Dominique, C-Rene (2016): Analyzing Market Economies From the Perspective of Information Production, Policy, and Self-organized Equilibrium. Published in: Expert Journal of Economics , Vol. 4, No. (1) (4 April 2016): pp. 14-23.
Preview |
PDF
MPRA_paper_70725.pdf Download (692kB) | Preview |
Abstract
A modern market economy is an exceedingly complex, infinite-dimensional, stochastic dynamical system. The failure of mainstream economists to characterize its dynamics may well be due to its intractability. This paper argues that the characterization of its dynamics becomes almost trivial when it is analyzed from the perspective of information production. Whether its Jacobian matrix is specifiable or not, a Lyapunov spectrum can be constructed from which the potential Kolmogorov-Sinai or Shannon entropy can be assessed. But, a self-organized equilibrium must first obtain, and for that a suitable policy must be operational.
| Item Type: | MPRA Paper |
|---|---|
| Original Title: | Analyzing Market Economies From the Perspective of Information Production, Policy, and Self-organized Equilibrium |
| English Title: | Analyzing Market Economies From the Perspective of Information Production, Policy, and Self-organized Equilibrium |
| Language: | English |
| Keywords: | Complexity, Kolmogorov-Sinai entropy, Shannon entropy, Lyapunov spectrum, Lyapunov dimension, Efficient policy, Self-organized equilibrium. |
| Subjects: | B - History of Economic Thought, Methodology, and Heterodox Approaches > B4 - Economic Methodology B - History of Economic Thought, Methodology, and Heterodox Approaches > B4 - Economic Methodology > B41 - Economic Methodology C - Mathematical and Quantitative Methods > C6 - Mathematical Methods ; Programming Models ; Mathematical and Simulation Modeling C - Mathematical and Quantitative Methods > C6 - Mathematical Methods ; Programming Models ; Mathematical and Simulation Modeling > C61 - Optimization Techniques ; Programming Models ; Dynamic Analysis |
| Item ID: | 70725 |
| Depositing User: | C-Rene Dominique |
| Date Deposited: | 15 Apr 2016 07:11 |
| Last Modified: | 08 Oct 2019 13:45 |
| References: | Ashby, W. R. (1947). “Principle of Self-Organizing Dynamic Systems.” The Journal of General Psychol-ogy, 37 (2), 125-128. Cohen, J. and Stewart, I. (1994). The Collapse of Chaos: discovering simplicity in a complex world. New York: Penguin Books. Danilov, D. and Zhigljavsky, A. (1997) Principal Components of Time Series: Caterpillar Method. St- Petersburg, Russia: St-Petersburg Univ. Press Eckman, J-P. and Ruelle, D. (1985). “Ergodic Theory of Chaos and Strange Attractors.” Review of Modern Physics, 57 (3), 617-656. Farmer, J., D. (1982). “Chaotic Attractor of Infinite-dimensional Dynamical Systems.” Physica 4D, 4 (3), 366-393. Frigg, R. (2004). “In What Sense is the Kolmogorov-Sinai Entropy is a Measure for Chaotic Behavior?” The British Journal for the Philosophy of Science, 55, 411-434. Golyandina, N, and Zhigljavsky, A. (2013) Singular Spectrum Analysis for Time Series. Berlin: Springer Verlag. ……….. (2005) “Automatic Extraction and Forecast of Time Series Cyclic Components Within the Framework of SSA.” Proceedings of the 5th St-Petersburg Workshop on Simulation.” St-Petersburg: St-Petersburg Univ. Press, 45-50. Hazy, J. and Ashley, A. (2004) “Unfolding the Future: Bifurcation in Organizing Forms and Emergence in Social Systems.” Emergence, Complexity and Organization, 13 (3), 57-79. Kaplan, J. and Yorke, J. (1979). “Chaotic Behavior of Multi-dimensional Difference Equations.” In Peit-gen, H. O. and Walther, H. O. (eds) Functional Difference Equations and the Approximation of Fixed-points: Lecture Notes in Mathematics. New York: Springer-Verlag, vol. 730,204 . …………. (1979). “Pre-turbulence: A Regime Observed in a Fluid Model of Lorenz.” Communications in Mathematical Physics, 67-93. Kolmogorov, A. (1958). “A New Metric Invariant of Transitive Dynamical Systems and Automorphisms of Lebesgue Spaces.” Dokl Acad. Nauk, SSSR, 119,861-864 Liu, Z. (2009). “Chaotic Time Series Analysis.” Mathematical Problems in Engineering, vol. 2010, Art.ID 720190. Los, A. C. (2000). “Visualization of Chaos for Finance Majors.” Working Paper 00-7, School of Economics, Adelaide Univ. 17-18. Mané, R. (1980). “On the Dimension of the Compact Invariant Sets of Certain Non-Linear Maps.” In Rand, D. A. and Young, L. S. (eds) Volume 898 of Springer Lecture Notes in Mathematics, Berlin: Springer Verlag, 320. Medio, A. (1992). Chaotic Dynamics: Theory and Applications. Cambridge, UK.: Cambridge Univ. Press. Mitchell, M., Crutchfield, J., and Hraber, P. (1994) “Dynamics, Computation, and the ‘Edge of Chaos’: A Reexamination.” In Cowan et al. (ed.) Complexity, Metaphors, and Reality, Santa Fe Inst. Stud. in the Sciences of Complexity, vol. 19. Reading, MA: Addison-Wesley. Nicolis, G. and Prigogine, I. (1977). Self-organization in Non-equilibrium Systems from Dissipative Struc-tures to Order through Fluctuations. New York: Wiley & Sons. Persin, J. B. (1977). “Lyapunov Characteristic Exponents and Smooth Ergodic Theory.” Russian Mathe-matical Surveys, 32 (4), 55-114. |
| URI: | https://mpra.ub.uni-muenchen.de/id/eprint/70725 |
All papers reproduced by permission. Reproduction and distribution subject to the approval of the copyright owners.
 |
View Item |
