Pennoni, Fulvia and Bartolucci, Francesco and Forte, Gianfranco and Ametrano, Ferdinando (2020): Exploring the dependencies among main cryptocurrency log-returns: A hidden Markov model.
Preview |
PDF
MPRA_paper_106150.pdf Download (714kB) | Preview |
Abstract
A multivariate hidden Markov model is proposed to explain the price evolution of Bitcoin, Ethereum, Ripple, Litecoin, and Bitcoin Cash. The observed daily log-returns of these five major cryptocurrencies are modeled jointly. They are assumed to be correlated according to a variance-covariance matrix conditionally on a latent Markov process having a finite number of states. For the purpose of comparing states according to their volatility, we estimate specific variance-covariance matrix varying across states. Maximum likelihood estimation of the model parameters is carried out by the Expectation-Maximization algorithm. The hidden states represent different phases of the market identified through the estimated expected values and volatility of the log-returns. We reach interesting results in detecting these phases of the market and the implied transition dynamics. We also find evidence of structural medium term trend in the correlations of Bitcoin with the other cryptocurrencies.
| Item Type: | MPRA Paper |
|---|---|
| Original Title: | Exploring the dependencies among main cryptocurrency log-returns: A hidden Markov model |
| Language: | English |
| Keywords: | Bitcoin, Bitcoin cash, decoding, Ethereum, expectation-maximization algorithm, Litecoin, Ripple, time-series |
| Subjects: | C - Mathematical and Quantitative Methods > C3 - Multiple or Simultaneous Equation Models ; Multiple Variables > C32 - Time-Series Models ; Dynamic Quantile Regressions ; Dynamic Treatment Effect Models ; Diffusion Processes ; State Space Models C - Mathematical and Quantitative Methods > C5 - Econometric Modeling > C51 - Model Construction and Estimation C - Mathematical and Quantitative Methods > C5 - Econometric Modeling > C53 - Forecasting and Prediction Methods ; Simulation Methods |
| Item ID: | 106150 |
| Depositing User: | Prof. Fulvia Pennoni |
| Date Deposited: | 19 Feb 2021 06:25 |
| Last Modified: | 19 Feb 2021 06:25 |
| References: | Agosto, A. and Cafferata, A. (2020). Financial bubbles: A study of co-explosivity in the cryptocurrency market. Risks, 8:1–14. Akaike, H. (1998). Markovian representation of stochastic processes and its application to the analysis of autoregressive moving average processes. In Selected Papers of Hirotugu Akaike, pages 223–247. Springer. Ang, A. and Bekaert, G. (2002). International asset allocation with regime shifts. The Review of Financial Studies, 15:1137–1187. Bartolucci, F. and De Luca, G. (2003). Likelihood-based inference for asymmetric stochastic volatility models. Computational statistics & data analysis, 42:445–449. Bartolucci, F., Farcomeni, A., and Pennoni, F. (2013). Latent Markov Models for Longitudinal Data. Chapman & Hall/CRC Press, Boca Raton, FL. Bartolucci, F., Pandolfi, S., and Pennoni, F. (2017). LMest: An R package for latent Markov models for longitudinal categorical data. Journal of Statistical Software, 81:1– 38. Bartolucci, F., Pandolfi, S., Pennoni, F., Farcomeni, A., and Serafini, A. (2020). LMest: Generalized Latent Markov Models. R package version 3.0.0. Baum, L. E., Petrie, T., Soules, G., and Weiss, N. (1970). A maximization technique occurring in the statistical analysis of probabilistic functions of Markov chains. The Annals of Mathematical Statistics, 41:164–171. Borri, N. (2019). Conditional tail-risk in cryptocurrency markets. Journal of Empirical Finance, 50:1–19. Bouri, E., Shahzad, S. J. H., and Roubaud, D. (2019). Co-explosivity in the cryptocurrency market. Finance Research Letters, 29:178–183. Cappé, O., Moulines, E., and Rydén, T. (1989). Inference in Hidden Markov Models. Springer-Verlag, New York. Chen, Y., Giudici, P., Hadji Misheva, B., and Trimborn, S. (2020). Lead behaviour in Bitcoin markets. Risks, 8:1–14. Corbet, S., Meegan, A., Larkin, C., Lucey, B., and Yarovaya, L. (2018). Exploring the dynamic relationships between cryptocurrencies and other financial assets. Economics Letters, 165:28–34. De Angelis, L. and Paas, L. J. (2013). A dynamic analysis of stock markets using a hidden Markov model. Journal of Applied Statistics, 40:1682–1700. Dempster, A. P., Laird, N. M., and Rubin, D. B. (1977). Maximum likelihood from incomplete data via the EM algorithm (with discussion). Journal of the Royal Statistical Society, Series B, 39:1–38. Genon-Catalot, V., Jeantheau, T., Lar ́edo, C., et al. (2000). Stochastic volatility models as hidden Markov models and statistical applications. Bernoulli, 6:1051–1079. Giudici, P. and Abu Hashish, I. (2020). A hidden Markov model to detect regime changes in cryptoasset markets. Quality and Reliability Engineering International, 36:2057– 2065. Giudici, P. and Pagnottoni, P. (2019). High frequency price change spillovers in Bitcoin markets. Risks, 7:1–18. Giudici, P. and Pagnottoni, P. (2020). Vector error correction models to measure connectedness of Bitcoin exchange markets. Applied Stochastic Models in Business and Industry, 36:95–109. Giudici, P. and Polinesi, G. (2019). Crypto price discovery through correlation networks. Annals of Operations Research, pages 1–15. Hamilton, J. (1989). A new approach to the economic analysis of nonstationary time series and the business cycle. Econometrica, 57:357–384. Huang, J.-Z., Huang, W., and Ni, J. (2019). Predicting Bitcoin returns using high- dimensional technical indicators. The Journal of Finance and Data Science, 5:140–155. Juang, B. H. and Rabiner, L. R. (1991). Hidden Markov models for speech recognition. Technometrics, 33:251–272. Katsiampa, P., Corbet, S., and Lucey, B. (2019). High frequency volatility co-movements in cryptocurrency markets. Journal of International Financial Markets, Institutions and Money, 62:35–52. Langrock, R., MacDonald, I. L., and Zucchini, W. (2012). Some nonstandard stochastic volatility models and their estimation using structured hidden Markov models. Journal of Empirical Finance, 19:147–161. Lin, Y., Xiao, Y., and Li, F. (2020). Forecasting crude oil price volatility via a HM-EGARCH model. Energy Economics,104–693. Mamon, R. S. and Elliott, R. J. (2007). Hidden Markov models in finance. Springer. McLachlan, G. and Peel, D. (2000). Finite Mixture Models. Wiley. Rossi, A. and Gallo, G. M. (2006). Volatility estimation via hidden Markov models. Journal of Empirical Finance, 13:203–230. Satoshi, N. (2008). Bitcoin: A peer-to-peer electronic cash system. Consulted, 1:28. Schwarz, G. (1978). Estimating the dimension of a model. Annals of Statistics, 6:461–464. Sifat, I. M., Mohamad, A., and Shariff, M. S. B. M. (2019). Lead-lag relationship between Bitcoin and Ethereum: Evidence from hourly and daily data. Research in International Business and Finance, 50:306–321. Trimborn, S. and Hardle, W. K. (2018). Crix an index for cryptocurrencies. Journal of Empirical Finance, 49:107–122. Viterbi, A. (1967). Error bounds for convolutional codes and an asymptotically optimum decoding algorithm. IEEE transactions on Information Theory, 13:260–269. Wang, S. and Vergne, J.P. (2017). Buzz factor or innovation potential: What explains cryptocurrencies’returns? PlusOne, 12:e0169556. Welch, L. R. (2003). Hidden Markov models and the Baum-Welch algorithm. IEEE Information Theory Society Newsletter, 53:1–13. Yi, S., Xu, Z., and Wang, G.-J. (2018). Volatility connectedness in the cryptocurrency market: Is Bitcoin a dominant cryptocurrency? International Review of Financial Analysis, 60:98–114. Zucchini, W., MacDonald, I. L., and Langrock, R. (2017). Hidden Markov Models for time series: an introduction using R. Springer-Verlag, New York. |
| URI: | https://mpra.ub.uni-muenchen.de/id/eprint/106150 |
All papers reproduced by permission. Reproduction and distribution subject to the approval of the copyright owners.
 |
View Item |
