Dimension estimation in sufficient dimension reduction: A unifying approach

Bura, Efstathia; Yang, Jie

doi:10.1016/j.jmva.2010.08.007

Cited by 53 publications

(58 citation statements)

References 32 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…., it can also be shown that their sample means are approximately normally distributed for large T (see Appendix B). Under the same assumptions we can then obtain that M h is asymptotically normal following similar arguments as Bura and Yang (2011) [17] who derived the asymptotic distribution of M when the data are i.i.d. draws from the joint distribution of (y, x).…”

Section: Propositionmentioning

confidence: 75%

“…It is based on the results of Section 3.1 and uses a sample counterpart to Σ −1 Var (E (x|y)). 17 The name derives from using the inverse regression of x on the sliced response y to estimate the reduction. For a univariate y, the method is particularly easy to implement, SIR's step functions being a simple nonparametric approximation to E(x|y).…”

Section: Sliced Inverse Regressionmentioning

confidence: 99%

See 1 more Smart Citation

A Unified Framework for Dimension Reduction in Forecasting

Barbarino

Bura²

2017

FEDS

View full text Add to dashboard Cite

Factor models are widely used in summarizing large datasets with few underlying latent factors and in building time series forecasting models for economic variables. In these models, the reduction of the predictors and the modeling and forecasting of the response y are carried out in two separate and independent phases. We introduce a potentially more attractive alternative, Sufficient Dimension Reduction (SDR), that summarizes x as it relates to y, so that all the information in the conditional distribution of y|x is preserved. We study the relationship between SDR and popular estimation methods, such as ordinary least squares (OLS), dynamic factor models (DFM), partial least squares (PLS) and RIDGE regression, and establish the connection and fundamental differences between the DFM and SDR frameworks. We show that SDR significantly reduces the dimension of widely used macroeconomic series data with one or two sufficient reductions delivering similar forecasting performance to that of competing methods in macro-forecasting. JEL Classification Number: C32, C53, C55, E17

show abstract

Section: Propositionmentioning

confidence: 75%

Section: Sliced Inverse Regressionmentioning

confidence: 99%

A Unified Framework for Dimension Reduction in Forecasting

Barbarino

Bura²

2017

FEDS

View full text Add to dashboard Cite

show abstract

“…The first two methods are based on the results in Theorem 1 while the third method relates to Theorem 2. In the Step 3 of Algorithm 1, one needs to determine an appropriate value for the dimension d. This can be done in several ways, either by the use of some test statistic [Bura and Yang, 2011] or via a straightforward inspection of a plot of the eigenvalues.…”

Section: Standardize the Regressorsmentioning

confidence: 99%

Inverse Regression for the Wiener Class of Systems

Lyzell

Enqvist

2012

IFAC Proceedings Volumes

View full text Add to dashboard Cite

The concept of inverse regression has turned out to be quite useful for dimension reduction in regression analysis problems. Using methods like sliced inverse regression (SIR) and directional regression (DR), some high-dimensional nonlinear regression problems can be turned into more tractable low-dimensional problems. Here, the usefulness of inverse regression for identification of nonlinear dynamical systems will be discussed. In particular, it will be shown that the inverse regression methods can be used for identification of systems of the Wiener class, that is, systems consisting of a number of parallel linear subsystems followed by a static multiple-input single-output nonlinearity. For a particular class of input signals, including Gaussian signals, the inverse regression approach makes it possible to estimate the linear subsystems without knowing or estimating the nonlinearity.Keywords: System identification; Dimension reduction; Inverse regression. Inverse Regression for the Wiener Class of SystemsChristian Lyzell, Martin Enqvist 2011-11-14 AbstractThe concept of inverse regression has turned out to be quite useful for dimension reduction in regression analysis problems. Using methods like sliced inverse regression (SIR) and directional regression (DR), some high-dimensional nonlinear regression problems can be turned into more tractable low-dimensional problems. Here, the usefulness of inverse regression for identification of nonlinear dynamical systems will be discussed. In particular, it will be shown that the inverse regression methods can be used for identification of systems of the Wiener class, that is, systems consisting of a number of parallel linear subsystems followed by a static multiple-input single-output nonlinearity. For a particular class of input signals, including Gaussian signals, the inverse regression approach makes it possible to estimate the linear subsystems without knowing or estimating the nonlinearity.

show abstract

“…If the nonlinearity in (1) is even about the origin, then the conditional expectation (4) will be zero and no information regarding the projection will be present in the data. To remedy this limitation, several methods involving second order moments have been proposed in the literature, see, for example, Cook and Weisberg [1991], Li and Wang [2007], Bura and Yang [2011]. The evaluation of some of the above methods on systems from the Wiener class can be found in Lyzell and Enqvist [2011].…”

Section: Inverse Regressionmentioning

confidence: 99%

“…In the one-dimensional case, it is well known that if ϕ(t) is elliptically distributed, the linear least-squares estimate of B is consistent [Bussgang, 1952]. In this paper, we are going to consider a related method called sliced inverse regression (SIR) [Li, 1991], which has had a considerable influence in the field of dimension reduction in the statistical community [see, for example, Bura and Cook, 2001, Li and Wang, 2007, Bura and Yang, 2011.…”

Section: Introductionmentioning

confidence: 99%

Sliced Inverse Regression for the Identification of Dynamical Systems

Lyzell

Enqvist

2012

IFAC Proceedings Volumes

View full text Add to dashboard Cite

The estimation of nonlinear functions can be challenging when the number of independent variables is high. This difficulty may, in certain cases, be reduced by first projecting the independent variables on a lower dimensional subspace before estimating the nonlinearity. In this paper, a statistical nonparametric dimension reduction method called sliced inverse regression is presented and a consistency analysis for dynamically dependent variables is given. The straightforward system identification application is the estimation of the number of linear subsystems in a Wiener class system and their corresponding impulse response.Keywords: System identification; Dimension reduction; Inverse regression. Sliced Inverse Regression for the Identification of Dynamical SystemsChristian Lyzell, Martin Enqvist 2011-11-14 AbstractThe estimation of nonlinear functions can be challenging when the number of independent variables is high. This difficulty may, in certain cases, be reduced by first projecting the independent variables on a lower dimensional subspace before estimating the nonlinearity. In this paper, a statistical nonparametric dimension reduction method called sliced inverse regression is presented and a consistency analysis for dynamically dependent variables is given. The straightforward system identification application is the estimation of the number of linear subsystems in a Wiener class system and their corresponding impulse response.

show abstract

Dimension estimation in sufficient dimension reduction: A unifying approach

Cited by 53 publications

References 32 publications

A Unified Framework for Dimension Reduction in Forecasting

A Unified Framework for Dimension Reduction in Forecasting

Inverse Regression for the Wiener Class of Systems

Sliced Inverse Regression for the Identification of Dynamical Systems

Contact Info

Product

Resources

About