This paper focuses on the prediction of cryptocurrency volatility. The stock market volatility represents a very influential aspect that affects a wide range of decisions in business and finance. Recently, the volatility spillovers between the cryptocurrency market and other financial markets are detecting. Nevertheless, the cryptocurrency volatility forecasts underperform the market dynamics. This paper develops a suitable model to capture the cryptocurrency volatility dynamics. We base on deep learning techniques, which produce more reliable results than standard methods in finance by capturing complex data interactions. Specifically, we refer to a Jordan Neural Network, which is a parsimonious recurrent neural network showing more predictability power compared to other models designed for time series, the Self Exciting Threshold Autoregressive model models and the Non-Linear Autoregressive Neural Networks. Empirical evidence is provided using data from three different cryptocurrencies, Bitcoin, Ripple, and Ethereum.

Deep learning in predicting cryptocurrency volatility / D'Amato, V.; Levantesi, S.; Piscopo, G.. - In: PHYSICA. A. - ISSN 0378-4371. - 596:(2022), pp. 127-158. [10.1016/j.physa.2022.127158]

Deep learning in predicting cryptocurrency volatility

D'Amato V.;Levantesi S.;
2022

Abstract

This paper focuses on the prediction of cryptocurrency volatility. The stock market volatility represents a very influential aspect that affects a wide range of decisions in business and finance. Recently, the volatility spillovers between the cryptocurrency market and other financial markets are detecting. Nevertheless, the cryptocurrency volatility forecasts underperform the market dynamics. This paper develops a suitable model to capture the cryptocurrency volatility dynamics. We base on deep learning techniques, which produce more reliable results than standard methods in finance by capturing complex data interactions. Specifically, we refer to a Jordan Neural Network, which is a parsimonious recurrent neural network showing more predictability power compared to other models designed for time series, the Self Exciting Threshold Autoregressive model models and the Non-Linear Autoregressive Neural Networks. Empirical evidence is provided using data from three different cryptocurrencies, Bitcoin, Ripple, and Ethereum.
2022
Cryptocurrency; Deep learning; Neural networks; Volatility
01 Pubblicazione su rivista::01a Articolo in rivista
Deep learning in predicting cryptocurrency volatility / D'Amato, V.; Levantesi, S.; Piscopo, G.. - In: PHYSICA. A. - ISSN 0378-4371. - 596:(2022), pp. 127-158. [10.1016/j.physa.2022.127158]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11573/1628787
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