Conferences related to Smart Grid

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2019 IEEE 69th Electronic Components and Technology Conference (ECTC)

premier components, packaging and technology conference


2018 20th European Conference on Power Electronics and Applications (EPE'18 ECCE Europe)

Energy conversion and conditioning technologies, power electronics, adjustable speed drives and their applications, power electronics for smarter grid, energy efficiency,technologies for sustainable energy systems, converters and power supplies


2018 Asia-Pacific Microwave Conference (APMC)

The conference topics include microwave theory and techniques, and their related technologies and applications. They also include active devices and circuits, passive components, wireless systems, EMC and EMI, wireless power transfer and energy harvesting, antennas and propagation, and others.


2018 IEEE Energy Conversion Congress and Exposition (ECCE)

The scope of ECCE 2018 includes all technical aspects of research, design, manufacture, application and marketing of devices, components, circuits and systems related to energyconversion, industrial power and power electronics.

  • 2019 IEEE Energy Conversion Congress and Exposition (ECCE)

    IEEE-ECCE 2019 brings together practicing engineers, researchers, entrepreneurs and other professionals for interactive and multi-disciplinary discussions on the latest advances in energy conversion technologies. The Conference provides a unique platform for promoting your organization.

  • 2017 IEEE Energy Conversion Congress and Exposition (ECCE)

    ECCE is the premier global conference covering topics in energy conversion from electric machines, power electronics, drives, devices and applications both existing and emergent

  • 2016 IEEE Energy Conversion Congress and Exposition (ECCE)

    The Energy Conversion Congress and Exposition (ECCE) is focused on research and industrial advancements related to our sustainable energy future. ECCE began as a collaborative effort between two societies within the IEEE: The Power Electronics Society (PELS) and the Industrial Power Conversion Systems Department (IPCSD) of the Industry Application Society (IAS) and has grown to the premier conference to discuss next generation technologies.

  • 2015 IEEE Energy Conversion Congress and Exposition

    The scope of ECCE 2015 includes all technical aspects of research, design, manufacture, application and marketing of devices, components, circuits and systems related to energy conversion, industrial power and power electronics.

  • 2014 IEEE Energy Conversion Congress and Exposition (ECCE)

    Those companies who have an interest in selling to: research engineers, application engineers, strategists, policy makers, and innovators, anyone with an interest in energy conversion systems and components.

  • 2013 IEEE Energy Conversion Congress and Exposition (ECCE)

    The scope of the congress interests include all technical aspects of the design, manufacture, application and marketing of devices, components, circuits and systems related to energy conversion, industrial power conversion and power electronics.

  • 2012 IEEE Energy Conversion Congress and Exposition (ECCE)

    The IEEE Energy Conversion Congress and Exposition (ECCE) will be held in Raleigh, the capital of North Carolina. This will provide a forum for the exchange of information among practicing professionals in the energy conversion business. This conference will bring together users and researchers and will provide technical insight as well.

  • 2011 IEEE Energy Conversion Congress and Exposition (ECCE)

    IEEE 3rd Energy Conversion Congress and Exposition follows the inagural event held in San Jose, CA in 2009 and 2nd meeting held in Atlanta, GA in 2010 as the premier conference dedicated to all aspects of energy processing in industrial, commercial, transportation and aerospace applications. ECCE2011 has a strong empahasis on renewable energy sources and power conditioning, grid interactions, power quality, storage and reliability.

  • 2010 IEEE Energy Conversion Congress and Exposition (ECCE)

    This conference covers all areas of electrical and electromechanical energy conversion. This includes power electrics, power semiconductors, electric machines and drives, components, subsystems, and applications of energy conversion systems.

  • 2009 IEEE Energy Conversion Congress and Exposition (ECCE)

    The scope of the conference include all technical aspects of the design, manufacture, application and marketing of devices, circuits, and systems related to electrical energy conversion technology


2018 IEEE Innovative Smart Grid Technologies - Asia (ISGT Asia)

The IEEE PES ISGT Asia 2018 conference will be a melting pot of participants from academia, industry, research and development organizations, electric power utilities, power and energy sector service providers to discuss, share and exchange ideas related to state-of-the-art innovations in smart grid technologies for the future grid. The theme of this year’s conference is “Smart Grid Technologies for Smart Nations” and includes industrial panel sessions, keynote speeches, tutorials, papers and poster presentation.

  • 2017 IEEE Innovative Smart Grid Technologies - Asia (ISGT-Asia)

    Sustainable Power and energy systems, Smart Grid and Smart Cities,

  • 2016 IEEE Innovative Smart Grid Technologies - Asia (ISGT-Asia)

    The conference will focus on power and energy systems and in particular application of innovative technologies to control and operate power grids.

  • 2015 IEEE Innovative Smart Grid Technologies - Asia (ISGT ASIA)

    ISGT Asia 2015 Bangkok will be a venue for stakeholders from the academia, electric utilities and the power industry to share and exchange experiences and new ideas which will contribute to the development of Smart Grid implementation and related technologies.

  • 2014 IEEE Innovative Smart Grid Technologies - Asia (ISGT ASIA)

    Renewable power generation and its efficient utilization 2) Smart grid information technology 3) Smart power bulk transmission system and EHV/UHV 4) Smart distribution system 5) Smart grid planning, assessment and management 6) Smart grid operation, control and protection 7) Electricity market under smart grid 8) Power quality and electromagnetic compatibility 9) Power electronics and its applications 10) Equipment and its technologies in power system

  • 2013 IEEE Innovative Smart Grid Technologies - Asia (ISGT Asia)

    The Conference on Innovative Smart Grid Technologies (ISGT ASIA 2013), sponsored by the IEEE Power & Energy Society (PES), will be held at Bangalore, India. The conference will be a forum for the participants to discuss state-of-the-art innovations in smart grid technologies. The Conference will feature plenary sessions, panels, technical papers, and tutorials by international experts on smart grid applications.

  • 2012 IEEE Innovative Smart Grid Technologies - Asia (ISGT Asia)

    1) Renewable power generation and its efficient utilization 2) Smart grid information technology 3) Smart power bulk transmission system and EHV/UHV 4) Smart distribution system 5) Smart grid planning, assessment and management 6) Smart grid operation, control and protection 7) Electricity market under smart grid 8) Power quality and electromagnetic compatibility 9) Power electronics and its applications 10) Equipment and its technologies in power system


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Periodicals related to Smart Grid

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Applied Superconductivity, IEEE Transactions on

Contains articles on the applications and other relevant technology. Electronic applications include analog and digital circuits employing thin films and active devices such as Josephson junctions. Power applications include magnet design as well asmotors, generators, and power transmission


Circuits and Systems Magazine, IEEE


Dielectrics and Electrical Insulation, IEEE Transactions on

Electrical insulation common to the design and construction of components and equipment for use in electric and electronic circuits and distribution systems at all frequencies.


Electromagnetic Compatibility, IEEE Transactions on

EMC standards; measurement technology; undesired sources; cable/grounding; filters/shielding; equipment EMC; systems EMC; antennas and propagation; spectrum utilization; electromagnetic pulses; lightning; radiation hazards; and Walsh functions


Energy Conversion, IEEE Transaction on

Research, development, design, application, construction, installation, and operation of electric power generating facilities (along with their conventional, nuclear, or renewable sources) for the safe, reliable, and economic generation of electrical energy for general industrial, commercial, public, and domestic consumption, and electromechanical energy conversion for the use of electrical energy


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Xplore Articles related to Smart Grid

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Sharing Storage in a Smart Grid: A Coalitional Game Approach

[{u'author_order': 1, u'affiliation': u'Department of Mechanical Engineering, University of California, Berkeley, CA, USA.', u'full_name': u'Pratyush Chakraborty'}, {u'author_order': 2, u'affiliation': u'Instituto de las Tecnologías Avanzadas de la Producción, Universidad de Valladolid, Valladolid, Spain.', u'full_name': u'Enrique Baeyens'}, {u'author_order': 3, u'affiliation': u'Department of Electrical Engineering and Computer Science, University of California, Berkeley, CA, USA.', u'full_name': u'Kameshwar Poolla'}, {u'author_order': 4, u'affiliation': u'Department of Electrical Engineering and Computer Science, University of California, Irvine, CA, USA.', u'full_name': u'Pramod P. Khargonekar'}, {u'author_order': 5, u'affiliation': u'Department of Electrical Engineering and Computer Science, University of California, Berkeley, CA, USA.', u'full_name': u'Pravin Varaiya'}] IEEE Transactions on Smart Grid, None

Sharing economy is a transformative socio-economic phenomenon built around the idea of sharing underused resources and services, e.g. transportation and housing, thereby reducing costs and extracting value. Anticipating continued reduction in the cost of electricity storage, we look into the potential opportunity in electrical power system where consumers share storage with each other. We consider two different scenarios. In the ...


Indemnity for Frequency Disruption in a Smart Grid during Cyber–Attack

[{u'author_order': 1, u'affiliation': u'Department of Electrical & Electronic Engineering, Rajshahi University of Engineering & Technology, Rajshahi, 6204, Bangladesh', u'full_name': u'M. A. Rahman'}, {u'author_order': 2, u'affiliation': u'Department of Electrical & Electronic Engineering, Rajshahi University of Engineering & Technology, Rajshahi, 6204, Bangladesh', u'full_name': u'M. S. Rana'}, {u'author_order': 3, u'affiliation': u'Department of Electrical & Electronic Engineering, Rajshahi University of Engineering & Technology, Rajshahi, 6204, Bangladesh', u'full_name': u'M. S. Anower'}] 2017 2nd International Conference on Electrical & Electronic Engineering (ICEEE), None

Indemnity for frequency disruption in smart grid system due to cyber-attack is essential to avoid unstable power supply which can cause severe blackout. In this paper, a protective model is proposed for providing robust control of frequency in any situation, especially during cyber-attack on automatic generation control. A controlled switching unit is included in the protective model for ensuring protection ...


Security Challenges in the Smart Grid Communication Infrastructure

[{u'author_order': 1, u'full_name': u'Feng Ye'}, {u'author_order': 2, u'full_name': u'Yi Qian'}, {u'author_order': 3, u'full_name': u'Rose Qingyang Hu'}] Smart Grid Communication Infrastructures:Big Data, Cloud Computing, and Security, None

This chapter discusses security challenges and some solutions for the smart grid communication infrastructure. It describes the requirements for building a reliable smart grid communications network, especially the requirements for the utility's private and public networks used in the smart grid. A logical security architecture needs to provide protection for data at all interfaces within and among all smart grid ...


Background of the Smart Grid

[{u'author_order': 1, u'full_name': u'Feng Ye'}, {u'author_order': 2, u'full_name': u'Yi Qian'}, {u'author_order': 3, u'full_name': u'Rose Qingyang Hu'}] Smart Grid Communication Infrastructures:Big Data, Cloud Computing, and Security, None

This chapter introduces the background of the smart grid, including its motivations, communication architecture, applications, and requirements. In order to achieve the objectives of the smart grid, several important applications must be added to or upgraded in the current power grid. The most important applications and requirements include demand response, advanced metering infrastructure, wide‐area situational awareness and wide‐area monitoring systems, ...


Smart Grid Communication Infrastructures

[{u'author_order': 1, u'full_name': u'Feng Ye'}, {u'author_order': 2, u'full_name': u'Yi Qian'}, {u'author_order': 3, u'full_name': u'Rose Qingyang Hu'}] Smart Grid Communication Infrastructures:Big Data, Cloud Computing, and Security, None

This chapter explores an information and communication technologies (ICT) framework to support the smart grid. It focuses on the communication networks and their roles and requirements in the smart grid communication infrastructures. Of the four entities in the ICT framework, internal data collectors, the service provider, and power generators are directly related to the smart grid. Communications in the smart ...


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Educational Resources on Smart Grid

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eLearning

No eLearning Articles are currently tagged "Smart Grid"

IEEE-USA E-Books

  • Security Challenges in the Smart Grid Communication Infrastructure

    This chapter discusses security challenges and some solutions for the smart grid communication infrastructure. It describes the requirements for building a reliable smart grid communications network, especially the requirements for the utility's private and public networks used in the smart grid. A logical security architecture needs to provide protection for data at all interfaces within and among all smart grid domains. The chapter categorizes all interfaces into two classes: utility‐owned private networks and public networks in the smart grid. The chapter also discusses the component‐based attacks and protocol based attacks in the smart grid communications infrastructure. A more comprehensive information communications technology framework is required in the smart grid to better evaluate security in the communication infrastructure. The chapter lists a few selected standards proposed for the traditional power grid and the smart grid.

  • Background of the Smart Grid

    This chapter introduces the background of the smart grid, including its motivations, communication architecture, applications, and requirements. In order to achieve the objectives of the smart grid, several important applications must be added to or upgraded in the current power grid. The most important applications and requirements include demand response, advanced metering infrastructure, wide‐area situational awareness and wide‐area monitoring systems, and communication networks and cybersecurity. The chapter explores some of the major topics in smart grid communication infrastructures and provides solutions and suggestions. It proposes a complete information and communication technologies (ICT) framework for the smart grid. The chapter introduces big data analytics and cloud computing into the smart grid communications to enhance grid operations and control. It also proposes security schemes for communications in the advanced metering infrastructure, and ID‐based security schemes for transmission over the Internet in the smart grid.

  • Smart Grid Communication Infrastructures

    This chapter explores an information and communication technologies (ICT) framework to support the smart grid. It focuses on the communication networks and their roles and requirements in the smart grid communication infrastructures. Of the four entities in the ICT framework, internal data collectors, the service provider, and power generators are directly related to the smart grid. Communications in the smart grid are achieved through _private_ and _public_ networks. Private networks are deployed and maintained by utilities. Public networks are provided by third‐party service providers, such as cellular connections and the Internet. Communications in the smart grid have various requirements. Some of the major requirements are latency and bandwidth, interoperability, scalability, and security. Those requirements must be considered together in the design and deployment of smart grid communications along with other issues, such as reliability, availability, and cost.

  • Big Data Analytics and Cloud Computing in the Smart Grid

    The advanced communications infrastructure to be deployed in the smart grid is used for data exchange in many systems. This chapter introduces big data analytics and cloud computing and discusses their relevance to the smart grid. It focuses on relevant issues in demand response and wide‐area monitoring for illustration. Applications such as demand response and modern control need the information provided by massive amounts of data. In particular, price and energy forecasts will be produced by big data analytics. Preliminary results were given to demonstrate the importance of big data analytics in energy forecasts. Besides demand response, attack detection in smart grid communications is critical for secure and efficient grid operations. Machine learning and data mining, as well as big data analytics, are useful tools to achieve attack detections for both metering data and sensing data. Thus, energy fraud and system failures can be prevented.

  • A Secure Data Learning Scheme for Big Data Applications in the Smart Grid

    This chapter proposes a secure data learning scheme for big data applications in the information and communication technology infrastructure of the smart grid. The proposed scheme allows multiple parties to find the predictive models from their overall data, while not revealing their own private data to one another at the same time. The chapter also proposes an associated secure scheme to guarantee the privacy of learning results during the information reassembly and value‐response process. The proposed scheme was targeted at improving the potential computation and security drawbacks of the centralized training task of big data applications. An evaluation is performed to verify the privacy of the training data set, as well as the accuracy of learning weights. The chapter presents a case study by adopting the proposed scheme to perform a regression problem and investigate the smart metering data in the smart grid.

  • Security Schemes for Smart Grid Communications over Public Networks

    This chapter focuses on security schemes for smart grid communications over public networks that utility companies subscribe to. The proposed security schemes can be applied by utilities even without full control of the communications network to add extra protection on top of existing security provided by network service providers. The chapter proposes an identity (ID)‐based security scheme to achieve digital signature and encryption simultaneously; thus the proposed scheme is also named as ID‐based signcryption (IBSC). The proposed IBSC scheme was reduced to an ID‐based digital signature scheme if confidentiality is not required for some messages. Performance of the proposed schemes is evaluated based on the number of operations and the efficiency of each type of operations. Delegation of signing rights from one local control center to another local control center was achieved by the proposed identity‐based schemes.

  • Design and Analysis of a Wireless Monitoring Network for Transmission Lines in the Smart Grid

    This chapter designs a monitoring network for the transmission lines in the smart grid, taking advantage of the existing utility backbone network. The designed monitoring network consists of hundreds of wireless sensor nodes that are deployed on top of selected power line transmission towers. The most imperative requirement of the transmission line monitoring network is timely delivery of data while being energy efficient. The chapter proposes several centralized power allocation schemes including two optimization problems, that minimize the total power consumption, a game theoretical scheme, and two relaxed schemes that converge to solutions quickly in a large scale network. A distributed power allocation scheme is proposed to improve the power efficiency of each sensor node for realistic cases with dynamic traffic. The chapter presents a case study to demonstrate the performance of the distributed scheme.

  • Perspectives of Demand‐Side Management Under Smart Grid Concept

    Demand‐side management (DSM) has a key role in the Smart Grid (SG) concept to control the demand‐side consumption and reduce peak loads. The ability to shift peak loads and provide the energy efficiency through better demand‐side management is currently one of the most promising approaches to solve problems related to peak demand. DSM has some different terms such as demand‐side energy management (DSEM), load energy management (LEM), demand response (DR), and automated load management (ALM) and all terms refer to the balancing of energy generation and consumption. DSM includes all the process in demand energy systems such as utilities renovation operations, metering, energy pricing, monitoring, customer comfort, home energy management systems, and so on. In addition, DSM has superior advantage that it is less expensive to intelligently influence a load than to build a new power plant or install some electric storage device. All these DSM strategies are used for optimum and efficient energy consumption. In this chapter, the general perspective is given for DSM under SG concept and describes the DSM architecture and its benefits of the customer side and utility side. Also, it explains the DR techniques and classified DR programs and give some information about dynamic pricing and smart metering. Then the impact of DR programs is discussed in residential energy management perspectives. It also gives some details about home energy management (HEM) concept. Finally, it discusses about DSM standards. In conclusion, the existing DSM applications and what could be done in the future works are discussed.

  • Modeling and Optimization of the Smart Grid Ecosystem

    The aim of the smart electric energy grid is to improve efficiency, flexibility, and stability of the electric energy generation and distribution system, with the ultimate goal being the added value of energy-related services to the end-consumer and to facilitate energy generation and prudent consumption toward energy efficiency. New technologies, such as networks and sensors, are combined with consumer behaviour to create a complex eco-system in which many factors interact. Modeling and Optimization of the Smart Grid Ecosystem gives some structure to the complex ecosystem and surveys key research problems that have shaped the area. The emphasis is on the presentation of the control and optimization methodology used in approaching each of these problems. This methodology spans convex and linear optimization theory, game theory, and stochastic optimization. Modeling and Optimization of the Smart Grid Ecosystem serves as a reference for researchers wishing to understand the fundamental rinciples and research problems underpinning the smart grid ecosystem, and the main mathematical tools used to model and analyze such systems.

  • Detecting Data Integrity Attacks in Smart Grid

    The smart grid, which is denoted as a next‐generation power grid system, integrates information and communication techniques in order to enable efficiency and reliability in energy service for consumers. This chapter shows a framework that can be used to explore different attack scenarios and design detection schemes to deal with data integrity attacks. It introduces the network model and the threat model, and then presents an approach to defend against data integrity attacks in the smart grid. The chapter then discusses the extension of work from the following aspects: detection schemes, scalability of detection, and other defensive schemes. It describes three detection schemes: statistical anomaly‐based detection, machine learning‐based detection, and sequential hypothesis testing‐based detection, and considers both line voltage and power load as detection features. The chapter also presents the performance evaluation conducted to validate the effectiveness of the investigated detection schemes to detect attacks. It explains the evaluation setup and then presents the results.



Standards related to Smart Grid

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Guide for Design, Operation, and Integration of Distributed Resource Island Systems with Electric Power Systems

This document provides alternative approaches and good practices for the design, operation, and integration of distributed resource (DR) island systems with electric power systems (EPS). This includes the ability to separate from and reconnect to part of the area EPS while providing power to the islanded local EPSs. This guide includes the distributed resources, interconnection systems, and participating electric power ...


Guide for Smart Grid Interoperability of Energy Technology and Information Technology Operation with the Electric Power System (EPS), and End-Use Applications and Loads

This document provides guidelines for smart grid interoperability. This guide provides a knowledge base addressing terminology, characteristics, functional performance and evaluation criteria, and the application of engineering principles for smart grid interoperability of the electric power system with end use applications and loads. The guide discusses alternate approaches to good practices for the smart grid.


Guide for Technical Guidelines for Interconnection of Electric Power Sources Greater than 10MVA to the Power Transmission Grid

This document provides guidelines regarding the technical requirements, including design, construction, commissioning acceptance testing and maintenance /performance requirements, for interconnecting dispatchable electric power sources with a capacity of more than 10 MVA to a bulk power transmission grid.


Guide to Conducting Distribution Impact Studies for Distributed Resource Interconnection

This guide describes criteria, scope, and extent for engineering studies of the impact on area electric power systems of a distributed resource or aggregate distributed resource interconnected to an area electric power distribution system.


IEEE Application Guide for IEEE Std 1547™, IEEE Standard for Interconnecting Distributed Resources with Electric Power Systems

This guide provides technical background and application details to support understanding of IEEE Std 1547-2003.


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Jobs related to Smart Grid

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