基于期权与高频数据信息的VaR度量研究

doi:10.16381/j.cnki.issn1003-207x.2019.1189

Abstract

Abstract: Value-at-Risk (VaR), is a widely used measure of financial market risk, which is conceptually simple and intuitive. Accurate measurement of VaR is important for financial risk managers and regulators. Traditionally, the measurement of market risk (VaR) doesn't use the information content of option and high-frequency data fully, and mainly based on the single-factor volatility models such as the GARCH and stochastic volatility models, which leads to the loss of information and the lack of flexibility of the model.
With the rapid development of derivative (option) markets, the option data become readily available. The option prices reflect market sentiment and/or investors' expectations about future stock market volatility. And a growing body of research has found that option data contain important (forward-looking) information for volatility forecasting and risk measurement. At the same time, with the advanced computers and communications technology, high-frequency financial data are now widely available, which usually summarized in terms of realized volatility measure, providing much more detailed information about the current level of volatility.
Motivated by the above interpretation, by extracting the forward-looking and current information of option and high-frequency data based on a flexible two-factor stochastic volatility model, a market risk measurement volatility model is proposed for measuring VaR. To estimate the model parameters, the continuous particle filters-based maximum likelihood estimation method is developed. Using iVX index and realized volatility measure as the proxies of the Shanghai 50ETF option and high-frequency data, an empirical study for the proposed market risk measurement volatility model is presented. The results show that the two-factor stochastic volatility model incorporated with option and high-frequency information can provide more accurate volatility estimates even in the rapidly changing market environment, which leads to more accurate VaR estimates than other volatility models, including the GARCH model incorporated with only historical information, the realized GARCH model incorporated with high-frequency information and the single-factor stochastic volatility model incorporated with option and high-frequency information. In particular, the proposed model can improve the accuracy of VaR estimates more significantly over others under the extreme risk condition.
The empirical results highlight the values of the information content of option and high-frequency data and the two-factor volatility in market risk management. And our model provides an efficient and promising tool to measuring VaR.

Key words: VaR, option pricing, high-frequency data, two-factor stochastic volatility, particle filters

CLC Number:

F830.9

WU Xin-yu, LI Xin-dan, MA Chao-qun. Measuring VaR Based on the Information Content of Option and High-frequency Data[J]. Chinese Journal of Management Science, 2021, 29(8): 13-23.

References

[1] So M, Yu P. Empirical analysis of GARCH models in value at risk estimation[J]. Journal of International Financial Markets, Institutions and Money, 2006, 16(2):180-197.
[2] 肖智, 傅肖肖, 钟波. 基于EVT-BM-FIGARCH的动态VaR风险测度[J]. 中国管理科学, 2008, 16(4):18-23. Xiao Zhi, Fu Xiaoxiao, Zhong Bo. Dynamic VaR risk measures based on EVT-BM-FIGARCH[J]. Chinese Journal of Management Science, 2008, 16(4):18-23.
[3] 林宇, 卫贵武, 魏宇, 等. 基于Skew-FIAPARCH的金融市场动态风险VaR测度研究[J]. 中国管理科学, 2009, 17(6):17-24. Lin Yu, Wei Guiwu, Wei Yu, et al. Study on dynamic risk measure of financial markets based on skew-t-FIAPARCH model[J]. Chinese Journal of Management Science, 2009, 17(6):17-24.
[4] 周孝华, 董耀武, 姜婷. 基于EVT-POT-SV-GED模型的极值风险度量[J]. 系统工程学报, 2012, 27(2):152-159. Zhou Xiaohua, Dong Yaowu, Jiang Ting. Extreme risk measurement based on EVT-POT-SV-GED model[J]. Journal of Systems Engineering,2012,27(2):152-159.
[5] 吴鑫育, 马宗刚, 汪寿阳, 等. 基于SV-SGED模型的动态VaR测度研究[J]. 中国管理科学, 2013, 21(6):1-10. Wu Xinyu, Ma Zonggang, Wang Shouyang, et al. Study on dynamic VaR measures based on SV-SGED model[J]. Chinese Journal of Management Science, 2013, 21(6):1-10.
[6] 周孝华, 张保帅. 基于SV-GED模型的极值风险度量研究[J]. 管理工程学报, 2014, 28(1):171-178. Zhou Xiaohua, Zhang Baoshuai. A research based on SV-GED model of extreme risk measure[J]. Journal of Industrial Engineering and Engineering Management, 2014, 28(1):171-178.
[7] Kiesel R, Rahe F. Option pricing under time-varying risk-aversion with applications to risk forecasting[J]. Journal of Banking & Finance, 2017, 76:120-138.
[8] Pati P C, Barai P, Rajib P. Forecasting stock market volatility and information content of implied volatility index[J]. Applied Economics, 2018, 50(23):2552-2568.
[9] Chun D, Cho H, Ryu D. Forecasting the KOSPI200 spot volatility using various volatility measures[J]. Physica A, 2019, 514:156-166.
[10] Qiao Gaoxiu, Teng Yuxin, Li Weiping, et al. Improving volatility forecasting based on Chinese volatility index information:Evidence from CSI 300 index and futures markets[J]. North American Journal of Economics and Finance, 2019, 49:133-151.
[11] Pan Zhiyuan, Wang Yudong, Liu Li, et al. Improving volatility prediction and option valuation using VIX information:A volatility spillover GARCH model[J]. Journal of Futures Market, 2019, 39(6):744-776.
[12] Black F, Scholes M. The pricing of options and corporate liabilities[J]. Journal of Political Economy, 1973, 81(3):637-654.
[13] Hull J C, White A D. The pricing of options on asset with stochastic volatilities[J]. Journal of Finance, 1987, 42(2):281-300.
[14] Heston S L. A closed-form solution for options with stochastic volatility with applications to bond and currency options[J]. Review of Financial Studies, 1993, 6(2):327-343.
[15] Christoffersen P, Heston S L, Jacobs K. The shape and term structure of the index option smirk:Why multifactor stochastic volatility models work so well[J]. Management Science, 2009, 55(12):1914-1932.
[16] Zhou Guofu, Zhu Yingzi. Volatility trading:What is the role of the long-run volatility component?[J]. Journal of Financial and Quantitative Analysis, 2012, 47(2):273-307.
[17] Guo Biao, Han Qian, Zhao Bin. The Nelson-Siegel model of the term structure of option implied volatility and volatility components[J]. Journal of Futures Markets, 2014, 34(8):788-806.
[18] Bardgett C, Gourier E, Leippold M. Inferring volatility dynamics and risk premia from the S&P 500 and VIX markets[R]. Journal of Financial Economics, 2019, 131(3):593-618.
[19] Branger N, Kraftschika A, Völkert C. The fine structure of variance:Pricing VIX derivatives in consistent and log-VIX models[R].Working Paper, SSRN, 2016.
[20] Amengual D, Xiu Dacheng. Resolution of policy uncertainty and sudden declines in volatility[J]. Journal of Econometrics, 2018, 203(2):297-315.
[21] Campbell J Y, Giglio S, Polk C, et al. An intertemporal CAPM with stochastic volatility[J]. Journal of Financial Economics, 2018, 128(2):207-233.
[22] Andersen T G, Bollerslev T, Diebold F X, et al. The distribution of realized stock return volatility[J]. Journal of Financial Economics, 2001, 61(1):43-76.
[23] Takahashi M, Omori Y, Watanabe T. Estimating stochastic volatility models using daily returns and realized volatility simultaneously[J]. Computational Statistics & Data Analysis, 2009, 53(6):2404-2426.
[24] Koopman S J, Scharth M. The analysis of stochastic volatility in the presence of daily realised measures[J]. Journal of Financial Econometrics, 2013, 11(1):76-115.
[25] Zheng Tingguo, Song Tao. A realized stochastic volatility model with Box-Cox transformation[J]. Journal of Business & Economic Statistics, 2014, 32(4):593-605.
[26] Takahashi M, Watanabe T, Omori Y. Volatility and quantile forecasts by realized stochastic volatility models with generalized hyperbolic distribution[J]. International Journal of Forecasting, 2016, 32(2):437-457.
[27] Asai M, Chang C, Mcaleer M. Realized stochastic volatility with general asymmetry and long memory[J]. Journal of Econometrics, 2017, 199:202-212.
[28] 吴鑫育,李心丹,马超群.门限已实现随机波动率模型及其实证研究[J].中国管理科学,2017,25(3):10-19. Wu Xinyu, Li Xindan, Ma Chaoqun. Threshold realized stochastic volatility model and its empirical test[J]. Chinese Journal of Management Science, 2017, 25(3):10-19.
[29] 吴鑫育, 周海林. 基于已实现SV模型的动态VaR测度研究[J]. 管理工程学报, 2018, 32(2), 144-150. Wu Xinyu, Zhou Hailin. Study on dynamic VaR measures based on realized SV model[J]. Journal of Industrial Engineering and Engineering Management, 2018, 32(2):144-150.
[30] 吴鑫育, 李心丹, 马超群. 双因子非对称已实现SV模型及其实证研究[J]. 中国管理科学, 2018, 26(2):1-13. Wu Xinyu, Li Xindan, Ma Chaoqun. The realized SV model of two-factor asymmetry and its empirical research[J]. Chinese Journal of Management Science, 2018, 26(2):1-13.
[31] 吴鑫育, 李心丹, 马超群. 混合正态双因子已实现SV模型及其实证研究[J]. 管理科学, 2019, 32(2):148-160. Wu Xinyu, Li Xindan, Ma Chaoqun. Two-factor realized SV model with mixture of normals and its empirical research[J]. Journal of Management Science, 2019, 32(2):148-160.
[32] Hansen P R, Huang Zhuo, Shek H H. Realized GARCH:A joint model for returns and realized measures of volatility[J]. Journal of Applied Econometrics, 2012, 27:877-906.
[33] Hansen P R, Huang Zhuo. Exponential GARCH modeling with realized measures of volatility[J]. Journal of Business & Economic Statistics, 2016, 34(2):269-287.
[34] 唐勇, 刘微. 加权已实现极差四次幂变差分析及其应用[J]. 系统工程理论与实践, 2013, 33(11):2766-2775. Tang Yong, Liu Wei. Analysis of weighted realized range-based quadpower variation and its application[J]. Systems Engineering-Theory & Practice, 2013, 33(11):2766-2775.
[35] 王天一, 赵晓军, 黄卓. 利用高频数据预测沪深300指数波动率——基于Realized GARCH模型的实证研究[J]. 世界经济文汇, 2014(5):17-30. Wang Tianyi, Zhao Xiaojun, Huang Zhuo. Forecasting volatility of the CSI 300 index with high frequency data-An empirical study based on the realized GARCH Model[J].World Economic Papers,2014(5):17-30.
[36] 王天一, 黄卓. Realized GAS-GARCH及其在VaR预测中的应用[J]. 管理科学学报, 2015, 18(5):79-86. Wang Tianyi, Huang Zhuo. Realized GAS-GARCH model and its application in Value-at-Risk forecast[J]. Journal of Management Sciences in China, 2015, 18(5):79-86.
[37] 黄友珀, 唐振鹏, 周熙雯. 基于偏分布realized GARCH模型的尾部风险估计[J]. 系统工程理论与实践, 2015, 35(9):2200-2208. Huang Youpo, Tang Zhenpeng, Zhou Xiwen. Estimation of tail risk based on realized GARCH model with skew-t distribution[J]. Systems Engineering-Theory & Practice, 2015, 35(9):2200-2208.
[38] 黄友珀, 唐振鹏, 唐勇. 基于藤copula-已实现GARCH的组合收益分位数预测[J]. 系统工程学报, 2016, 31(1):45-54. Huang Youpo, Tang Zhenpeng, Tang Yong. Portfolio quantile forecasts based on vine copula and realized GARCH[J]. Journal of Systems Engineering, 2016, 31(1):45-54.
[39] Huang Zhuo, Liu Hao, Wang Tianyi. Modeling long memory volatility using realized measures of volatility:A realized HAR GARCH model[J]. Economic Modeling, 2016, 52(1):812-821.
[40] Wu Xinyu, Xie Haibin. A realized EGARCH-MIDAS model with higher moments[J]. Finance Research Letters, 2019, DOI:10.1016/j.frl.2019.101392.
[41] Wu Xinyu, Xia Chaoxiong, Zhang Huanming. Forecasting VaR using realized EGARCH model with skewness and kurtosis[J]. Finance Research Letters, 2019, DOI:10.1016/j.frl.2019.01.002.
[42] Christoffersen P, Jacobs K, Mimouni K. Volatility dynamics for the S&P 500:Evidence from realized volatility, daily returns, and option prices[J]. Review of Financial Studies, 2010, 23(8):3141-3189.
[43] Kaeck A, Alexander C. Volatility dynamics for the S&P 500:Further evidence from non-affine, multi-factor jump diffusions[J]. Journal of Banking & Finance, 2012, 36(11):3110-3121.
[44] Yang Hanxue, Kanniainen J. Jump and volatility dynamics for the S&P 500:Evidence for infinite-activity jumps with non-affine volatility dynamics from stock and option markets[J]. Reveiw of Finance, 2017, 21(2):811-844.
[45] Wu Xinyu, Zhou Hailin, Wang Shouyang. Estimation of market prices of risks in the G.A.R.C.H. diffusion model[J]. Economic Research-Ekonomska Istra?ivanja, 2018, 31(1):15-36.
[46] 吴鑫育, 赵凯, 李心丹, 等. 时变风险厌恶下的期权定价——基于上证50ETF期权的实证研究[J]. 中国管理科学, 2019, 27(11):11-22. Wu Xinyu, Zhao Kai, Li Xindan, et al. Option pricing under time-varying risk aversion:An empirical study based on SSE 50ETF options[J]. Chinese Journal of Management Science, 2019, 27(11):11-22.
[47] Gordon N J, Salmond D J, Smith A FM. Novel approach to nonlinear/non-Gaussian Bayesian state estimation[J]. IEE Proceedings-F, 1993, 140(2):107-113.
[48] Malik S, Pitt M K. Particle filters for continuous likelihood evaluation and maximization[J]. Journal of Econometrics, 2011, 165:190-209.
[49] Kupiec P. Techniques for verifying the accuracy of risk measurement models[J]. Journal of Derivatives, 1995, 3(2):73-84.

Measuring VaR Based on the Information Content of Option and High-frequency Data

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