Infrastructure

The surveying profession has evolved significantly with technology. Modern surveyors employ Geographic Information Systems (GIS), 3D laser scanning, and drone technology to collect and analyze data more efficiently and accurately.

These innovations enhance the ability to model infrastructure projects virtually, conduct impact assessments, and plan construction phases with greater precision. As a result, infrastructure projects can be optimized for cost, safety, and sustainability.

Conclusion

Understanding what does a surveyor do for infrastructure planning reveals the indispensable nature of surveying in the successful delivery of infrastructure projects. Surveyors provide the foundational data needed for accurate design, legal compliance, risk management, and stakeholder collaboration. Their expertise ensures that infrastructure development proceeds smoothly, safely, and sustainably, supporting the growth and well-being of communities across Australia.

Accurate and comprehensive surveying remains a cornerstone of effective infrastructure planning, highlighting the value of skilled surveyors in shaping the built environment.

Bathymetric : An Overview of Underwater Mapping | Epitome

In a world increasingly reliant on precise geospatial data, bathymetry surveys stand out as an indispensable tool for understanding the hidden landscapes beneath bodies of water. From enhancing maritime navigation to aiding scientific research and supporting infrastructure development, bathymetric surveys serve as the cornerstone for any project requiring detailed information about underwater topography.

This blog delves into the essence of bathymetry surveys, why they are vital, and how modern technology has redefined the way we map the seafloor.

What is a Bathymetric ?

Bathymetric is the study and mapping of the underwater features of oceans, seas, rivers, and lakes. A bathymetry survey involves the measurement of the depth of water bodies to determine the shape and features of the seabed or riverbed. It is essentially the aquatic counterpart to topography and involves collecting depth data and converting it into charts or 3D models.

Why Bathymetric Surveys Matter

Accurate bathymetric data is critical across a wide range of industries and applications:

Maritime Navigation: Helps ensure safe passage for ships by identifying shallow areas, submerged obstacles, and underwater channels.

Dredging Projects: Provides pre- and post-dredging data to guide excavation and verify results.

Flood Modeling and Risk Management: Supports hydrological modeling and floodplain mapping for better disaster planning.

Environmental Studies: Assists in assessing aquatic habitats, sediment transport, and underwater ecosystems.

Infrastructure Development: Informs the design and placement of bridges, pipelines, ports, and offshore structures.

How Bathymetric Surveys Are Conducted

Modern Bathymetric surveys employ various technologies to capture precise data:

Single-Beam Echo Sounders (SBES): Emit a single sonar beam directly below the survey vessel to measure depth. Ideal for smaller, simpler projects.

Multi-Beam Echo Sounders (MBES): Offer broader coverage by emitting multiple sonar beams, allowing high-resolution mapping of large areas quickly and accurately.

LiDAR (Light Detection and Ranging): Airborne systems that use lasers to map shallow coastal waters, combining bathymetric and topographic data.

Side Scan Sonar: Provides detailed images of the seafloor's texture and structure, often used alongside MBES for comprehensive analysis.

GPS and Motion Sensors: Integrated to enhance the accuracy of positional and depth data, compensating for vessel movement and water currents.

The Epitome of Precision and Technology

Today’s bathymetry surveys are not just about depth—they’re about data accuracy, spatial resolution, and the ability to visualize the unseen. The use of real-time kinematic positioning (RTK), autonomous surface vessels (ASVs), and advanced data processing software ensures that surveys deliver pinpoint precision. High-definition 3D models and GIS integration allow stakeholders to make informed decisions faster and more confidently.

Applications Across Industries

Whether it’s for offshore wind farms, marine construction, coastal management, or pipeline routing, bathymetry surveys play a pivotal role. Ports and harbors rely on them for dredging and safe navigation. Oil and gas companies use them for subsea asset installation. Governments depend on them for environmental monitoring and disaster resilience.

Conclusion

A bathymetry survey is far more than just measuring water depths—it's the epitome of underwater spatial intelligence. As technology evolves, these surveys continue to unlock new frontiers beneath the surface, offering insights that drive safety, innovation, and sustainability. Whether you're an engineer, scientist, or policymaker, understanding the power of bathymetric data is crucial for any venture touching the water.

Dimensional Control Survey Services 

Dimensional Control Survey Services: Precision That Powers Modern Industry

In the complex world of engineering, construction, and manufacturing, precision isn’t just a preference—it’s a necessity. Whether aligning massive offshore platforms, verifying the position of structural steel in skyscrapers, or assembling high-tolerance equipment in aerospace, accuracy can mean the difference between success and costly rework. This is where Dimensional Control Survey Services play a crucial role.

These services are designed to ensure that every component of a project—no matter how large or intricate—is positioned and constructed exactly as intended. With the help of advanced technology and proven measurement methodologies, dimensional control survey services provide the confidence industries need to move forward with precision.

What Are Dimensional Control Survey Services?

Dimensional control survey services refer to the application of highly accurate measurement techniques to verify and align physical components according to design specifications. Unlike general land surveying, which might focus on mapping property lines or topography, dimensional control specializes in the precise spatial positioning of structures, systems, and equipment.

These services are used in settings where tolerances are tight and accuracy is critical. They ensure that fabricated parts, structural assemblies, and installed systems fit together perfectly, preventing errors that can delay projects, compromise safety, or increase costs.

Industries That Depend on Dimensional Control

A wide range of industries rely on dimensional control survey services, including:

Oil and Gas In offshore and onshore environments, dimensional control is essential for platform installation, module alignment, and pipeline routing. These projects require millimeter-level accuracy to ensure safety and structural integrity under harsh conditions.

Construction and Infrastructure Large-scale building projects often involve prefabricated components and complex geometries. Dimensional control helps ensure everything fits correctly during assembly—especially in high-rise buildings, bridges, stadiums, and industrial plants.

Aerospace and Defense In industries where performance and safety standards are non-negotiable, dimensional control supports quality assurance during manufacturing, assembly, and inspection processes.

Shipbuilding and Maritime From hull construction to engine alignment, dimensional control enables the accurate fitting of components and systems on vessels of all sizes.

Renewable Energy Wind turbines and solar arrays require exact positioning to optimize performance. Dimensional control survey services ensure proper alignment, especially in offshore installations.

Heavy Equipment Manufacturing Complex assemblies such as turbines, pressure vessels, and large machinery parts need to meet precise tolerances. Survey services help verify alignment during manufacturing and installation.

How Dimensional Control Works

Dimensional control survey services follow a systematic process that includes planning, measurement, analysis, and reporting:

Planning and Setup Surveyors begin by establishing reference points or control grids based on design drawings and engineering requirements. These control points form the basis for all measurements.

Data Acquisition Using advanced equipment like total stations, 3D laser scanners, photogrammetry tools, and laser trackers, surveyors capture exact spatial data about structures or components. These instruments offer sub-millimeter precision.

Data Processing and Analysis Collected data is processed through specialized software to compare actual measurements with design specifications. Deviations, if any, are identified and quantified.

Reporting and Recommendations A detailed report is generated, often with 3D models or visual overlays, showing the current condition of the structure or system relative to the intended design. If corrections are needed, the survey team provides adjustment instructions.

Key Technologies Used in Dimensional Control Surveying

Total Stations Combining electronic distance measurement and angle measurement, total stations are used to collect precise point data in 2D or 3D space.

Laser Scanners 3D laser scanners capture millions of data points quickly, creating high-resolution point clouds that represent the measured environment in detail.

Laser Trackers These portable instruments are often used in industrial environments for measuring large components with extreme accuracy.

Photogrammetry Using high-resolution photographs to reconstruct accurate 3D models, this method is valuable for both documentation and measurement.

CAD Integration Modern survey services integrate directly with Computer-Aided Design (CAD) software, enabling a seamless comparison between as-built and as-designed models.

Benefits of Dimensional Control Survey Services

Accuracy and Precision Dimensional control ensures that construction and assembly are performed to exact specifications, minimizing rework and error.

Time and Cost Savings Identifying potential misalignments or discrepancies early in the process reduces costly delays and material waste.

Improved Safety By ensuring proper alignment and structural integrity, these services reduce the risk of failure during or after construction.

Quality Assurance Dimensional control adds an extra layer of verification that helps maintain the high standards required in industries like aerospace and energy.

Digital Documentation Survey results are stored in digital formats, enabling future reference, maintenance planning, and compliance documentation.

Challenges in Dimensional Control Surveying

Although dimensional control survey services offer undeniable benefits, they also come with challenges:

Complex Environments Crowded job sites, poor lighting, and weather conditions can impact the ease and accuracy of measurement.

Technical Expertise Operating advanced surveying instruments and interpreting the data correctly requires specialized training and experience.

Integration with Other Systems Ensuring smooth communication between field data and design software is critical for accurate comparisons and adjustments.

Cost of Equipment High-end laser scanners and trackers are expensive, and maintaining them to ensure accuracy requires ongoing investment.

The Future of Dimensional Control Surveying

As technology advances, dimensional control survey services are poised to become even more precise, efficient, and integrated. Future trends include:

Automation and Robotics Robotic systems will increasingly take on repetitive or hazardous measurement tasks, improving safety and consistency.

Real-Time Monitoring Using sensors and IoT technology, engineers will be able to track structural changes in real time, enabling predictive maintenance and early intervention.

Artificial Intelligence AI algorithms will help process survey data faster, identify errors automatically, and suggest optimal correction strategies.

Virtual and Augmented Reality VR and AR tools will allow engineers and clients to visualize survey data interactively, enhancing collaboration and decision-making.

Conclusion

Dimensional control survey services are the unsung heroes of precision-driven industries. They ensure that what’s built in the field matches what’s designed on paper—down to the last millimeter. From massive offshore platforms to finely tuned manufacturing assemblies, these services reduce errors, enhance safety, and uphold the highest standards of quality and efficiency.

As industries continue to evolve and embrace digital transformation, the demand for dimensional control will only grow. Investing in these services is more than a measure of precision—it’s a commitment to excellence, sustainability, and the future of modern engineering.

Distributed Temperature Sensing Market Size Projected To Reach $55 Billion By 2025

The global distributed temperature sensing market size is anticipated to reach USD 849.0 million by 2025, according to a new report by Grand View Research, Inc. It is expected to exhibit a CAGR of 10.7% from 2019 to 2025.

In the Distributed Temperature Sensing (DTS) the optical fiber are used as a sensor. The operators can receive information related to temperature after installing such sensors in the fiber cable. The adoption of these sensors has increased rapidly in recent years due to their cost advantages. The DTS uses standard telecoms fiber, thereby requiring no special sensors, and thus saving cost. The cost of material, system design, installation, and maintenance are very low for these sensors, which in turn is projected to positively influence the market growth.

DTS offer fully distributed data, which minimized uncertainties and increased the amount of information received. In addition, these sensors offer very high reliability along with immunity to electromagnetic interference and shock/vibration. Also, distributed temperature sensing can be easily used in space-restricted areas. It also offer other advantages, such as high-temperature performance, long measuring ranges, high-temperature resolutions.

Various advantages of DTS contribute to its adoption across various industrial applications. Distributed temperature sensing is used for long length applications, such as in power cables, tunnels, and pipelines. The oil and gas segment are expected hold majority of the market share by 2025. The oil well industries are prominent customers, owing to its small size and easy accessibility of DTS. The safety and security segment is expected to register the fastest CAGR over the forecast period, due to substantial use of DTS in safety-critical applications where all points need to be monitored is also observed. These critical applications include electrochemical processes, LNG plants, and refineries.

To request a sample copy or view summary of this report, click the link below: www.grandviewresearch.com/industry-analysis/distributed-temperature-sensing-market

Further key findings from the report suggest:

Optical Time Domain Reflectometry (OTDR) is anticipated to continue holding the largest market share over the forecast period, owing to high usage of OTDR as it offers robust measurements

The multi-mode fiber is projected to hold a high market share in near future. This type of fiber has better ability to launch more power than single-mode fiber, which is expected to drive the growth

Benefits such as high spatial density and distributed temperature profile provided by a distributed temperature sensing are driving the growth of market

Asia Pacific is expected to register significant growth over the forecast period, owing to the rising adoption of cost efficient and reliable temperature measuring solutions

Key market players areSilixa Ltd, AP Sensing GmbH, NKT Photonics A/S, Bandweaver, Sensornet Limited, OFS Fitel, LLC., Schlumberger Limited, Halliburton, OPTROMIX, and Yokogawa Corporation of America

Grand View Research has segmented the global distributed temperature sensing market based on operating principle, fiber type, application, and region:

Distributed Temperature Sensing Operating Principle Outlook (Revenue, USD Million, 2014 - 2025)

Optical Time Domain Reflectometry (OTDR)

Optical Frequency Domain Reflectometry (OFDR)

Distributed Temperature Sensing Fiber Type Outlook (Revenue, USD Million, 2014 - 2025)

Single-Mode Fiber

Multi-Mode Fiber

Distributed Temperature Sensing Application Outlook (Revenue, USD Million, 2014 - 2025)

Oil and Gas

Power and Utility

Safety and Security

Industrial

Civil Engineering

Distributed Temperature Sensing Regional Outlook (Revenue, USD Million, 2014 - 2025)

North America

Europe

Asia Pacific

South America

Middle East and Africa

U.S.

Canada

Mexico

Germany

U.K.

France

China

Japan

India

Brazil

About Grand View Research

Grand View Research, Inc. is a U.S. based market research and consulting company, registered in the State of California and headquartered in San Francisco. The company provides syndicated research reports, customized research reports, and consulting services. To help clients make informed business decisions, we offer market intelligence studies ensuring relevant and fact-based research across a range of industries, from technology to chemicals, materials and healthcare.

Basic Uses of GIS in Different Sectors

A geographic information system is a computer system that can help individuals and organizations better understand spatial patterns and relationships by relating seemingly unrelated data. It is used by a number of different sectors. Determining the optimum site location for retail outlets, manufacturing plants, etc. is a key function of geographic business analysis. This uses demographics such as income, population breakdown, etc. to target geographic product preferences and marketing campaign strategies. It helps you to record a base map with a geospatial referencing system. A Few of the Advantages of GIS Applications - •It provides effective and better decision-making about the location which is strategic to the success of an organization. •It helps to enhance communication between departments, professional fields, organizations, and the public. •It can provide a strong framework for managing systems with full transaction support and reporting tools. •It leads to cost savings and has definitely improved customer service, reducing the number of return visits.                       GIS Mapping Services: The mapping and analysis of the environment covers a broad range of services using geospatial data, such as:- •Mapping and analyzing land usage relative to geographic features •Identifying and mapping the best lands for species habitat conservancy. •Choosing the best lands for agricultural purchase. Also, development in a region based on a number of geographic selection criteria, etc. •Preparing maps of species distribution, soil types and analyzing zoning, terrain, vegetation.

  Geopolitical and Community Mapping: It involves the preparation of reference maps to show the geospatial distribution of specific features in a selected area including:- •Area of government facilities, hospitals, and emergency facilities, etc. •Location and area covered by school districts, city wards. •Geopolitical and community mapping and Geospatial relationship between districts •The Services Offered In Infrastructure Mapping:   It involves establishing accurate coordinate locations of point features of a network. This includes electric transfer stations and towers and the lines that connect them to a power grid and creating databases. From this, reference maps and lookup tables can be produced. Such Databases and Reference Maps Are Typically Produced For: •Electric power grids showing the location of transfer stations and power towers. Also, poles, transmission lines, and property boxes. •Communication networks showing the location of cell phones and communication towers. •Water and Sewer Systems displaying the location of pumping stations and treatment plants. •Pedestrian networks showing the location of sidewalks, traffic lights, and crosswalks. •Natural Gas distribution networks indicating the location of pumping stations, pipelines, and customer points. The GIS Mapping and Analysis of Transportation: This includes location and hierarchy of roads, rail lines, airports to complex maps combining reference and thematic maps. It may help with services such as: •For preparing reference maps of transit networks showing the location of routes, stations, and stops. •For creating combined thematic maps analyzing the source, and route pattern of commuter traffic from survey data. •Creating combined thematic maps analyzing the source and creating a distribution network and channel. •Developing thematic maps analyzing accident rates, traffic patterns. Urbanismo Consultants Pvt. Ltd’s GIS Mapping experts provide high-quality GIS and Mapping services for different planning and turnkey projects. We have dedicated and committed GIS experts to meet all your GIS and Mapping Needs.

GIS and Remote Sensing- Application in Pipeline Route Selection in Oil and Gas Industry

Route selection for optimal location is a foremost and crucial step in the overall pipeline design and construction process and also minimizing economic cost. GIS technologies can be used effectively in route determination process. Various thematic layers such as landslide, slope, geology, land use, soil, stream, lithology, road, culture and protected areas can be generated and integrated using RS-GIS techniques. ArcGIS Spatial Analysis module plays its part to convert these data layers into raster format to perform queries and analyses and finally obtain the shortest and the least cost path. In short, GIS-RS techniques can be deployed, integrating the human, environmental and financial factors, to obtain the best cost effective pipelines routes. 

 SATPALDA is a certified leading provider of geospatial products and services. The company is also a reseller of multiple satellite data products and has a proven track record of delivering project-critical geospatial products, including satellite imagery, UAV imagery, elevation models, LULC maps, Planimetry, terrain solutions. For more details, visit www.satpalda.com.

Global Satellite Data Services Market By Region – Opportunities and Forecast, 2019-2026

This detailed market study covers satellite data services market growth opportunities and competitive scenarios, which can assist the stakeholders in understanding market trends and prospects in the satellite data services market. The market report focuses on data from a combination of primary and secondary sources and analyses the information using numerous tools. The research report also offers a detailed analysis of each segment in the satellite data service and evaluates the impact of the COVID-19 outbreak on the industry.

Satellite Data Services Market Competitive Rivalry

The market report includes an analysis of the competitive landscape present in the industry. It consists of an assessment of the existing and ongoing trends that players can invest in. The notable players in the global satellite data services market are Harris Geospatial Solutions, Inc., Geospatial Intelligence Pyt. Ltd., Earth-i Ltd., Planet Labs, Inc., Land Info Worldwide Mapping, Satellite Imaging Corporation, Ursa Space Systems, Airbus SE, Digitalglobe, Inc., Satpalda Geospatial Services, Imagesat International (ISI), and Gisat S.R.O., among others.

Satellite Data Services Market Drivers

The significant factors contributing to the growth of the global satellite data services market include the rising number of advancements in geospatial imagery analytics and the increasing implementation of Artificial Intelligence (AI), Machine Learning (ML), and big data, privatization of space industry, and growth of cloud computing. Machine Learning (ML) algorithms provide efficient tools for analyzing satellite imagery and applicable insights. In addition to this, the accelerating demand for satellite imaging for agriculture, increasing penetration of technology such as IoT and data analytics to retrieve data, and the growing requirement to understand environmental impact on a global scale are certain factors that are responsible for the expansion of the satellite data services market size.

The strong demand for satellite data among enterprises to ensure their market competitiveness and implementation of 4D GIS software with satellite data is boosting the growth of the market over the forecast period. On the other edge, numerous stringent government regulations for the implementation of satellite and the lack of dedicated launch vehicles for small satellites are likely to restrain the growth of the market.s

Satellite Data Services Market Segmentation

The chapter of segmentation provides the readers with an overview of the global satellite data services market, such as its products, applications, and other relevant factors of the industry. Understanding the market segments helps in identifying the importance of different factors that surges market growth over the forecast period (2020-2027).

Segment by Service:

Image Data

Data Analytics

Spatial

Spectral

Temporal

Radiometric

Very High Resolution

High Resolution

Medium-Low Resolution

Image Data Processing

Feature Extraction

Digital Models

Classification

Pan-Sharpening

Orthorectification

Mosaicking

Cloud Patching

Digital Terrain Models (DTM)

Digital Surface Models (DSM)

Digital Elevation Models (DEM)

Object Classification or Identification

Land Cover and Change Detection

Segment by End use:

Government & Military

Commercial

National Space Agencies

Departments of Defense

National Security Agencies

Academic and Research Institutions

Departments of Environment & Agriculture

National Mapping & Topographic Agencies

Others

Geological Companies

Mapping and Cartographic Companies

Mining, Oil, and Gas Companies

Transport, Construction, and Infrastructure Companies

Satellite Operators/Owners

Media and Entertainment

Others

Segment by Vertical:

Energy & Power

Engineering & Infrastructure

Defense & Security

Environmental

Agriculture

Maritime

Forestry

Transportation & Logistics

Insurance

Mining and Mineral Exploration

Oil and Gas Operation

Pipeline and Transmission Survey

3D Urban and Terrain Modeling (DTM)

Airport Mapping

Land & Urban Management

Maritime and Land Surveillance Activities

Critical Infrastructure Protection

Crime Mapping

Monitoring of Airfields

Global Climate Change

Land Cover and Change Detection

Air & Water Pollution

Natural Disasters

Natural Hazards

Crop Type Identification

Precision Farming

Ports & Harbors Monitoring

Coastal Management (Survey Waters, Detect Vessels, Track Activities)

Flood Monitoring

Property Damage Estimation

 Segment by Region:

North America

United States of America

Canada

Asia Pacific

China

Japan

India

Rest of APAC

Europe

United Kingdom

Germany

France

Spain

Rest of Europe

RoW

Brazil

South Africa

Saudi Arabia

UAE

Rest of the world (remaining countries of the LAMEA region)

About GMI Research

GMI Research is a market research and consulting firm which provides bespoke industry & market research to help businesses in making the toughest business decision. We know the significance of accurate data; that’s why our analyst uses a tailored methodology to study every market in detail because one size doesn’t fit all. We not only cover the traditional well-established market but also focuses on the niche market and markets in the emerging economies, where getting data and information is a challenge. This factor makes us pioneer in emerging market research space. Our syndicate reports cover multiple industries across various regions and countries.

Our in-depth market reports help propel your business with all the data, strategic inputs, and competitive intelligence to move ahead even in the most uncertain times. Featured in the ‘Top 20 Most Promising Market Research Consultants’ list of Silicon India Magazine in 2018, we at GMI Research look forward to helping businesses stay ahead of the curve.

Proposed Chickahominy Gas Power Station, Charles City County, Virginia from River Healers on Vimeo.

This is the Pearsall Power Station, a fracked gas power station in Texas with a capacity of 203 megawatts. What you are seeing is thermal video documentation of the Pearsall Station’s air emissions. The video was recorded by Earthworks and shows volatile organic compounds being released into the air during normal station activity. Two much larger fracked gas power stations are being proposed in Virginia that have a total capacity of 2,700 megawatts. The proposed Chickahominy Power Station would be 1,650 megawatts and the proposed C4GT Power Station would be 1,060 megawatts. Together that’s more than 13 times larger in scale than what you see in the video.

Both of these fracked gas stations would be within one mile of each other in the community of Roxbury in Charles City County Virginia. Citizen Drone documentation of the proposed Chickahominy Power Station site shows a farm with livestock within .2 miles of the station’s point of emissions. Another farm is .4 miles away from the proposed point of emissions. Union Baptist Church, a historical black baptist church is only .8 miles from emissions and you can see many more houses in this same area as close as .75 and .2 miles away from the proposed point of emissions.

Within a mile radius of the Chickahominy Power Station site would be the C4GT fracked gas Power Station, which together would make this the 5th largest gas emissions area in the United Sates. This community is also faced with Dominion Energy’s substation, the Colonial Pipeline, a Virginia Natural gas station, multiple transmission lines, and a massive landfill.

Energy Justice Network found that residents in close proximity are 40% African American and 19% Native American. An independent spatial analysis done by Stephen Metts reported that the area is made up of 65% and higher minorities which surpasses levels for an environmental justice review. The majority of the 1,200 members of the Chickahominy Tribe live within 2 miles of the proposed gas plants. Neither the state or applicant have consulted or been given free, prior, and informed consent from the Eastern Chickahominy tribe who also live in the area or the Weyanoke Association who have occupied the area for more than 8,000 years, and who have an abundant Native American, African American, and red-black history across Charles City County.

Annual air emissions of the Chickahomny Gas Station would include 407 tons of Nitrogen Oxides, 323 tons of Carbon Monoxide, 211 tons of Volatile Organic Compounds, 169 tons of Particulate Matter, 62 tons of Sulphur Dioxide, up to 6 1/2 million tons of Carbon Dioxide Equivalent, 129 tons of Methane, 65 tons of Sulfuric Acid Mist, and 10 tons of Hazardous Air Pollutants.

No community needs these toxins in their air, water, or soil! . To get involved go to Concerned Citizens of Charles City County (C5) c5groupinform.wixsite.com/charlescity and follow on facebook facebook.com/groups/909084206093313/ and twitter twitter.com/concerned_city . Cited sources and imagery:

Stephen Metts of The New School independent spatial analysis gist.github.com/VzPI/96d56d480fe1ca84820d53919a87058f

spatial-analysis-findings.s3.us-east-2.amazonaws.com/Independent+spatial+data+analyses+of+the+2019+Chickahominy+Power+Plant_6-4-19.pdf

Annual emissions fro the Chickahominy Power Station deq.virginia.gov/Portals/0/DEQ/Air/Chickahominy_Power_Plant/Documents/52610_engineering_analysis.pdf

energyjustice.net/map/displayfacility-71956.htm

dhr.virginia.gov/historic-registers/018-0029/

weyanoke.org/index.html

chickahominytribe.org/

Earthworks thermal video of the Pearsall Gas Power Station youtu.be/7FhocMhWK_U

Music by Eric Eckhart ericeckhart1.bandcamp.com/

Hire Professionals for Quality Void Detection and Seismic Surveys

Geophysical surveys help to collect comprehensive information about the subsurface non-destructively. Civil engineering, energy, archaeology, mineral exploration, and geotechnical sectors utilize seismic survey, methane gas survey, utility survey, and other different surveys to investigate sites to find out water/ mineral resources, geo-hazards, archaeological structures, brown-field features, geothermal prospects, mine-workings, geotechnical properties, voids, bedrock profiles, UXO, etc. Unlike conventional techniques, a geophysical site investigation is low cost and ensures success in invasive work.

Common Geophysical Surveys 

A geophysical survey is a process in which geophysical data is orderly collected for spatial investigations. It is done for the geophysical signal detection and analysis to obtain information related to the internal structure, seismic activities, etc. Special equipment and techniques are used by professionals to investigate a site. For instance, the void detection survey is done through the Ground Penetrating Radar (GPR) to scan a particular area of ground and discover the location of underground voids, subsidence, and sink-holes. It is essential to check the integrity of the ground before employing heavy equipment. The most important advantage of these geophysical surveys is that operators and people on site are not exposed to dangerous substances.

Why is Professional Services Crucial?

Established survey companies in the UK have the necessary equipment and team of experience and skills people to execute void detection, seismic, or mine shaft survey for flawless ground investigation and exploration for different industries. They utilize various geophysical methods, including ground radar (GPR), microgravity cross-hole seismic, seismic reflection, ground conductivity (EM), seismic refraction, magnetics MASW (Surface Wave Surveys), microgravity, electrical resistivity, and Tomography (ERT). Industries and organizations that need reliable geophysical intelligence for the detection of unexploded ordnance, deformation monitoring on buildings, archaeological mapping, water exploration/drainage, aerial orthophoto creation, profiling bedrock properties for pipeline/bridge river crossings demand specialist geophysicists and survey instrumentation.

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Satellite Services Market for Oil & Gas Industry Revenue to Record Stellar Growth Rate during 2017– 2025

Satellites are playing vital role in the oil & gas industry. Right from exploration of fossil fuel to production and transportation of crude oil, satellite services assist upstream, midstream, and downstream branches of the oil & gas industry. Operations in the oil & gas industry, whether they are onshore or offshore, are mostly carried out in remote locations. These locations are far from any infrastructural development, isolated, and with harsh environmental conditions. The difficulty and risk levels are high in offshore operations, due to uncertain and continuously changing conditions of winds and waves. Satellite services comprise communication services and remote-sensing services that can be utilized in the oil & gas industry.Read report overview@

https://www.transparencymarketresearch.com/satellite-services-market.html

With their innovative technology of high spatial resolution imaging, remote-sensing satellite services can help in the exploration of new hydrocarbon reserves. The high-resolution surface data obtained from satellite imagery exhibits different surface features of the area of interest. This, in turn, helps to design, manage, and execute geophysical exploration surveys required for the exploration of oil and gas deposits.In midstream oil & gas operations, remote sensing satellite services can be used for continuous monitoring and mapping of widespread, extensively long network of pipelines. Leakage or damage of crude oil pipelines can cause severe environmental pollution. This can be a major loss in terms of revenue to any oil & gas company. Thus, maintaining the safety and integrity of pipeline satellite services can save great amount of time and money involved in midstream oil & gas operations.Communication satellite services are capable to provide broadband Internet, voice over IP (VoIP), real-time video, and reliable wireless communications in harsh offshore as well as onshore environments. Instant and crucial decision-making is a regular task in upstream oil & gas operations, wherein the communication between management, scientists, and onsite workforce plays a key role. Communication satellite services help in addressing health- and safety-related issues in such high-risk operations.The ever-increasing demand for crude oil is a key driver for the satellite services market for the oil & gas industry. The era of easy oil is over. The rise in demand for this favored energy source is creating need for exploring new oil and gas deposits across the world. The new reserves of oil and gas are being discovered in deeper, offshore environments. The future of the oil & gas industry lies mostly in offshore environments. This presents growth opportunities for the satellite services market for the oil & gas industry.Though the oil & gas industry is currently suffering due to low oil prices, it is likely to recover in the next few years. On the other hand, increased use of renewable energy sources could be one of the major restraints for the industry. However, along with renewable energy sources, natural gas has emerged as one of the most favored fuels in recent times. Thus, the satellite service market for the oil & gas industry is likely to expand at a significant rate in the near future.

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Geographically, North America holds a major share of the global satellite services market for the oil & gas industry. The region has several players that offer satellite services and is also one of the major producers of oil and gas. Middle East & Africa is known for its oil and gas reserves and hence, the region is estimated to be a lucrative market for satellite services in the near future. Asia Pacific is home to some of the major petroleum refineries in the world. This presents growth opportunities for the market in the region.Major players operating in the satellite services market for the oil & gas industry are ESOA, Ground Control, DHI GRAS A/S., i-cubed, LLC. ESRI, Infosat Communications, Castor Networks, ND SatCom GmbH, Network Innovations, Datasat Communications, Orange Business Services, and Hughes Network Systems LLC.The report offers a comprehensive evaluation of the market. It does so via in-depth qualitative insights, historical data, and verifiable projections about market size. The projections featured in the report have been derived using proven research methodologies and assumptions. By doing so, the research report serves as a repository of analysis and information for every facet of the market, including but not limited to: Regional markets, technology, types, and applications.The study is a source of reliable data on:

Market segments and sub-segments

Market trends and dynamics

Supply and demand

Market size

Current trends/opportunities/challenges

Competitive landscape

Technological breakthroughs

Value chain and stakeholder analysis

The regional analysis covers:

North America (U.S. and Canada)

Latin America (Mexico, Brazil, Peru, Chile, and others)

Western Europe (Germany, U.K., France, Spain, Italy, Nordic countries, Belgium, Netherlands, and Luxembourg)

Eastern Europe (Poland and Russia)

Asia Pacific (China, India, Japan, ASEAN, Australia, and New Zealand)

Middle East and Africa (GCC, Southern Africa, and North Africa)

The report has been compiled through extensive primary research (through interviews, surveys, and observations of seasoned analysts) and secondary research (which entails reputable paid sources, trade journals, and industry body databases). The report also features a complete qualitative and quantitative assessment by analyzing data gathered from industry analysts and market participants across key points in the industry’s value chain.

The uncertain role of natural gas in the transition to clean energy

A new MIT study examines the opposing roles of natural gas in the battle against climate change — as a bridge toward a lower-emissions future, but also a contributor to greenhouse gas emissions.

Natural gas, which is mostly methane, is viewed as a significant “bridge fuel” to help the world move away from the greenhouse gas emissions of fossil fuels, since burning natural gas for electricity produces about half as much carbon dioxide as burning coal. But methane is itself a potent greenhouse gas, and it currently leaks from production wells, storage tanks, pipelines, and urban distribution pipes for natural gas. Increasing its usage, as a strategy for decarbonizing the electricity supply, will also increase the potential for such “fugitive” methane emissions, although there is great uncertainty about how much to expect. Recent studies have documented the difficulty in even measuring today’s emissions levels.

This uncertainty adds to the difficulty of assessing natural gas’ role as a bridge to a net-zero-carbon energy system, and in knowing when to transition away from it. But strategic choices must be made now about whether to invest in natural gas infrastructure. This inspired MIT researchers to quantify timelines for cleaning up natural gas infrastructure in the United States or accelerating a shift away from it, while recognizing the uncertainty about fugitive methane emissions.

The study shows that in order for natural gas to be a major component of the nation’s effort to meet greenhouse gas reduction targets over the coming decade, present methods of controlling methane leakage would have to improve by anywhere from 30 to 90 percent. Given current difficulties in monitoring methane, achieving those levels of reduction may be a challenge. Methane is a valuable commodity, and therefore companies producing, storing, and distributing it already have some incentive to minimize its losses. However, despite this, even intentional natural gas venting and flaring (emitting carbon dioxide) continues.

The study also finds policies that favor moving directly to carbon-free power sources, such as wind, solar, and nuclear, could meet the emissions targets without requiring such improvements in leakage mitigation, even though natural gas use would still be a significant part of the energy mix.

The researchers compared several different scenarios for curbing methane from the electric generation system in order to meet a target for 2030 of a 32 percent cut in carbon dioxide-equivalent emissions relative to 2005 levels, which is consistent with past U.S. commitments to mitigate climate change. The findings appear today in the journal Environmental Research Letters, in a paper by MIT postdoc Magdalena Klemun and Associate Professor Jessika Trancik.

Methane is a much stronger greenhouse gas than carbon dioxide, although how much more depends on the timeframe you choose to look at. Although methane traps heat much more, it doesn’t last as long once it’s in the atmosphere — for decades, not centuries.  When averaged over a 100-year timeline, which is the comparison most widely used, methane is approximately 25 times more powerful than carbon dioxide. But averaged over a 20-year period, it is 86 times stronger.

The actual leakage rates associated with the use of methane are widely distributed, highly variable, and very hard to pin down. Using figures from a variety of sources, the researchers found the overall range to be somewhere between 1.5 percent and 4.9 percent of the amount of gas produced and distributed. Some of this happens right at the wells, some occurs during processing and from storage tanks, and some is from the distribution system. Thus, a variety of different kinds of monitoring systems and mitigation measures may be needed to address the different conditions.

“Fugitive emissions can be escaping all the way from where natural gas is being extracted and produced, all the way along to the end user,” Trancik says. “It’s difficult and expensive to monitor it along the way.”

That in itself poses a challenge. “An important thing to keep in mind when thinking about greenhouse gases,” she says, “is that the difficulty in tracking and measuring methane is itself a risk.” If researchers are unsure how much there is and where it is, it’s hard for policymakers to formulate effective strategies to mitigate it. This study’s approach is to embrace the uncertainty instead of being hamstrung by it, Trancik says: The uncertainty itself should inform current strategies, the authors say, by motivating investments in leak detection to reduce uncertainty, or a faster transition away from natural gas.

“Emissions rates for the same type of equipment, in the same year, can vary significantly,” adds Klemun. “It can vary depending on which time of day you measure it, or which time of year. There are a lot of factors.”

Much attention has focused on so-called “super-emitters,” but even these can be difficult to track down. “In many data sets, a small fraction of point sources contributes disproportionately to overall emissions,” Klemun says. “If it were easy to predict where these occur, and if we better understood why, detection and repair programs could become more targeted.” But achieving this will require additional data with high spatial resolution, covering wide areas and many segments of the supply chain, she says.

The researchers looked at the whole range of uncertainties, from how much methane is escaping to how to characterize its climate impacts, under a variety of different scenarios. One approach places strong emphasis on replacing coal-fired plants with natural gas, for example; others increase investment in zero-carbon sources while still maintaining a role for natural gas.

In the first approach, methane emissions from the U.S. power sector would need to be reduced by 30 to 90 percent from today’s levels by 2030, along with a 20 percent reduction in carbon dioxide. Alternatively, that target could be met through even greater carbon dioxide reductions, such as through faster expansion of low-carbon electricity, without requiring any reductions in natural gas leakage rates. The higher end of the published ranges reflects greater emphasis on methane’s short-term warming contribution.

One question raised by the study is how much to invest in developing technologies and infrastructure for safely expanding natural gas use, given the difficulties in measuring and mitigating methane emissions, and given that virtually all scenarios for meeting greenhouse gas reduction targets call for ultimately phasing out natural gas that doesn’t include carbon capture and storage by mid-century. “A certain amount of investment probably makes sense to improve and make use of current infrastructure, but if you’re interested in really deep reduction targets, our results make it harder to make a case for that expansion right now,” Trancik says.

The detailed analysis in this study should provide guidance for local and regional regulators as well as policymakers all the way to federal agencies, they say. The insights also apply to other economies relying on natural gas. The best choices and exact timelines are likely to vary depending on local circumstances, but the study frames the issue by examining a variety of possibilities that include the extremes in both directions — that is, toward investing mostly in improving the natural gas infrastructure while expanding its use, or accelerating a move away from it.

The research was supported by the MIT Environmental Solutions Initiative. The researchers also received support from MIT’s Policy Lab at the Center for International Studies.

The uncertain role of natural gas in the transition to clean energy syndicated from https://osmowaterfilters.blogspot.com/

Global Market Insights looks at the factors driving the geographic information system (GIS) market and how the energy segment will contribute towards the market growth.

The research firm forecasts the GIS market to surpass a valuation of $$9 billion by 2024.

Touted to boast of a broad application scope spanning key business sectors, the global GIS market has surfaced as a fundamental entity representing profitability and operational efficiency over the past several years.

From conducting surveys and mapping activities for the energy segment to developing telematics and navigational solutions for transportation purpose, GIS services have become a basic necessity while undertaking new ventures or expanding territorial operations.

The prominent resources and data which companies acquire as well as manage using geographically-relevant information include demographics, workforce distribution, customer behavior and real-time asset monitoring.

Suitable GIS allows for more reliable analysis of this data to make critical business decisions, unlike complex legacy systems and previous data collection methods where small bits of important statistics could easily be overlooked. 

Development of modern hardware and software components, that can work with remote sensing technologies and spatial information-gathering objects, has picked up pace with the increased consumer demand for various services.

In recent years, with the surge in demand for energy and communication along with the need for more extensive and reliable energy infrastructure, the utility industry, including power, oil & gas and telecom, has rapidly adopted GIS to achieve significant business transformation and bring more efficiency into every day operations.

Managing the integration of wind and solar energy with modernised electricity grids to meet national sustainability goals has further induced the need for high-tech utility solutions.

Geographical data tracking has the potential to considerably improve the service capabilities of telecom companies as well, since mapping, mobile asset management and consumer data are crucial factors that influence major decisions.

Keeping an eye on investments like tools, people and communications, infrastructure through GIS data helps in timely equipment maintenance, while access to demographic information enables better handling of customer contracts.

Utility applications and the GIS market

Regardless of the type of utility services, GIS is essential to determine infrastructure requirements, forecast vulnerabilities using real-time data, prioritise repair-maintenance tasks as per geographic specifications and ensure interoperability of different business components. These features have increasingly become vital due to growing power consumption and stringent policies regarding utility rates and environmental control.

Planning and designing networks: Accounting for the largest share of investments made by a utility firm, networks form the core of business operations which need effective planning and design to avoid failure of services.

GIS-powered insights and decisions enable companies to not only design efficient networks to reach customers, but also save considerable cost incurred on engineering, development and supply chain services.

Referring to data submitted to the US Federal Energy Regulatory Committee, between 2015-2016 running one mile of natural gas pipeline cost around $$7.65 million per mile. This demonstrates the importance of building a robust network which is able to reach customers, allows for easy workflow management and tracking of resources.

GIS software are able to assist planners in developing critical utility networks like water and gas distribution, district energy grids, wastewater systems, among others using precise mapping technologies and data analytics.

Managing business assets: Utility services are by default asset-based and firms have always struggled to manage them due to the spread of physical networks over vast territories and in different weather conditions.

Although a large number of existing assets are difficult to monitor and maintain, the GIS industry can help in enhancing the management of new assets which are a part of a more decentralized, smart grids.

Duke Energy, for instance, has total assets of $133 billion and serves more than 7.4 million electric customers in the US.

The company is consistently expanding its solar energy initiatives and recently bid for a 680 MW project that would power almost 125,000 households at peak output.

Such efforts underscore the requirement of GIS and other smart technologies to manage and optimize physical assets of utility providers with the growing mix of renewables in the energy supply. 

Outage management: Power failures caused by weather events and faults in equipment could lead to millions in losses for utility providers as well as commercial operations in the area. Reportedly, eight major markets in the U.S. forfeit nearly $27 billion every year owing to power outages, with some businesses accruing bigger losses than others.

Today, utilities can avail the services of GIS providers to acquire mapping and data management abilities for enhancing outage management, by building a map that indicates physical assets and offering a graphic display of size and effect of events such as storms.

Continuous gathering of data can assist in forecasting when an outage could take place, possible location of the damage and anticipate which areas may get affected by weather. It also allows firms to dispatch a field crew even before an event occurs, enabling predictive maintenance. GIS also makes it easy for mobile workers to access the same information as those in the back offices, making operations more efficient.

Regulatory compliance: Most countries around the world have strict regulatory standards to be implemented during city planning activities or setting up of utility services like water supply, sewer flow gas pipelines and electricity lines.

Precise mapping and monitoring is needed to determine the delivery flow of utilities and predict service interruptions. In doing so, enormous amounts of data are collected regarding the area and GIS is a technology that is able to manage and analyze this data more effectively.         

Planners have to evaluate whether new infrastructure will comply with regulatory demands, which can be done using GIS-based data. Remarkably, GIS software could help create visual presentations of the environmental conditions in an area, helping to compare between current settings and estimated outcomes of proposed utility network design and development. In addition to helping meet regulatory demands, the GIS industry would also help utilities in creating strategies to make amenities and services more accessible and reliable.

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Satellite Services: playing vital role in the oil & gas industry; Global Industry Analysis | 2025

Satellites are playing vital role in the oil & gas industry. Right from exploration of fossil fuel to production and transportation of crude oil, satellite services assist upstream, midstream, and downstream branches of the oil & gas industry. Operations in the oil & gas industry, whether they are onshore or offshore, are mostly carried out in remote locations. These locations are far from any infrastructural development, isolated, and with harsh environmental conditions. The difficulty and risk levels are high in offshore operations, due to uncertain and continuously changing conditions of winds and waves. Satellite services comprise communication services and remote-sensing services that can be utilized in the oil & gas industry.

With their innovative technology of high spatial resolution imaging, remote-sensing satellite servicescan help in the exploration of new hydrocarbon reserves. The high-resolution surface data obtained from satellite imagery exhibits different surface features of the area of interest. This, in turn, helps to design, manage, and execute geophysical exploration surveys required for the exploration of oil and gas deposits.

In midstream oil & gas operations, remote sensing satellite services can be used for continuous monitoring and mapping of widespread, extensively long network of pipelines. Leakage or damage of crude oil pipelines can cause severe environmental pollution. This can be a major loss in terms of revenue to any oil & gas company. Thus, maintaining the safety and integrity of pipeline satellite services can save great amount of time and money involved in midstream oil & gas operations.

Communication satellite services are capable to provide broadband Internet, voice over IP (VoIP), real-time video, and reliable wireless communications in harsh offshore as well as onshore environments. Instant and crucial decision-making is a regular task in upstream oil & gas operations, wherein the communication between management, scientists, and onsite workforce plays a key role. Communication satellite services help in addressing health- and safety-related issues in such high-risk operations.

The ever-increasing demand for crude oil is a key driver for the satellite services market for the oil & gas industry. The era of easy oil is over. The rise in demand for this favored energy source is creating need for exploring new oil and gas deposits across the world. The new reserves of oil and gas are being discovered in deeper, offshore environments. The future of the oil & gas industry lies mostly in offshore environments. This presents growth opportunities for the satellite services market for the oil & gas industry.

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Though the oil & gas industry is currently suffering due to low oil prices, it is likely to recover in the next few years. On the other hand, increased use of renewable energy sources could be one of the major restraints for the industry. However, along with renewable energy sources, natural gas has emerged as one of the most favored fuels in recent times. Thus, the satellite service market for the oil & gas industry is likely to expand at a significant rate in the near future.

Geographically, North America holds a major share of the global satellite services market for the oil & gas industry. The region has several players that offer satellite services and is also one of the major producers of oil and gas. Middle East & Africa is known for its oil and gas reserves and hence, the region is estimated to be a lucrative market for satellite services in the near future. Asia Pacific is home to some of the major petroleum refineries in the world. This presents growth opportunities for the market in the region.

Major players operating in the satellite services market for the oil & gas industry are ESOA, Ground Control, DHI GRAS A/S., i-cubed, LLC. ESRI, Infosat Communications, Castor Networks, ND SatCom GmbH, Network Innovations, Datasat Communications, Orange Business Services, and Hughes Network Systems LLC.

The global market for Smart Gas Solutions is projected to reach US$23.5 billion by 2024, driven by the growing need for efficient utilization of energy and rising awareness over the importance of information management technologies in enabling intelligent metering, monitoring, measurement, and control of gas resources. Also driving growth in the market are factors such as growing global gas demand from 3,000 Mtoe in 2015 to 4,100 Mtoe by 2035 and the ensuing need for efficient distribution networks and billing system; spiraling shale gas production with technology developments promising to tap into the over 5,770 trillion cubic feet of technically recoverable shale gas reserves worldwide; robust demand for modular & integrated gas meters; increasing adoption of SCADA; increasing integration of cloud computing, IoT & artificial intelligence in advanced metering infrastructure (AMI); and rise of smart cities to over 170 cities from 85 countries and growing investments in smart distribution of utility resources such as electricity, water and gas. The scenario is driving increased investments in national smart meter programs, spatial management of transmission pipeline networks; on-site automation systems; use of intelligent metering software and cloud computing for gas leakage and outflow detection and identification of safety issues.  Few of the benefits of smart gas solutions driving investments in transformation of gas networks include operational cost benefits that accompany automation; better energy planning as it offers real-time data on energy costs and related carbon emissions; provides opportunity for voluntarily reducing household gas consumption; enables implementation of multi tariff features to allow for better demand response management; improved profitability for utilities as it reduces the ‘costs to serve’; and helps governments battle climate change and achieve slated goals of energy directives. Europe represents the largest market worldwide, supported by favorable regulations and funding support that encourage adoption of smart gas solutions across the entire natural gas chain comprising mining, storage, transmission, distribution and final consumption. Asia-Pacific ranks as the fastest growing market with a CAGR of 22.6% over the analysis period led by stringent energy efficiency regulations given the fact that developing countries utilize more resources partially due to energy wastages and mismanagement. More…

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