Exchange Economy in Two-User Multiple-Input Single-Output Interference Channels

We study the conflict between two links in a multiple-input single-output interference channel. This setting is strictly competitive and can be related to perfectly competitive market models. In such models, general equilibrium theory is used to determine equilibrium measures that are Pareto optimal...

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Bibliographic Details
Published inIEEE journal of selected topics in signal processing Vol. 6; no. 2; pp. 151 - 164
Main Authors Mochaourab, R., Jorswieck, E. A.
Format Journal Article
LanguageEnglish
Published IEEE 01.04.2012
Subjects
Array signal processing
Beamforming
Biological system modeling
exchange economy
interference channels
multiple-input single-output (MISO)
Pareto optimality
Pareto optimization
Resource management
Signal to noise ratio
Transmitters
Vectors
Walrasian equilibrium
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Summary:We study the conflict between two links in a multiple-input single-output interference channel. This setting is strictly competitive and can be related to perfectly competitive market models. In such models, general equilibrium theory is used to determine equilibrium measures that are Pareto optimal. First, we consider the links to be consumers that can trade goods within themselves. The goods in our setting correspond to beamforming vectors. We utilize the conflict representation of the consumers in the Edgeworth box, a graphical tool that depicts the allocation of the goods for the two consumers, to provide closed-form solution to all Pareto optimal outcomes. Afterwards, we model the situation between the links as a competitive market which additionally defines prices for the goods. The equilibrium in this economy is called Walrasian and corresponds to the prices that equate the demand to the supply of goods. We calculate the unique Walrasian equilibrium and propose a coordination process that is realized by an arbitrator which distributes the Walrasian prices to the consumers. The consumers then calculate in a decentralized manner their optimal demand corresponding to beamforming vectors that achieve the Walrasian equilibrium. This outcome is Pareto optimal and dominates the noncooperative outcome of the systems. Thus, based on the game theoretic model and solution concept, an algorithm for a distributed implementation of the beamforming problem in multiple-input single-output interference channels is provided.
ISSN:1932-4553
1941-0484
DOI:10.1109/JSTSP.2011.2174962