research-article

Small-Scale Communities Are Sufficient for Cost- and Data-Efficient Peer-to-Peer Energy Sharing

Authors:

Romaric Duvignau,

Verena Heinisch,

Lisa Göransson,

Vincenzo Gulisano,

Marina PapatriantafilouAuthors Info & Claims

e-Energy '20: Proceedings of the Eleventh ACM International Conference on Future Energy Systems

Pages 35 - 46

https://doi.org/10.1145/3396851.3397741

Published: 18 June 2020 Publication History

Abstract

Due to ever lower cost, investments in renewable electricity generation and storage have become more attractive to electricity consumers in recent years. At the same time, electricity generation and storage have become something to share or trade locally in energy communities or microgrid systems. In this context, peer-to-peer (P2P) sharing has gained attention, since it offers a way to optimize the cost-benefits from distributed resources, making them financially more attractive. However, it is not yet clear in which situations consumers do have interests to team up and how much cost is saved through cooperation in practical instances. While introducing realistic continuous decisions, through detailed analysis based on large-scale measured household data, we show that the financial benefit of cooperation does not require an accurate forecasting. Furthermore, we provide strong evidence, based on analysis of the same data, that even P2P networks with only 2--5 participants can reach a high fraction (96% in our study) of the potential gain, i.e., of the ideal offline (i.e., non-continuous) achievable gain. Maintaining such small communities results in much lower associated costs and better privacy, as each participant only needs to share its data with 1--4 other peers. These findings shed new light and motivate requirements for distributed, continuous and dynamic P2P matching algorithms for energy trading and sharing.

References

[1]

Valentin Bertsch, Jutta Geldermann, and Tobias Lühn. 2017. What drives the profitability of household PV investments, self-consumption and self-sufficiency? Applied Energy 204 (2017), 1--15.

[2]

Sid Chi-Kin Chau, Jiajia Xu, Wilson Bow, and Khaled Elbassioni. 2019. Peer-to-Peer Energy Sharing: Effective Cost-Sharing Mechanisms and Social Efficiency. In Proceedings of the Tenth ACM International Conference on Future Energy Systems. ACM, 215--225.

Digital Library

[3]

Tianyi Chen and Shengrong Bu. 2019. Realistic Peer-to-Peer Energy Trading Model for Microgrids using Deep Reinforcement Learning. In 2019 IEEE PES Innovative Smart Grid Technologies Europe (ISGT-Europe). IEEE, 1--5.

[4]

Can Dang, Jiangfeng Zhang, Chung-Ping Kwong, and Li Li. 2019. Demand Side Load Management for Big Industrial Energy Users under Blockchain-Based Peer-to-Peer Electricity Market. IEEE Transactions on Smart Grid (2019).

[5]

Philippe Duchon and Romaric Duvignau. 2014. Local update algorithms for random graphs. In Latin American Symposium on Theoretical Informatics. Springer, 367--378.

[6]

Romaric Duvignau, Vincenzo Gulisano, Marina Papatriantafilou, and Vladimir Savic. 2019. Streaming piecewise linear approximation for efficient data management in edge computing. In Proceedings of the 34th ACM/SIGAPP Symposium on Applied Computing. 593--596.

Digital Library

[7]

Zhang Fu, Magnus Almgren, Olaf Landsiedel, and Marina Papatriantafilou. 2014. Online temporal-spatial analysis for detection of critical events in cyber-physical systems. In 2014 IEEE International Conference on Big Data (Big Data). IEEE, 129--134.

[8]

Giorgos Georgiadis and Marina Papatriantafilou. 2012. Adaptive distributed b-matching in overlays with preferences. In International Symposium on Experimental Algorithms. Springer, 208--223.

Digital Library

[9]

Giorgos Georgiadis and Marina Papatriantafilou. 2013. Overlays with preferences: Distributed, adaptive approximation algorithms for matching with preference lists. Algorithms 6, 4 (2013), 824--856.

[10]

Giorgos Georgiadis and Marina Papatriantafilou. 2014. Dealing with storage without forecasts in smart grids: problem transformation and online scheduling algorithm. In Proceedings of the 29th Annual ACM Symposium on Applied Computing. ACM, 518--524.

Digital Library

[11]

Ulf JJ Hahnel, Mario Herberz, Alejandro Pena-Bello, David Parra, and Tobias Brosch. 2019. Becoming prosumer: Revealing trading preferences and decision-making strategies in peer-to-peer energy communities. Energy Policy (2019), 111098.

[12]

William E Hart, Carl D Laird, Jean-Paul Watson, David L Woodruff, Gabriel A Hackebeil, Bethany L Nicholson, and John D Siirola. 2017. Pyomo-optimization modeling in python. Vol. 67. Springer.

[13]

Bastian Havers, Romaric Duvignau, Hannaneh Najdataei, Vincenzo Gulisano, Marina Papatriantafilou, and Ashok Chaitanya Koppisetty. 2020. DRIVEN: A framework for efficient Data Retrieval and clustering in Vehicular Networks. Future Generation Computer Systems 107 (2020), 1--17.

Digital Library

[14]

Verena Heinisch, Lisa Göransson, Mikael Odenberger, and Filip Johansson. 2019. Interconnection of the electricity and heating sectors to support the energy transition in cities. International Journal of Sustainable Energy Planning and Management 24 (2019).

[15]

Verena Heinisch, Mikael Odenberger, Lisa Göransson, and Filip Johnsson. 2019. Organizing prosumers into electricity trading communities: Costs to attain electricity transfer limitations and self-sufficiency goals. International Journal of Energy Research (2019).

[16]

Verena Heinisch, Mikael Odenberger, Lisa Göransson, and Filip Johnsson. 2019. Prosumers in the Electricity System---Household vs. System Optimization of the Operation of Residential Photovoltaic Battery Systems. Frontiers in Energy Research 6 (2019), 145.

[17]

Rodrigo Henriquez-Auba, Patricia Pauli, Dileep Kalathil, Duncan S Callaway, and Kameshwar Poolla. 2018. The Sharing Economy for Residential Solar Generation. In 2018 IEEE Conference on Decision and Control (CDC). IEEE, 7322--7329.

[18]

Jean-Laurent Hippolyte, Shaun Howell, Baris Yuce, Monjur Mourshed, Hassan A Sleiman, Meritxell Vinyals, and Loïs Vanhée. 2016. Ontology-based demand-side flexibility management in smart grids using a multi-agent system. In 2016 IEEE International Smart Cities Conference (ISC2). IEEE, 1--7.

[19]

Joern Hoppmann, Jonas Volland, Tobias S Schmidt, and Volker H Hoffmann. 2014. The economic viability of battery storage for residential solar photovoltaic systems-A review and a simulation model. Renewable and Sustainable Energy Reviews 39 (2014), 1101--1118.

[20]

S Howell, Y Rezgui, JL Hippolyte, and M Mourshed. 2016. Semantic Interoperability for Holonic Energy Optimization of Connected Smart Homes and Distributed Energy Resources. In eWork and eBusiness in Architecture, Engineering and Construction: ECPPM 2016: Proceedings of the 11th European Conference on Product and Process Modelling (ECPPM 2016), Limassol, Cyprus, 7-9 September 2016. CRC Press, 259.

[21]

Dileep Kalathil, Chenye Wu, Kameshwar Poolla, and Pravin Varaiya. 2017. The sharing economy for the electricity storage. IEEE Transactions on Smart Grid 10, 1 (2017), 556--567.

[22]

Arif Khan, Alex Pothen, Md Mostofa Ali Patwary, Nadathur Rajagopalan Satish, Narayanan Sundaram, Fredrik Manne, Mahantesh Halappanavar, and Pradeep Dubey. 2016. Efficient approximation algorithms for weighted b-matching. SIAM Journal on Scientific Computing 38, 5 (2016), S593-S619.

Digital Library

[23]

Ali Khodabakhsh, Jimmy Horn, Evdokia Nikolova, and Emmanouil Pountourakis. 2019. Prosumer Pricing, Incentives and Fairness. In Proceedings of the Tenth ACM International Conference on Future Energy Systems. ACM, 116--120.

Digital Library

[24]

Mohsen Khorasany, Yateendra Mishra, and Gerard Ledwich. 2018. Market framework for local energy trading: a review of potential designs and market clearing approaches. IET Generation, Transmission & Distribution 12, 22 (2018), 5899--5908.

[25]

Harold W Kuhn. 1955. The Hungarian method for the assignment problem. Naval research logistics quarterly 2, 1--2 (1955), 83--97.

[26]

Stephen Lee, Prashant Shenoy, Krithi Ramamritham, and David Irwin. 2018. VSolar: Virtualizing community solar and storage for energy sharing. In Proceedings of the Ninth International Conference on Future Energy Systems. 178--182.

Digital Library

[27]

Woongsup Lee, Lin Xiang, Robert Schober, and Vincent WS Wong. 2014. Direct electricity trading in smart grid: A coalitional game analysis. IEEE Journal on Selected Areas in Communications 32, 7 (2014), 1398--1411.

[28]

Fabio Lilliu, Meritxell Vinyals, Roman Denysiuk, and Diego Reforgiato Recupero. 2019. A novel payment scheme for trading renewable energy in smart grid. In Proc. of the 10-th ACM Int'l Conference on Future Energy Systems. ACM, 111--115.

Digital Library

[29]

Jingkun Liu, Ning Zhang, Chongqing Kang, Daniel S Kirschen, and Qing Xia. 2017. Decision-making models for the participants in cloud energy storage. IEEE Transactions on Smart Grid 9, 6 (2017), 5512--5521.

[30]

Zvi Lotker, Boaz Patt-Shamir, and Seth Pettie. 2015. Improved distributed approximate matching. Journal of the ACM (JACM) 62, 5 (2015), 1--17.

Digital Library

[31]

Xi Luo, Yanfeng Liu, Jiaping Liu, and Xiaojun Liu. 2020. Energy scheduling for a three-level integrated energy system based on energy hub models: A hierarchical Stackelberg game approach. Sustainable Cities and Society 52 (2020), 101814.

[32]

Fredrik Manne, Md Naim, Håkon Lerring, and Mahantesh Halappanavar. 2016. On stable marriages and greedy matchings. In 2016 Proceedings of the Seventh SIAM Workshop on Combinatorial Scientific Computing. SIAM, 92--101.

[33]

Chathurika Prasadini Mediwaththe, Marnie Shaw, Saman Halgamuge, David Smith, and Paul Scott. 2019. An Incentive-compatible Energy Trading Framework for Neighborhood Area Networks with Shared Energy Storage. IEEE Transactions on Sustainable Energy (2019).

[34]

Esther Mengelkamp, Johannes Gärttner, Kerstin Rock, Scott Kessler, Lawrence Orsini, and Christof Weinhardt. 2018. Designing microgrid energy markets: A case study: The Brooklyn Microgrid. Applied Energy 210 (2018), 870--880.

[35]

Ashot Mnatsakanyan and Scott W Kennedy. 2014. A novel demand response model with an application for a virtual power plant. IEEE Transactions on Smart Grid 6, 1 (2014), 230--237.

[36]

Zack Norwood, Emil Nyholm, Todd Otanicar, and Filip Johnsson. 2014. A geospatial comparison of distributed solar heat and power in Europe and the US. PloS one 9, 12 (2014), e112442.

[37]

Emil Nyholm, Joel Goop, Mikael Odenberger, and Filip Johnsson. 2016. Solar photovoltaic-battery systems in Swedish households-Self-consumption and self-sufficiency. Applied energy 183 (2016), 148--159.

[38]

Amrit Paudel, Kalpesh Chaudhari, Chao Long, and Hoay Beng Gooi. 2018. Peer-to-Peer Energy Trading in a Prosumer-Based Community Microgrid: A Game-Theoretic Model. IEEE Trans. on Industrial Electronics 66, 8 (2018), 6087--6097.

[39]

Ruggero Schleicher-Tappeser. 2012. How renewables will change electricity markets in the next five years. Energy policy 48 (2012), 64--75.

[40]

Ashish Shrestha, Rajiv Bishwokarma, Anish Chapagain, Sandesh Banjara, Shanta Aryal, Bijen Mali, Rajiv Thapa, Diwakar Bista, Barry P Hayes, Antonis Papadakis, et al. 2019. Peer-to-Peer Energy Trading in Micro/Mini-Grids for Local Energy Communities: A Review and Case Study of Nepal. IEEE Access 7 (2019), 131911--131928.

[41]

Chen Sijie and Liu Chen-Ching. 2017. From demand response to transactive energy: state of the art. Journal of Modern Power Systems and Clean Energy 5, 1 (2017), 10--19.

[42]

Wayes Tushar, Bo Chai, Chau Yuen, Shisheng Huang, David B Smith, H Vincent Poor, and Zaiyue Yang. 2016. Energy storage sharing in smart grid: A modified auction-based approach. IEEE Transactions on Smart Grid 7, 3 (2016), 1462--1475.

[43]

Wayes Tushar, Chau Yuen, Hamed Mohsenian-Rad, Tapan Kumar Saha, H. Vincent Poor, and Kristin L. Wood. 2018. Transforming Energy Networks via Peer-to-Peer Energy Trading: The Potential of Game-Theoretic Approaches. IEEE Signal Processing Magazine 35 (2018), 90--111.

[44]

Joris van Rooij, Vincenzo Gulisano, and Marina Papatriantafilou. 2018. Locovolt: Distributed detection of broken meters in smart grids through stream processing. In Proceedings of the 12th ACM International Conference on Distributed and Event-based Systems. 171--182.

Digital Library

[45]

Joris van Rooij, Johan Swetzén, Vincenzo Gulisano, Magnus Almgren, and Marina Papatriantafilou. 2018. echidna: Continuous data validation in advanced metering infrastructures. In 2018 IEEE International Energy Conference (ENERGYCON). IEEE, 1--6.

[46]

Mirjam Wattenhofer and Roger Wattenhofer. 2004. Distributed weighted matching. In International Symposium on Distributed Computing. Springer, 335--348.

[47]

Joakim Widén, Ewa Wäckelgård, and Peter D Lund. 2009. Options for improving the load matching capability of distributed photovoltaics: Methodology and application to high-latitude data. Solar Energy 83, 11 (2009), 1953--1966.

[48]

Chenye Wu, Dileep Kalathil, Kameshwar Poolla, and Pravin Varaiya. 2016. Sharing electricity storage. In 2016 IEEE 55th Conference on Decision and Control (CDC). IEEE, 813--820.

Digital Library

[49]

Chenghua Zhang, Jianzhong Wu, Meng Cheng, Yue Zhou, and Chao Long. 2016. A bidding system for peer-to-peer energy trading in a grid-connected microgrid. Energy Procedia 103 (2016), 147--152.

[50]

Zhenyuan Zhang, Haoyue Tang, Qi Huang, and Wei-Jen Lee. 2019. Two-Stages Bidding Strategies for Residential Microgrids Based Peer-to-Peer Energy Trading. In 2019 IEEE/IAS 55th Industrial and Commercial Power Systems Technical Conference (I&CPS). IEEE, 1--9.

[51]

Yanglin Zhou, Song Ci, Ni Lin, Hongjia Li, and Yang Yang. 2018. Distributed Energy Management of P2P Energy Sharing in Energy Internet Based on Cloud Energy Storage. In Proceedings of the Ninth International Conference on Future Energy Systems. ACM, 173--177.

Digital Library

Cited By

Jensen VJensen R(2024)Just Share It! Designing for Justice in Peer-to-Peer Energy-sharingCompanion Publication of the 2024 ACM Designing Interactive Systems Conference10.1145/3656156.3663727(266-270)Online publication date: 1-Jul-2024
https://dl.acm.org/doi/10.1145/3656156.3663727
Jensen VLaursen KJensen RSmith R(2024)Imagining Sustainable Energy Communities: Design Narratives of Future Digital Technologies, Sites, and ParticipationProceedings of the 2024 CHI Conference on Human Factors in Computing Systems10.1145/3613904.3642609(1-17)Online publication date: 11-May-2024
https://dl.acm.org/doi/10.1145/3613904.3642609
Duvignau RGulisano VPapatriantafilou M(2023)Cost-Optimization for Win-Win P2P Energy Systems2023 IEEE Power & Energy Society Innovative Smart Grid Technologies Conference (ISGT)10.1109/ISGT51731.2023.10066367(1-5)Online publication date: 16-Jan-2023
https://doi.org/10.1109/ISGT51731.2023.10066367
Show More Cited By

Index Terms

Small-Scale Communities Are Sufficient for Cost- and Data-Efficient Peer-to-Peer Energy Sharing

Recommendations

An Efficient Hybrid Peer-to-Peer System for Distributed Data Sharing

Peer-to-peer overlay networks are widely used in distributed systems. Based on whether a regular topology is maintained among peers, peer-to-peer networks can be divided into two categories: structured peer-to-peer networks in which peers are connected ...
Efficient and scalable geographical peer matching for P2P energy sharing communities
SAC '22: Proceedings of the 37th ACM/SIGAPP Symposium on Applied Computing

Significant cost reductions attract ever more households to invest in small-scale renewable electricity generation and storage. Energy Peer-to-Peer (P2P) systems have been shown to be beneficial for prosumers and consumers through reductions in energy ...
An efficient and secure overlay network for general peer-to-peer systems

Comments

Information & Contributors

Information

Published In

cover image ACM Other conferences

e-Energy '20: Proceedings of the Eleventh ACM International Conference on Future Energy Systems

June 2020

601 pages

ISBN:9781450380096

DOI:10.1145/3396851

Copyright © 2020 ACM.

Permission to make digital or hard copies of all or part of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for profit or commercial advantage and that copies bear this notice and the full citation on the first page. Copyrights for components of this work owned by others than ACM must be honored. Abstracting with credit is permitted. To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior specific permission and/or a fee. Request permissions from [email protected]

Sponsors

SIGEnergy: ACM Special Interest Group on Energy Systems and Informatics

Publisher

Association for Computing Machinery

New York, NY, United States

Publication History

Published: 18 June 2020

Permissions

Request permissions for this article.

Request Permissions

Check for updates

Author Tags

Qualifiers

Research-article
Research
Refereed limited

Funding Sources

Energy Area of Advance, Chalmers University of Technology

Conference

e-Energy '20

Sponsor:

SIGEnergy

e-Energy '20: The Eleventh ACM International Conference on Future Energy Systems

June 22 - 26, 2020

Virtual Event, Australia

Acceptance Rates

e-Energy '20 Paper Acceptance Rate 77 of 173 submissions, 45%;

Overall Acceptance Rate 160 of 446 submissions, 36%

Contributors

Other Metrics

View Article Metrics

Bibliometrics & Citations

Bibliometrics

Article Metrics

6
Total Citations
View Citations
276
Total Downloads

Downloads (Last 12 months)24
Downloads (Last 6 weeks)7

Reflects downloads up to 06 Oct 2024

Other Metrics

View Author Metrics

Citations

Cited By

Jensen VJensen R(2024)Just Share It! Designing for Justice in Peer-to-Peer Energy-sharingCompanion Publication of the 2024 ACM Designing Interactive Systems Conference10.1145/3656156.3663727(266-270)Online publication date: 1-Jul-2024
https://dl.acm.org/doi/10.1145/3656156.3663727
Jensen VLaursen KJensen RSmith R(2024)Imagining Sustainable Energy Communities: Design Narratives of Future Digital Technologies, Sites, and ParticipationProceedings of the 2024 CHI Conference on Human Factors in Computing Systems10.1145/3613904.3642609(1-17)Online publication date: 11-May-2024
https://dl.acm.org/doi/10.1145/3613904.3642609
Duvignau RGulisano VPapatriantafilou M(2023)Cost-Optimization for Win-Win P2P Energy Systems2023 IEEE Power & Energy Society Innovative Smart Grid Technologies Conference (ISGT)10.1109/ISGT51731.2023.10066367(1-5)Online publication date: 16-Jan-2023
https://doi.org/10.1109/ISGT51731.2023.10066367
Duvignau RGulisano VPapatriantafilou MHong JBures MPark JCerny T(2022)Efficient and scalable geographical peer matching for P2P energy sharing communitiesProceedings of the 37th ACM/SIGAPP Symposium on Applied Computing10.1145/3477314.3507203(187-190)Online publication date: 25-Apr-2022
https://dl.acm.org/doi/10.1145/3477314.3507203
Ghorbani-Renani NOdonkor P(2022)An Energy Cost Optimization Model for Electricity Trading in Community Microgrids2022 IEEE International Smart Cities Conference (ISC2)10.1109/ISC255366.2022.9922504(1-7)Online publication date: 26-Sep-2022
https://doi.org/10.1109/ISC255366.2022.9922504
Duvignau RHeinisch VGöransson LGulisano VPapatriantafilou M(2021)Benefits of small-size communities for continuous cost-optimization in peer-to-peer energy sharingApplied Energy10.1016/j.apenergy.2021.117402301(117402)Online publication date: Nov-2021
https://doi.org/10.1016/j.apenergy.2021.117402

View Options

Get Access

Login options

Check if you have access through your login credentials or your institution to get full access on this article.

Full Access

Get this Publication

View options

PDF

View or Download as a PDF file.

eReader

View online with eReader.

Media

Figures

Other

Tables

View Table of Contents