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An agent-based “proof of principle” for Walrasian macroeconomic theory
Author(s) -
Edoardo Gaffeo,
Mauro Gallegati,
Umberto Gostoli
Publication year - 2014
Publication title -
computational and mathematical organization theory
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.426
H-Index - 27
eISSN - 1572-9346
pISSN - 1381-298X
DOI - 10.1007/s10588-014-9180-7
Subject(s) - economics , general equilibrium theory , mathematical economics , set (abstract data type) , bounded function , computer science , microeconomics , mathematics , mathematical analysis , programming language
Macroeconomic models are typically solved through the imposition of a top-down general equilibrium solution constraining agents' rational behavior. This is customarily obtained by recurring, explicitly or not, to the Walrasian auctioneer artifice. In this paper we aim at contributing to the small but burgeoning literature that deals with the consequences of removing it from the start by means of agent-based techniques. We let the textbook full-employment neoclassical macroeconomic model be populated by a large number of bounded-rational, autonomous agents, who are repeatedly engaged in decentralized transactions in interrelated markets. We set up a computational laboratory to perform several experiments, whose designs differ as regards the way we treat learning on the one side, and the institutional arrangement determining who--between firms and workers--is bound to bear the risk associated to incomplete markets on the other one. We show that our fully decentralized multi-market system admits the possibility to attain the Walrasian full-employment solution, but also that serious coordination failures emerge endogenously as learning mechanisms and institutional settings are varied.

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