Your search keyword '"Coalitional Game Theory"' showing total 122 results

1. Enabling Active Distribution Systems’ Participation in Tertiary Frequency Regulation Through Coalitional Game Theory-Based Reserve Allocation

Author

Mukesh Gautam, Mohammad MansourLakouraj, Rakib Hossain, Narayan Bhusal, Mohammed Benidris, and Hanif Livani

Subjects

Coalitional game theory, distributed energy resources, tertiary frequency regulation, Shapley value, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

The integration of distributed energy resources (DERs) into the power grid has made it important for distribution systems to participate in frequency regulation. Regulatory authorities (e.g., Federal Electricity Regulatory Commission in the United States) are recommending that DERs participate in energy and reserve markets, and a mechanism is needed to facilitate this at the distribution level. Though a single distribution system may not have sufficient reserves for tertiary frequency regulation, stacked reserves from multiple distribution systems can be utilized in frequency regulation. This paper proposes a coalitional game theory-based approach for reserve allocation, enabling DERs to participate in tertiary frequency regulation. The proposed two-stage approach involves computing worthiness index (WI) and power loss reduction (PLR) characteristic functions in the first stage and equivalent Shapley values in the second stage. The Shapley values are then used to determine distribution factors for reserve allocation among DERs. We demonstrate the effectiveness of the proposed method through case studies on IEEE 13-node, IEEE 34-node, and IEEE 123-node distribution test systems. The method is shown to be effective in allocating reserves and determining active power set-points of DERs, and can enable efficient participation of DERs in tertiary frequency regulation.

Published

2024

2. Feature Selection as a Hedonic Coalition Formation Game for Arabic Topic Detection.

Author

Koulali, Rim and Koulali, Mohammed-Amine

Subjects

*FEATURE selection, *NATURAL language processing, *COALITIONS

Abstract

• Review of existing feature selection methods for Arabic topic detection. • Introduce a novel Hedonic Coalition Formation Game-based feature selection approach. • Use the proposed approach to provide inputs for an Arabic topic detection system. • Performance comparison against other well-known feature selection method. Arabic topic detection is a Natural Language Processing (NLP) task that aims to assign a topic or a set of topics to a new document based on its content and selected features. Feature selection is an essential topic detection technique used to capture discriminative and descriptive features in documents to enhance the performance of topic detection. This paper proposes a novel feature selection approach formulated as a Hedonic Coalition Formation Game. We use the proposed method to describe each topic with a unique Topic Oriented Vocabulary (TOV) vector. We inspect the performances of the vocabularies obtained by solving the Hedonic game in topic detection over several Arabic corpora. In addition, the proposed feature selection method is compared with a Mutual Information (MI) based vocabulary vector generation method. The reported results show the effectiveness of the proposed feature selection approach by generating new vocabularies with highly discriminating features and reduced dimensions. [ABSTRACT FROM AUTHOR]

Published

2023

3. Contribution- and Participation-Based Federated Learning on Non-IID Data.

Author

Hu, Fei, Zhou, Wuneng, Liao, Kaili, and Li, Hongliang

Subjects

INCENTIVE (Psychology)

Abstract

The learning process takes place inside clients in federated learning (FL). How to effectively motivate clients and avoid the impact of statistical heterogeneity are challenges in FL. This article proposes contribution- and participation-based federated learning (CPFL) to address these challenges. CPFL can effectively allocate client incentives and aggregate models according to client contribution ratios, by which it can reduce the impact of heterogeneous data. To get effective and approximately fair client contributions faster, we propose an extended Raiffa solution (ERS). Compared to the conventional solution Shapley value, the time complexity of ERS goes from $\mathscr {O}(2^{n})$O(2n) down to $\mathscr {O}(n)$O(n). We perform extensive experiments with the MNIST/EMNIST datasets, heterogeneous datasets, and with different ratios of participation reward. Experimental results demonstrate that CPFL generally has a better learning effect in the heterogeneous case. [ABSTRACT FROM AUTHOR]

Published

2022

4. Consumer Flexibility Aggregation Using Partition Function Games With Non-Transferable Utility

Author

Tiago Pinto, Michael Wooldridge, and Zita Vale

Subjects

Coalitional game theory, consumer flexibility, large-scale application, partition function games, non-transferable utility, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper explores the aggregation of electricity consumers flexibility. A novel coalitional game theory model for partition function games with non-transferable utility is proposed. This model is used to formalize a game in which electricity consumers find coalitions among themselves in order to trade their consumption flexibility in the electricity market. Utility functions are defined to enable measuring the players preferences. Two case studies are presented, including a simple illustrative case, which assesses and explains the model in detail; and a large-scale scenario based on real data, comprising more than 20,000 consumers. Results show that the proposed model is able to reach solutions that are more suitable for the consumers when compared to the solutions achieved by traditional aggregation techniques in power and energy systems, such as clustering-based methodologies. The solutions found by the proposed model consider the perspectives from all players involved in the game and thus are able to reflect the rational behaviour of the involved players, rather than imposing an aggregation solution that is only beneficial from the perspective of the aggregator.

Published

2021

5. Coalitional Game Theory Based Value Sharing in Energy Communities

Author

Amir Safdarian, Poria Astero, Marius Baranauskas, Antti Keski-Koukkari, and Anna Kulmala

Subjects

Coalitional game theory, energy community, optimization problem, payoff allocation, prosumer, redundant constraint, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper presents a coalitional game for value sharing in energy communities (ECs). It is proved that the game is super-additive, and the grand coalition effectively increases the global payoff. It is also proved that the model is balanced and thus, it has a nonempty core. This means there always exists at least one value sharing mechanism that makes the grand coalition stable. Therefore, prosumers will always achieve lower bills if they join to form larger ECs. A counterexample is presented to demonstrate that the game is not convex and value sharing based on Shapley values does not necessarily ensure the stability of the coalition. To find a stabilizing value sharing mechanism that belongs to the core of the game, the worst-case excess minimization concept is applied. In this concept, however, size of the optimization problem increases exponentially with respect to the number of members in EC. To make the problem computationally tractable, the idea of clustering members based on their generation/load profiles and considering the same profile and share for members in the same cluster is proposed here. K-means algorithm is used for clustering prosumers’ profiles. This way, the problem would have several redundant constraints that can be removed. The redundant constraints are identified and removed via the generalized Llewellyn’s rules. Finally, value sharing in an apartment building in the southern part of Finland in the metropolitan area is studied to demonstrate effectiveness of the method.

Published

2021

6. Modeling Economic Sharing of Joint Assets in Community Energy Projects Under LV Network Constraints

Author

Sonam Norbu, Benoit Couraud, Valentin Robu, Merlinda Andoni, and David Flynn

Subjects

Battery degradation model, coalitional game theory, community energy storage, community vs individual energy assets, energy community, energy sharing mechanism, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

The trend of decentralization of energy services has given rise to community energy systems. These energy communities aim to maximize the self-consumption of local renewable energy generated and stored in assets that are typically connected to low-voltage (LV) distribution networks. Energy community schemes often involve jointly owned assets such as community-owned solar photo-voltaic panels (PVs), wind turbines and/or shared battery storage. This raises the question of how these assets should be controlled in real-time, and how the energy outputs from these jointly owned assets should be shared fairly among heterogeneous community members. Crucially, such real-time control and fair sharing of energy must also consider the technical constraints of the community, such as the local LV network characteristics, voltage limits and power ratings of electric cables and transformers. In this paper, we design and analyze a heuristic-based battery control algorithm that considers the influence of battery life degradation, and the resultant increase in local renewable energy consumption within local operating constraints of the LV network. We provide a model that first studies the techno-economic benefits of community-owned versus individually-owned energy assets considering the network/grid constraints. Then, using the methodology and principles from cooperative game theory, we propose a redistribution model for benefits in a community based on the marginal contribution of each household. The results from our study demonstrate that the redistribution mechanism is fairer and computationally tractable compared to the existing state-of-the-art methods. Thus, our methodology is more scalable with respect to modeling the economic sharing of joint assets in community energy systems.

Published

2021

7. Game theoretic centrality: a novel approach to prioritize disease candidate genes by combining biological networks with the Shapley value

Author

Min Woo Sun, Stefano Moretti, Kelley M. Paskov, Nate T. Stockham, Maya Varma, Brianna S. Chrisman, Peter Y. Washington, Jae-Yoon Jung, and Dennis P. Wall

Subjects

Coalitional game theory, Biological network, Shapley value, Game theoretic centrality, Autism spectrum disorder, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Background Complex human health conditions with etiological heterogeneity like Autism Spectrum Disorder (ASD) often pose a challenge for traditional genome-wide association study approaches in defining a clear genotype to phenotype model. Coalitional game theory (CGT) is an exciting method that can consider the combinatorial effect of groups of variants working in concert to produce a phenotype. CGT has been applied to associate likely-gene-disrupting variants encoded from whole genome sequence data to ASD; however, this previous approach cannot take into account for prior biological knowledge. Here we extend CGT to incorporate a priori knowledge from biological networks through a game theoretic centrality measure based on Shapley value to rank genes by their relevance–the individual gene’s synergistic influence in a gene-to-gene interaction network. Game theoretic centrality extends the notion of Shapley value to the evaluation of a gene’s contribution to the overall connectivity of its corresponding node in a biological network. Results We implemented and applied game theoretic centrality to rank genes on whole genomes from 756 multiplex autism families. Top ranking genes with the highest game theoretic centrality in both the weighted and unweighted approaches were enriched for pathways previously associated with autism, including pathways of the immune system. Four of the selected genes HLA-A, HLA-B, HLA-G, and HLA-DRB1–have also been implicated in ASD and further support the link between ASD and the human leukocyte antigen complex. Conclusions Game theoretic centrality can prioritize influential, disease-associated genes within biological networks, and assist in the decoding of polygenic associations to complex disorders like autism.

Published

2020

8. Utility Aware Cooperative Spectrum Sensing Using Coalitional Game Theory

Author

Chauhan, Prakash, Sharma, Meenakshi, Deka, Sanjib K., Sarma, Nityananda, Kacprzyk, Janusz, Series Editor, Mandal, J. K., editor, Saha, Goutam, editor, Kandar, Debdatta, editor, and Maji, Arnab Kumar, editor

Published

2018

9. A Coalitional Game-Theoretic Framework for Cooperative Data Exchange Using Instantly Decodable Network Coding

Author

Mariem Zayene, Oussama Habachi, Vahid Meghdadi, Tahar Ezzedine, and Jean Pierre Cances

Subjects

Coalitional game theory, cooperative data exchange, instantly decodable network coding, unmanned aerial network, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper investigates the cooperative data exchange (CDE) scheme using the instantly decodable network coding across energy-constrained devices over the wireless channels. In fact, enabling the CDE brings several challenges, such as how to extend the network lifetime and how to reduce the number of transmissions in order to satisfy the urgent delay requirements. The problem is modeled using the cooperative game theory in partition form. Unlike most existing studies, which are only delay-sensitive, we take into account both the completion time and the consumed energy. We propose a distributed merge-and-split algorithm to allow the wireless nodes to self-organize into the independent disjoint coalitions in a distributed manner. Indeed, the proposed algorithm guarantees reduced energy consumption and minimizes the delay in the resulting clustered network structure. Note that we have considered not only the transmission energy but also the computational energy consumption. Moreover, we focus on the mobility issue and we analyze how, in the proposed framework, the nodes can adapt to the dynamics of the network. Such an important result offers insights into how to design the scalable energy and delay aware CDE framework. The simulation results validate the proposed framework and show that, interestingly, the nodes reduce both the energy consumption and the completion time.

Published

2019

10. User Grouping for Hybrid VLC/RF Networks With NOMA: A Coalitional Game Approach

Author

Vasilis K. Papanikolaou, Panagiotis D. Diamantoulakis, and George K. Karagiannidis

Subjects

Coalitional game theory, heterogeneous network, non-orthogonal multiple access (NOMA), user grouping, visible light communications (VLC), Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Recently, visible light communication (VLC) networks have emerged as a promising alternative for indoor data access, due to high data rate, low implementation cost, and immunity to radio frequency (RF) interference. However, the co-existence of VLC with the RF access points as well as the dependence of VLC to room illumination compel both technologies to work in parallel and thus, to form a hybrid heterogeneous VLC/RF network. This network offers the advantages of both technologies, namely increased capacity and ubiquitous coverage. Furthermore, non-orthogonal multiple access (NOMA) is a very promising candidate technique for the next generation of wireless networks, mainly due to its increased spectrum efficiency compared to orthogonal access schemes. However, the optimal user grouping in NOMA is a combinatorial NP-complete problem, which calls for low complexity techniques. To this end, in this paper, we propose the use of coalitional game theory, where the users served by the same access point (VLC or RF) form a single coalition, while the users can switch through coalitions based on their payoff. A novel utility function is proposed that takes into account the peculiarities of the NOMA hybrid VLC/RF network. Finally, a coalition formation algorithm is presented as well as an efficient power allocation policy. Computer simulations validate the presented analysis and reveal the effectiveness of the proposed user grouping scheme compared to an opportunistic approach.

Published

2019

11. Joint Power Control and Subchannel Allocation for D2D Communications Underlaying Cellular Networks: A Coalitional Game Perspective

Author

Dong, Yanjie, Hossain, Md. Jahangir, Cheng, Julian, Akan, Ozgur, Series editor, Bellavista, Paolo, Series editor, Cao, Jiannong, Series editor, Coulson, Geoffrey, Series editor, Dressler, Falko, Series editor, Ferrari, Domenico, Series editor, Gerla, Mario, Series editor, Kobayashi, Hisashi, Series editor, Palazzo, Sergio, Series editor, Sahni, Sartaj, Series editor, Shen, Xuemin Sherman, Series editor, Stan, Mircea, Series editor, Xiaohua, Jia, Series editor, Zomaya, Albert Y., Series editor, Cheng, Julian, editor, Hossain, Ekram, editor, Zhang, Haijun, editor, Saad, Walid, editor, and Chatterjee, Mainak, editor

Published

2017

12. A Cooperative Task Allocation Game for Multi-Target Imaging in Radar Networks.

Author

Wang, Dan, Li, Kai-Ming, Zhang, Qun, Lu, Xiao-Fei, and Luo, Ying

Abstract

In radar networks, research on the task allocation strategy for multi-target imaging is essential, especially under limited radar resources. From the targets’ perspective, the goal is to acquire enough resources to obtain high-quality inverse synthetic aperture radar (ISAR) images. Then there is competition among targets for radar resources. Therefore, the task allocation optimization problem is considered as a cooperative game, specifically a non-transferable coalitional game when the sparse ISAR imaging algorithm is adopted. A stable coalition structure, which allows cooperation among targets to achieve satisfactory image resolution using the least amount of time, represents an optimal task allocation scheme. Then, the corresponding algorithm based on coalition-forming rules is proposed. Through the framework of cooperative game theory, a stable network structure (i.e., the task allocation strategy) is formed while minimizing the radar time resource cost. Finally, experiments confirm that the proposed algorithm can achieve an optimal task allocation strategy with a lower computation time cost. [ABSTRACT FROM AUTHOR]

Published

2021

13. Game theoretic centrality: a novel approach to prioritize disease candidate genes by combining biological networks with the Shapley value.

Author

Sun, Min Woo, Moretti, Stefano, Paskov, Kelley M., Stockham, Nate T., Varma, Maya, Chrisman, Brianna S., Washington, Peter Y., Jung, Jae-Yoon, and Wall, Dennis P.

Subjects

*GENES, *BIOLOGICAL networks, *HLA histocompatibility antigens, *AUTISM spectrum disorders, *CENTRALITY, *GAME theory

Abstract

Background: Complex human health conditions with etiological heterogeneity like Autism Spectrum Disorder (ASD) often pose a challenge for traditional genome-wide association study approaches in defining a clear genotype to phenotype model. Coalitional game theory (CGT) is an exciting method that can consider the combinatorial effect of groups of variants working in concert to produce a phenotype. CGT has been applied to associate likely-gene-disrupting variants encoded from whole genome sequence data to ASD; however, this previous approach cannot take into account for prior biological knowledge. Here we extend CGT to incorporate a priori knowledge from biological networks through a game theoretic centrality measure based on Shapley value to rank genes by their relevance–the individual gene's synergistic influence in a gene-to-gene interaction network. Game theoretic centrality extends the notion of Shapley value to the evaluation of a gene's contribution to the overall connectivity of its corresponding node in a biological network. Results: We implemented and applied game theoretic centrality to rank genes on whole genomes from 756 multiplex autism families. Top ranking genes with the highest game theoretic centrality in both the weighted and unweighted approaches were enriched for pathways previously associated with autism, including pathways of the immune system. Four of the selected genes HLA-A, HLA-B, HLA-G, and HLA-DRB1–have also been implicated in ASD and further support the link between ASD and the human leukocyte antigen complex. Conclusions: Game theoretic centrality can prioritize influential, disease-associated genes within biological networks, and assist in the decoding of polygenic associations to complex disorders like autism. [ABSTRACT FROM AUTHOR]

Published

2020

14. Core-Selecting Mechanisms in Electricity Markets.

Author

Karaca, Orcun and Kamgarpour, Maryam

Abstract

Due to its theoretical virtues, several recent works propose the use of the incentive-compatible Vickrey–Clarke–Groves (VCG) mechanism for electricity markets. Coalitions of participants, however, can influence the VCG outcome to obtain higher collective utility. To address this issue, core-selecting mechanisms are proposed for their coalition-proofness. We show that core-selecting mechanisms generalize the economic rationale of the locational marginal pricing (LMP) mechanism. Namely, these mechanisms are the exact class of mechanisms that ensure the existence of a competitive equilibrium in linear/nonlinear prices. This implies that the LMP mechanism is also core-selecting, and hence coalition-proof. In contrast to the LMP mechanism, core-selecting mechanisms exist for a broad class of electricity markets, such as ones involving nonconvex costs and nonconvex constraint sets. In addition, they can approximate truthfulness without the price-taking assumption of the LMP mechanism. Finally, we show that they are also budget-balanced. Our results are verified with case studies based on OPF test systems and Swiss reserve market. [ABSTRACT FROM AUTHOR]

Published

2020

15. Coalitional Games for Computation Offloading in NOMA-Enabled Multi-Access Edge Computing.

Author

Pham, Quoc-Viet, Nguyen, Hoang T., Han, Zhu, and Hwang, Won-Joo

Subjects

*COOPERATIVE game theory, *RADIO access networks, *ALGORITHMS, *ENERGY consumption, *GAMES

Abstract

Multi-access edge computing (MEC) and nonorthogonal multiple access (NOMA) are two enabling technologies in the 5 G network and beyond. MEC admits user equipments (UEs) running many more compute-intensive applications by providing computing capabilities at the network edge and within radio access networks, while NOMA enables multiple UEs to share the same resource block, thus leveraging considerable advantages such as greater spectral efficiency and a larger number of supported UEs. The state-of-the-art showed that the combination of NOMA and MEC can lower the energy consumption and/or overall latency; however, they mostly focused on single-carrier NOMA. In this paper, we investigate the computation offloading problem in multi-carrier NOMA enabled MEC systems and solve it from the cooperative game theory viewpoint using coalition formation game. Particularly, UEs are considered as game players and subcarriers are regarded as coalitions that can be used for computation offloading of multiple UEs. Based on the introduced coalition formation game, we develop a low-complexity algorithm with convergence guarantee to achieve the Nash-stable solution. Numerical results are provided to validate the effectiveness of the proposed coalition game based algorithm as well as its comparison with three baseline schemes. [ABSTRACT FROM AUTHOR]

Published

2020

16. Multi-objective distributed cooperative spectrum sensing for cognitive radio networks using greedy-based coalitional game.

Author

Chauhan, Prakash, Deka, Sanjib K., and Sarma, Nityananda

Subjects

COGNITIVE radio, RADIO networks, POLYNOMIAL time algorithms, HEURISTIC algorithms, GLOBAL optimization, COMPUTATIONAL complexity

Abstract

In this work, we propose a distributed cooperative spectrum sensing (CSS) scheme for cognitive radio networks applying a greedy-based coalitional game. We formulate the cooperative spectrum sensing problem as a multi-objective optimization problem using the weighted global criteria method. The objective of the formulated problem is to jointly consider the relative impacts of the three key performance metrics in CSS: throughput gain, penalty cost, and energy overhead. By integrating these three distinct metrics into a global optimization problem, we aimed to achieve a well-balanced trade-off, essential for deploying the CSS scheme across diverse network and application environments. We prove that the formulated CSS problem is non-deterministic polynomially hard (NP-hard). The computational complexity of the formulated CSS problem is decreased by proposing a heuristic scheme that produces a sub-optimal solution in polynomial time. We develop the heuristic scheme by putting forward a greedy-based coalitional game theoretic model. The proposed scheme exploits the spatial diversity of secondary users (SUs) in forming distributed coalitions to minimize the effects of attenuation and distortion on the transmitted signal. Further sensing energy overhead is reduced by dynamically deciding the sensing duration for the SUs based on their received signal strength. To establish the stability of the coalitional game model, we carry out proof which shows that the proposed heuristic algorithm converges to a stable coalition structure. Simulation-based results show the effectiveness of the proposed scheme in terms of average detection accuracy, utility, and energy overhead compared to conventional schemes. [ABSTRACT FROM AUTHOR]

Published

2023

17. Power Trading Coordination in Smart Grids Using Dynamic Learning and Coalitional Game Theory

Author

Shams, Farshad, Tribastone, Mirco, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Campos, Javier, editor, and Haverkort, Boudewijn R., editor

Published

2015

18. Robust coalitional game theoretic optimisation for cooperative energy hubs with correlated wind power.

Author

Cong, Hao, Wang, Xu, and Jiang, Chuanwen

Abstract

As the development of the energy industry, the integration and complementary of various energy resources will be trends of future multiple energy systems. Energy hub (EH) plays an important role in allocating energy resources efficiently. This study proposes a robust coalitional game theoretic optimisation model to execute the cooperative operation of multiple EHs with correlated wind power. First, an EH model with wind power generation is established. It considers both uncertainties and correlations of wind power. Then, coalitional game theory is introduced to solve the cooperation problem of multiple EHs. Distributed coalition formation algorithm called merge–split rule is developed to form coalitions of EHs. Furthermore, the robust optimisation method is presented to cope with the uncertainties of wind power. Scenarios of correlated historical data are covered by minimum volume enclosing ellipsoid and solved by Khachiyan's first‐order algorithm. Numerical results are given to verify the feasibility and efficiency of our proposed models and methods. [ABSTRACT FROM AUTHOR]

Published

2019

19. Secret-Key Generation in Many-to-One Networks: An Integrated Game-Theoretic and Information-Theoretic Approach.

Author

Chou, Remi A. and Yener, Aylin

Subjects

*RANDOM variables, *GENERATIONS, *PUBLIC communication, *GAME theory, *SELF-interest

Abstract

This paper considers secret-key generation between several agents and a base station that observe independent and identically distributed realizations of correlated random variables. Each agent wishes to generate the longest possible individual key with the base station by means of public communication. All keys must be jointly kept secret from all external entities. In this many-to-one secret-key generation setting, it can be shown that the agents can take advantage of a collective protocol to increase the sum rate of their generated keys. However, when each agent is only interested in maximizing its own secret-key rate, agents may be unwilling to participate in a collective protocol. Furthermore, when such a collective protocol is employed, how to fairly allocate individual key rates arises as a valid issue. This paper studies the tension between cooperation and self-interest with a game-theoretic treatment. This paper establishes that cooperation is in the best interest of all individualistic agents and that there exist individual secret-key rate allocations that incentivize the agents to follow the protocol. In addition, an explicit coding scheme that achieves such allocations is proposed. [ABSTRACT FROM AUTHOR]

Published

2019

20. Enabling inter-area reserve exchange through stable benefit allocation mechanisms

Author

Orcun Karaca, Stefanos Delikaraoglou, Gabriela Hug, and Maryam Kamgarpour

Subjects

Electricity markets, Information Systems and Management, Strategy and Management, part i, core, Stochastic programming, integration, Management Science and Operations Research, expansion, Bilevel programming, power-systems, Optimization and Control (math.OC), generation, electricity market, FOS: Mathematics, procurement, nucleolus, Coalitional game theory, Mathematics - Optimization and Control, energy

Abstract

The establishment of a single European day-ahead market has accomplished the integration of the regional day-ahead markets. However, reserve provision and activation remain an exclusive responsibility of regional operators. This limited spatial coordination and the separated structure hinder the efficient utilization of flexible generation and transmission, since their capacities have to be ex-ante allocated between energy and reserves. To promote reserve exchange, recent work proposed a preemptive model that withdraws a portion of the inter-area transmission capacity available from day-ahead energy for reserves by minimizing the expected system cost. This decision-support tool, formulated as a stochastic bilevel program, respects the current architecture but does not suggest area-specific costs that guarantee sufficient benefits for areas to accept the solution. To this end, we formulate a preemptive model in a framework that allows application of game theory methods to obtain a stable benefit allocation, i.e., an outcome immune to coalitional deviations ensuring willingness of areas to coordinate. We show that benefit allocation mechanisms can be formulated either at the day-ahead or the real-time stages, in order to distribute the expected or the scenario-specific benefits, respectively. For both games, the proposed benefits achieve minimal stability violation, while allowing for a tractable computation with limited queries to the bilevel program. Our case studies, based on an illustrative and a more realistic test case, compare our method with well-studied benefit allocations, namely, the Shapley value and nucleolus, and analyze the factors that drive these allocations (e.g., flexibility, network structure, wind correlations). We show that our method performs better in stability and tractability., Omega (United Kingdom), 113

Published

2022

21. An Approach for Sponsored Search Auctions Based on the Coalitional Game Theory

Author

Xu, Wenlin, Yue, Kun, Li, Jin, Duan, Liang, Liu, Suiye, Liu, Weiyi, Hutchison, David, editor, Kanade, Takeo, editor, Kittler, Josef, editor, Kleinberg, Jon M., editor, Mattern, Friedemann, editor, Mitchell, John C., editor, Naor, Moni, editor, Nierstrasz, Oscar, editor, Pandu Rangan, C., editor, Steffen, Bernhard, editor, Sudan, Madhu, editor, Terzopoulos, Demetri, editor, Tygar, Doug, editor, Vardi, Moshe Y., editor, Weikum, Gerhard, editor, Lin, Xuemin, editor, Manolopoulos, Yannis, editor, Srivastava, Divesh, editor, and Huang, Guangyan, editor

Published

2013

22. Hierarchical Coalition Formation Game of Relay Transmission in IEEE 802.16m

Author

Niyato, Dusit, Zhou, Xiangyun, Hjørungnes, Are, Wang, Ping, Li, Yifan, Akan, Ozgur, Series editor, Bellavista, Paolo, Series editor, Cao, Jiannong, Series editor, Dressler, Falko, Series editor, Ferrari, Domenico, Series editor, Gerla, Mario, Series editor, Kobayashi, Hisashi, Series editor, Palazzo, Sergio, Series editor, Sahni, Sartaj, Series editor, Shen, Xuemin (Sherman), Series editor, Stan, Mircea, Series editor, Xiaohua, Jia, Series editor, Zomaya, Albert, Series editor, Coulson, Geoffrey, Series editor, Jain, Rahul, editor, and Kannan, Rajgopal, editor

Published

2012

23. Facial Expression Recognition Using Game Theory

Author

Roy, Kaushik, Kamel, Mohamed S., Hutchison, David, editor, Kanade, Takeo, editor, Kittler, Josef, editor, Kleinberg, Jon M., editor, Mattern, Friedemann, editor, Mitchell, John C., editor, Naor, Moni, editor, Nierstrasz, Oscar, editor, Pandu Rangan, C., editor, Steffen, Bernhard, editor, Sudan, Madhu, editor, Terzopoulos, Demetri, editor, Tygar, Doug, editor, Vardi, Moshe Y., editor, Weikum, Gerhard, editor, Goebel, Randy, editor, Siekmann, Jörg, editor, Wahlster, Wolfgang, editor, Mana, Nadia, editor, Schwenker, Friedhelm, editor, and Trentin, Edmondo, editor

Published

2012

24. A Nash Stable Cross-Layer Coalitional Game for Resource Utilization in Device-to-Device Communications.

Author

Sawyer, Nicole and Smith, David B.

Subjects

*WIRELESS communications, *INTERFERENCE (Telecommunication), *RESOURCE allocation, *TELECOMMUNICATION systems, *MANAGEMENT

Abstract

In this paper, the problem of distributed mode selection, resource allocation, and interference management is studied for device-to-device (D2D) communications underlaying future cellular networks. In existing underlaid D2D communications, the base station (BS) typically assists D2D pairs in selecting a transmission mode to operate in (network-assisted), that is, either cellular, dedicated, or reuse mode. Network-assisted D2D communications assumes the BS has global knowledge of the network, which includes complete channel state information (CSI). However, acquiring global network information causes signaling overhead and network complexity to increase, due to the large number of users in the network. Therefore, we investigate user-assisted D2D communications as a viable solution for D2D communications, in which the BS has partial knowledge of the network (and partial CSI). To address this problem, a cross-layer coalitional (CLC) game is formulated, where D2D pairs and cellular users are clustered into coalitions based on resource allocation/sharing and mode selection, in a fully distributed and autonomous manner. Clustering D2D pairs allows resources to be shared fairly amongst users in a cluster, while also ensuring D2D pairs operate efficiently. To coordinate the interference between cellular and D2D pairs, an interference management subproblem is proposed that schedules D2D pairs reusing cellular user resources, as well as minimizing the transmission power of all users. To solve this game, a distributed algorithm is proposed, which converges to a Nash stable coalition partition that is socially efficient and has a nonempty core. Simulation results show that the proposed approach can effectively cluster D2D pairs into coalitions based on resource allocation and mode selection, which, in turn, reduces network sum power and increases network sum rate across all D2D pairs. [ABSTRACT FROM AUTHOR]

Published

2018

25. Cyber defense analysis of smart grid including renewable energy resources based on coalitional game theory.

Author

Fardad, Noorollah, Soleymani, Soodabeh, and Faghihi, Faramarz

Subjects

*RENEWABLE energy sources, *SMART power grids, *FOSSIL fuels, *EMISSIONS (Air pollution), *GAME theory

Abstract

In order to avoid the environmental emission of fossil fuels, renewable energy resources expansion trend is undeniable. This paper analyzes the possibility of cooperation between neighboring independent microgids in a smart grid with renewable resources considering the security assets and vulnerabilities. The ultimate goal is to decrease the overall security risks on the smart grid. Modeling of microgrids cooperation is formulated via a coalition game definition considering the permissible amount of their vulnerabilities. Load shedding minimization can be obtained during cyber-attack occurrence for each member of coalition microgrids. This paper presents a comprehensive algorithm for optimal coalition of neighboring microgrids based on a utility function calculation which has three major components: Budget for Attack (BA), Budget for Defense (BD) and microgrid relationship effectiveness, to contribute more understanding, microgrid relationship effectiveness formulation is developed by the introduction of friction and influence matrices. Proportional Fairness (PF) index is employed to illustrate the improvement of utility function in case of optimal coalition in comparison with non-cooperative state. Microgrids coalition optimal choice based on suggested algorithm is validated by probability attack and loss of load probability (LOLP) simulation for each microgrid before and after the coalition form. [ABSTRACT FROM AUTHOR]

Published

2018

26. Do new entrants sustain, destroy, or create guaranteed profitability?

Author

MacDonald, Glenn and Ryall, Michael

Subjects

PROFITABILITY, VALUE capture, AGENT (Philosophy), VALUE creation, COOPERATIVE game theory, ECONOMIC competition

Abstract

Research and Managerial Summary: We examine the effect of any new agent on the value captured by an incumbent: e.g., a new rival, a new source of supply, a new customer, etc. Regardless of the new agent's type, entry has two opposing effects on the incumbent's minimum profitability guaranteed by competition. First, is the creation of more economic value. This tends to blunt competition and lowers minimum guaranteed profit. Second, is the potential generation of new productive alternatives for the incumbent, thereby inducing the opposite effect. We describe whether entry allows guaranteed profits to persist or creates guaranteed profits when they did not previously exist. We show that knowing that the entrant can replace the incumbent is not enough to determine the impact of entry on guaranteed minimum profits. [ABSTRACT FROM AUTHOR]

Published

2018

27. Coalitional Tracker for Deception Detection in Thermal Imagery

Author

Dowdall, Jonathan, Pavlidis, Ioannis, Tsiamyrtzis, Panagiotis, Singh, Sameer, editor, and Hammoud, Riad I., editor

Published

2009

28. Nonideal Iris Recognition Using Level Set Approach and Coalitional Game Theory

Author

Roy, Kaushik, Bhattacharya, Prabir, Hutchison, David, editor, Kanade, Takeo, editor, Kittler, Josef, editor, Kleinberg, Jon M., editor, Mattern, Friedemann, editor, Mitchell, John C., editor, Naor, Moni, editor, Nierstrasz, Oscar, editor, Pandu Rangan, C., editor, Steffen, Bernhard, editor, Sudan, Madhu, editor, Terzopoulos, Demetri, editor, Tygar, Doug, editor, Vardi, Moshe Y., editor, Weikum, Gerhard, editor, Fritz, Mario, editor, Schiele, Bernt, editor, and Piater, Justus H., editor

Published

2009

29. Coalitional Game Theory Based Value Sharing in Energy Communities

Author

Anna Kulmala, Marius Baranauskas, Antti Keski-Koukkari, Amir Safdarian, and Poria Hasanpor Divshali

Subjects

Optimization, 0209 industrial biotechnology, Mathematical optimization, Optimization problem, General Computer Science, redundant constraint, Computer science, prosumer, 020209 energy, Stability (learning theory), 02 engineering and technology, payoff allocation, value sharing, 020901 industrial engineering & automation, energy community, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Buildings, Microgrids, Coalitional game theory, Cluster analysis, Urban areas, Game theory, Stochastic game, General Engineering, Minimization, TK1-9971, worst-case excess minimization, Core (game theory), Electrical engineering. Electronics. Nuclear engineering, Games, optimization problem, Value (mathematics), Counterexample

Abstract

This paper presents a coalitional game for value sharing in energy communities (ECs). It is proved that the game is super-additive, and the grand coalition effectively increases the global payoff. It is also proved that the model is balanced and thus, it has a nonempty core. This means there always exists at least one value sharing mechanism that makes the grand coalition stable. Therefore, prosumers will always achieve lower bills if they join to form larger ECs. A counterexample is presented to demonstrate that the game is not convex and value sharing based on Shapley values does not necessarily ensure the stability of the coalition. To find a stabilizing value sharing mechanism that belongs to the core of the game, the worst-case excess minimization concept is applied. In this concept, however, size of the optimization problem increases exponentially with respect to the number of members in EC. To make the problem computationally tractable, the idea of clustering members based on their generation/load profiles and considering the same profile and share for members in the same cluster is proposed here. K-means algorithm is used for clustering prosumers’ profiles. This way, the problem would have several redundant constraints that can be removed. The redundant constraints are identified and removed via the generalized Llewellyn’s rules. Finally, value sharing in an apartment building in the southern part of Finland in the metropolitan area is studied to demonstrate effectiveness of the method.

Published

2021

30. On Physical Layer Security: Weighted Fractional Fourier Transform Based User Cooperation.

Author

Fang, Xiaojie, Zhang, Ning, Zhang, Shan, Chen, Dajiang, Sha, Xuejun, and Shen, Xuemin

Abstract

In this paper, we propose a novel user cooperation scheme based on weighted fractional Fourier transform (WFRFT), to enhance the physical (PHY) layer security of wireless transmissions against eavesdropping. Specifically, instead of dissipating additional transmission power for friendly jamming, by leveraging the features of WFRFT, the information bearing signal of cooperators can create an identical artificial noise effect at the eavesdropper while causing no performance degradation on the legitimate receiver. Furthermore, to form the cooperation set in an autonomous and distributed manner, we model WFRFT-based PHY-layer security cooperation problem as a coalitional game with non-transferable utility. A distributed merge-and-split algorithm is devised to facilitate the autonomous coalition formation to maximize the security capacity while accounting for the cooperation cost in terms of power consumption. We analyze the stability of the proposed algorithm and also investigate how the network topology efficiently adapts to the mobility of intermediate nodes. Simulation results demonstrate that the WFRFT-based user cooperation scheme leads to a significant performance advantage, in terms of secrecy ergodic capacity, compared with the conventional security-oriented user cooperation schemes, such as relay-jamming and cluster-beamforming. [ABSTRACT FROM PUBLISHER]

Published

2017

31. Traffic Scheduling and Revenue Distribution Among Providers in the Internet: Tradeoffs and Impacts.

Author

Lee, Hyojung, Jang, Hyeryung, Cho, Jeong-woo, and Yi, Yung

Subjects

INTERNET traffic, INTERNET service providers, COMPUTER scheduling

Abstract

The Internet consists of economically selfish players in terms of access/transit connection and content distribution. Such selfish behaviors often lead to techno-economic inefficiencies, such as unstable peering and revenue imbalance. Recent research results suggest that cooperation-based fair revenue sharing, i.e., multi-level Internet service provider (ISP) settlements, can be a candidate solution to avoid unfair revenue share. However, it has been under-explored whether selfish ISPs actually cooperate or not (often referred to as the stability of coalition), because they may partially cooperate or even do not cooperate, depending on how much revenue is distributed to each individual ISP. In this paper, we study this stability of coalition in the Internet, where our aim is to investigate the conditions under which ISPs cooperate under different regimes on the traffic demand and network bandwidth. We first consider the under-demanded regime, i.e., network bandwidth exceeds traffic demand, where revenue sharing based on Shapley value leads ISPs to entirely cooperate, i.e., stability of the grand coalition. Next, we consider the over-demanded regime, i.e., traffic demand exceeds network bandwidth, where there may exist some ISPs who deviate from the grand coalition. In particular, this deviation depends on how users’ traffic is handled inside the network, for which we consider three traffic scheduling policies having various degrees of content-value preference. We analytically compare those three scheduling policies in terms of network neutrality, and stability of cooperation that provides useful implications on when and how multi-level ISP settlements help and how the Internet should be operated for stable peering and revenue balance among ISPs. [ABSTRACT FROM AUTHOR]

Published

2017

32. Information Security Risk Management and Incompatible Parts of Organization.

Author

Talabeigi, Elham and Naeeini, Seyyed Gholamreza Jalali

Subjects

*INFORMATION technology security, *RISK management in business, *GAME theory, *INDUSTRIAL management, *UNIVERSITY & college administration

Abstract

Purpose: we prepared a questionnaire to evaluate Incompatible parts and also risk management in University of Science and Technology E-Learning Center and studying the Incompatible parts impacts on utility of organization. Design/methodology/approach: By using coalitional game theory we present a new model to recognize the degrees of incompatibility among independent divisions of an organization with dependent security assets. Based on positive and negative interdependencies in the parts, the model provides how the organization can decrease the security risks through non-cooperation rather than cooperation. we implement the proposed model of this paper by analyzing the data which have been provided by questionnaires from different three managers' ideas of Iran University of Science and Technology E-Learning Center located in Iran University of Science and Technology, Tehran, Iran. Findings: In general, by collecting data and analyzing them, the survey showed that Incompatible parts of organizations have negative impacts on utility of organization risk management process. Furthermore, it adds values to other organizations and provides the best practices in planning, developing, implementing and monitoring risk management in organizations. Research limitations/implications: Since Information security and also Risk Management are still areas which need to improve in some Iranian universities, we couldn't consider them in our analysis. On the other hand, due to questionnaire limitation, the study's sample size is 1. This size may be considered large for our statistical analysis. Originality/value: The main contribution of this paper is to propose a model for noncooperation among a number of divisions in an organization and using risk management factors. [ABSTRACT FROM AUTHOR]

Published

2016

33. Strategic thinking under social influence: Scalability, stability and robustness of allocations.

Author

Bauso, Dario and Başar, Tamer

Subjects

VIDEO games, STOCHASTIC processes, SCALABILITY

Abstract

This paper studies the strategic behavior of a large number of game designers and studies the scalability, stability and robustness of their allocations in a large number of homogeneous coalitional games with transferable utilities (TU). For each TU game, the characteristic function is a continuous-time stochastic process. In each game, a game designer allocates revenues based on the extra reward that a coalition has received up to the current time and the extra reward that the same coalition has received in the other games. The approach is based on the theory of mean-field games with heterogeneous groups in a multi-population regime. [ABSTRACT FROM AUTHOR]

Published

2016

34. Operator Collusion and Market Regulation Policies for Wireless Spectrum Management.

Author

Korcak, Omer, Iosifidis, George, Alpcan, Tansu, and Koutsopoulos, Iordanis

Subjects

COLLUSION, FINANCIAL liberalization, WIRELESS communications, COST effectiveness, PRICE fixing

Abstract

The liberalization of wireless communication services markets and the subsequent competition among network operators, is expected to foster optimal utilization of the scarce wireless spectrum and ensure the provision of cost-efficient services to users. However, such markets may function inefficiently due to collusion of operators which yields a de-facto monopoly. Although it is illegal and detrimental to the users, creation of such cartels arises often in the form of implicit price fixing. In this paper, we consider a general such market where a set of operators sell communication services to a large population of users. We use an evolutionary game model to capture the user dynamics in selecting operators, under limited information about the actual service quality, and we analyze the anticipated interaction of the operators using coalitional game theory. We define a coalition formation game in order to rigorously study the conditions that render monopolistic or oligopolistic markets stable under different notions of coalition stability. We also provide direct and indirect regulation methods, such as setting price upper bounds or allocating different amounts of spectrum, in order to discourage undesirable equilibriums. Our approach provides intuitions about collusion strategies, as well as on directions for identifying and preventing them. [ABSTRACT FROM PUBLISHER]

Published

2016

35. Adaptive Pilot Clustering in Heterogeneous Massive MIMO Networks.

Author

Mochaourab, Rami, Bjornson, Emil, and Bengtsson, Mats

Abstract

We consider the uplink of a cellular massive multiple-input multiple-output network. Acquiring channel state information at the base stations (BSs) requires uplink pilot signaling. Since the number of orthogonal pilot sequences is limited by the channel coherence, pilot reuse across cells is necessary to achieve high spectral efficiency. However, finding efficient pilot reuse patterns is non-trivial, especially in practical asymmetric BS deployments. We approach this problem using the coalitional game theory. Each BS has a few unique pilots and can form coalitions with other BSs to gain access to more pilots. The BSs in a coalition, thus, benefit from serving more users in their cells at the expense of higher pilot contamination and interference. Given that a cell’s average spectral efficiency depends on the overall pilot reuse pattern, the suitable coalitional game model is in the partition form. We develop a low-complexity distributed coalition formation based on individual stability. By incorporating a BS intercommunication budget constraint, we are able to control the overhead in message exchange between the BSs and ensure the algorithm’s convergence to a solution of the game called individually stable coalition structure. Simulation results reveal fast algorithmic convergence and substantial performance gains over the baseline schemes with no pilot reuse, full pilot reuse, or random pilot reuse pattern. [ABSTRACT FROM PUBLISHER]

Published

2016

36. On the approachability principle for distributed payoff allocation in coalitional games

Author

Raja, A.A. (author), Grammatico, S. (author), Raja, A.A. (author), and Grammatico, S. (author)

Abstract

In the context of coalitional games, we present a partial operator-theoretic characterization of the approachability principle and, based on this characterization, we interpret a particular distributed payoff allocation algorithm to be a sequence of time-varying paracontractions. Then, we also propose a distributed payoff allocation algorithm on time-varying communication networks. The state in the proposed algorithm converges to a consensus in the”CORE” set as desired. For the convergence analysis, we rely on an operator-theoretic property of paracontraction., Team Sergio Grammatico, Team DeSchutter

Published

2021

37. Modeling economic sharing of joint assets in community energy projects under LV network constraints

Author

Norbu, Sonam (author), Couraud, Benoit (author), Robu, Valentin (author), Andoni, Merlinda (author), Flynn, David (author), Norbu, Sonam (author), Couraud, Benoit (author), Robu, Valentin (author), Andoni, Merlinda (author), and Flynn, David (author)

Abstract

The trend of decentralization of energy services has given rise to community energy systems. These energy communities aim to maximize the self-consumption of local renewable energy generated and stored in assets that are typically connected to low-voltage (LV) distribution networks. Energy community schemes often involve jointly owned assets such as community-owned solar photo-voltaic panels (PVs), wind turbines and/or shared battery storage. This raises the question of how these assets should be controlled in real-time, and how the energy outputs from these jointly owned assets should be shared fairly among heterogeneous community members. Crucially, such real-time control and fair sharing of energy must also consider the technical constraints of the community, such as the local LV network characteristics, voltage limits and power ratings of electric cables and transformers. In this paper, we design and analyze a heuristic-based battery control algorithm that considers the influence of battery life degradation, and the resultant increase in local renewable energy consumption within local operating constraints of the LV network. We provide a model that first studies the techno-economic benefits of community-owned versus individually-owned energy assets considering the network/grid constraints. Then, using the methodology and principles from cooperative game theory, we propose a redistribution model for benefits in a community based on the marginal contribution of each household. The results from our study demonstrate that the redistribution mechanism is fairer and computationally tractable compared to the existing state-of-the-art methods. Thus, our methodology is more scalable with respect to modeling the economic sharing of joint assets in community energy systems., Algorithmics

Published

2021

38. A market-based approach for enabling inter-area reserve exchange

Author

Maryam Kamgarpour, Orcun Karaca, and Stefanos Delikaraoglou

Subjects

FOS: Computer and information sciences, Computer science, electricity markets, coalitional game theory, mechanism design, public choice problem, media_common.quotation_subject, 0211 other engineering and technologies, Stability (learning theory), Rationality, 02 engineering and technology, Management Science and Operations Research, 01 natural sciences, Industrial and Manufacturing Engineering, Microeconomics, 010104 statistics & probability, Computer Science - Computer Science and Game Theory, FOS: Mathematics, Clearing, 0101 mathematics, Mathematics - Optimization and Control, media_common, 021103 operations research, Applied Mathematics, Payment, Core (game theory), Balance (accounting), Transmission (telecommunications), Optimization and Control (math.OC), Incentive compatibility, Software, Computer Science and Game Theory (cs.GT)

Abstract

Considering the sequential clearing of energy and reserves in Europe, enabling inter-area reserve exchange requires optimally allocating inter-area transmission capacities between these two markets. To achieve this, we provide a market-based allocation framework and derive payments with desirable properties. The proposed min-max least core selecting payments achieve individual rationality, budget balance, and approximate incentive compatibility and coalitional stability. The results extend the works on private discrete items to a network of continuous public choices., Operations Research Letters, 49 (4), ISSN:0167-6377, ISSN:1872-7468

Published

2021

39. User Grouping for Hybrid VLC/RF Networks With NOMA: A Coalitional Game Approach

Author

Panagiotis D. Diamantoulakis, Vasilis K. Papanikolaou, and George K. Karagiannidis

Subjects

General Computer Science, Computer science, business.industry, Wireless network, heterogeneous network, General Engineering, Visible light communication, 020206 networking & telecommunications, 02 engineering and technology, Spectral efficiency, non-orthogonal multiple access (NOMA), Interference (wave propagation), user grouping, 0202 electrical engineering, electronic engineering, information engineering, 020201 artificial intelligence & image processing, General Materials Science, Radio frequency, lcsh:Electrical engineering. Electronics. Nuclear engineering, Coalitional game theory, business, Game theory, lcsh:TK1-9971, Computer network, visible light communications (VLC)

Abstract

Recently, visible light communication (VLC) networks have emerged as a promising alternative for indoor data access, due to high data rate, low implementation cost, and immunity to radio frequency (RF) interference. However, the co-existence of VLC with the RF access points as well as the dependence of VLC to room illumination compel both technologies to work in parallel and thus, to form a hybrid heterogeneous VLC/RF network. This network offers the advantages of both technologies, namely increased capacity and ubiquitous coverage. Furthermore, non-orthogonal multiple access (NOMA) is a very promising candidate technique for the next generation of wireless networks, mainly due to its increased spectrum efficiency compared to orthogonal access schemes. However, the optimal user grouping in NOMA is a combinatorial NP-complete problem, which calls for low complexity techniques. To this end, in this paper, we propose the use of coalitional game theory, where the users served by the same access point (VLC or RF) form a single coalition, while the users can switch through coalitions based on their payoff. A novel utility function is proposed that takes into account the peculiarities of the NOMA hybrid VLC/RF network. Finally, a coalition formation algorithm is presented as well as an efficient power allocation policy. Computer simulations validate the presented analysis and reveal the effectiveness of the proposed user grouping scheme compared to an opportunistic approach.

Published

2019

40. Real-time energy exchange strategy of optimally cooperative microgrids for scale-flexible distribution system.

Author

Chakraborty, Shantanu, Nakamura, Shin, and Okabe, Toshiya

Subjects

*ENERGY transfer, *SMART power grids, *ELECTRIC power systems electric loss prevention, *HIERARCHICAL Bayes model, *GAME theory, *COMPUTER simulation

Abstract

This paper presents an optimal coalition formation mechanism of microgrids in a smart distribution system and analyzes the characteristics from the coalitional game theoretical perspective. Microgrids coalitions can (1) minimize the energy burden and dependency on the utility grid, (2) minimize the overall grid network power loss, and (3) maximize intra-coalition energy transfer. In order to form cooperative microgrids, a Hierarchical priority based Coalition Scheme ( HRCoalition ) is proposed. Given an intra-coalition distance threshold, the proposed HRCoalition mechanism can provide the optimal coalition that achieves the aforementioned objectives. The optimality is realized by reaching a state of cooperative equilibrium for all microgrids and coalitions. The optimality of the formed coalitions is proved by Coalitional Game Theory . A Greedy based strategy is designed to perform network constrained energy exchange (GreedEnEx) within a formed coalition. Thus, HRCoalition provides a higher level optimization while, GreedEnEx yields system level optimization using output of HRCoalition . The proposed HRCoalition scheme is computationally very efficient and can scale up to a huge number of microgrids and thus makes it suitable for near real-time operation. An equivalent pricing mechanism is designed to provide a form of economic incentive to the microgrids participating coalition formation. The performance of the proposed method is reported to scale up to 500 microgrids with a loss reduction ranging from 26% to 80%. The provided numerical simulation results back the claim of optimality as well as prove the effectiveness of the proposed coalition formation method. [ABSTRACT FROM AUTHOR]

Published

2015

41. Hybrid Overlay/Underlay Cognitive Femtocell Networks: A Game Theoretic Approach.

Author

Ma, Bojiang, Cheung, Man Hon, Wong, Vincent W. S., and Huang, Jianwei

Abstract

Femtocell networks have the potential to satisfy the increasing demand of mobile data usage. The recently proposed concept of cognitive femtocell network provides an effective way to further improve the spectrum spatial and frequency reuse. In this paper, we study the subchannel allocation problem for orthogonal frequency division multiple access (OFDMA)-based hybrid overlay/underlay cognitive femtocell networks. While most of the previous related studies did not fully exploit the potential of spatial and frequency reuse of the network, we propose a hybrid overlay and underlay spectrum access mechanism to further improve the performance of cognitive femtocell networks. We formulate the subchannel allocation problem as a coalition formation game among femtocell users under the hybrid access scheme, and analyze the stability of the coalition structure. We propose an efficient algorithm based on the solution concept of recursive core, and achieve a stable and efficient allocation. Simulation results show that the proposed algorithm achieves an improvement in aggregate network throughput up to 72% comparing to the overlay only scheme, 35% comparing to the underlay only scheme, and 18% comparing to a recently proposed coalition formation algorithm in the literature. [ABSTRACT FROM PUBLISHER]

Published

2015

42. Forbidding undesirable agreements*.

Author

Turrini, Paolo, Grossi, Davide, Broersen, Jan, and Meyer, John-Jules Ch.

Subjects

GAME theory, MATHEMATICAL models, COMBINATORIAL games, DIFFERENTIAL games, DESCRIPTION logics

Abstract

The purpose of this contribution is to set up a language to evaluate the results of concerted action among interdependent agents against predetermined properties that we can recognize as desirable from a deontic point of view. Unlike the standard view of logics to reason about coalitionally rational action, the capacity of a set of agents to take a rational decision will be restricted to what we will call agreements, which can be seen as solution concepts to a dependence structure present in a certain game. The language will identify those agreements that act accordingly or disaccordingly with the desirable properties arbitrarily set up in the beginning, and will reveal, by logical reasoning, a variety of structural properties of this type of collective action. [ABSTRACT FROM AUTHOR]

Published

2015

43. Managing a pool of rules for credit card fraud detection by a Game Theory based approach

Author

Gianini, G, Ghemmogne Fossi, L, Mio, C, Caelen, O, Brunie, L, Damiani, E, Gianini, G, Ghemmogne Fossi, L, Mio, C, Caelen, O, Brunie, L, and Damiani, E

Abstract

In the automatic credit card transaction classification there are two phases: in the Real-Time (RT) phase the system decides quickly, based on the bare transaction information, whether to authorize the transaction; in the subsequent Near-Real-Time (NRT) phase, the system enacts a slower ex-post evaluation, based on a larger information context. The classification rules in the NRT phase trigger alerts on suspicious transactions, which are transferred to human investigators for final assessment. The management criteria used to select the rules, to be kept operational in the NRT pool, are traditionally based mostly on the performance of individual rules, considered in isolation; this approach disregards the non-additivity of the rules (aggregating rules with high individual precision does not necessarily make a high-precision pool). In this work, we propose to apply, to the rule selection for the NRT phase, an approach which assigns a normalized score to the individual rule, quantifying the rule influence on the overall performance of the pool. As a score we propose to use a power-index developed within Coalitional Game Theory, the Shapley Value (SV), summarizing the performance in collaboration. Such score has two main applications: (1) it can be used, within the periodic rule assessment process, to support the decision of whether to keep or drop the rule from the pool; (2) it can be used to select the k top-ranked rules, so as to work with a more compact rule set. Using real-world credit card fraud data containing approximately 300 rules and 3×105 transactions records, we show that: (1) this score fares better – in granting the performance of the pool – than the one assessing the rules in isolation; (2) that the same performance of the whole pool can be achieved keeping only one tenth of the rules — the top-k SV-ranked rules. We observe that the latter application can be reframed in terms of Feature Selection (FS) task for a classifier: we show that our approach is c

Published

2020

44. Selection of Information Streams in Social Sensing: an Interdependence- and Cost-aware Ranking Method

Author

Chbeir, R, Manolopoulos, Y, Damiani, E, Benslimane, D, Gianini, G, Mio, C, Viola, F, Lin, J, Almoosa, N, Chbeir, R, Manolopoulos, Y, Damiani, E, Benslimane, D, Gianini, G, Mio, C, Viola, F, Lin, J, and Almoosa, N

Abstract

In this work we address the problem of critical source selection in social sensing. We propose an approach to the ranking of information streams, which is aware of the interdependence among streams (redundancy and synergies), of the cost of individual streams, and of the cost related to the integration of multiple streams. The method is based on the use of the Coalitional Game Theory concept of Power Index, and relies on the polynomial-time estimate of the stream sets characteristics. With respect to other works using a power index, the method takes into account that the problem has a non-trivial cost structure.

Published

2020

45. Selection of Information Streams in Social Sensing: An Interdependence-and Cost-aware Ranking Method

Author

Gianini, G., Mio, C., Viola, F., Lin, Jianyi, Almoosa, N., Lin J. (ORCID:0000-0002-3299-448X), Gianini, G., Mio, C., Viola, F., Lin, Jianyi, Almoosa, N., and Lin J. (ORCID:0000-0002-3299-448X)

Abstract

In this work we address the problem of critical source selection in social sensing. We propose an approach to the ranking of information streams, which is aware of the interdependence among streams (redundancy and synergies), of the cost of individual streams, and of the cost related to the integration of multiple streams. The method is based on the use of the Coalitional Game Theory concept of Power Index, and relies on the polynomial-time estimate of the stream sets characteristics. With respect to other works using a power index, the method takes into account that the problem has a non-trivial cost structure.

Published

2020

46. Coalitional Games for Determining Rate Region of Multiple Description Coding.

Author

Azimi, Seyyed Mohammadreza

Abstract

To combat erasure channels, multiple description coding (MDC) introduces diversity at source coding level. Each description provides a coarse reconstruction of source information at destination. As the number of received description increases, the reconstruction quality would be improved. Rate region of MDC is the set of achievable rates for a given set of expected distortions. In this paper, coalitional game theory is proposed as a nontrivial approach for determining rate region of MDC. To this end, elaborate game theoretic analysis is provided. Moreover, Shapley value is utilized to determine each description's rate. As a result, a fair rate adjustment is obtained that comprises entropy and mutual information of original and reconstructed descriptions. [ABSTRACT FROM PUBLISHER]

Published

2015

47. A Coalitional Game-Based Algorithm for OFDMA Resource Allocation in Multicast Cognitive Radio Networks.

Author

Tan, Chee, Chuah, Teong, and Tan, Su

Subjects

ORTHOGONAL frequency division multiplexing, COGNITIVE radio, COOPERATIVE game theory, MULTICASTING (Computer networks), MULTIUSER computer systems

Abstract

This letter investigates resource allocation for orthogonal frequency division multiple access (OFDMA)-based multicast cognitive radio networks (MCRNs) under the consideration of primary users' activities. Due to the heterogeneity of channel gains among secondary users (SUs), the existing multicast schemes are highly conservative and spectrally inefficient. To address this issue, we formulate a novel multicasting problem for MCRNs. This new formulation optimally and adaptively exploits multiuser diversity of OFDMA through dynamic group formation, which clusters SUs within a multicast group into multiple smaller subgroups (coalitions) based on their channel gains. Subcarriers and power are then allocated to these subgroups to maximize aggregate data rate (ADR) of the system. A coalitional game theory is adopted to model the group formation where SUs are allowed to form coalitions to compete for resources. A novel cognitive multicast coalitional game (CMCG) is proposed for SUs to self-organize to reach multi-coalitional equilibrium where optimality can be obtained. Simulation results show that the proposed CMCG algorithm significantly improves the system ADR as compared to the conventional unicast and multicast schemes. [ABSTRACT FROM AUTHOR]

Published

2015

48. Introduction of storage integrated PV sytems as an enabling technology for smart energy grids.

Author

Ampatzis, M., Nguyen, P. H., and Kling, W. L.

Abstract

Merging advanced control and information and communication technology (ICT) technology with the power grid is an appropriate approach for realizing the promising potential of massive distributed energy resources (DERs) integration, that is necessary for the vision of a sustainable society. This paper introduces a storage integrated photovoltaic (S-PV) system at residential areas as a multiple objective unit to address requirements either from technical or commercial side. Furthermore, a coordination mechanism for multiple S-PV units based on multi-agent system (MAS) technology will be discussed. The decision-making ability of the agents is necessary for arbitrating possible conflict of interests among S-PV units in case of disagreement between serving network functions and trading in the energy market. The proposed decision-making method of the agents is based on the coalitional game theory. More specifically, the two concepts for solving a coalition game with transferable pay-off are examined including the Shapley value and the Nucleolus. These concepts are compared to pro rata division of payoff in order to demonstrate their effectiveness in providing economic incentives for the S-PV units to participate in a coalition. A simulation with three S-PV units is used to verify the proposed coordination mechanism. [ABSTRACT FROM PUBLISHER]

Published

2013

49. A game theoretic framework for energy efficient deployment and operation of heterogeneous LTE networks.

Author

Yaacoub, Elias, Imran, Ali, Dawy, Zaher, and Abu-Dayya, Adnan

Abstract

In this paper, a game theoretical framework for energy efficient operation of heterogeneous LTE cellular networks is proposed. Within this framework, two game theoretic concepts are studied and analyzed. The first approach is a coalition-based method that assumes a group of base stations (BSs) in a network form a coalition. The second approach is based on the Nash bargaining solution and considers that BSs play a bargaining game where each BS attempts to maximize its own utility. These methods were implemented with utilities focusing either on traffic load and quality of service (QoS), or on the QoS versus the consumed power in the network. The tradeoffs between QoS and energy consumption are investigated, depending on the utility selected. Simulation results show that the results are utility dependent, and that the centralized coalition-based approach generally leads to better performance. [ABSTRACT FROM PUBLISHER]

Published

2013

50. On the approachability principle for distributed payoff allocation in coalitional games

Author

Aitazaz Ali Raja and Sergio Grammatico

Subjects

0209 industrial biotechnology, Mathematical optimization, Sequence, Computer Science::Computer Science and Game Theory, Computer science, 020208 electrical & electronic engineering, Stochastic game, Context (language use), 02 engineering and technology, State (functional analysis), 16. Peace & justice, Approachability, Paracontraction, Set (abstract data type), Core (game theory), 020901 industrial engineering & automation, Approachability principle, Control and Systems Engineering, Convergence (routing), 0202 electrical engineering, electronic engineering, information engineering, Coalitional game theory

Abstract

In the context of coalitional games, we present a partial operator-theoretic characterization of the approachability principle and, based on this characterization, we interpret a particular distributed payoff allocation algorithm to be a sequence of time-varying para-contractions. Then, we also propose a distributed payoff allocation algorithm on time-varying communication networks. The state in the proposed algorithm converges to a consensus in the ”CORE” set as desired. For the convergence analysis, we rely on an operator-theoretic property of paracontraction.

Published

2021