拟得分驱动条件异方差自回归极差模型及其实证研究

doi:10.16381/j.cnki.issn1003-207x.2022.1331

摘要/Abstract

摘要：

条件自回归极差（CARR）模型是基于极差的波动模型，在实际中有广泛应用。本文从得分驱动时变参数模型的角度分析CARR模型的缺陷，发现基于极差条件分布设定的得分驱动更新项对分布误设不具有稳健性，同时忽略了当期样本信息。此外，CARR模型中波动的条件方差为常数，不能刻画波动自身的条件异方差特性（即所谓的“波动的波动”现象）。因此本文对CARR模型进行改进和拓展，用拟得分驱动（Quasi Score-Driven）方法改进更新项，将极差当期信息引入波动模型，同时在模型中考虑“波动的波动”效应，提出拟得分驱动条件异方差自回归极差（QSD-CHARR）模型。对得分函数曲线和信息反应曲线的分析表明，QSD-CHARR模型的波动更新机制更为合理和稳健。蒙特卡洛模拟显示，与CARR模型相比，QSD-CHARR模型拟合能力显著提高。基于上证综指和标普500指数的实证分析表明，QSD-CHARR模型在波动拟合、预测上对CARR模型的改进具有统计显著性。

关键词: 价格极差, CARR模型, 拟得分驱动, 波动的波动, QSD-CHARR

Abstract:

The latent volatility process of asset returns is relevant for a wide variety of applications， such as option pricing and risk management， and return-based volatility models， including GARCH models and related extensions， are widely used to model the dynamics of volatility. Standard return-based models mainly utilize daily returns （typically squared returns） to extract information about the current level of volatility and to form out-of-sample forecast. It is， however， well-known that squared returns are quite noisy proxies of volatility， which further translates to a relatively poor performance of related models. Volatility measures based on high-frequency financial data are far more informative about the “true” volatility than is the square return， but they are readily available for only a small number of assets. A sub-optimal alternative is to employ range-based volatility measures which are constructed from daily high and low prices， and achieve significantly higher efficiency than squared returns.A benchmark model for describing the dynamic feature of range-based measures is the conditional autoregressive range （CARR） model and it generally provides far more accurate volatility nowcast and forecast than comparable GARCH-type models. Despite its empirical superiority， CARR model implicitly imposes a strong link between the conditional distribution of volatility measures and the updating equation of volatility， which is not always desirable. More importantly， it formulates volatility as a function of lagged samples， thus ignoring the contemporaneous observations which is apparently more informative about the current level of volatility and the empirically relevant “volatility of volatility” effect， that is， the conditional heteroskedasticity of volatility.Inspired by the real-time GARCH models of Smetanina （2017）， the SHARV models of Ding （2023） and the quasi score-driven models of Blasques et al. （2023）， a new range-based volatility model， Quasi Score-Driven Conditional Heteroskedastic AutoRegressive Range （QSD-CHARR） model， is introduced that incorporates a quasi score-driven term in the volatility dynamics which generalizes the corresponding term in CARR model， and accounts for contemporaneous information and “volatility of volatility” effect simultaneously. Compared to the news impact curve of CARR model， that of QSD-CHARR model presents a more reasonable pattern. The conditional distribution of volatility measures is derived and the QMLE of parameters is defined. A preliminary Monte Carlo study shows that the QMLE performs reasonably well in finite samples. An empirical application utilizing daily Parkinson estimator series of Shanghai securities composite index and Standard & Poor’s 500 index reveals that a parsimonious QSD-CHARR structure leads to substantial improvements in volatility filtering and short-period volatility forecasting over CARR models， and the results highlight the empirical relevance of contemporaneous information and the conditional heteroskedasticity of volatility.

Key words: price range, CARR, quasi score-driven, volatility of volatility, QSD-CHARR

中图分类号:

F830.9

沈根祥, 周泽峰. 拟得分驱动条件异方差自回归极差模型及其实证研究[J]. 中国管理科学, 2025, 33(5): 34-44.

Genxiang Shen, Zefeng Zhou. Quasi Score-driven Conditional Heteroskedastic Autoregressive Range Model and It's Empirical Study[J]. Chinese Journal of Management Science, 2025, 33(5): 34-44.

图/表 8

图1

图2

表1

蒙特卡罗模拟：参数估计"

分布 $F ε (⋅)$	参数值	$β = 0.8$	$α = 0.1$	$ϕ = 0.1$	$θ = 0.1$	$b = 0.5$	$E λ t ̑$
Gamma	估计值	0.7994	0.0997	0.1014	0.0998	0.4467	1.0011
	标准差	0.0237	0.0055	0.0142	0.0226	0.4432	0.0333
	RMSE	0.0237	0.0056	0.0144	0.0227	0.4456	0.0333
Lgnorm	估计值	0.7918	0.0979	0.1045	0.1041	0.3745	1.0065
	标准差	0.0238	0.0063	0.0171	0.0221	0.3642	0.0412
	RMSE	0.0253	0.0066	0.0177	0.0225	0.3984	0.0417
F	估计值	0.7966	0.1004	0.1032	0.0993	0.3715	1.0054
	标准差	0.0235	0.0063	0.0178	0.0210	0.4069	0.0409
	RMSE	0.0236	0.0063	0.0181	0.0210	0.4356	0.0412

表1

表2

表3

表4

参数估计结果"

参数	$ω$	$α$	$β$	$φ$	$θ$	$b$	$ν$	-logL
Panel A: SSE
M0	0.0179	0.1633	0.9829				5.5524	2371.58
	(0.0031)	(0.0094)	(0.0034)				(0.1141)
M1	0.0053	0.1758	0.9991			0.9166	5.5826	2356.97
	(0.0032)	(0.0095)	(0.0045)			(0.1184)	(0.1105)
M2		0.1504	0.9677	0.0323			5.9871	2344.38
		(0.0090)	(0.0047)	(0.0045)			(0.1158)
M3		0.1569	0.9714	0.0282		0.6835	5.9624	2334.81
		(0.0096)	(0.0057)	(0.0051)		(0.1529)	(0.1391)
M4		0.1588	0.8904	0.0239	0.0898	0.5602	7.0043	2301.66
		(0.0095)	(0.0169)	(0.0053)	(0.0158)	(0.1539)	(0.2889)
Panel B: SPX
M0	0.0206	0.2453	0.9720				5.5942	568.44
	(0.0026)	(0.0111)	(0.0042)				(0.1121)
M1	0.0186	0.2596	0.9751			0.1620	5.5975	566.76
	(0.0028)	(0.0141)	(0.0048)			(0.0895)	(0.1058)
M2		0.2195	0.9604	0.0282			6.1532	535.03
		(0.0102)	(0.0046)	(0.0030)			(0.1210)
M3		0.2351	0.9610	0.0273		0.2075	6.1440	532.32
		(0.0129)	(0.0049)	(0.0030)		(0.0901)	(0.1261)
M4		0.1609	0.8427	0.0228	0.1262	0.2826	7.6119	498.49
		(0.0195)	(0.0181)	(0.0032)	(0.0171)	(0.1095)	(0.3189)

表4

表5

波动拟合评估"

模型	M0	M1	M2	M3	M4
SSE
MSE	0.1663	0.1570	0.1610	0.1544	0.1291
$p M C S$	(0.0000)	(0.0000)	(0.0000)	(0.0000)	(1.0000)
QLIKE	0.0466	0.0456	0.0432	0.0429	0.0349
$p M C S$	(0.0000)	(0.0000)	(0.0000)	(0.0000)	(1.0000)
SPX
MSE	0.1165	0.1137	0.1154	0.1123	0.0961
$p M C S$	(0.0000)	(0.0000)	(0.0000)	(0.0000)	(1.0000)
OLIKE	0.0529	0.0527	0.0484	0.0484	0.0401
$p M C S$	(0.0000)	(0.0000)	(0.0000)	(0.0000)	(1.0000)

表5

表6

波动预测评估"

模型	M0	M1	M2	M3	M4
Panel A: SSE
1步预测
MSE	0.1556	0.1491	0.1575	0.1483	0.1372
$p M C S$	(0.0800)	(0.1594)	(0.3322)	(0.1542)	(1.0000)
QLIKE	0.0465	0.0475	0.0465	0.0466	0.0450
$p M C S$	(0.5692)	(0.3318)	(0.5790)	(0.4460)	(1.0000)
5步预测
MSE	0.2295	0.2295	0.2348	0.2242	0.2092
$p M C S$	(0.1284)	(0.8864)	(0.2750)	(1.0000)	(1.0000)
QLIKE	0.0673	0.0681	0.0692	0.0691	0.0684
$p M C S$	(1.0000)	(1.0000)	(0.7458)	(0.6912)	(1.0000)
10步预测
MSE	0.2776	0.3044	0.2859	0.2915	0.2875
$p M C S$	(1.0000)	(0.2306)	(1.0000)	(0.9032)	(1.0000)
QLIKE	0.0801	0.0831	0.0845	0.0850	0.0826
$p M C S$	(1.0000)	(0.4118)	(0.1414)	(0.0714)	(0.5792)
Panel B: SPX
1步预测
MSE	0.1163	0.1129	0.1181	0.1142	0.1041
$p M C S$	(0.1110)	(0.0894)	(0.1536)	(0.1106)	(1.0000)
QLIKE	0.0623	0.0621	0.0620	0.0619	0.0603
$p M C S$	(0.1092)	(0.2546)	(0.5004)	(0.4702)	(1.0000)
5步预测
MSE	0.1961	0.1942	0.1978	0.1956	0.1838
$p M C S$	(0.1796)	(0.6690)	(0.5568)	(0.5964)	(1.0000)
QLIKE	0.1122	0.1122	0.1124	0.1123	0.1131
$p M C S$	(1.0000)	(1.0000)	(0.9964)	(0.9982)	(0.9124)
10步预测
MSE	0.2461	0.2464	0.2456	0.2451	0.2463
$p M C S$	(0.9648)	(0.8800)	(1.0000)	(1.0000)	(0.9968)
QLIKE	0.1373	0.1374	0.1377	0.1376	0.1399
$p M C S$	(1.0000)	(1.0000)	(1.0000)	(1.0000)	(0.4810)

表6

参考文献 32

1	Bollerslev T. Generalized autoregressive conditional heteroskedasticity［J］. Journal of Econometrics， 1986， 31（3）： 307-327.
2	Parkinson M. The extreme value method for estimating the variance of the rate of return［J］. The Journal of Business， 1980， 53（1）： 61-65.
3	Alizadeh S， Brandt M W， Diebold F X. Range-based estimation of stochastic volatility models［J］. The Journal of Finance， 2002， 57（3）： 1047-1091.
4	Brandt M W， Diebold F X. A no‐arbitrage approach to range‐based estimation of return covariances and correlations［J］. The Journal of Business， 2006， 79（1）： 61-74.
5	Shu J H， Zhang J E. Testing range estimators of historical volatility［J］. The Journal of Futures Markets， 2006， 26（3）： 297-313.
6	Chou R Y. Forecasting financial volatilities with extreme values： The conditional autoregressive range （CARR） model［J］. Journal of Money， Credit and Banking， 2005， 37（3）： 561-582.
7	Brandt M W， Jones C S. Volatility forecasting with range-based EGARCH models［J］. Journal of Business & Economic Statistics， 2006， 24（4）： 470-486.
8	王沁. 基于杠杆效应CARR模型的波动率预测［J］. 数理统计与管理， 2017， 36（1）： 51-58.
	Wang Q. The volatility forecast based on the leverage effect CARR model［J］. Journal of Applied Statistics and Management， 2017， 36（1）： 51-58.
9	Chen C W S， Gerlach R， Lin E M H. Volatility forecasting using threshold heteroskedastic models of the intra-day range［J］. Computational Statistics & Data Analysis， 2008， 52（6）： 2990-3010.
10	Xie H B. Financial volatility modeling： The feedback asymmetric conditional autoregressive range model［J］. Journal of Forecasting， 2019，38（1）： 11-28.
11	Sin C Y. Using CARRX models to study factors affecting the volatilities of Asian equity markets ［J］. The North American Journal of Economics and Finance， 2013， 26： 552-564.
12	Kumar D. Sudden changes in extreme value volatility estimator： Modeling and forecasting with economic significance analysis ［J］. Economic Modelling， 2015， 49： 354-371.
13	吴鑫育，谢海滨，马超群. 得分驱动乘性成分已实现CARR模型及其实证研究［J］. 中国管理科学， 2023， 31（8）： 214-225.
	Wu X Y， Xie H B， Ma C Q. Score-driven multiplicative component realized CARR model and its empirical study［J］. Chinese Journal of Management Science， 2023， 31（8）： 214-225.
14	Chen W P， Choudhry T， Wu C C. The extreme value in crude oil and US dollar markets ［J］. Journal of International Money and Finance， 2013， 36： 191-210.
15	Lin E M H， Chen C W S， Gerlach R. Forecasting volatility with asymmetric smooth transition dynamic range models［J］. International Journal of Forecasting， 2012，28（2）： 384-399.
16	Miao D W， Wu C， Su Y. Regime-switching in volatility and correlation structure using range-based models with Markov-switching［J］. Economic Modelling， 2013， 31： 87-93.
17	Harris R D F， Stoja E， Yilmaz F. A cyclical model of exchange rate volatility ［J］. Journal of Banking & Finance， 2011， 35 （11）： 3055-3064.
18	Wu X Y， Hou X M. Forecasting volatility with component conditional autoregressive range model［J］. The North American Journal of Economics and Finance， 2020， 51：101078.
19	Xie H B. Range-based volatility forecasting： a multiplicative component conditional autoregressive range model［J］. Journal of Risk， 2020， 22（5）： 43-65.
20	吴鑫育，谢海滨，汪寿阳. 双因子随机条件极差模型及其实证研究［J］. 管理科学学报， 2020， 23（1）： 47-64.
	Wu X Y， Xie H B， Wang S Y. Two-factor stochastic conditional range model and its empirical study［J］. Journal of Management Sciences in China， 2020， 23（1）： 47-64.
21	鲁万波，于翠婷，王敏. 基于非参数条件自回归极差模型的中国股市波动性预测［J］. 数理统计与管理， 2018， 37（3）： 544-553.
	Lu W B， Yu C T， Wang M. Forecasting volatility of Chinese stock market with nonparametric conditional autoregressive range model［J］. Journal of Applied Statistics and Management， 2018， 37（3）： 544-553.
22	王沁. 金融市场间波动溢出效应研究——基于Gumber的二维CARR模型和生存Copula-CARR模型［J］. 数理统计与管理， 2019， 38（3）： 535-548.
	Wang Q. Research on the volatility spillover between financial markets based on the Gumber’s two-dimensional CARR model and the survival coupla-CARR model［J］. Journal of Applied Statistics and Management， 2019， 38（3）： 535-548.
23	Blasques F， Francq C， Laurent S. Quasi score-driven models［J］. Journal of Econometrics， 2023， 234（1）： 251-275.
24	Smetanina E. Real-time GARCH［J］. Journal of Financial Econometrics， 2017， 15（4）： 561-601.
25	Xie H B， Wu X Y. A conditional autoregressive range model with gamma distribution for financial volatility modelling［J］. Economic Modelling， 2017， 64： 349-356.
26	Creal D， Koopman S J， Lucas A. Generalized autoregressive score models with applications［J］. Journal of Applied Econometrics， 2013， 28（5）： 777-795.
27	Blasques F， Koopman S J， Lucas A. Information-theoretic optimality of observation-driven time series models for continuous responses［J］. Biometrika， 2015， 102（2）： 325-343.
28	Koopman S J， Lucas A， Scharth M. Predicting time-varying parameters with parameter-driven and observation-driven models［J］. The Review of Economics and Statistics， 2016， 98（1）： 97-110.
29	Patton A J. Volatility forecast comparison using imperfect volatility proxies［J］. Journal of Econometrics， 2011， 160（1）： 246-256.
30	Ding Y D. A simple joint model for returns， volatility and volatility of volatility［J］. Journal of Econometrics， 2023， 232（2）： 521-543.
31	Engle R F， Ng V K. Measuring and testing the impact of news on volatility［J］. The Journal of Finance， 1993， 48（5）： 1749-1778.
32	Hansen P R， Lunde A， James M N， The model confidence set［J］. Econometrica， 2011， 79（2）： 453-497.

损失函数	M0	M1	M2	M3	M4
MSE	0.2933	0.2922	0.2662	0.2643	0.2432
QLIKE	0.1237	0.1205	0.1108	0.1112	0.1036

指数波动	SSE		SPX
指数波动	R	RV	R	RV
样本量	5093	5075	5286	5264
均值	1.0494	1.0669	0.7689	0.8293
标准差	0.7094	0.6654	0.6059	0.6161
最大值	6.3914	6.5411	6.5486	8.8021
最小值	0.1514	0.1882	0.0875	0.1104
偏度	2.2829	2.3400	3.1841	3.4625
峰度	10.7413	11.6535	19.9484	23.3971

[1]	吴鑫育,姜晓晴,李心丹,马超群. 基于已实现EGARCH-FHS模型的上证50ETF期权定价研究[J]. 中国管理科学, 2024, 32(3): 105-115.
[2]	吴鑫育,谢海滨,马超群. 得分驱动乘性成分已实现CARR模型及其实证研究[J]. 中国管理科学, 2023, 31(8): 214-225.
[3]	刘维奇, 邢红卫, 张信东. 投资偏好与“特质波动率之谜”——以中国股票市场A股为研究对象[J]. 中国管理科学, 2014, 22(8): 10-20.
[4]	李红权, 汪寿阳. 基于价格极差的金融波动率建模：理论与实证分析[J]. 中国管理科学, 2009, 17(6): 1-8.