nep-ets New Economics Papers
on Econometric Time Series
Issue of 2022‒03‒07
nine papers chosen by
Jaqueson K. Galimberti
Auckland University of Technology

  1. Dynamic Mixture Vector Autoregressions with Score-Driven Weights By Alexander Georges Gretener; Matthias Neuenkirch; Dennis Umlandt
  2. Adaptive information-based methods for determining the co-integration rank in heteroskedastic VAR models By H. Peter Boswijk; Giuseppe Cavaliere; Luca De Angelis; A. M. Robert Taylor
  3. Threshold Asymmetric Conational Autoregressive Range (TACARR) Model By Isuru Ratnayake; V. A. Samaranayake
  4. High-Dimensional Sparse Multivariate Stochastic Volatility Models By Benjamin Poignard; Manabu Asai
  5. On Local Projection Based Inference By Ke-Li Xu
  6. Estimating growth at risk with skewed stochastic volatility models By Wolf, Elias
  7. Lead-lag detection and network clustering for multivariate time series with an application to the US equity market By Stefanos Bennett; Mihai Cucuringu; Gesine Reinert
  8. First-order integer-valued autoregressive processes with Generalized Katz innovations By Federico Bassetti; Giulia Carallo; Roberto Casarin
  9. Estimation of Impulse-Response Functions with Dynamic Factor Models: A New Parametrization By Juho Koistinen; Bernd Funovits

  1. By: Alexander Georges Gretener; Matthias Neuenkirch; Dennis Umlandt
    Abstract: We propose a novel dynamic mixture vector autoregressive (VAR) model in which time-varying mixture weights are driven by the predictive likelihood score. Intuitively, the state weight of the k-th component VAR model in the subsequent period is increased if the current observation is more likely to be drawn from this particular state. The model is not limited to a specific distributional assumption and allows for straightforward likelihood-based estimation and inference. We conduct a Monte Carlo study and find that the score-driven mixture VAR model is able to adequately filter the mixture dynamics from a variety of different data generating processes which most other observation-driven dynamic mixture VAR models cannot appropriately cope with. Finally, we illustrate our approach by an application where we model the conditional joint distribution of economic and financial conditions and derive generalized impulse responses.
    Keywords: Dynamic Mixture Models; Generalized Autoregressive Score Models; Macro-Financial Linkages; Nonlinear VAR
    JEL: C32 C34 G17
    Date: 2022
    URL: http://d.repec.org/n?u=RePEc:trr:qfrawp:202202&r=
  2. By: H. Peter Boswijk; Giuseppe Cavaliere; Luca De Angelis; A. M. Robert Taylor
    Abstract: Standard methods, such as sequential procedures based on Johansen's (pseudo-)likelihood ratio (PLR) test, for determining the co-integration rank of a vector autoregressive (VAR) system of variables integrated of order one can be significantly affected, even asymptotically, by unconditional heteroskedasticity (non-stationary volatility) in the data. Known solutions to this problem include wild bootstrap implementations of the PLR test or the use of an information criterion, such as the BIC, to select the co-integration rank. Although asymptotically valid in the presence of heteroskedasticity, these methods can display very low finite sample power under some patterns of non-stationary volatility. In particular, they do not exploit potential efficiency gains that could be realised in the presence of non-stationary volatility by using adaptive inference methods. Under the assumption of a known autoregressive lag length, Boswijk and Zu (2022) develop adaptive PLR test based methods using a non-parameteric estimate of the covariance matrix process. It is well-known, however, that selecting an incorrect lag length can significantly impact on the efficacy of both information criteria and bootstrap PLR tests to determine co-integration rank in finite samples. We show that adaptive information criteria-based approaches can be used to estimate the autoregressive lag order to use in connection with bootstrap adaptive PLR tests, or to jointly determine the co-integration rank and the VAR lag length and that in both cases they are weakly consistent for these parameters in the presence of non-stationary volatility provided standard conditions hold on the penalty term. Monte Carlo simulations are used to demonstrate the potential gains from using adaptive methods and an empirical application to the U.S. term structure is provided.
    Date: 2022–02
    URL: http://d.repec.org/n?u=RePEc:arx:papers:2202.02532&r=
  3. By: Isuru Ratnayake; V. A. Samaranayake
    Abstract: This paper introduces a Threshold Asymmetric Conditional Autoregressive Range (TACARR) formulation for modeling the daily price ranges of financial assets. It is assumed that the process generating the conditional expected ranges at each time point switches between two regimes, labeled as upward market and downward market states. The disturbance term of the error process is also allowed to switch between two distributions depending on the regime. It is assumed that a self-adjusting threshold component that is driven by the past values of the time series determines the current market regime. The proposed model is able to capture aspects such as asymmetric and heteroscedastic behavior of volatility in financial markets. The proposed model is an attempt at addressing several potential deficits found in existing price range models such as the Conditional Autoregressive Range (CARR), Asymmetric CARR (ACARR), Feedback ACARR (FACARR) and Threshold Autoregressive Range (TARR) models. Parameters of the model are estimated using the Maximum Likelihood (ML) method. A simulation study shows that the ML method performs well in estimating the TACARR model parameters. The empirical performance of the TACARR model was investigated using IBM index data and results show that the proposed model is a good alternative for in-sample prediction and out-of-sample forecasting of volatility. Key Words: Volatility Modeling, Asymmetric Volatility, CARR Models, Regime Switching.
    Date: 2022–02
    URL: http://d.repec.org/n?u=RePEc:arx:papers:2202.03351&r=
  4. By: Benjamin Poignard; Manabu Asai
    Abstract: Although multivariate stochastic volatility models usually produce more accurate forecasts compared to MGARCH models, their estimation techniques such as Bayesian MCMC typically suffer from the curse of dimensionality. We propose a fast and efficient estimation approach for MSV based on a penalized OLS framework. Specifying the MSV model as a multivariate state-space model, we carry out a two-step penalized procedure. We provide the asymptotic properties of the two-step estimator and the oracle property of the first-step estimator when the number of parameters diverges. The performances of our method are illustrated through simulations and financial data.
    Date: 2022–01
    URL: http://d.repec.org/n?u=RePEc:arx:papers:2201.08584&r=
  5. By: Ke-Li Xu (Indiana University Bloomington)
    Abstract: We consider inference for predictive regressions with multiple predictors. Extant tests for predictability may perform unsatisfactorily and tend to discover spurious predictability as the number of predictors increases. We propose a battery of new instrumental-variables based tests which involve enforcement or partial enforcement of the null hypothesis in variance estimation. A test based on the few-predictors-at-a-time parsimonious system approach is recommended. Empirical Monte Carlos demonstrate the remarkable finite-sample performance regardless of numerosity of predictors and their persistence properties. Empirical application to equity premium predictability is provided.
    Keywords: Uniform inference, impulse responses, local projections, persistence
    Date: 2022–02
    URL: http://d.repec.org/n?u=RePEc:inu:caeprp:2022002&r=
  6. By: Wolf, Elias
    Abstract: This paper proposes a Skewed Stochastic Volatility (SSV) model to model time varying, asymmetric forecast distributions to estimate Growth at Risk as introduced in Adrian, Boyarchenko, and Giannone's (2019) seminal paper "Vulnerable Growth". In contrary to their semi-parametric approach, the SSV model enables researchers to capture the evolution of the densities parametrically to conduct statistical tests and compare different models. The SSV-model forms a non-linear, non-gaussian state space model that can be estimated using Particle Filtering and MCMC algorithms. To remedy drawbacks of standard Bootstrap Particle Filters, I modify the Tempered Particle Filter of Herbst and Schorfheide's (2019) to account for stochastic volatility and asymmetric measurement densities. Estimating the model based on US data yields conditional forecast densities that closely resemble the findings by Adrian et al. (2019). Exploiting the advantages of the proposed model, I find that the estimated parameter values for the effect of financial conditions on the variance and skewness of the conditional distributions are statistically significant and in line with the intuition of the results found in the existing literature.
    Keywords: Growth at Risk,Macro Finance,Bayesian Econometrics,Particle Filters
    JEL: C10 E32 E58 G01
    Date: 2022
    URL: http://d.repec.org/n?u=RePEc:zbw:fubsbe:20222&r=
  7. By: Stefanos Bennett; Mihai Cucuringu; Gesine Reinert
    Abstract: In multivariate time series systems, it has been observed that certain groups of variables partially lead the evolution of the system, while other variables follow this evolution with a time delay; the result is a lead-lag structure amongst the time series variables. In this paper, we propose a method for the detection of lead-lag clusters of time series in multivariate systems. We demonstrate that the web of pairwise lead-lag relationships between time series can be helpfully construed as a directed network, for which there exist suitable algorithms for the detection of pairs of lead-lag clusters with high pairwise imbalance. Within our framework, we consider a number of choices for the pairwise lead-lag metric and directed network clustering components. Our framework is validated on both a synthetic generative model for multivariate lead-lag time series systems and daily real-world US equity prices data. We showcase that our method is able to detect statistically significant lead-lag clusters in the US equity market. We study the nature of these clusters in the context of the empirical finance literature on lead-lag relations and demonstrate how these can be used for the construction of predictive financial signals.
    Date: 2022–01
    URL: http://d.repec.org/n?u=RePEc:arx:papers:2201.08283&r=
  8. By: Federico Bassetti; Giulia Carallo; Roberto Casarin
    Abstract: A new integer-valued autoregressive process (INAR) with Generalised Lagrangian Katz (GLK) innovations is defined. We show that our GLK-INAR process is stationary, discrete semi-self-decomposable, infinite divisible, and provides a flexible modelling framework for count data allowing for under- and over-dispersion, asymmetry, and excess of kurtosis. A Bayesian inference framework and an efficient posterior approximation procedure based on Markov Chain Monte Carlo are provided. The proposed model family is applied to a Google Trend dataset which proxies the public concern about climate change around the world. The empirical results provide new evidence of heterogeneity across countries and keywords in the persistence, uncertainty, and long-run public awareness level.
    Date: 2022–02
    URL: http://d.repec.org/n?u=RePEc:arx:papers:2202.02029&r=
  9. By: Juho Koistinen; Bernd Funovits
    Abstract: We propose a new parametrization for the estimation and identification of the impulse-response functions (IRFs) of dynamic factor models (DFMs). The theoretical contribution of this paper concerns the problem of observational equivalence between different IRFs, which implies non-identification of the IRF parameters without further restrictions. We show how the minimal identification conditions proposed by Bai and Wang (2015) are nested in the proposed framework and can be further augmented with overidentifying restrictions leading to efficiency gains. The current standard practice for the IRF estimation of DFMs is based on principal components, compared to which the new parametrization is less restrictive and allows for modelling richer dynamics. As the empirical contribution of the paper, we develop an estimation method based on the EM algorithm, which incorporates the proposed identification restrictions. In the empirical application, we use a standard high-dimensional macroeconomic dataset to estimate the effects of a monetary policy shock. We estimate a strong reaction of the macroeconomic variables, while the benchmark models appear to give qualitatively counterintuitive results. The estimation methods are implemented in the accompanying R package.
    Date: 2022–02
    URL: http://d.repec.org/n?u=RePEc:arx:papers:2202.00310&r=

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