There are two ways of modeling cross-sectional dependence: spatial models and factor models. In Chapter 3, we introduce three leading approaches of estimating large panel data regression models with an error factor structure: the common correlated effects (CCE) approach proposed by Pesaran (2006), Bai’s (2009) iterated principal components (IPC) approach and the maximum likelihood estimation (MLE) method proposed by Bai and Li (2014). The use of these approaches is illustrated by an empirical example in the context of the productivity of infrastructure investment in China.
Chapter 4 examines the issue of structural changes in large panel data regression models. In the literature on panel data models with large time dimension, e.g., Kao (1999), Phillips and Moon (1999), Hahn and Kuersteiner (2002), Alvarez and Arellano (2003), Phillips and Sul (2007), Pesaran and Yamagata (2008), Hayakawa (2009), to name a few, the implicit assumption is that the slope coefficients are constant over time. However, due to policy implementation or technological shocks, structural breaks are possible especially for panels with a long time span. Consequently, ignoring structural breaks may lead to inconsistent estimation and invalid inference.
Based on Baltagi, Feng and Kao (2016, 2019), Chapter 4 extends Pesaran’s (2006) work on CCE estimators for large heterogeneous panels with a general multifactor error structure by allowing for unknown common structural breaks in slopes and unobserved factor structure. We propose a general framework that includes heterogeneous panel data models and structural break models as special cases. The least squares method proposed by Bai (1997a, 2010) is applied to estimate the common change points, and the consistency of the estimated change points is established. We find that the CCE estimators have the same asymptotic distribution as if the true change points were known. Additionally, Monte Carlo simulations are used to verify the main findings.
By considering both cross-sectional dependence and structural breaks in a general panel data model, this chapter also contributes to the change point literature in several ways. First, it extends Bai’s (1997a) time-series regression model to heterogeneous panels, showing that the consistency of estimated change points can be achieved with the information along the cross-sectional dimension. This result confirms the findings of Bai (2010) and Kim (2011). Second, it also enriches the analysis of common breaks of Bai (2010) and Kim (2011) in a panel mean-shift model and a panel deterministic time trend model by extending them to a regression model using panel data. This makes it possible to allow for structural breaks and cross-sectional dependence in empirical work using panel regressions. In particular, our methods can be applied to regression models using large stationary panel data, such as country-level panels and state/provincial-level panels.
Regarding estimating common breaks in panels, Feng, Kao and Lazarova (2009) and Baltagi, Kao and Liu (2012) also show the consistency of the estimated change point in a simple panel regression model. Hsu and Lin (2012) examine the consistency properties of the change point estimators for non-stationary panels. More recently, Qian and Su (2016) and Li, Qian and Su (2016) study the estimation and inference of common breaks in panel data models with and without interactive fixed effects using Lasso-type methods. Westerlund (2019) establishes the consistency of least squares estimator of break point in a mean-shift model with fixed T, using the CCE approach to deal with unobserved error factors. In terms of detecting structural breaks in panels, some recent literature includes Horváth and Hušková (2012) in a panel mean-shift model with and without cross-sectional dependence, De Wachter and Tzavalis (2012) in dynamic panels, and Pauwels, Chan and Mancini-Griffoli (2012) in heterogeneous panels, Oka and Perron (2018) in multiple equation systems, to name a few.
Chapter 5 studies heterogeneity and grouping issues in large dimensional panel data models. When a large number of individuals/countries are involved in the regression, it is costly to allow for individual unobserved heterogeneity, for example, fixed effects, which may lead to incidental parameter problem in the regression. One way to balance between modeling heterogeneity and incidental parameters is grouping. With within-group homogeneity and cross-group difference, we can still allow for a certain degree of heterogeneity and avoid incidental parameter problem.
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