Abstract
Economic data provide little evidence -if any- of linear, simple dynamics, and of lasting convergence to stationary states or regular cyclical behavior. In spite of this the linear approach absolutely dominates mainstream economics. The problem is that mainstream economics is now in deep crisis. The recent financial crisis clearly showed that orthodox economics was quite unprepared to deal with it. Most mainstream economists not only did not foresee the depth of the current crisis, they not even consider it possible. It is well known since the famous contribution of Mandelbrot (1963) that many economic and financial time series have fat tails, i.e. that the probability of extreme events is higher than if the data-generating process were normal. However, the usual practice among orthodox economists has been to assume-implicitly or explicitly- a normal distribution. Orthodox economists represent the economy as a stable equilibrium system resembling the planetary one. The concept of equilibrium plays a key role in traditional economics. This approach is useful in normal, stable times. However, it is incapable of dealing with unstable, turbulent, chaotic times. The crisis has clearly showed this. Heterodox contributions shed much more light on what happens during these crucial periods in which a good part of the economy is reshaped; they provide powerful insights towards what policies to follow in those extraordinary circumstances. However, they remain as theories mainly suitable for those periods of instability and crisis. The challenge is to arrive at a unified theory valid both for normal and abnormal times. In this respect, the complexity approach with its use of non-linear models offers the advantage that the same model allows to describe stable as well as unstable and even chaotic behaviors. Although the results of chaos tests do not prove so far the existence of chaos in all economic variables they are consistent with its existence. The detection of chaos in economic time series faces three types of difficulties: (1) the limited number of observations such series contain; (2) the high noise level in economic time series; and (3) the high dimension of economic systems. However, topological methods for chaos detection seem to be a highly promising tool. On the other hand, in economics, there are no such things as crucial experiments. Economists seldom practice the falsificationism they preach. Confidence in the implications of economics derives from confidence in its axioms rather than from testing their implications. Therefore, non-linear dynamics and chaos theory should not be subject to more stringent rules than what is usual for the rest of economic theory.
Helpful comments by an anonymous referee are deeply thanked. The usual caveats apply.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
Notes
- 1.
For some time the terms “strange” and “chaotic” attractors were used as synonymous. However, later on it was discovered that there are strange non-chaotic attractors—they have a fractal structure but do not possess the property of sensitive dependence on initial conditions—and non-strange chaotic attractors—they do not possess a fractal structure. For example, Starrett (2012) shows a chaotic dynamical system which has a one-dimensional attractor.
- 2.
The Lyapunov time (\(\tau \)) is measured by the inverse of the Lyapunov exponent: \(\tau =\frac{1}{L}\).
- 3.
Strictly speaking, market efficiency does not necessarily imply a random walk model but the latter does assume market efficiency.
- 4.
Low-dimensional chaos is characterised by only one positive Lyapunov exponent while high-dimensional chaos by more than one such exponent.
- 5.
As Samuelson (1983, p. 21) points out, this method has been taken from equilibrium thermodynamics, which is based on linear relationships. It was the introduction of non-linear relationships which allowed the development of non-equilibrium thermodynamics.
References
Altavilla, C., De Grauwe, P.: Non-linearities in the relation between the exchange rate and its fundamentals. Int. J. Finance Econ. 15(1), 1–21 (2010)
Arthur, B.W.: Increasing Returns and Path Dependence in the Economy. The University of Michigan Press, Ann Arbor (1994)
Arthur, W.B., Durlauf, S.N., Lane, D.A. (eds.): The Economy as an Evolving Complex System II. Addison-Wesley, Reading (1997)
Arthur, W.B.: Complexity, the Santa Fe approach and nonequilibrium economics. In: Faucci, R., Marchionatti, R. (eds.) History of Economic Ideas. Fabrizio Serra Editore, Rome (2010)
Bala, V., Majumdar, M., Mitra, T.: Controlling Chaos: Some Analytical Results and Applications to Tattonement. Cornell University, Ithaca Center for Analytic Economics (1996)
Barnett, W. A., He, Y.: Unsolved econometric problems in nonlinearity, Chaos, and Bifurcation. Working papers series in theoretical and applied economics. University of Kansas, Department of Economics No 201231 (2012)
Barnett, W. A., Serletis, A.: Martingales, nonlinearity, and chaos. J. Econ. Dyn. Control 24(5–7), 703–24 (2000)
Bak, P., Chen, K.: Self-organized criticality. Sci Am. 264(1), 46–53 (1991)
Baumol, W., Benhabib, J.: Chaos: significance, mechanism, and economic implications. J. Econ. Perspect. 3(1), 77–105 (1989)
Bayar, L.B.: Chaos Theory and its Importance and Applications in Economics. Marmara University, Institute of Social Sciences, Department of Economics, T.C, Istanbul (2005)
Beker, P.F.: Are inefficient entrepreneurs driven out of the market? J. Econ. Theory 114, 329–344 (2004)
Beker, V.A.: Is Economics a Science? A Discussion of Some Methodological Issues (2005). http://ssrn.com/abstract=839307
Beker, V.A.: Per una teoria economica del non-equilibrio. Note economiche: rivista economica del Monte dei Paschi di Siena 24(1), 20–34 (1994)
Beker, V.A.: Non-linear dynamics and Chaos in economics. In: Dahiya, S.B. (ed.) The Current State of Economic Science, vol. 1, pp. 169–193. Spellbound Publications, Rohtak (1999)
Blume, L., Easley, D.: Evolution and market behavior. J. Econ. Theory 58, 9–40 (1992)
Blume, L., Easley, D.: If you’re so smart, why aren’t you rich? Belief selection in completeand incomplete markets. Econometrica 74, 929–966 (2006)
Boldrin, M.: The impact of chaos on economic theory. In: Grebogi, C., Yorke, J. (eds.) Impact of Chaos on Science and Society, pp. 275–297. United Nations University Press. New York (1997)
Brock, W.: Pathways to randomness in the economy: emergent nonlinearity and chaos in economics and finance. Estudios Econ. 8, 3–55 (1993)
Brock, W.A.: Asset price behavior in complex environments. In: Arthur, W.B., Durlauf, S.N., Lane, D.A. (eds.) The Economy as an Evolving Complex System II, pp. 385–423. Addison-Wesley, Reading (1997)
Daubechies, I.: Ten Lectures on Wavelets. CBMS-NSF Lecture Notes No. 61. SIAM, Philadelphia (1992)
Day, R.H.: Complex Economic Dynamics, An Introduction to Dynamical Systems and Market Mechanisms, vol. I. MIT Press, Cambridge (1994)
De Grauwe, P., Grimaldi, M.: The Exchange Rate in a Behavioural Finance Framework. Princeton University Press, Princeton (2006)
De Grauwe, P., Rovira Kaltwasser, P.: Animal spirits in the foreign exchange market. J. Econ. Dyn. Control 36(8),1176–1192 (2012)
Faggini, M.: Chaos detection in economics. Metric versus topological tools. MPRA Paper No. 30928. http://mpra.ub.uni-muenchen.de/30928/ (2010)
Faggini, M.: Chaotic time series analysis in economics: balance and perspectives. Working Paper No. 25. Universitá degli Studi di Torino, Department of Economics and Public Finance. http://web.econ.unito.it/prato/papers/n25.pdf (2011)
Faggini, M., Parziale, A.: The failure of economic theory. Lessons from chaos theory. Mod. Econ. 3, 1–10 (2012). www.scirp.org/journal/PaperDownload.aspx?paperID=16802
Frankel, J., Froot, K.: Chartists, fundamentalists, and trading in the foreign exchange market. Am. Econ. Rev. 80(2), 181–185 (1990)
Friedman, M.: The methodology of positive economics. In: Friedman, M. (ed.) Essays in Positive Economics. University of Chicago Press, Chicago (1953)
Gao, J., Sultan, H., Hu, J., Tung, W.W.: Denoising nonlinear time series by adaptive filtering and wavelet shrinkage: a comparison. IEEE Signal Proces. Lett. 17(3), 127 (2010)
Goldstein, J.: Attractors and Nonlinear Dynamical Systems. Plexus Institute, Bordentown (2011). http://c.ymcdn.com/sites/www.plexusinstitute.org/resource/resmgr/files/deeperlearningspring2011.pdf
Guégan, D., Hoummiya, K.: Denoising with wavelets method in chaotic time series: application in climatology, energy and finance. In: Abbott, D., Bouchaud, J.P., Gabaix, X., McCaulay, J.L. (eds.) Noise and Fluctuations in Econophysics and Finance. Proceedings of SPIE, vol. 5848, pp. 174–185. (2005)
Hausman, D.M.: The Inexact and Separate Science of Economics. Cambridge University Press, Cambridge (1992)
Hawkins, S.: A Brief History of Time. Bantam Books, London (1988)
Hommes, C., Manzan, S.: Testing for nonlinear structure and chaos in economic time. A comment. J. Macroecon. 28(1), 169–174. Elsevier (2006)
Hommes, C., Wagener, F.: Complex evolutionary systems in behavioral finance. In: Hens, T., Schenk-Hopp, K.R. (eds.) Handbook of Financial Markets: Dynamics and Evolution. North-Holland, Amsterdam (2008)
Horgan, J.: From complexity to perplexity. Sci. Am. 272(6), 104–109 (1995)
Katz, F.: Methodological Contributions of Chaos Theory to Economic Thought (2002). http://staffnet.kingston.ac.uk/ku32530/PPE/katz.pdf
Kyrtsou, C., Serletis, A.: Univariate tests for nonlinear structure. J. Macroecon. 28(1), 154–168. Elsevier (2006)
LeBaron, B.: Building financial markets with artificial agents: desired goals, and present techniques. In: Karakoulas, G. (ed.) Computational Markets. MIT Press, Cambridge (1999)
Li, H., Jr, Barkley Rosser: Emergent volatility in asset markets with heterogeneous agents. Discrete Dyn. Nat. Soc. 6, 171–180 (2001)
Lucas, R.E.: Asset prices in an exchange economy. Econometrica 46(6), 1429–1445 (1978)
Mandelbrot, B.: The variation of certain speculative prices. J. Bus. 36(4), 394–419 (1963)
Martelli, M., Dang, M., Seph, T.: Defining chaos. Math. Mag. 71, 112–122 (1998)
Milgrom, P., Stokey, N.: Information, trade and common knowledge. J. Econ. Theory 26, 17–27 (1982)
North, D.C.: Economic performance through time. Am. Econ. Rev. 84(3), 359–368 (1994)
Ott, E., Grebogi, C., Yorke, J.A.: Controlling chaos. Phys. Rev. Lett. 64, 1196–1199 (1990)
Rosser, J.B.: On the complexities of complex economic dynamics. J. Econ. Perspect. Fall 13(4), 169–192 (1999)
Ruelle, D.: Turbulence, Strange Attractors, and Chaos. World Scientific, Singapore (1994)
Salzano, M.: The Analysis of Extreme Events - Some Forecasting Approaches. In: Perna, C., Sibillo, M. (eds.) Mathematical and Statistical Methods in Insurance and Finance. Springer, New York (2008)
Samuelson, P.A.: Foundations of Economic Analysis. Harvard University Press, Cambridge (1983)
Scheinkmann, J., Woodford, M.: Self-organized criticality and economic fluctuations. Am. Econ. Rev. 84(2), 417–421 (1994) (Papers and Proceedings)
Schumpeter, J.A. (1987). History of Economic Analysis. Routledge, London
Starrett, J.: Non-strange chaotic attractors equivalent to their templates. Dyn. Sys. Int. J. 27(2), 187–196 (2012)
Tirole, J.: On the possibility of speculation under rational expectations. Econometrica 50(5), 1163–1181 (1982)
Vitolo, R., Holland, M.P., Ferro, C.: Robust extremes in chaotic desterministic systems. Chaos 19(4), 043127 (2009)
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2014 Springer International Publishing Switzerland
About this chapter
Cite this chapter
Beker, V.A. (2014). Why Should Economics Give Chaos Theory Another Chance?. In: Faggini, M., Parziale, A. (eds) Complexity in Economics: Cutting Edge Research. New Economic Windows. Springer, Cham. https://doi.org/10.1007/978-3-319-05185-7_11
Download citation
DOI: https://doi.org/10.1007/978-3-319-05185-7_11
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-319-05184-0
Online ISBN: 978-3-319-05185-7
eBook Packages: Business and EconomicsEconomics and Finance (R0)