Conditional quantile correlation learning for ultrahigh dimensional varying coefficient models and its application in survival analysis

Xia, Xiaochao; Li, Jialiang; Fu, Bo

doi:10.5705/ss.202016.0402

Cited by 6 publications

(7 citation statements)

References 34 publications

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“…Variable or feature selection in highdimensional linear quantile regression has been extensively studied in the literature and various shrinkage and screening techniques have been introduced to identify these significant covariates(e.g., Wang, Wu and Li, 2012;Fan, Fan and Barut, 2014;Zheng, Peng and He, 2015;Ma, Li and Tsai, 2017). For extensions to high-dimensional nonparametric quantile regression, we refer to Fernández-Val (2011), He, Wang andHong (2013) and Xia, Li and Fu (2018). In this section, we consider a general nonparametric quantile regression setting which contains high-dimensional mixed continuous and discrete covariates.…”

Section: Extension To High-dimensional Settingmentioning

confidence: 99%

“…The above theorem complements some existing sure screening properties in highdimensional quantile estimation (c.f., He, Wang and Hong, 2013;Ma, Li and Tsai, 2017;Xia, Li and Fu, 2018). An alternative kernel screening procedure is to conduct the leaveone-out kernel estimation for each marginal quantile regression and then use the datadriven CV method to determine the optimal smoothing parameter.…”

Section: Letmentioning

confidence: 99%

“…Furthermore, we generalize the model setting and methodology to the case when the dimension of covariates is large (growing with the sample size n) and introduce a two-step procedure: (i) use a kernel-based quantile screening technique to remove the irrelevant continuous and discrete covariates, and (ii) apply the CV criterion to those that survive in the first step of screening and further select the significant covariates and determine the optimal smoothing parameters. Note that the existing literature on variable or feature selection in highdimensional quantile regression only considers the case of purely continuous covariates (e.g., He, Wang and Hong, 2013;Ma, Li and Tsai, 2017;Xia, Li and Fu, 2018). The present paper considers a more general setting which contains both the discrete and continuous covariates.…”

Section: Introductionmentioning

confidence: 99%

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Nonparametric estimation of conditional quantile functions in the presence of irrelevant covariates

Chen

et al. 2019

Journal of Econometrics

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Allowing for the existence of irrelevant covariates, we study the problem of estimating a conditional quantile function nonparametrically with mixed discrete and continuous data. We estimate the conditional quantile regression function using the check-function-based kernel method and suggest a data-driven cross-validation (CV) approach to simultaneously determine the optimal smoothing parameters and remove the irrelevant covariates. When the number of covariates is large, we first use a screening method to remove the irrelevant covariates and then apply the CV criterion to those that survive the screening procedure. Simulations and an empirical application demonstrate the usefulness of the proposed methods.

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Section: Extension To High-dimensional Settingmentioning

confidence: 99%

Section: Letmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Nonparametric estimation of conditional quantile functions in the presence of irrelevant covariates

Chen

et al. 2019

Journal of Econometrics

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“…Assuming that error term follows the normal distribution, the Wald P value for testing null hypothesis β j =0 can be obtained by survreg function in R. After sorting 20 000 P values in an ascending order, the top markers in the ranked list reflect the strongest covariate effects on the mean survival time. Following the recommendation by Fan and Lv and other references, we keep the top

⌊ \frac{n}{normall normalo normalg false(n false)} ⌋

variables in the ranked list and screen out the rest of the covariates. Thus, the first 66 variables in the ranked list are selected to conduct downstream analysis.…”

Section: Simulationmentioning

confidence: 99%

Sparse boosting for high‐dimensional survival data with varying coefficients

2017

Statistics in Medicine

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Motivated by high-throughput profiling studies in biomedical research, variable selection methods have been a focus for biostatisticians. In this paper, we consider semiparametric varying-coefficient accelerated failure time models for right censored survival data with high-dimensional covariates. Instead of adopting the traditional regularization approaches, we offer a novel sparse boosting (SparseL Boosting) algorithm to conduct model-based prediction and variable selection. One main advantage of this new method is that we do not need to perform the time-consuming selection of tuning parameters. Extensive simulations are conducted to examine the performance of our sparse boosting feature selection techniques. We further illustrate our methods using a lung cancer data analysis.

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“…To the best of our knowledge, there are very few works applying this classical dependence concept in high-dimensional setting. Xia et al (2018) proposed a robust conditional feature screening approach, however, their method performs only robustly against the response but not against the covariates. Another relevant recent work is Ma et al (2017).…”

Section: Introductionmentioning

confidence: 99%

Copula-based Partial Correlation Screening: a Joint and Robust Approach

Xia¹,

Li²

2021

STAT SINICA

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Screening for ultrahigh dimensional features may encounter complicated issues such as outlying observations, heterogeneous or heavy-tailed distribution, multi-collinearity and confounding effects. Standard correlation-based marginal screening methods may be a weak solution to these issues. We contribute a novel robust joint screener to safeguard against outliers and distribution mis-specification for both the response variable and the covariates, and to account for external variables at the screening step. Specifically, we introduce a copula-based partial correlation (CPC) screener. We show that the empirical process of the estimated CPC converges weakly to a Gaussian process and establish the sure screening property for CPC screener under very mild technical conditions, where we need not require any moment condition, weaker than existing alternatives in the literature. Moreover, our approach allows for a diverging number of conditional variables from the theoretical point of view. Extensive simulation studies 1 and two data applications are included to illustrate our proposal.

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Conditional quantile correlation learning for ultrahigh dimensional varying coefficient models and its application in survival analysis

Cited by 6 publications

References 34 publications

Nonparametric estimation of conditional quantile functions in the presence of irrelevant covariates

Nonparametric estimation of conditional quantile functions in the presence of irrelevant covariates

Sparse boosting for high‐dimensional survival data with varying coefficients

Copula-based Partial Correlation Screening: a Joint and Robust Approach

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