Internet of Things in Energy Market by Offering (Hardware, Services, Software), Application (Asset Tracking, Demand Response Management, Grid Monitoring And Management), Connectivity Technology, End User, Deployment Model - Global Forecast 2025-2032
Description
The Internet of Things in Energy Market was valued at USD 27.24 billion in 2024 and is projected to grow to USD 30.19 billion in 2025, with a CAGR of 10.77%, reaching USD 61.78 billion by 2032.
Harnessing the Internet of Things in Energy to Accelerate Operational Efficiency Sustainability and System Resilience Across Modern Power Infrastructure
The integration of Internet of Things technologies within energy systems has emerged as a pivotal catalyst for driving operational efficiency, enhancing system resilience, and advancing decarbonization objectives across modern power infrastructure. As legacy networks evolve into intelligent ecosystems, real time data collection, analytics, and automated control mechanisms converge to optimize performance at every touchpoint. This evolution facilitates granular visibility into asset health, grid performance, and demand patterns, enabling proactive decision making and minimizing unplanned downtime.
Moreover, IoT driven solutions bridge the digital divide between distributed energy resources, centralized control centers, and end users, fostering a dynamic interplay that underpins demand response management and distributed energy integration. Transitioning from reactive maintenance to predictive maintenance strategies not only reduces lifecycle costs of critical equipment but also enhances overall system safety. As environmental regulations tighten and sustainability targets become more aggressive, IoT platforms play a transformative role in tracking emissions, streamlining renewable integration, and validating compliance in real time.
Ultimately, the adoption of IoT in energy marks a fundamental shift from siloed operations to an interconnected, data driven paradigm. This transformation empowers stakeholders across utilities, commercial enterprises, and residential networks to unlock new efficiencies, deliver superior service reliability, and accelerate progress toward a low carbon future.
Exploring the Profound Technological and Market Shifts Reshaping the Energy Sector Through IoT Integration and Emerging Digital Innovations
Over the past decade, the energy sector has witnessed profound shifts as digital innovation and IoT connectivity converge to reshape traditional paradigms. Advanced sensor networks now capture high resolution operational data from substations, wind farms, and solar arrays, fueling AI driven analytics that unlock deeper insights into grid performance and asset health. Simultaneously, edge computing capabilities have migrated intelligence closer to field devices, reducing latency and enabling real time automation of critical control loops.
In parallel, evolving regulatory frameworks and growing emphasis on carbon reporting have magnified the importance of transparent, auditable data streams. The proliferation of interoperable communication standards, such as MQTT and OPC UA, has accelerated vendor agnostic integration, fostering collaborative ecosystems. Coupled with the rise of 5G and private LTE networks, these advances are expanding the scope of connectivity from centralized generation facilities to remote microgrids and behind the meter resources.
As digital twins gain traction, stakeholders can simulate complex scenarios-from peak demand events to extreme weather disruptions-bolstering resilience planning and operational agility. These transformative shifts underscore a broader trend toward holistic energy management, where predictive intelligence, decentralized control, and seamless interoperability define the next frontier of sustainable power delivery.
Assessing the Cumulative Effect of 2025 United States Tariffs on Global IoT Energy Supply Chains and Cross Border Technology Collaboration Dynamics
The introduction of new tariff measures by the United States in 2025 has had a cascading effect on global IoT energy supply chains and cross border technology collaboration. Manufacturers of controllers, gateways, and meters have encountered increased cost pressures as key components sourced from international suppliers now incur higher import duties. This has prompted several hardware vendors to re engineer product designs, diversify sourcing strategies, and explore nearshoring options to mitigate tariff related disruptions.
On the software and analytics front, heightened procurement costs have spurred cloud service providers and platform developers to revisit their pricing models. Many organizations have begun renegotiating long term contracts to offset incremental fees, while some smaller integrators have temporarily delayed deployment timelines to reassess total cost of ownership. Meanwhile, the impact on predictive and real time analytics solutions has been tempered by the rising importance of operational efficiency and resilience, which continue to justify strategic investments despite elevated import costs.
Overall, the cumulative effect of these tariff adjustments has accelerated supply chain optimization efforts, driving greater emphasis on regional manufacturing hubs and fostering collaboration among stakeholders seeking to ensure uninterrupted deployment of IoT driven energy solutions.
Unraveling Deep Segmentation Perspectives in IoT for Energy Across Offerings Applications Connectivity Technology End Users and Deployment Models
Insight into market segmentation reveals a multifaceted landscape where offering, application, connectivity technology, end user, and deployment model each play a critical role in shaping IoT adoption strategies. Based on offering, the landscape spans hardware, services, and software, with hardware encompassing controllers, gateways, meters, and an array of sensors that include current sensors, environment sensors, and metering sensors. Within services, consulting, integration, and support and maintenance provide essential expertise that underpins successful implementation. Software offerings comprise analytics, application software, and platform solutions; analytics solutions further divide into predictive analytics and real time analytics while platforms split between IoT platforms and management platforms.
From an application standpoint, IoT in energy addresses asset tracking, demand response management, grid monitoring and management, and smart meter management, with demand response covering both industrial and residential segments. Connectivity technologies range from cellular networks to various LPWAN protocols like LoRaWAN, NB-IoT, and Sigfox, as well as short range solutions. End users include commercial enterprises, industrial facilities, residential consumers, and utilities, each with distinct requirements for scalability, security, and service availability. Finally, deployment models vary between cloud based implementations and on premises solutions, enabling organizations to align their digital infrastructure with regulatory constraints and internal IT policies.
This detailed segmentation analysis underscores the importance of tailored strategies that address unique demands across each dimension, ensuring comprehensive coverage and optimized return on IoT investments.
Mapping Regional Dynamics of Internet of Things in Energy Across the Americas Europe Middle East Africa and Asia Pacific Markets
Across the Americas, adoption of IoT in energy has accelerated thanks to robust investment in smart grid modernization and aggressive decarbonization targets set by governments and industry consortiums. North American utilities are deploying advanced meter infrastructure and leveraging real time analytics to optimize load balancing and outage management, while Latin American markets are embracing distributed solar and microgrid controls to enhance rural electrification and grid resilience.
In Europe, Middle East & Africa, stringent emissions regulations and ambitious renewable integration goals have driven widespread IoT adoption for carbon monitoring and asset performance management. European grid operators are pioneering digital twin initiatives to simulate complex scenarios, while EMEA utilities leverage LPWAN connectivity and private networks to monitor remote infrastructure across vast geographies.
In the Asia Pacific region, rapid urbanization and surging energy demand have prompted extensive rollouts of smart metering programs and demand response platforms. Leading APAC nations are forging public private partnerships to advance IoT deployment in industrial parks and smart cities, supported by government subsidies and innovation hubs. These regional dynamics highlight the critical interplay between policy frameworks, infrastructure readiness, and market appetite in shaping the future trajectory of IoT in energy.
Profiling Leading Stakeholders Driving IoT Innovation in Energy with Strategic Partnerships Product Portfolios and Growth Initiatives
A number of leading technology providers and energy incumbents are shaping the trajectory of IoT deployment in the energy sector through targeted partnerships, robust R&D investments, and comprehensive solution portfolios. Several firms are integrating edge computing modules with advanced sensor arrays to deliver turnkey hardware solutions optimized for harsh electrical environments. At the same time, major software vendors are deepening capabilities in predictive and real time analytics, embedding machine learning algorithms that enable anomaly detection and dynamic load forecasting.
Strategic collaborations between utilities and telecommunications companies have resulted in the creation of dedicated private networks for mission critical energy applications, reducing latency and enhancing data security. Meanwhile, specialized system integrators are leveraging proprietary management platforms to orchestrate multi vendor ecosystems, providing utilities with unified dashboards for asset monitoring, outage response, and regulatory reporting. Across the board, organizations are investing in open standards and interoperability initiatives to future proof their IoT architectures and minimize vendor lock in.
These company level insights underscore a broader industry push toward end to end solutions that seamlessly blend hardware, software, and services, empowering stakeholders to accelerate digital transformation and address evolving regulatory and sustainability imperatives.
Delivering Actionable Strategic Recommendations for Industry Leaders to Capitalize on IoT Driven Energy Transformation and Sustainability Objectives
Industry leaders seeking to capitalize on the Internet of Things revolution in energy must adopt a cohesive strategy that integrates technology selection, ecosystem partnerships, and talent development. First, organizations should establish clear governance frameworks that define IoT objectives, data ownership protocols, and cybersecurity standards. By aligning cross functional teams around shared metrics for efficiency and sustainability, companies can accelerate time to value and mitigate operational risks.
Second, forging strategic alliances with telecommunication providers, platform developers, and system integrators ensures seamless end to end implementation. Collaborative pilots that test edge analytics, AI driven control algorithms, and predictive maintenance workflows can validate ROI and inform scaled deployments. Concurrently, investment in workforce upskilling-particularly in data science, network engineering, and cybersecurity-will be critical to unlocking the full potential of IoT enabled solutions.
Finally, embedding sustainability criteria into procurement and project evaluation processes elevates the strategic impact of IoT initiatives. By prioritizing low carbon technologies and circular economy principles, industry leaders can achieve both regulatory compliance and enhanced brand value. Through these targeted actions, organizations will be well positioned to lead the next wave of digital transformation in the energy sector.
Detailing Rigorous Multimethod Research Methodology Employed to Analyze Technological Trends Competitive Landscapes and Stakeholder Insights
This research employs a robust multimethod approach to uncover key trends and insights in IoT adoption within the energy sector. Primary data collection included in depth interviews with senior executives at utilities, technology providers, and system integrators, as well as structured surveys targeting asset managers and grid operators. These qualitative and quantitative inputs were triangulated with secondary research derived from industry publications, regulatory filings, and technology standards documentation.
Analysts conducted case study evaluations of exemplar IoT deployments to assess performance metrics, scalability, and integration challenges. A comparative analysis framework was applied to benchmark hardware architectures, software platforms, and service delivery models across diverse geographies and end user segments. Additionally, a scenario planning exercise examined the potential impact of macroeconomic factors, such as tariff changes and regulatory shifts, on supply chain resilience and technology adoption trajectories.
Data validation protocols included cross referencing interview findings with publicly reported performance indicators and vendor disclosed capabilities. This comprehensive methodology ensures that conclusions reflect both current market dynamics and emerging innovations, offering stakeholders a nuanced understanding of the evolving IoT in energy landscape.
Summarizing Key Findings and Strategic Implications of Internet of Things Adoption for Energy Sector Stakeholders and Policy Makers
The Internet of Things is fundamentally redefining how energy is generated, transmitted, distributed, and consumed. As we have seen, transformative technology shifts, tariff dynamics, and nuanced segmentation factors converge to shape a complex, opportunity rich ecosystem. Regional variations underscore the importance of policy frameworks and infrastructure readiness, while leading companies demonstrate the strategic value of integrated hardware, software, and services offerings.
Crucially, the transition toward real time analytics, edge computing, and digital twins is unlocking unprecedented levels of operational insight and resilience. These capabilities will be vital as the sector navigates evolving regulatory requirements and ambitious sustainability commitments. By adopting the actionable recommendations outlined, industry stakeholders can align talent, governance, and partnerships to accelerate innovation and deliver measurable gains in efficiency and decarbonization.
In conclusion, the evolution of IoT within the energy sector heralds a new era of data driven decision making and collaborative ecosystems. Stakeholders that leverage these insights and methodologies will be best positioned to lead sustainable growth and drive the energy transition forward.
Market Segmentation & Coverage
This research report categorizes to forecast the revenues and analyze trends in each of the following sub-segmentations:
Offering
Hardware
Controllers
Gateways
Meters
Sensors
Current Sensors
Environment Sensors
Metering Sensors
Services
Consulting
Integration
Support And Maintenance
Software
Analytics
Predictive Analytics
Real Time Analytics
Application Software
Platform
IoT Platform
Management Platform
Application
Asset Tracking
Demand Response Management
Industrial Demand Response
Residential Demand Response
Grid Monitoring And Management
Smart Meter Management
Connectivity Technology
Cellular
LPWAN
LoRaWAN
NB-IoT
Sigfox
Short Range
End User
Commercial
Industrial
Residential
Utilities
Deployment Model
Cloud
On Premises
This research report categorizes to forecast the revenues and analyze trends in each of the following sub-regions:
Americas
North America
United States
Canada
Mexico
Latin America
Brazil
Argentina
Chile
Colombia
Peru
Europe, Middle East & Africa
Europe
United Kingdom
Germany
France
Russia
Italy
Spain
Netherlands
Sweden
Poland
Switzerland
Middle East
United Arab Emirates
Saudi Arabia
Qatar
Turkey
Israel
Africa
South Africa
Nigeria
Egypt
Kenya
Asia-Pacific
China
India
Japan
Australia
South Korea
Indonesia
Thailand
Malaysia
Singapore
Taiwan
This research report categorizes to delves into recent significant developments and analyze trends in each of the following companies:
Schneider Electric SE
Siemens AG
ABB Ltd
General Electric Company
Honeywell International Inc.
Cisco Systems, Inc.
International Business Machines Corporation
Oracle Corporation
Itron, Inc.
Landis+Gyr AG
Note: PDF & Excel + Online Access - 1 Year
Harnessing the Internet of Things in Energy to Accelerate Operational Efficiency Sustainability and System Resilience Across Modern Power Infrastructure
The integration of Internet of Things technologies within energy systems has emerged as a pivotal catalyst for driving operational efficiency, enhancing system resilience, and advancing decarbonization objectives across modern power infrastructure. As legacy networks evolve into intelligent ecosystems, real time data collection, analytics, and automated control mechanisms converge to optimize performance at every touchpoint. This evolution facilitates granular visibility into asset health, grid performance, and demand patterns, enabling proactive decision making and minimizing unplanned downtime.
Moreover, IoT driven solutions bridge the digital divide between distributed energy resources, centralized control centers, and end users, fostering a dynamic interplay that underpins demand response management and distributed energy integration. Transitioning from reactive maintenance to predictive maintenance strategies not only reduces lifecycle costs of critical equipment but also enhances overall system safety. As environmental regulations tighten and sustainability targets become more aggressive, IoT platforms play a transformative role in tracking emissions, streamlining renewable integration, and validating compliance in real time.
Ultimately, the adoption of IoT in energy marks a fundamental shift from siloed operations to an interconnected, data driven paradigm. This transformation empowers stakeholders across utilities, commercial enterprises, and residential networks to unlock new efficiencies, deliver superior service reliability, and accelerate progress toward a low carbon future.
Exploring the Profound Technological and Market Shifts Reshaping the Energy Sector Through IoT Integration and Emerging Digital Innovations
Over the past decade, the energy sector has witnessed profound shifts as digital innovation and IoT connectivity converge to reshape traditional paradigms. Advanced sensor networks now capture high resolution operational data from substations, wind farms, and solar arrays, fueling AI driven analytics that unlock deeper insights into grid performance and asset health. Simultaneously, edge computing capabilities have migrated intelligence closer to field devices, reducing latency and enabling real time automation of critical control loops.
In parallel, evolving regulatory frameworks and growing emphasis on carbon reporting have magnified the importance of transparent, auditable data streams. The proliferation of interoperable communication standards, such as MQTT and OPC UA, has accelerated vendor agnostic integration, fostering collaborative ecosystems. Coupled with the rise of 5G and private LTE networks, these advances are expanding the scope of connectivity from centralized generation facilities to remote microgrids and behind the meter resources.
As digital twins gain traction, stakeholders can simulate complex scenarios-from peak demand events to extreme weather disruptions-bolstering resilience planning and operational agility. These transformative shifts underscore a broader trend toward holistic energy management, where predictive intelligence, decentralized control, and seamless interoperability define the next frontier of sustainable power delivery.
Assessing the Cumulative Effect of 2025 United States Tariffs on Global IoT Energy Supply Chains and Cross Border Technology Collaboration Dynamics
The introduction of new tariff measures by the United States in 2025 has had a cascading effect on global IoT energy supply chains and cross border technology collaboration. Manufacturers of controllers, gateways, and meters have encountered increased cost pressures as key components sourced from international suppliers now incur higher import duties. This has prompted several hardware vendors to re engineer product designs, diversify sourcing strategies, and explore nearshoring options to mitigate tariff related disruptions.
On the software and analytics front, heightened procurement costs have spurred cloud service providers and platform developers to revisit their pricing models. Many organizations have begun renegotiating long term contracts to offset incremental fees, while some smaller integrators have temporarily delayed deployment timelines to reassess total cost of ownership. Meanwhile, the impact on predictive and real time analytics solutions has been tempered by the rising importance of operational efficiency and resilience, which continue to justify strategic investments despite elevated import costs.
Overall, the cumulative effect of these tariff adjustments has accelerated supply chain optimization efforts, driving greater emphasis on regional manufacturing hubs and fostering collaboration among stakeholders seeking to ensure uninterrupted deployment of IoT driven energy solutions.
Unraveling Deep Segmentation Perspectives in IoT for Energy Across Offerings Applications Connectivity Technology End Users and Deployment Models
Insight into market segmentation reveals a multifaceted landscape where offering, application, connectivity technology, end user, and deployment model each play a critical role in shaping IoT adoption strategies. Based on offering, the landscape spans hardware, services, and software, with hardware encompassing controllers, gateways, meters, and an array of sensors that include current sensors, environment sensors, and metering sensors. Within services, consulting, integration, and support and maintenance provide essential expertise that underpins successful implementation. Software offerings comprise analytics, application software, and platform solutions; analytics solutions further divide into predictive analytics and real time analytics while platforms split between IoT platforms and management platforms.
From an application standpoint, IoT in energy addresses asset tracking, demand response management, grid monitoring and management, and smart meter management, with demand response covering both industrial and residential segments. Connectivity technologies range from cellular networks to various LPWAN protocols like LoRaWAN, NB-IoT, and Sigfox, as well as short range solutions. End users include commercial enterprises, industrial facilities, residential consumers, and utilities, each with distinct requirements for scalability, security, and service availability. Finally, deployment models vary between cloud based implementations and on premises solutions, enabling organizations to align their digital infrastructure with regulatory constraints and internal IT policies.
This detailed segmentation analysis underscores the importance of tailored strategies that address unique demands across each dimension, ensuring comprehensive coverage and optimized return on IoT investments.
Mapping Regional Dynamics of Internet of Things in Energy Across the Americas Europe Middle East Africa and Asia Pacific Markets
Across the Americas, adoption of IoT in energy has accelerated thanks to robust investment in smart grid modernization and aggressive decarbonization targets set by governments and industry consortiums. North American utilities are deploying advanced meter infrastructure and leveraging real time analytics to optimize load balancing and outage management, while Latin American markets are embracing distributed solar and microgrid controls to enhance rural electrification and grid resilience.
In Europe, Middle East & Africa, stringent emissions regulations and ambitious renewable integration goals have driven widespread IoT adoption for carbon monitoring and asset performance management. European grid operators are pioneering digital twin initiatives to simulate complex scenarios, while EMEA utilities leverage LPWAN connectivity and private networks to monitor remote infrastructure across vast geographies.
In the Asia Pacific region, rapid urbanization and surging energy demand have prompted extensive rollouts of smart metering programs and demand response platforms. Leading APAC nations are forging public private partnerships to advance IoT deployment in industrial parks and smart cities, supported by government subsidies and innovation hubs. These regional dynamics highlight the critical interplay between policy frameworks, infrastructure readiness, and market appetite in shaping the future trajectory of IoT in energy.
Profiling Leading Stakeholders Driving IoT Innovation in Energy with Strategic Partnerships Product Portfolios and Growth Initiatives
A number of leading technology providers and energy incumbents are shaping the trajectory of IoT deployment in the energy sector through targeted partnerships, robust R&D investments, and comprehensive solution portfolios. Several firms are integrating edge computing modules with advanced sensor arrays to deliver turnkey hardware solutions optimized for harsh electrical environments. At the same time, major software vendors are deepening capabilities in predictive and real time analytics, embedding machine learning algorithms that enable anomaly detection and dynamic load forecasting.
Strategic collaborations between utilities and telecommunications companies have resulted in the creation of dedicated private networks for mission critical energy applications, reducing latency and enhancing data security. Meanwhile, specialized system integrators are leveraging proprietary management platforms to orchestrate multi vendor ecosystems, providing utilities with unified dashboards for asset monitoring, outage response, and regulatory reporting. Across the board, organizations are investing in open standards and interoperability initiatives to future proof their IoT architectures and minimize vendor lock in.
These company level insights underscore a broader industry push toward end to end solutions that seamlessly blend hardware, software, and services, empowering stakeholders to accelerate digital transformation and address evolving regulatory and sustainability imperatives.
Delivering Actionable Strategic Recommendations for Industry Leaders to Capitalize on IoT Driven Energy Transformation and Sustainability Objectives
Industry leaders seeking to capitalize on the Internet of Things revolution in energy must adopt a cohesive strategy that integrates technology selection, ecosystem partnerships, and talent development. First, organizations should establish clear governance frameworks that define IoT objectives, data ownership protocols, and cybersecurity standards. By aligning cross functional teams around shared metrics for efficiency and sustainability, companies can accelerate time to value and mitigate operational risks.
Second, forging strategic alliances with telecommunication providers, platform developers, and system integrators ensures seamless end to end implementation. Collaborative pilots that test edge analytics, AI driven control algorithms, and predictive maintenance workflows can validate ROI and inform scaled deployments. Concurrently, investment in workforce upskilling-particularly in data science, network engineering, and cybersecurity-will be critical to unlocking the full potential of IoT enabled solutions.
Finally, embedding sustainability criteria into procurement and project evaluation processes elevates the strategic impact of IoT initiatives. By prioritizing low carbon technologies and circular economy principles, industry leaders can achieve both regulatory compliance and enhanced brand value. Through these targeted actions, organizations will be well positioned to lead the next wave of digital transformation in the energy sector.
Detailing Rigorous Multimethod Research Methodology Employed to Analyze Technological Trends Competitive Landscapes and Stakeholder Insights
This research employs a robust multimethod approach to uncover key trends and insights in IoT adoption within the energy sector. Primary data collection included in depth interviews with senior executives at utilities, technology providers, and system integrators, as well as structured surveys targeting asset managers and grid operators. These qualitative and quantitative inputs were triangulated with secondary research derived from industry publications, regulatory filings, and technology standards documentation.
Analysts conducted case study evaluations of exemplar IoT deployments to assess performance metrics, scalability, and integration challenges. A comparative analysis framework was applied to benchmark hardware architectures, software platforms, and service delivery models across diverse geographies and end user segments. Additionally, a scenario planning exercise examined the potential impact of macroeconomic factors, such as tariff changes and regulatory shifts, on supply chain resilience and technology adoption trajectories.
Data validation protocols included cross referencing interview findings with publicly reported performance indicators and vendor disclosed capabilities. This comprehensive methodology ensures that conclusions reflect both current market dynamics and emerging innovations, offering stakeholders a nuanced understanding of the evolving IoT in energy landscape.
Summarizing Key Findings and Strategic Implications of Internet of Things Adoption for Energy Sector Stakeholders and Policy Makers
The Internet of Things is fundamentally redefining how energy is generated, transmitted, distributed, and consumed. As we have seen, transformative technology shifts, tariff dynamics, and nuanced segmentation factors converge to shape a complex, opportunity rich ecosystem. Regional variations underscore the importance of policy frameworks and infrastructure readiness, while leading companies demonstrate the strategic value of integrated hardware, software, and services offerings.
Crucially, the transition toward real time analytics, edge computing, and digital twins is unlocking unprecedented levels of operational insight and resilience. These capabilities will be vital as the sector navigates evolving regulatory requirements and ambitious sustainability commitments. By adopting the actionable recommendations outlined, industry stakeholders can align talent, governance, and partnerships to accelerate innovation and deliver measurable gains in efficiency and decarbonization.
In conclusion, the evolution of IoT within the energy sector heralds a new era of data driven decision making and collaborative ecosystems. Stakeholders that leverage these insights and methodologies will be best positioned to lead sustainable growth and drive the energy transition forward.
Market Segmentation & Coverage
This research report categorizes to forecast the revenues and analyze trends in each of the following sub-segmentations:
Offering
Hardware
Controllers
Gateways
Meters
Sensors
Current Sensors
Environment Sensors
Metering Sensors
Services
Consulting
Integration
Support And Maintenance
Software
Analytics
Predictive Analytics
Real Time Analytics
Application Software
Platform
IoT Platform
Management Platform
Application
Asset Tracking
Demand Response Management
Industrial Demand Response
Residential Demand Response
Grid Monitoring And Management
Smart Meter Management
Connectivity Technology
Cellular
LPWAN
LoRaWAN
NB-IoT
Sigfox
Short Range
End User
Commercial
Industrial
Residential
Utilities
Deployment Model
Cloud
On Premises
This research report categorizes to forecast the revenues and analyze trends in each of the following sub-regions:
Americas
North America
United States
Canada
Mexico
Latin America
Brazil
Argentina
Chile
Colombia
Peru
Europe, Middle East & Africa
Europe
United Kingdom
Germany
France
Russia
Italy
Spain
Netherlands
Sweden
Poland
Switzerland
Middle East
United Arab Emirates
Saudi Arabia
Qatar
Turkey
Israel
Africa
South Africa
Nigeria
Egypt
Kenya
Asia-Pacific
China
India
Japan
Australia
South Korea
Indonesia
Thailand
Malaysia
Singapore
Taiwan
This research report categorizes to delves into recent significant developments and analyze trends in each of the following companies:
Schneider Electric SE
Siemens AG
ABB Ltd
General Electric Company
Honeywell International Inc.
Cisco Systems, Inc.
International Business Machines Corporation
Oracle Corporation
Itron, Inc.
Landis+Gyr AG
Note: PDF & Excel + Online Access - 1 Year
Table of Contents
183 Pages
- 1. Preface
- 1.1. Objectives of the Study
- 1.2. Market Segmentation & Coverage
- 1.3. Years Considered for the Study
- 1.4. Currency & Pricing
- 1.5. Language
- 1.6. Stakeholders
- 2. Research Methodology
- 3. Executive Summary
- 4. Market Overview
- 5. Market Insights
- 5.1. Integration of edge computing in smart grid infrastructure to optimize real-time energy distribution
- 5.2. Deployment of advanced IoT-enabled demand response solutions for residential solar storage management
- 5.3. Utilization of digital twin technology with IoT for predictive asset management in wind farms
- 5.4. Implementation of blockchain-based IoT platforms for secure peer-to-peer energy trading networks
- 5.5. Evolution of AI-driven energy optimization algorithms using IoT data from commercial buildings
- 5.6. Adoption of wireless sensor networks with energy harvesting for remote pipeline monitoring in oil and gas
- 5.7. Development of 5G-connected smart meters for enhanced consumption analytics and fault detection in utilities
- 5.8. Emergence of interoperability standards for multi-vendor IoT devices in microgrid control systems
- 6. Cumulative Impact of United States Tariffs 2025
- 7. Cumulative Impact of Artificial Intelligence 2025
- 8. Internet of Things in Energy Market, by Offering
- 8.1. Hardware
- 8.1.1. Controllers
- 8.1.2. Gateways
- 8.1.3. Meters
- 8.1.4. Sensors
- 8.1.4.1. Current Sensors
- 8.1.4.2. Environment Sensors
- 8.1.4.3. Metering Sensors
- 8.2. Services
- 8.2.1. Consulting
- 8.2.2. Integration
- 8.2.3. Support And Maintenance
- 8.3. Software
- 8.3.1. Analytics
- 8.3.1.1. Predictive Analytics
- 8.3.1.2. Real Time Analytics
- 8.3.2. Application Software
- 8.3.3. Platform
- 8.3.3.1. IoT Platform
- 8.3.3.2. Management Platform
- 9. Internet of Things in Energy Market, by Application
- 9.1. Asset Tracking
- 9.2. Demand Response Management
- 9.2.1. Industrial Demand Response
- 9.2.2. Residential Demand Response
- 9.3. Grid Monitoring And Management
- 9.4. Smart Meter Management
- 10. Internet of Things in Energy Market, by Connectivity Technology
- 10.1. Cellular
- 10.2. LPWAN
- 10.2.1. LoRaWAN
- 10.2.2. NB-IoT
- 10.2.3. Sigfox
- 10.3. Short Range
- 11. Internet of Things in Energy Market, by End User
- 11.1. Commercial
- 11.2. Industrial
- 11.3. Residential
- 11.4. Utilities
- 12. Internet of Things in Energy Market, by Deployment Model
- 12.1. Cloud
- 12.2. On Premises
- 13. Internet of Things in Energy Market, by Region
- 13.1. Americas
- 13.1.1. North America
- 13.1.2. Latin America
- 13.2. Europe, Middle East & Africa
- 13.2.1. Europe
- 13.2.2. Middle East
- 13.2.3. Africa
- 13.3. Asia-Pacific
- 14. Internet of Things in Energy Market, by Group
- 14.1. ASEAN
- 14.2. GCC
- 14.3. European Union
- 14.4. BRICS
- 14.5. G7
- 14.6. NATO
- 15. Internet of Things in Energy Market, by Country
- 15.1. United States
- 15.2. Canada
- 15.3. Mexico
- 15.4. Brazil
- 15.5. United Kingdom
- 15.6. Germany
- 15.7. France
- 15.8. Russia
- 15.9. Italy
- 15.10. Spain
- 15.11. China
- 15.12. India
- 15.13. Japan
- 15.14. Australia
- 15.15. South Korea
- 16. Competitive Landscape
- 16.1. Market Share Analysis, 2024
- 16.2. FPNV Positioning Matrix, 2024
- 16.3. Competitive Analysis
- 16.3.1. Schneider Electric SE
- 16.3.2. Siemens AG
- 16.3.3. ABB Ltd
- 16.3.4. General Electric Company
- 16.3.5. Honeywell International Inc.
- 16.3.6. Cisco Systems, Inc.
- 16.3.7. International Business Machines Corporation
- 16.3.8. Oracle Corporation
- 16.3.9. Itron, Inc.
- 16.3.10. Landis+Gyr AG
Pricing
Currency Rates
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