Volatility models applied to geophysics and high frequency financial market data

Maria C. Mariani; Md Al Masum Bhuiyan; Osei K. Tweneboah; Hector Gonzalez-Huizar; Ionut Florescu

doi:10.1016/j.physa.2018.02.167

Volatility models applied to geophysics and high frequency financial market data

Maria C. Mariani, Md Al Masum Bhuiyan, Osei K. Tweneboah, Hector Gonzalez-Huizar, Ionut Florescu

School of Business

University of Texas at El Paso

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

This work is devoted to the study of modeling geophysical and financial time series. A class of volatility models with time-varying parameters is presented to forecast the volatility of time series in a stationary environment. The modeling of stationary time series with consistent properties facilitates prediction with much certainty. Using the GARCH and stochastic volatility model, we forecast one-step-ahead suggested volatility with ±2 standard prediction errors, which is enacted via Maximum Likelihood Estimation. We compare the stochastic volatility model relying on the filtering technique as used in the conditional volatility with the GARCH model. We conclude that the stochastic volatility is a better forecasting tool than GARCH (1,1), since it is less conditioned by autoregressive past information.

Original language	English
Pages (from-to)	304-321
Number of pages	18
Journal	Physica A: Statistical Mechanics and its Applications
Volume	503
DOIs	https://doi.org/10.1016/j.physa.2018.02.167
State	Published - 1 Aug 2018

Keywords

ADF test
Financial time series
GARCH model
Geophysical time series
KPSS test
Maximum likelihood estimation
Seismogram
Stochastic volatility model

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10.1016/j.physa.2018.02.167

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title = "Volatility models applied to geophysics and high frequency financial market data",

abstract = "This work is devoted to the study of modeling geophysical and financial time series. A class of volatility models with time-varying parameters is presented to forecast the volatility of time series in a stationary environment. The modeling of stationary time series with consistent properties facilitates prediction with much certainty. Using the GARCH and stochastic volatility model, we forecast one-step-ahead suggested volatility with ±2 standard prediction errors, which is enacted via Maximum Likelihood Estimation. We compare the stochastic volatility model relying on the filtering technique as used in the conditional volatility with the GARCH model. We conclude that the stochastic volatility is a better forecasting tool than GARCH (1,1), since it is less conditioned by autoregressive past information.",

keywords = "ADF test, Financial time series, GARCH model, Geophysical time series, KPSS test, Maximum likelihood estimation, Seismogram, Stochastic volatility model",

author = "Mariani, {Maria C.} and Bhuiyan, {Md Al Masum} and Tweneboah, {Osei K.} and Hector Gonzalez-Huizar and Ionut Florescu",

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doi = "10.1016/j.physa.2018.02.167",

language = "English",

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T1 - Volatility models applied to geophysics and high frequency financial market data

AU - Mariani, Maria C.

AU - Bhuiyan, Md Al Masum

AU - Tweneboah, Osei K.

AU - Gonzalez-Huizar, Hector

AU - Florescu, Ionut

PY - 2018/8/1

Y1 - 2018/8/1

N2 - This work is devoted to the study of modeling geophysical and financial time series. A class of volatility models with time-varying parameters is presented to forecast the volatility of time series in a stationary environment. The modeling of stationary time series with consistent properties facilitates prediction with much certainty. Using the GARCH and stochastic volatility model, we forecast one-step-ahead suggested volatility with ±2 standard prediction errors, which is enacted via Maximum Likelihood Estimation. We compare the stochastic volatility model relying on the filtering technique as used in the conditional volatility with the GARCH model. We conclude that the stochastic volatility is a better forecasting tool than GARCH (1,1), since it is less conditioned by autoregressive past information.

AB - This work is devoted to the study of modeling geophysical and financial time series. A class of volatility models with time-varying parameters is presented to forecast the volatility of time series in a stationary environment. The modeling of stationary time series with consistent properties facilitates prediction with much certainty. Using the GARCH and stochastic volatility model, we forecast one-step-ahead suggested volatility with ±2 standard prediction errors, which is enacted via Maximum Likelihood Estimation. We compare the stochastic volatility model relying on the filtering technique as used in the conditional volatility with the GARCH model. We conclude that the stochastic volatility is a better forecasting tool than GARCH (1,1), since it is less conditioned by autoregressive past information.

KW - ADF test

KW - Financial time series

KW - GARCH model

KW - Geophysical time series

KW - KPSS test

KW - Maximum likelihood estimation

KW - Seismogram

KW - Stochastic volatility model

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EP - 321

JO - Physica A: Statistical Mechanics and its Applications

JF - Physica A: Statistical Mechanics and its Applications

ER -

Volatility models applied to geophysics and high frequency financial market data

Abstract

Keywords

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