On the Log Periodogram Regression Estimator of the 
Memory Parameter in Long Memory Stochastic Volatility Models

Deo, Rohit S.; Hurvich, Clifford M.

doi:10.1017/s0266466601174025

Cited by 127 publications

(115 citation statements)

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“…However, whether these statistics form a suitable basis for model identification for long-memory time series has not been investigated yet. On the other hand, it is also worth pointing out that there are some popular semiparametric estimators of the parameter d in LMSV models, based on the sample autocorrelations of log-squared, squared, and absolute returns, which are typically negatively biased [see, e.g., Andersen and Bollerslev (1997), Bollerslev and Wright (2000), Deo and Hurvich (2001), and Crato and Ray (2002)]. The biases found in these estimators might be related to the negative biases of the sample autocorrelations reported in this article.…”

Section: Resultsmentioning

confidence: 82%

Properties of the Sample Autocorrelations of Nonlinear Transformations in Long-Memory Stochastic Volatility Models

Pérez¹

2003

Journal of Financial Econometrics

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The autocorrelations of log-squared, squared, and absolute financial returns are often used to infer the dynamic properties of the underlying volatility. This article shows that, in the context of long-memory stochastic volatility models, these autocorrelations are smaller than the autocorrelations of the log volatility and so is the rate of decay for squared and absolute returns. Furthermore, the corresponding sample autocorrelations could have severe negative biases, making the identification of conditional heteroscedasticity and long memory a difficult task. Finally, we show that the power of some popular tests for homoscedasticity is larger when they are applied to absolute returns.keywords: absolute transformation, Box-Ljung text, conditional heteroscedasticity, log-squared transformation, Peña Rodriguez test, squared observations. It is by now rather popular to measure the volatility of financial returns by some nonlinear transformations as, for example, log-squared, squared, or absolute returns. Consequently the autocorrelations of these transformations have often been used to test for the presence of conditional heteroscedasticity and to model and estimate the volatility [see, e

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Section: Resultsmentioning

confidence: 82%

Properties of the Sample Autocorrelations of Nonlinear Transformations in Long-Memory Stochastic Volatility Models

Pérez¹

2003

Journal of Financial Econometrics

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“…This rules out most LMSV/LMSD models, since {log v 2 t } is typically non-Gaussian. For the LMSV/LMSD model, results analogous to those of [DH01] were obtained by [Art04] for the GSE estimator, based once again on {log X 2 t }. The use of GSE instead of GPH allows the assumption that {h t } is Gaussian to be weakened to linearity in a Martingale difference sequence.…”

Section: Estimation Of the Memory Parameter Of The Lmsv And Lmsd Modelsmentioning

confidence: 81%

“…This upper bound, m = o[n 4d/(4d+1) ], where n is the sample size, becomes increasingly stringent as d approaches zero. The results in [DH01] assume that d > 0 and hence rule out valid tests for the presence of long memory in {h t }. Such a test based on the GPH estimator was provided and justified theoretically by [HS02].…”

Section: Estimation Of the Memory Parameter Of The Lmsv And Lmsd Modelsmentioning

confidence: 87%

“…The first term in (19) imposes a lower bound on the allowable value of m, requiring that m tend to ∞ faster than n 4d/(4d+1) . It is interesting that [DH01], under similar smoothness assumptions, found that for m 1/2 (d GP H − d) to be asymptotically normal with mean zero, whered GP H is the GPH estimator, the bandwidth m must tend to ∞ at a rate slower than n 4d/(4d+1) . Thus for any given d, the optimal rate of convergence for the local Whittle estimator is faster than that for the GPH estimator.…”

Section: Estimation Of the Memory Parameter Of The Lmsv And Lmsd Modelsmentioning

confidence: 99%

“…This provides some justification for the use of GPH for estimating long memory in volatility. Nevertheless, it can also be seen from Theorem 1 of [DH01] that the presence of the noise term {u t } induces a negative bias in the GPH estimator, which in turn limits the number m of Fourier frequencies which can be used in the estimator while still guaranteeing √ m-consistency and asymptotic normality. This upper bound, m = o[n 4d/(4d+1) ], where n is the sample size, becomes increasingly stringent as d approaches zero.…”

Section: Estimation Of the Memory Parameter Of The Lmsv And Lmsd Modelsmentioning

confidence: 99%

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Stochastic Volatility Models: A Survey with Applications to Option Pricing and Value at Risk

Billio

Sartore

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Applied Quantitative Methods for Trading and Investment

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This chapter presents an introduction to the current literature on stochastic volatility models. For these models the volatility depends on some unobserved components or a latent structure.Given the time-varying volatility exhibited by most financial data, in the last two decades there has been a growing interest in time series models of changing variance and the literature on stochastic volatility models has expanded greatly. Clearly, this chapter cannot be exhaustive, however we discuss some of the most important ideas, focusing on the simplest forms of the techniques and models used in the literature.The chapter is organised as follows. Section 1 considers some motivations for stochastic volatility models: empirical stylised facts, pricing of contingent assets and risk evaluation. While section 2 presents models of changing volatility, section 3 focuses on stochastic volatility models and distinguishes between models with continuous and discrete volatility, the latter depending on a hidden Markov chain. Section 4 is devoted to the estimation problem which is still an open question, then a wide range of possibility is given. Sections 5 and 6 introduce some extensions and multivariate models. Finally, in section 7 an estimation program is presented and some possible applications to option pricing and risk evaluation are discussed.Readers interested in the practical utilisation of stochastic volatility models and in the applications can skip section 4.3 without hindering comprehension.

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On the Log Periodogram Regression Estimator of the Memory Parameter in Long Memory Stochastic Volatility Models

Cited by 127 publications

References 0 publications

Properties of the Sample Autocorrelations of Nonlinear Transformations in Long-Memory Stochastic Volatility Models

Properties of the Sample Autocorrelations of Nonlinear Transformations in Long-Memory Stochastic Volatility Models

Long Memory in Nonlinear Processes

Stochastic Volatility Models: A Survey with Applications to Option Pricing and Value at Risk

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