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1. Introduction

The partially linear single-index model is as follows:$$\begin{array}{}\text{(1)}& Y=g{Z}^T\beta +X^T\mathbf{\theta }+\epsilon ,\end{array}$$where $Y$ is a response variable, $Z,X\in {ℝ}^p\times {ℝ}^q$ is the covariate, $g\cdot$ is an unknown univariate measurable function, $\epsilon$ is a random error, and $\beta ,\theta$ is an unknown vector in ${ℝ}^p\times {ℝ}^q$ with $\beta =1$ (where $\cdot$ denotes the Euclidean norm). The restriction $\beta =1$ assures identifiability.

Model (1) is flexible enough to include many important statistical models, so it has attracted much attention and has been extensively studied in recent years. Relevant studies about Model (1) have been done by [1–5]; all of which are based on the independent error sequence. In practice, all the parts of the random error sequence are often associated with each other, such as negatively associated errors, m-dependent errors, and ARCH errors, so that the abovementioned findings cannot be used directly. Therefore, it is necessary to study Model (1) with associated errors.

The finite random variable sequence ${\xi }_i,1\le i\le n$ is negatively associated (NA); if, on the condition of any two arbitrary disjoint subsets $A$, $B\subset \mathrm{1,2},\dots ,n$ and any real-valued coordinate-wise nondecreasing functions $f_1$ and $f_2$, it is established that there is$$\begin{array}{}\text{(2)}& \text{Cov}{f}_1{\xi }_i,i\in A,f_2{\xi }_j,j\in B\le 0.\end{array}$$

As for infinite random variable sequence, if any arbitrary finite subset is negatively associated, the infinite sequence is negatively associated.

NA sequence has been introduced and studied by the authors of [6, 7] since the 1980s. Because the NA sequence includes the independent sequence, it has been widely applied in multivariate statistical analysis, the permeability analysis, and reliability theory drew much attention, and a lot of research results have been obtained. Under the fields of NA random variables, the author of [8] presented the asymptotic normality and central limit theorem; the authors of [9] proved the law of the iterated logarithm; the authors of [10] studied the exponential inequality, and so on.

However, there is little research about the partially linear single-index model under NA error. This paper, with the enlightenment of [11, 12], focuses on estimating $\beta$, $\theta$ with blockwise empirical likelihood when the errors are subjected to NA in Model (1). Throughout this paper, we assume that the data $X_i,Z_i,Y_i,i=\mathrm{1,2},\dots ,n$ are generated from Model (1), and ${\epsilon }_i,i=1,\dots ,n$ are NA errors with $E{\epsilon }_i|Z_i,X_i=0$ and $\text{Var}{\epsilon }_i|Z_i,X_i={\sigma }_i^2<\infty$ in Model (1).

The rest of this paper is organized as follows. In Section 2, the blockwise empirical likelihood method and the relative asymptotic result are presented. In Section 3, some simulations are conducted to illustrate the proposed approach. All proofs are shown in Section 4.

2. Methodology and Main Results

2.1. Bias-Corrected Blockwise Empirical Likelihood

In this part, we will use the bias-corrected blockwise empirical likelihood to construct the confidence region for $\beta ,\theta$. For this reason, first we introduce an auxiliary vector using the bias-corrected method of [2]. The details are as follows. Now that $\beta =1$ means that the value $\beta$ is a boundary point on the unit sphere and $g{Z}^{\text{T}}\beta$ does not have a derivative at the point $\beta$ of the parameter space. Nevertheless, the derivative of $g{Z}^{\text{T}}\beta$ on $\beta$ in the building of the empirical likelihood ratio statistics must be used. Thereby, we adopt the “delete-one-component” method which is widely used in the semiparameter model. Let $\beta ={{\beta }_1,{\beta }_2,\dots ,{\beta }_p}^{\text{T}}$ and ${\beta }^r={{\beta }_1,\dots ,{\beta }_{r-1},{\beta }_{r+1},\dots ,{\beta }_p}^{\text{T}}$ be a $p-1$-dimensional parameter vector after deleting the rth component of $\beta$. Without losing its generality, we assume ${\beta }_r>0$. Then, we can write$$\begin{array}{}\text{(3)}& \beta ={{\beta }_1,\dots ,{\beta }_{r-1},{1-{{\beta }^r}^2}^{1/2},{\beta }_{r+1},\dots ,{\beta }_p}^T.\end{array}$$

Since $\beta$ can be determined by ${\beta }^r$, only the confidence regions of ${\beta }^r,\theta$ need to be taken into consideration. Moreover, ${\beta }^r<1$, which means that $\beta$ is infinitely differentiable in a neighborhood of the parameter ${\beta }^r$. Thus, the Jacobian matrix is$$\begin{array}{}\text{(4)}& J_{{\mathbf{\beta }}^r}={{\gamma }_1,\dots ,{\gamma }_p}^{\text{T}},\end{array}$$where ${\gamma }_{s}1\le s\le p,s\ne r$ is a $p-1$-dimensional vector with $s$th component 1 and ${\gamma }_r=-{1-{{\beta }^r}^2}^{-1/2}{\beta }^r$.

Suppose ${\mu }_{1}t=EZ|Z^{\text{T}}\beta =t$ and ${\mu }_{2}t=EX|Z^{\text{T}}\beta =t$ and the auxiliary vector is defined as$$\begin{array}{c}\text{(5)}& {\eta }_i{\mathbf{\beta }}^r,\mathbf{\theta }=Y_i-g{Z}_i^{\text{T}}\mathbf{\beta }-X_i^{\text{T}}\mathbf{\theta }\times {g\prime Z_i^{\text{T}}\mathbf{\beta }{Z_i-{\mu }_1{Z}_i^{\text{T}}\mathbf{\beta }}^{\text{T}}{J}_{{\mathbf{\beta }}^r},{X_i-{\mu }_2{Z}_i^{\text{T}}\mathbf{\beta }}^{\text{T}}}^{\text{T}},\end{array}$$where $g\prime \cdot$ is the derivative of $g\cdot$ with respect to ${\beta }^r$. Note that $E{\eta }_i{\beta }^r,\theta =0$ on the condition that ${\beta }^r,\theta$ is the true parameter. Therefore, the empirical likelihood by [13] is used to construct the bias-corrected empirical log-likelihood, which is defined as$$\begin{array}{}\text{(6)}& l_n{\mathbf{\beta }}^r,\mathbf{\theta }=-2\max {\displaystyle \sum _{i=1}^n\log n{p}_i}:p_i\ge 0,{\displaystyle \sum _{i=1}^n{p}_i}=1,{\displaystyle \sum _{i=1}^n{p}_i{\eta }_i{\mathbf{\beta }}^r,\theta }=0.\end{array}$$

Since $g\cdot$, $g\prime \cdot$, ${\mu }_1\cdot$, and ${\mu }_2\cdot$ are unknown, formula (5) cannot be used to construct the confidence regions directly. To replace them with their estimators is what the researchers usually do. Next, we apply the local linear smooth method of [14] to obtain the estimators of $g\cdot$ and $g\prime \cdot$. For any fixed $\beta ,\theta$, we focus on finding a and b to minimize$$\begin{array}{}\text{(7)}& {\displaystyle \sum _{i=1}^n{Y_i-X_i^T\mathbf{\theta }-a-b{Z}_i^T\mathbf{\beta }-t}^2{K}_h{Z}_i^T\mathbf{\beta }-t},\end{array}$$where $K_h\cdot =K\cdot /h/h$, $K\cdot$ is a kernel function and $h=hn$ is a bandwidth. Let $\widehat{a},\widehat{b}$ be the solution to minimize (7). Through a simple calculation,$$\begin{array}{}\text{(8)}& \widehat{g}t;\mathbf{\beta },\mathbf{\theta }=\widehat{a}={\displaystyle \sum _{i=1}^n{W}_{ni}t;\mathbf{\beta }{Y}_i-X_i^T\mathbf{\theta }},\text{(9)}& \widehat{g}\prime t;\mathbf{\beta },\mathbf{\theta }=\widehat{b}={\displaystyle \sum _{i=1}^n{\tilde{W}}_{ni}t;\mathbf{\beta }{Y}_i-X_i^T\mathbf{\theta }},\end{array}$$where$$\begin{array}{c}\text{(10)}& W_{ni}t;\mathbf{\beta }=\frac{n^{-1}{K}_h{Z}_i^T\mathbf{\beta }-t{S}_{n,2}t;\mathbf{\beta }-Z_i^{\text{T}}\mathbf{\beta }-t{S}_{n,1}t;\mathbf{\beta }}{S_{n,0}t;\mathbf{\beta }{S}_{n,2}t;\mathbf{\beta }-S_{n,1}^{2}t;\mathbf{\beta }},{\tilde{W}}_{ni}t;\mathbf{\beta }=\frac{n^{-1}{K}_h{Z}_i^{\text{T}}\mathbf{\beta }-t{Z}_i^{\text{T}}\mathbf{\beta }-t{S}_{n,0}t;\mathbf{\beta }-S_{n,1}t;\mathbf{\beta }}{S_{n,0}t;\mathbf{\beta }{S}_{n,2}t;\mathbf{\beta }-S_{n,1}^{2}t;\mathbf{\beta }},\hspace{1em}i=\mathrm{1,2},\dots ,n,\\ S_{n,l}t;\mathbf{\beta }=\frac{1}{n}{\displaystyle \sum _{i=1}^n{K}_h{Z}_i^{\text{T}}\mathbf{\beta }-t{Z_i^{\text{T}}\mathbf{\beta }-t}^l},\hspace{1em}l=\mathrm{0,1,2.}\end{array}$$

Then, we define$$\begin{array}{}\text{(11)}& {\widehat{\mu }}_{1}t;\mathbf{\beta }={\displaystyle \sum _{i=1}^n{W}_{ni}t;\mathbf{\beta }{Z}_i},\end{array}$$and$$\begin{array}{}\text{(12)}& {\widehat{\mu }}_{2}t;\mathbf{\beta }={\displaystyle \sum _{i=1}^n{W}_{ni}t;\mathbf{\beta }{X}_i},\end{array}$$as the estimators of ${\mu }_{1}t$ and ${\mu }_{2}t$, respectively.

When (8), (9), (11), and (12) are plugged in (5) and (6), an estimated auxiliary vector and an estimated bias-corrected empirical log-likelihood ratio can be, respectively, defined as follows:$$\begin{array}{c}\text{(13)}& {\widehat{\eta }}_i{\mathbf{\beta }}^r,\mathbf{\theta }=Y_i-\widehat{g}{Z}_i^T\mathbf{\beta };\mathbf{\beta },\mathbf{\theta }-X_i^T\mathbf{\theta }\times \widehat{g}\prime Z_i^T\mathbf{\beta };\mathbf{\beta },\mathbf{\theta }{Z_i-{\widehat{\mu }}_1{Z}_i^T\mathbf{\beta };\mathbf{\beta }}^T{J}_{{\mathbf{\beta }}^r},{{X_i-{\widehat{\mu }}_2{Z}_i^T\mathbf{\beta };\mathbf{\beta }}^T}^T,\\ {\widehat{l}}_n{\mathbf{\beta }}^r,\mathbf{\theta }=-2\max {\displaystyle \sum _{i=1}^n\log n{p}_i}:p_i\ge 0,{\displaystyle \sum _{i=1}^n{p}_i}=1,{\displaystyle \sum _{i=1}^n{p}_i{\widehat{\eta }}_i{\mathbf{\beta }}^r,\mathbf{\theta }}=0.\end{array}$$

Under the independent identically distributed errors, the empirical likelihood ratio statistic is constructed by [2]; and its asymptotic result is presented. In this paper, ${\widehat{\eta }}_i{\beta }^r,\theta ,i=1,\dots ,n$ may be dependent when the error satisfies NA, so the method of [2] cannot be applied directly. For this, we apply the small-block and large-block arguments to construct the blockwise empirical likelihood ratio. Let $k=k_n=n/d+s$, where $a$ denotes the integral part of $a$, and $d=dn$ and $s=sn$ are positive integers satisfying $d+s\le n$. For $m=1,\dots ,k$, let$$\begin{array}{c}\text{(14)}& {\omega }_{n,2m-1}{\mathbf{\beta }}^r,\mathbf{\theta }=e_{nm},{\omega }_{n,2m}{\mathbf{\beta }}^r,\mathbf{\theta }=e_{nm}^{\prime },\\ {\omega }_{n,2k+1}{\mathbf{\beta }}^r,\mathbf{\theta }=e_{n,k+1}^{\prime },\end{array}$$where$$\begin{array}{c}\text{(15)}& e_{nm}={\displaystyle \sum _{i=r_m}^{r_m+d-1}{\widehat{\eta }}_i{\mathbf{\beta }}^r,\mathbf{\theta }},e_{nm}^{\prime }={\displaystyle \sum _{i=l_m}^{l_m+s-1}{\widehat{\eta }}_i{\mathbf{\beta }}^r,\mathbf{\theta }},\\ e_{n,k+1}^{\prime }={\displaystyle \sum _{i=kd+s+1}^n{\widehat{\eta }}_i{\mathbf{\beta }}^r,\mathbf{\theta }},\\ r_m=m-1d+s+1,\\ l_m=m-1d+s+d+1.\end{array}$$

By using the Lagrange multiplier method, the bias-corrected blockwise empirical likelihood ratio statistic is$$\begin{array}{}\text{(16)}& {\tilde{l}}_n{\mathbf{\beta }}^r,\mathbf{\theta }=2{\displaystyle \sum _{j=1}^{2k+1}\log 1+{\lambda }^T{\mathbf{\beta }}^r,\mathbf{\theta }{\omega }_{nj}{\mathbf{\beta }}^r,\mathbf{\theta }},\end{array}$$where $\lambda \in {ℝ}^{p+q-1}$ is determined by$$\begin{array}{}\text{(17)}& \frac{1}{2k+1}{\displaystyle \sum _{j=1}^{2k+1}\frac{{\omega }_{nj}{\mathbf{\beta }}^r,\mathbf{\theta }}{1+{\lambda }^{\text{T}}{\omega }_{nj}{\mathbf{\beta }}^r,\mathbf{\theta }}}=0.\end{array}$$

2.2. Asymptotic Result

In this subsection, the main result of this paper is summarized. In order to state the asymptotic result, the following assumptions will be used:

(i) ${\mathbf{C}}_1$: the density function $ft$ of $Z^{\text{T}}\beta$ is bounded away from 0 on $\tau$ and satisfies the Lipschitz condition of order 1 on $\tau$, where $\tau =t=Z^{\text{T}}\beta :Z\in A$ and $A$ is a compact support set of $Z$

Based on Theorem 1, ${\tilde{l}}_n{\beta }^r,\theta$ can be used to construct confidence regions for ${\beta }^r,\theta$. For any given $0<\alpha <1$, there exists $c_{\alpha }$ which makes $P{\chi }_{p+q-1}^2>c_{\alpha }=\alpha$ tenable, and then$$\begin{array}{}\text{(20)}& I_{\alpha }{\mathbf{\beta }}^r,\mathbf{\theta }={\mathbf{\beta }}^r,\mathbf{\theta }|{\tilde{l}}_n{\mathbf{\beta }}^r,\mathbf{\theta }<c_{\alpha },{\mathbf{\beta }}^r<1,\end{array}$$which is the confidence regions of ${\beta }^r,\theta$ with the asymptotically correct coverage probability $1-\alpha$.

3. Simulation

In this section, we use two examples to conduct some simulation studies to compare the performance of the proposed empirical likelihood method (ELM) and the normal approximation method (NAM).

We assume $e_i\sim N0.001\ast i,1,i=1,\dots ,n$, and ${\epsilon }_i=e_{i+1}-e_i$. Then, we can get ${\epsilon }_i\sim N0.001,2$ for $1\le i\le n$ and $\text{Cov}{\epsilon }_i,{\epsilon }_{j}i\ne j=-1$ for $i-j=1$, otherwise $\text{Cov}{\epsilon }_i,{\epsilon }_{j}i\ne j=0$. Thus, ${\epsilon }_i,1\le i\le n$ is a NA sequence, and its mean is approximately zero. According to ${\mathbf{C}}_5$, the rate of $h$ is between $n^{-1/4}$ and $n^{-1/7}$. Therefore, the bandwidth is selected as $\widehat{h}=h_{opt}$ by using the cross-validation (CV) method. The details of the CV method have been discussed in the references [15] of the study by H$\ddot{a}$rdle et al. [15], This selected bandwidth $\widehat{h}$ satisfies the condition ${\mathbf{C}}_5$. Let $d=n^{1/4}$ and $s=n^{1/8}$, which satisfy the condition ${\mathbf{C}}_9$.

Table 1

Simulation results of Example 1. The coverage probabilities of the confidence regions for ${\beta }_1,\theta$ when the nominal level is 0.95, respectively.

Table 2

Simulation results of Example 2. The average lengths (AI) and empirical coverage probabilities (CP) of the confidence intervals for ${\beta }_1$, ${\beta }_2$, ${\beta }_3$, ${\theta }_1$, and ${\theta }_2$ with sample size n = 200 when the nominal level is 0.90.

4. Proofs

In order to prove Theorem 1, we first give some lemmas. Throughout this section, for a concise and convenient representation, we use $c0<c<\infty$ to denote any constant which may take a different values for each appearance, use ${\lambda }_{\min }A$ and ${\lambda }_{\max }A$ to denote the smallest and largest eigenvalues of A, respectively, and write $A^{\otimes 2}=A\cdot A^{\text{T}}$.

The proof of Lemma 1. Firstly, we assume $b_i\ge 0,i=\mathrm{1,2},\dots ,n$. Via Abel inequality, it follows that$$\begin{array}{}\text{(23)}& {\displaystyle \sum _{i=1}^n{a}_i{b}_i}\le 2{\max }_{1\le i\le n}{b}_i\cdot {\max }_{1\le k\le n}{\displaystyle \sum _{i=1}^k{a}_{j_i}}.\end{array}$$

Secondly, we assume $b_i<0,i=\mathrm{1,2},\dots ,n$, and it also follows that$$\begin{array}{}\text{(24)}& {\displaystyle \sum _{i=1}^n{a}_i{b}_i}={\displaystyle \sum _{i=1}^n-a_i\cdot -b_i}\le 2{\max }_{1\le i\le n}{b}_i\cdot {\max }_{1\le k\le n}{\displaystyle \sum _{i=1}^k{a}_{j_i}}.\end{array}$$

Combining (23) and (24), then we get$$\begin{array}{}\text{(25)}& {\displaystyle \sum _{i=1}^n{a}_i{b}_i}\le {\displaystyle \sum _{i:b_i\ge 0}{a}_i}{b}_i+{\displaystyle \sum _{i:b_i<0}-a_i}-b_i\le c\cdot {\max }_{1\le i\le n}{b}_i\cdot {\max }_{1\le k\le n}{\displaystyle \sum _{i=1}^k{a}_{j_i}}.\end{array}$$

Refer to the proof of Lemma 1 of [11].

The proof of Lemma 3 can be finished with the work by [16].

The proof of Lemma 4 is similar to the proof of Lemma 3 by [12]. So, the details are omitted here.

The proof of Lemma 5. It is easy to show that$$\begin{array}{}\text{(31)}& \frac{1}{\sqrt{n}}{\displaystyle \sum _{i=1}^n{\widehat{\eta }}_i{\mathbf{\beta }}^r,\mathbf{\theta }}=\frac{1}{\sqrt{n}}{\displaystyle \sum _{i=1}^n{\tilde{\Lambda }}_i{\epsilon }_i}+{\displaystyle \sum _{v=1}^4{M}_v},\end{array}$$where$$\begin{array}{c}\text{(32)}& M_1={M_{11}^{\text{T}}{J}_{{\mathbf{\beta }}^r},M_{12}^{\text{T}}}^{\text{T}},M_2={M_{21}^{\text{T}}{J}_{{\mathbf{\beta }}^r},O_{1\times q}}^{\text{T}},\\ M_3={M_{31}^{\text{T}}{J}_{{\mathbf{\beta }}^r},M_{32}^T}^{\text{T}},\\ M_4={M_{41}^{\text{T}}{J}_{{\mathbf{\beta }}^r},O_{1\times q}}^{\text{T}},\\ M_{11}=\frac{1}{\sqrt{n}}{\displaystyle \sum _{i=1}^n{\mu }_1{Z}_i^{\text{T}}\mathbf{\beta }-{\widehat{\mu }}_1{Z}_i^{\text{T}}\mathbf{\beta };\mathbf{\beta }g\prime Z_i^{\text{T}}\mathbf{\beta }{\epsilon }_i},\\ M_{12}=\frac{1}{\sqrt{n}}{\displaystyle \sum _{i=1}^n{\mu }_2{Z}_i^{\text{T}}\mathbf{\beta }-{\widehat{\mu }}_2{Z}_i^{\text{T}}\mathbf{\beta };\mathbf{\beta }{\epsilon }_i},\\ M_{21}=\frac{1}{\sqrt{n}}{\displaystyle \sum _{i=1}^n\widehat{g}\prime Z_i^{\text{T}}\mathbf{\beta };\mathbf{\beta },\mathbf{\theta }-g\prime Z_i^{\text{T}}\mathbf{\beta }\cdot Z_i-{\widehat{\mu }}_1{Z}_i^{\text{T}}\mathbf{\beta };\mathbf{\beta }{\epsilon }_i},\\ M_{31}=\frac{1}{\sqrt{n}}{\displaystyle \sum _{i=1}^{n}g{Z}_i^{\text{T}}\mathbf{\beta }-\widehat{g}{Z}_i^{\text{T}}\mathbf{\beta };\mathbf{\beta },\mathbf{\theta }\cdot Z_i-{\widehat{\mu }}_1{Z}_i^{\text{T}}\mathbf{\beta };\mathbf{\beta }g\prime Z_i^{\text{T}}\mathbf{\beta }},\\ M_{32}=\frac{1}{\sqrt{n}}{\displaystyle \sum _{i=1}^{n}g{Z}_i^{\text{T}}\mathbf{\beta }-\widehat{g}{Z}_i^{\text{T}}\mathbf{\beta };\mathbf{\beta },\mathbf{\theta }\cdot X_i-{\widehat{\mu }}_2{Z}_i^{\text{T}}\mathbf{\beta };\mathbf{\beta }},\\ M_{41}=\frac{1}{\sqrt{n}}{\displaystyle \sum _{i=1}^{n}g{Z}_i^{\text{T}}\mathbf{\beta }-\widehat{g}{Z}_i^{\text{T}}\mathbf{\beta };\mathbf{\beta },\mathbf{\theta }\cdot \widehat{g}\prime Z_i^{\text{T}}\mathbf{\beta };\mathbf{\beta },\mathbf{\theta }-g\prime Z_i^{\text{T}}\mathbf{\beta }\cdot Z_i-{\widehat{\mu }}_1{Z}_i^{\text{T}}\mathbf{\beta };\mathbf{\beta }.}\end{array}$$

In order to prove (29), we firstly need to show that$$\begin{array}{}\text{(33)}& \frac{1}{\sqrt{n}}{\displaystyle \sum _{i=1}^n{\tilde{\Lambda }}_i{\epsilon }_i}\stackrel{L}{⟶}N0,\Gamma .\end{array}$$

Let ${\mathrm{\Delta }}_n=1/n{\displaystyle {\sum }_{i=1}^n{\tilde{\mathrm{\Lambda }}}_i{\epsilon }_i^2{\tilde{\mathrm{\Lambda }}}_i^{\text{T}}}$. For the central limit theorem of ${n{\mathrm{\Delta }}_n}^{-1/2}{\displaystyle {\sum }_{i=1}^n{\tilde{\mathrm{\Lambda }}}_i{\epsilon }_i}$, we refer to Lemma 5 of [11]; then, we can obtain (33).

Secondly, we need to show that $M_{u1}\stackrel{P}{⟶}0u=\mathrm{1,2,3,4}$ and $M_{m2}\stackrel{P}{⟶}0m=\mathrm{1,3}$. Here, we consider $M_{12}$. Let $M_{12,s}$ denote the sth component of $M_{12}$. By ${\mathbf{C}}_2$ and ${\mathbf{C}}_4$ and Lemma 1 and Lemma 4, we can get$$\begin{array}{c}\text{(34)}& E{M}_{12,s}^2\le c\cdot {\sup }_{z}E{\epsilon }_i^2|Z_i=z{\displaystyle \sum _{i=1}^{n}E{{\mu }_{2s}{Z}_i^{\text{T}}\mathbf{\beta }-{\widehat{\mu }}_{2s}{Z}_i^{\text{T}}\mathbf{\beta };\mathbf{\beta }}^2}\le c{h}^4+c{nh}^{-1}⟶0.\end{array}$$

The other formulas mentioned above can be proved by using Lemma 1, Lemma 3, and Lemma 4 and the similar methods of [2]. These formulas, together with (31) and (33), complete the proof of (29).

The proof of (30) uses a similar method to the proof of Lemma 5 by [12]. Here, we only give some key steps. For any $c\in {ℝ}^{p+q-1}$ with $c=1$, we will show that$$\begin{array}{}\text{(35)}& \frac{1}{n}{c}^{\text{T}}{\Gamma }^{-1/2}{\displaystyle \sum _{i=1}^{2k+1}{\omega }_{ni}{\omega }_{ni}^{\text{T}}{\Gamma }^{-1/2}c}=1+o_{p}1.\end{array}$$

Then, we need to show that$$\begin{array}{}\text{(36)}& \frac{1}{n}{c}^{\text{T}}{T}_{n1}c=1+o_{p}1,\text{(37)}& \frac{1}{n}{c}^{\text{T}}{T}_{n2}c=o_{p}1,\text{(38)}& \frac{1}{n}{c}^{\text{T}}{T}_{n3}c=o_{p}1,\end{array}$$where $T_{n1}={\mathrm{\Gamma }}^{-1/2}{\displaystyle {\sum }_{i=1}^k{e}_{ni}{e}_{ni}^{\text{T}}{\mathrm{\Gamma }}^{-1/2}},T_{n2}={\mathrm{\Gamma }}^{-1/2}{\displaystyle {\sum }_{i=1}^k{e}_{ni}^{\prime }{e}_{ni}^{\prime \text{T}}{\mathrm{\Gamma }}^{-1/2}},\text{\hspace{0.17em}and\hspace{0.17em}}{T}_{n3}={\mathrm{\Gamma }}^{-1/2}{e}_{n,k+1}^{\prime }{e}_{n,k+1}^{\prime T},{\mathrm{\Gamma }}^{-1/2}$.

Similar to (31), we have$$\begin{array}{}\text{(39)}& \frac{1}{n}{c}^{\text{T}}{T}_{n1}c=\frac{1}{n}{\displaystyle \sum _{i=1}^k{c^{\text{T}}{\Gamma }^{-1/2}{\displaystyle \sum _{j=r_i}^{r_i+d-1}{\tilde{\Lambda }}_j{\epsilon }_j+c^{\text{T}}{\Gamma }^{-1/2}}{\displaystyle \sum _{j=r_i}^{r_i+d-1}{R}_{nj}}}^2}≕\frac{1}{n}{\displaystyle \sum _{i=1}^k{v_{i1}+v_{i2}}^2},\end{array}$$where$$\begin{array}{c}\text{(40)}& R_{nj}={{\epsilon }_{j}g\prime Z_j^{\text{T}}\mathbf{\beta }{\tilde{\mu }}_{1j}^T{J}_{{\mathbf{\beta }}^r},{\epsilon }_j{\tilde{\mu }}_{2j}^{\text{T}}}^{\text{T}}-{{\epsilon }_j{\tilde{g}}_j^{\prime }{\tilde{Z}}_j^{\text{T}}{J}_{{\mathbf{\beta }}^r},0}^{\text{T}}+{{\tilde{g}}_{j}g\prime Z_j^{\text{T}}\mathbf{\beta }{\tilde{Z}}_j^{\text{T}}{J}_{{\mathbf{\beta }}^r},{\tilde{g}}_j{\tilde{X}}_j^{\text{T}}}^{\text{T}}-{{\tilde{g}}_j{\tilde{g}}_j^{\prime }{\tilde{Z}}_j^{\text{T}}{J}_{{\mathbf{\beta }}^r},0}^{\text{T}},\\ {\tilde{\mu }}_{1j}={\mu }_1{Z}_j^{\text{T}}\mathbf{\beta }-{\widehat{\mu }}_1{Z}_j^{\text{T}}\mathbf{\beta };\mathbf{\beta },\\ {\tilde{\mu }}_{2j}={\mu }_2{Z}_j^{\text{T}}\mathbf{\beta }-{\widehat{\mu }}_2{Z}_j^{\text{T}}\mathbf{\beta };\mathbf{\beta },\\ {\tilde{Z}}_j=Z_j-{\widehat{\mu }}_1{Z}_j^{\text{T}}\mathbf{\beta };\mathbf{\beta },\\ {\tilde{X}}_j=X_j-{\widehat{\mu }}_2{Z}_j^{\text{T}}\mathbf{\beta };\mathbf{\beta },\\ {\tilde{g}}_j=g{Z}_j^{\text{T}}\mathbf{\beta }-\widehat{g}{Z}_j^{\text{T}}\mathbf{\beta };\mathbf{\beta },\mathbf{\theta },\\ {\tilde{g}}_j^{\prime }=g\prime Z_j^{\text{T}}\mathbf{\beta }-{\widehat{g}}^{\prime }{Z}_j^{\text{T}}\mathbf{\beta };\mathbf{\beta },\mathbf{\theta }.\end{array}$$

As arguments in [11], we can get (36). Similar decomposition and proof can be used in (37) and (38). Thus, (30) is completely proved.

The proof of Lemma 6. Now that$$\begin{array}{}\text{(42)}& {\max }_{1\le i\le 2k+1}{\omega }_{ni}\le c\cdot {\max }_{1\le i\le n}{\widehat{\eta }}_i{\mathbf{\beta }}^r,\theta ,\end{array}$$we only need to prove$$\begin{array}{}\text{(43)}& {\max }_{1\le i\le n}{\widehat{\eta }}_i{\mathbf{\beta }}^r,\mathbf{\theta }=o_p{n}^{1/2}.\end{array}$$

Let ${\widehat{\eta }}_{i,s}$ denote the sth component of ${\widehat{\eta }}_i$, and the notation of Lemma 5 is used.

We consider the later $q$ components of ${\widehat{\eta }}_i{\beta }^r,\theta$. By a simple calculation, we can obtain$$\begin{array}{c}\text{(44)}& {\max }_{1\le i\le n}{\widehat{\eta }}_{i,s}{\mathbf{\beta }}^r,\mathbf{\theta }\le c\cdot {\max }_{1\le i\le n}{\tilde{\Lambda }}_{i,s}{\epsilon }_i+c\cdot {\max }_{1\le i\le n}{\tilde{\mu }}_{2i,s}{\epsilon }_i+c\cdot {\max }_{1\le i\le n}{\tilde{g}}_i{\tilde{X}}_{i,s}≕A_{n1,s}+A_{n2,s}+A_{n3,s},p\le s\le p+q-1.\end{array}$$

Applying Lemma 2 with $E{\epsilon }_i^2<\infty$,$$\begin{array}{}\text{(45)}& {\max }_{1\le i\le n}{\epsilon }_i=O_p{n}^{1/2}.\end{array}$$

This implies that $A_{n1,s}=o_p{n}^{1/2}$ since $E{{\tilde{\mathrm{\Lambda }}}_{i,s}{\epsilon }_i}^2<\infty$. Combining the Markov inequality, Lemma 4 and ${\mathbf{C}}_4$, for any $\delta >0$,$$\begin{array}{c}\text{(46)}& P{A}_{n2,s}>\delta \sqrt{n}\le {\displaystyle \sum _{i=1}^{n}P{\mu }_{2s}{Z}_i^{\text{T}}\mathbf{\beta }-{\widehat{\mu }}_{2s}{Z}_i^{\text{T}}\mathbf{\beta };\mathbf{\beta }{\epsilon }_i>\delta \sqrt{n}},\le \frac{1}{n{\delta }^2}{\text{sup}}_{z}E{\epsilon }_i^2|Z_i=z{\displaystyle \sum _{i=1}^{n}E{{\mu }_{2s}{Z}_i^{\text{T}}\mathbf{\beta }-{\widehat{\mu }}_{2s}{Z}_i^{\text{T}}\mathbf{\beta };\mathbf{\beta }}^2},\\ \le c{h}^4+c{nh}^{-1}⟶0.\end{array}$$

Hence, $A_{n2,s}=o_p{n}^{1/2}$. $A_{n3,s}$ can be dealt similarly. Then,$$\begin{array}{}\text{(47)}& {\max }_{1\le i\le n}{\widehat{\eta }}_{i,s}{\mathbf{\beta }}^r,\mathbf{\theta }=o_p{n}^{1/2},\hspace{1em}\text{for\hspace{0.17em}}p\le s\le p+q-1.\end{array}$$

Moreover,$$\begin{array}{}\text{(48)}& {\max }_{1\le i\le n}{\widehat{\eta }}_{i,s}{\mathbf{\beta }}^r,\mathbf{\theta }=o_p{n}^{1/2},\hspace{1em}\text{for\hspace{0.17em}}1\le s\le p-1,\end{array}$$can be similarly dealt with. Thus, (43) can be shown.