2.1. Role of Country of Origin in Immigration Preference

Immigration is one of the most contentious issues in the United States today. In an influential study, Hainmueller and Hopkins (Reference Hainmueller and Hopkins2015) use a conjoint analysis to empirically examine the immigrant characteristics favored or disfavored by U.S. citizens. The study used the forced-choice design, in which each respondent was presented with a pair of hypothetical immigrant profiles and asked which immigrant they would “personally prefer to see admitted to the United States.” Each of 1,396 respondents rated five pairs of profiles.

An immigrant profile consists of nine factors—prior trips to the United States, reason for application, country of origin, language skills, profession, job experience, employment plans, education level, and gender, each of which has multiple levels (see Table 5 in Appendix H of the Supplementary Material as well as the original article for details). Most factors are independently and uniformly randomized across their levels with the exception of two restrictions to avoid implausible pairs. First, immigrant profiles that list escape persecution as the “reason of immigration” can only have Iraq, Sudan, or Somalia as their “country of origin.” Second, a high-skill “profession” such as financial analyst, research scientist, doctor, and computer programmer is possible only if the “education level” is at least 2 years of college. This restricted randomization scheme induces dependencies between these factors. The survey also contains information about respondents’ age, education, ethnicity, gender, and ethnocentrism. The study contains a random sample of 14,018 profiles.

In this study, Hainmueller and Hopkins estimate the AMCE, which represents the marginal effect of a factor of interest averaging over the other factors. Based on the statistically insignificant estimates for the AMCEs of the “country of origin” factor for Mexico and European countries (reproduced in Figure 1),Footnote ¹ they conclude that “despite media frames focusing on low-skilled, unauthorized immigration from Mexico, there is little evidence of penalty specific to Mexicans” (539). The authors obtain these estimates by fitting a linear regression model, where the outcome variable indicates whether the profile is selected and the predictors are the nine randomized factors. To account for the restricted randomization, they also include two sets of interaction terms, one between “country of origin” and “reason of immigration” and the other between “profession” and “education level.” To obtain the estimated AMCE of Germany, for example, Hainmueller and Hopkins take the main effect of Germany (the baseline is India) and then add it to the average of all the interaction terms between Germany and the “reason of immigration” factor. Clustered standard errors are computed by clustering on each respondent to account for dependency within a respondent.

Figure 1 The estimated average marginal component effects (AMCEs) of immigrants’ countries of origin in the Hainmueller and Hopkins (Reference Hainmueller and Hopkins2015) study. The plot shows the estimated AMCEs for France, Germany, Mexico, and Poland, which represent the average differences in the estimated probability of choosing an immigrant profile with a specific level of the “country of origin” factor, marginalizing other attributes. The baseline factor level is India, and the 95% confidence intervals are also shown.

Despite this overall finding, the AMCE-based approach may mask relevant interactions and heterogeneous treatment effects. Indeed, Hainmueller and Hopkins conduct a subgroup analysis and find that the “country of origin” factor has statistically significant interactions with the respondents’ ethnocentrism. They measure ethnocentrism using the feeling thermometer score (ranging from $0$ to $100$ ) for the respondent’s own groups minus the average feeling thermometer across the other groups. In addition, Newman and Malhotra (Reference Newman and Malhotra2019) reanalyze the same dataset and estimate three-way interactions among respondents’ ethnocentrism, “country of origin,” and “profession.” The authors compute the AMCEs of high-skilled immigrants (baseline of janitor) separately for each country of origin and respondent’s ethnocentric group. They find that these AMCEs are different between Mexican and European immigrants when compared among highly ethnocentric respondents (see Figure 1 in Newman and Malhotra Reference Newman and Malhotra2019 for further details).

In this paper, we apply the proposed hypothesis testing approach to testing whether or not immigrants from Mexico and those from Europe are viewed differently in any way while controlling for all the other experimental factors as well as the respondent characteristics. The rejection of this null hypothesis would mean that the country of origin of an individual plays a statistically significant role in some U.S. citizens’ preferences about that individual’s immigration to the United States.

2.2. Limitations of Existing Approaches

Although the AMCE is a useful causal quantity of interest and can be easily and reliably estimated, it is not free of limitations. The AMCE is a marginal effect based on two types of averaging: (1) averaging over the distribution of other attributes and (2) averaging over the responses (and hence respondents). Recall that in the standard causal inference setting with a binary treatment, a zero average treatment effect does not necessarily imply zero treatment effect for everyone. The treatment may benefit some and harm others, and these positive and negative effects can cancel out through averaging. The AMCE suffers from a similar problem, potentially masking important causal heterogeneity if there are interactions among attributes and/or between attributes and respondent characteristics.

Additionally, although an AMCE-based confidence interval that does not contain zero represents evidence that the factor matters, a narrow AMCE-based confidence interval that contains zero only implies that a factor has a weak marginal effect. Nevertheless, practitioners tend to use narrow AMCE-based confidence intervals that contain zero to conclude that a factor does not matter. For example, Hainmueller et al. (Reference Hainmueller, Hopkins and Yamamoto2014) conclude that the “candidates’ income does not matter much” and that the “candidates’ racial and ethnic backgrounds are even less influential,” based on the AMCE-based confidence interval for income and ethnicity (19). Ono and Burden (Reference Ono and Burden2018) also claim that “the bias against female candidates [...] is limited to presidential rather than congressional elections” (585) after obtaining a statistically insignificant AMCE estimate for gender among congressional candidates. Lastly, Spilker, Bernauer, and Umaña (Reference Spilker, Bernauer and Umaña2016) interpret statistically insignificant country effects to conclude that “in spite of different national contexts, individuals in [Costa Rica, Nicargua, and Vietnam] hold similar preferences regarding potential [Preferential Trade Agreement] partners” (712). In all cases, the lack of a significant AMCE estimate is not sufficient to conclude that the factor of interest does not matter. Instead, it only implies that the factor may have little impact “on average.” Furthermore, although the AMCE can be generalized to account for interactions, it requires researchers to choose a specific interaction term out of many possible interactions and may lead to the problems similar to those of subgroup analysis, including multiple testing.

Although the AMCE is popular, there also exist model-based approaches to flexibly estimate potentially any quantity of interest. In particular, logistic regression remains a popular model-based alternative in conjoint analysis (Campbell et al. Reference Campbell, Mhlanga and Lesschaeve2013; Green and Srinivasan Reference Green and Srinivasan1990; McFadden Reference McFadden and Zarembka1973) especially in marketing research. Although a hierarchical modeling approach remains another popular model-based alternative in conjoint studies, we do not consider it here because it is based on a Bayesian framework rather than frequentist approach taken in this paper (Andrews, Ansari, and Currim Reference Andrews, Ansari and Currim2002). Model misspecification, however, remains a significant challenge. Although researchers may add more interactions to account for all possible effects, such an approach can reduce statistical power and more importantly lead to invalid p-values (Candès and Sur Reference Candès and Sur2018). We show in Figure 9 in Appendix J of the Supplementary Material that using logistic regression and accounting for all two-way interactions to reduce model misspecification can easily lead to invalid p-values.

Consequently, a consensus among researchers has emerged that flexible ML algorithms are necessary for capturing these causal interactions (Abramson et al. Reference Abramson, Kocak, Magazinnik and Strezhnev2020; Bansak et al. Reference Bansak, Hainmueller, Hopkins and Yamamoto2020; de la Cuesta et al. Reference de la Cuesta, Egami and Imai2022; Goplerud et al. Reference Goplerud, Imai and Pashley2022). Yet ML algorithms, despite their flexibility, cannot yield consistent estimates in high-dimensional settings without strong assumptions. In addition, statistical inference in small samples remains a challenge (Chernozhukov et al. Reference Chernozhukov, Demirer, Duflo and Fern’andez-Val2017; Dezeure et al. Reference Dezeure, Bühlmann, Meier and Meinshausen2015; Imai and Li Reference Imai and Li2021). Our goal is to address these problems through an assumption-free approach based on the CRT.

3.1. Notation and Setup

For concreteness, we focus on the forced-choice conjoint design, under which a respondent is asked to choose one of two profiles. Our methodology is general and can be extended to other designs. Let n be the total number of respondents. As is often done in practice, suppose that each respondent evaluates J pairs of profiles, yielding a total of $nJ$ responses (for notational simplicity, we assume the same number of evaluations for each respondent).

We use $Y_{ij} \in \{0, 1\}$ to represent the binary outcome variable for evaluation j by respondent i, which equals 1 for selecting the left profile and 0 for choosing the right profile. Although for convenience we use “left” and “right” to distinguish two profiles under each evaluation, the profiles do not necessarily have to be placed side by side on the actual survey platform. We use the following $nJ \times 1$ stacked vector representation for this outcome variable $\mathbf {Y} = [\mathbf {Y}_1; \mathbf {Y}_2; \ldots; \mathbf {Y}_n]$ , where $\mathbf {Y}_i = [Y_{i1}; Y_{i2}; \ldots; Y_{iJ}]$ of dimension $J \times 1$ denotes the outcome variable for respondent i. We use $[a_1; a_2; \dots; a_n]$ to denote a vertical stacking of vectors or matrices $a_1, a_2, \dots , a_n$ . We often observe some characteristics of the respondents, and we use $\mathbf {V}_i$ to denote a $J \times r$ -dimensional matrix of r pre-treatment covariates for respondent i that are repeated across J rows.

Next, let p represent the total number of attributes or factorsFootnote ² used for each conjoint profile. We use a scalar $X_{ij \ell }^{L} \in \{1, 2, \dots , K_{\ell }\}$ to denote the value of the $\ell $ th factor of interest for evaluation j by respondent i, where the superscript distinguishes the factors for the left (L) and right (R) profiles, and $K_{\ell } \ge 2$ is the total number of factor levels for factor $\ell $ . We use $\mathbf {X}_{ij}^{L} = [X_{ij1}^L; \dots; X_{ijq}^L]$ to denote a q-dimensional column vector, containing all q factors of interest for the left profile for respondent i in the jth evaluation where $q \le p$ . We define $\mathbf {X}_{ij}^R$ similarly for the right profile. In addition, we use $\mathbf {X}_{ij} =[\mathbf {X}_{ij}^{L}; \mathbf {X}_{ij}^{R}]$ as a column vector of length $2q$ to represent the main factors of interest from two profiles together. Lastly, the remaining $(p-q)$ factors are denoted by $\mathbf {Z}_{ij} = [\mathbf {Z}_{ij}^{L}; \mathbf {Z}_{ij}^{R}]$ , where each term is similarly defined. For example, in the immigration conjoint experiment, if the main factor of interest is “country of origin,” the other factors include “education” and “profession.”

As done for the outcome variable, we stack all evaluation-specific factors to define respondent-level factor matrices, which are further combined to yield the factor matrix $\mathbf {X}=[\mathbf {X}_{1}; \mathbf {X}_{2}; \ldots ;\mathbf {X}_{n}]$ and $\mathbf {Z}=[\mathbf {Z}_{1}; \mathbf {Z}_{2}; \ldots; \mathbf {Z}_{n}]$ of dimension $nJ \times 2q$ and $nJ \times 2(p-q)$ , respectively, where $\mathbf {X}_i =[\mathbf {X}_{i1}^\top; \mathbf {X}_{i2}^\top; \ldots; \mathbf {X}_{iJ}^\top ]$ and $\mathbf {Z}_i=[\mathbf {Z}_{i1}^\top; \mathbf {Z}_{i2}^\top; \ldots; \mathbf {Z}_{iJ}^\top ]$ are matrices of dimension $J \times 2q$ and $J \times 2(p-q)$ , respectively. Lastly, we also stack all respondent characteristics $\mathbf {V} = [\mathbf {V}_1; \mathbf {V}_2; \dots; \mathbf {V}_n]$ of dimension $nJ \times r$ .

Finally, we use $\mathbf {Y}(\mathbf {x}, \mathbf {z})$ to denote the $nJ$ -dimensional vector of the potential outcomes when $\mathbf {X} = \mathbf {x}$ and $\mathbf {Z} = \mathbf {z}$ . We avoid the assumption of no interference effect since our vector of potential outcomes is a function of the entire set of treatments $\mathbf {X}$ and $\mathbf {Z}$ (Rubin Reference Rubin1990). We assume a super-population framework, where the potential outcomes $\mathbf {Y}(\mathbf {x}, \mathbf {z})$ are assumed to be drawn from a population of infinite size. In Appendix B of the Supplementary Material, we discuss how our framework is related to a finite-population framework, which is the basis of Fisher’s randomization test. In conjoint analysis, the profile attributes are randomized according to a known distribution, $P(\mathbf {X}, \mathbf {Z})$ , and we allow for any randomization distribution. In general, the randomization of the factors implies the following independence relation:

(1) $$ \begin{align} \mathbf{Y}(\mathbf{x}, \mathbf{z}) \perp \!\!\! \perp (\mathbf{X}, \mathbf{Z}) \hspace{0.1cm} \text{ for all } \mathbf{x} \in \mathcal{X},\ \mathrm{and}\ \mathbf{z} \in \mathcal{Z}, \end{align} $$

where we use $\mathcal {X}$ and $\mathcal {Z}$ to represent the support of $\mathbf {X}$ and that of $\mathbf {Z}$ , respectively, and $\mathbf {x}$ and $\mathbf {z}$ to denote the value of $\mathbf {X}$ and that of $ \mathbf {Z}$ , respectively (see Chapter 3.6 of Imbens and Rubin Reference Imbens and Rubin2015).

3.2. The Conditional Randomization Test

The CRT is an assumption-free approach that can combine design-based inference with flexible ML algorithms. For ease of presentation, we first introduce the CRT without incorporating the respondent characteristics $\mathbf {V}$ and then return in Section 3.6 to show how $\mathbf {V}$ can be incorporated in all the proposed methods. The CRT allows us to examine whether the factors of interest $\mathbf {X}$ change the response $\mathbf {Y}$ while holding the other factors $\mathbf {Z}$ constant. Specifically, we test the following null hypothesis:

(2) $$ \begin{align} H_{0}: \mathbf{Y}(\mathbf{x},\mathbf{z}) \overset{d}{=} \mathbf{Y}(\mathbf{x}', \mathbf{z}) \hspace{0.1cm} \text{ for all } \mathbf{x}, \mathbf{x}' \in \mathcal{X},\ \mathrm{and}\ \mathbf{z} \in \mathcal{Z}, \end{align} $$

where we use $\overset {d}{=}$ to denote distributional equality. As a reminder, $H_0$ states that our entire vector of potential outcomes are equal in distribution for any values of $\mathbf {X}$ . Our alternative hypothesis states that $\mathbf {X}$ affects $\mathbf {Y}$ in some way while keeping $\mathbf {Z}$ unchanged. This is formalized as

(3) $$ \begin{align} \quad H_{1}: \mathbf{Y}(\mathbf{x},\mathbf{z}) \overset{d}{\neq} \mathbf{Y}(\mathbf{x}',\mathbf{z}) \hspace{0.1cm} \text{ for some } \mathbf{x}, \mathbf{x}' \in \mathcal{X},\ \mathrm{and}\ \mathbf{z} \in \mathcal{Z}. \end{align} $$

We emphasize that the null hypothesis defined in Equation (2) implies the absence of any causal effects involving the main factor(s) of interest. For example, the null hypothesis is false if $\mathbf {X}$ affects $\mathbf {Y}$ for any individual respondent or subgroup of respondents. Similarly, the null hypothesis does not hold if $\mathbf {X}$ influences $\mathbf {Y}$ only when $\mathbf {Z}$ takes a certain set of values. Thus, the null hypothesis precludes any heterogeneous or interaction effects between the selected factors of interest X and other factors Z included in the experiment.

Contrast this hypothesis test formulation with that of the standard AMCE-based analysis, which asks whether each factor of interest $\mathbf {X}_{i}$ matters on average. More specifically, Hainmueller, Hopkins, and Yamamoto assume that each individual’s potential outcome is only a function of its own profile task, that is, $Y_{ij}(\mathbf {X},\mathbf {Z}) = Y_{ij}(\mathbf {X}_{ij}, \mathbf {Z}_{ij})$ , and computes the marginal importance of $\mathbf {X}_i$ by averaging each individual potential outcome over $\mathbf {Z}_i$ as well as the respondents, which are assumed to be exchangeable, leading to the following null hypothesis:

(4) $$ \begin{align} H_0^{\text{AMCE}}: \mathbb{E}\{Y_{ij}(\mathbf{x}, \mathbf{Z}_{ij})\} \ = \ \mathbb{E}\{Y_{ij}(\tilde{\mathbf{x}}, \mathbf{Z}_{ij})\}, \end{align} $$

where $\mathbf {x}$ and $\tilde {\mathbf {x}}$ are the specified values of the main factors and the expectation is taken over $\mathbf {Z}_{ij}$ (other factors) and the respondents. As briefly explained in Section 2.2, the limitation of the AMCE-based approach is that averaging over other factors can mask important causal interaction and heterogeneity.

We now establish the equivalence between the null hypothesis about the potential outcomes defined in Equation (2) and the conditional independence relation among observed variables. This result allows us to use the CRT, which is a general assumption-free methodology for testing conditional independence relations in designed experiments (Candès et al. Reference Candès, Fan, Janson and Lv2018). We state this result as the following theorem whose proof is given in Appendix A of the Supplementary Material.

Theorem 3.1 Equivalence

The null hypothesis defined in Equation (2) is equivalent to the following conditional independence hypothesis under the randomization assumption of Equation (1):

$$ \begin{align*}H_0^{\text{CRT}}: \mathbf{Y} \perp \!\!\! \perp \mathbf{X} \mid \mathbf{Z}.\end{align*} $$

The CRT produces exact p-values without asymptotic approximation while enabling the use of any test statistic, including ones based on complex ML algorithms, without making any modeling assumptions. In the conjoint analysis literature, researchers have used traditional regression modeling (e.g., Barone, Lombardo, and Tarantino Reference Barone, Lombardo and Tarantino2007; Hauber et al. Reference Hauber2016; McFadden Reference McFadden and Zarembka1973) and more recently modern ML algorithms (e.g., Abramson et al. Reference Abramson, Kocak, Magazinnik and Strezhnev2020; Egami and Imai Reference Egami and Imai2019). However, the validity of these analyses critically depends on modeling assumptions, parameter tuning, and/or asymptotic approximation. In contrast, the CRT assumes nothing about the conditional distribution of the outcome $\mathbf {Y}$ given $(\mathbf {X},\mathbf {Z})$ . Indeed, it does not even require the data to be independently or identically distributed, a property which we use later to test carryover and profile order effects. The only requirement is the specification of the conditional distribution of $\mathbf {X}$ given $\mathbf {Z}$ , which is readily available from the experimental design of conjoint analysis. Although the power of the CRT critically depends on the test statistic, the CRT always controls type 1 error no matter what the true model is. This contrasts with other model-based approaches that require modeling assumptions to be valid (see Appendix J of the Supplementary Material for more details).

Algorithm 1 summarizes the general procedure used to compute the exact p-value for the CRT. Note that if $\mathbf {X}$ and $\mathbf {Z}$ are independently randomized, as is often the case, one can simply sample $\mathbf {X}^{(b)}$ from the marginal distribution of $\mathbf {X}$ . If, on the other hand, certain combinations of $\mathbf {X}$ and $\mathbf {Z}$ values (e.g., doctor without a college degree in the immigration conjoint experiment) are excluded, then we must use the appropriate conditional distribution of $\mathbf {X}$ given $\mathbf {Z}$ . Critically, Algorithm 1 is valid for complicated experimental designs, so long as one can sample from the conditional distribution $\mathbf {X}$ given $\mathbf {Z}$ .

The CRT can be computationally intensive since it requires computing the test statistic T a total of $B+1$ times. However, these computations can easily be parallelized. Furthermore, recent works (Liu et al. Reference Liu, Katsevich, Janson and Ramdas2020; Tansey et al. Reference Tansey, Veitch, Zhang, Rabadan and Blei2018) have shown that certain test statistic constructions also alleviate the need for these computations. In Appendix I of the Supplementary Material, we detail several tricks that can be used to dramatically reduce the computation time when implementing the CRT. For the main application results presented in Section 4 (first column of Table 1), we note that the parallelized computational time was approximately 6 minutes with 50 cores to calculate each p-value with $B = 2,000$ . Our software package makes it easy for practitioners to use multiple cores and provides a step-by-step instruction for using many cores on Amazon Web Services.Footnote ⁴

Table 1 The p-values based on the conditional randomization test (CRT) and the average marginal component effect (AMCE) estimation. The first p-values are from the HierNet-based CRT and AMCE-based test statistics, testing whether the immigrant’s “country of origin” (Mexico or Europe) matters for immigration preferences. The other three p-values are from the HierNet-based CRT test statistics, testing the regularity conditions commonly used for conjoint analysis.

The p-value of the CRT is validFootnote ⁵ regardless of sample size and test statistic (Candès et al. Reference Candès, Fan, Janson and Lv2018). This is especially attractive because the number of second-order interactions are comparable or even larger than the sample size in typical conjoint studies. To see the validity of the p-values, it suffices to recognize that under the null hypothesis, all $B+1$ test statistics, $T(\mathbf {X}, \mathbf {Y}, \mathbf {Z})$ , $T(\mathbf {X}^{(1)}, \mathbf {Y}, \mathbf {Z})$ , $\dots $ , $T(\mathbf {X}^{(B)}, \mathbf {Y}, \mathbf {Z})$ , are exchangeable given $(\mathbf {Y}, \mathbf {Z})$ . While any test statistic produces a valid p-value under the CRT, the choice of test statistic determines the statistical power. We now turn to this practically important consideration.

3.3. Test Statistics

Although $H_0$ is logically false, if there is any difference in the potential outcome distribution, the potential outcome distribution for binary random variables is completely characterized by its conditional mean and marginal mean. Therefore, in this setting, both the CRT and AMCE test hypotheses related to the marginal or conditional means. To obtain a powerful test statistic that does not mask important interactions, we consider a test statistic based on the Lasso logistic regression with hierarchical interactions, or HierNet (Bien, Taylor, and Tibshirani Reference Bien, Taylor and Tibshirani2013). Specifically, HierNet constrains the two-way interaction effects to be smaller in magnitude than their corresponding main effects. For example, this implies that a two-way interaction effect will be set to zero if its relevant main effects are all zero. Although this constraint may not actually hold in practice, a stricter regularization on the interactions is desirable. This is because the space of possible two-way interactions is large and grows quadratically, and many of them are expected to be indistinguishable from zero. Thus, we view the hierarchical sparsity constraint as an important tool that may lead to greater power when interactions are weak or do not exist. Although the practical implementation of the HierNet leverages the sparsity constraint, we emphasize that the validity of the CRT does not depend on the appropriateness of this constraint. When fitting HierNet, we use the dummy variable encoding (i.e., each factor level is represented by its own dummy variable) but do not omit the baseline level. We can fit this overparameterized model because of the regularization of HierNet. The primary advantage of this approach is that the results are no longer dependent on the choice of baseline levels (Egami and Imai Reference Egami and Imai2019). Finally, we use the publicly available HierNet package in R, where the response is the $nJ$ -dimensional $\mathbf {Y}$ and the design matrix is the $nJ \times 2p$ dimensional features $(\mathbf {X}, \mathbf {Z})$ for both the left and right profiles.

We begin by considering the simplest case where we have a single main factor of interest $\mathbf {X}$ ( $q = 1$ ). Without loss of generality, we assume that this is the first factor among the total of p factors. There are two types of interaction effects to consider (de la Cuesta et al. Reference de la Cuesta, Egami and Imai2022). First, a within-profile interaction effect represents the interaction between one level of the main factor and another level of a different factor within the same profile. Second, a between-profile interaction effect represents the factor interaction between two profiles (left vs. right) that are being compared under the forced choice design.

(5) $$ \begin{align} T_{\text{HierNet}} & = \underbrace{\sum_{k=1}^{K_1} (\hat\beta_{k} - \bar\beta)^2}_{\text{main effects}} + \underbrace{\sum_{\ell = 2}^{p} \sum_{k=1}^{K_1} \sum_{k^\prime = 1}^{K_{\ell}} (\hat\gamma_{1 \ell kk^\prime} - \bar\gamma_{1 \ell k^\prime})^{2}}_{\text{within-profile interaction effects}} + \underbrace{\sum_{\ell = 1}^{p} \sum_{k=1}^{K_1} \sum_{k^\prime = 1}^{K_{\ell}} (\hat\delta_{1 \ell kk^\prime} - \bar\delta_{1 \ell k^\prime})^{2}}_{\text{between-profile interaction effects}}, \end{align} $$

where $\hat \beta _{k}$ is the estimated main effect coefficient for the kth level of our factor of interest $\mathbf {X}$ with $\bar {\beta }$ denoting the average of these estimated main effect coefficients, and $\hat \gamma _{1 \ell kk^\prime }$ and $\hat \delta _{1 \ell kk^\prime }$ represent the estimated within-profile and between-profile interaction effect coefficients between the kth level of the factor of interest $\mathbf {X}$ and the $k^\prime $ th level of the $\ell $ th factor, respectively. Similar to the main effects, $\bar {\gamma }_{1 \ell k^\prime }$ and $\bar {\delta }_{1 \ell k^\prime }$ denote the averages of their corresponding estimated interaction effect coefficients. We do not consider third- or higher-order interactions because of the typical sample size in a conjoint experiment and a lack of powerful methods to detect such interactions. However, in Appendix G of the Supplementary Material, we illustrate how to incorporate third-order interactions when prior substantive knowledge is available.

This test statistic can be easily generalized to the setting where there is more than one factor of interest ( $q> 1$ ). In such a case, we simply compute Equation (5) for each factor of interest, and then sum the resulting values to arrive at the final test statistic. $T_{\text {HierNet}}$ aims to capture any differential effects the levels of $\mathbf {X}$ have on the response through their main effects and relevant interaction effects.

For example, suppose that $\mathbf {X}$ is “country of origin” in the immigration conjoint experiment (Section 2.1). Under $H_0$ , we would expect all main effects and any interaction effects of Mexico and Germany to be roughly equivalent, thus making $T_{\text {HierNet}}$ close to zero. However, suppose that immigrants from Germany with a certain “education level” were favored more than those from Mexico with a certain “education level.” Then, we would expect these interactions to differ, making $T_{\text {HierNet}}$ further from zero.

We use cross-validationFootnote ⁶ to choose the value of HierNet’s tuning parameter, which controls the degree of regularization. In addition, when the sample size and the number of factors are large, fitting HierNet can be computationally demanding. To alleviate this issue, we propose computational speedups of the HierNet test statistics, which are detailed in Appendix I of the Supplementary Material. In particular, we drop $\mathbf {X}$ when fitting the HierNet tuning parameter via cross-validation. Since this computationally expensive step does not depend on $\mathbf {X}$ , we do not need to re-run it for each $\mathbf {X}^b$ .

So far, we have constructed our test statistic as if there is no profile order effect. This implies that the effects of each factor do not depend on whether it belongs to the left or right profile. Formally, we have imposed the following symmetry constraints in our HierNet test statistic:

(6) $$ \begin{align} \hat\beta_{k} \ & = \ \hat\beta_{k}^{L} \ = \ - \hat\beta_{k}^{R}, \quad \hat\gamma_{1\ell kk^\prime} \ = \ \hat\gamma_{\ell \ell^\prime kk^\prime}^{L} \ = \ -\hat\gamma_{\ell \ell^\prime kk^\prime}^{R}, \quad \hat\delta_{\ell \ell^\prime kk^\prime} \ = \ -\hat\delta_{\ell^\prime \ell k^\prime k}, \end{align} $$

where the superscripts L and R denote the left and right profile effects, respectively. $\hat \delta _{\ell \ell ^\prime k k^\prime }$ denotes the between profile interaction between the kth level of factor $\ell $ in the left profile with the $k^\prime $ th level of factor $\ell ^\prime $ in the right profile.Footnote ⁷ The signs of the estimated coefficients reflect the fact that the response variable $\mathbf {Y}$ is recorded as 1 if the left profile is chosen and as 0 if the right profile is selected. These constraints reduce the dimension of parameters to be estimated by half.

Importantly, the validity of the proposed tests does not depend on whether the assumption of no profile order effect holds. Through simulations, Figure 6 in Appendix E of the Supplementary Material shows that these constraints can significantly increase statistical power when there is no profile order effect. Appendix D.2 of the Supplementary Material also presents simulations that show a substantial power gain from using the HierNet-based CRT test statistic compared to using the AMCE-based test statistic. To incorporate this symmetry constraint, we append another copy of the dataset below the original dataset, where the appended copy is identical to the original dataset except that the order of left and right profiles is flipped and the response variable is transformed as $\mathbf {1} - \mathbf {Y}$ before fitting HierNet (see Appendix E of the Supplementary Material for details). In Section 3.5, we show how to use the CRT for testing the validity of the assumption of no profile order effect.

Because the validity of the CRT does not depend on modeling assumptions, one can incorporate a variety of assumptions into test statistics. In general, test statistics have a greater statistical power if the assumptions hold in the true (unknown) data generating process. Therefore, as much as possible the choice of test statistic should reflect researchers’ substantive knowledge. Appendix G of the Supplementary Material presents an empirical example of leveraging substantive knowledge in the test statistic.

3.4. Generalization of the Null Hypothesis and Test Statistic

Researchers are often interested in testing only a few levels of interest as opposed to testing the whole factor. Yet, simply dropping the observations that correspond to those irrelevant factor levels can lead to a loss of statistical power. An advantage of the formulation described below is that we can retain all observations including those whose factor levels are irrelevant, which can improve statistical power.

For example, suppose we are interested in how respondents differentiate immigrants from Mexico and Germany. If the way in which respondents differentiate between immigrants from Mexico and those from China is different from how they distinguish between immigrants from Germany and those from China, then this implies that the respondents are viewing immigrants from Mexico differently than those from Germany. Therefore, detecting any differences for even the irrelevant levels may help improve the statistical power.

Here, we generalize the null hypothesis and test statistic, given in Equations (2) and (5), so that the methodology can accommodate any combinations of factor levels. We introduce a coarsening function h that groups factor levels of interest while assigning other factor levels to themselves. Formally, this coarsening function is defined as $h: \mathcal {X} \mapsto \widetilde {\mathcal {X}}$ , where $|\mathcal {X}| \ge |\widetilde {\mathcal {X}}|$ . Thus, for our aforementioned immigration example, h will assign the same value to immigrants from Mexico and Germany while leaving all other combinations mapped to different values.

Under this setup, we can test the null hypothesis that specific levels within $\mathbf {X}$ do not affect the potential outcome in any way. Formally,

(7) $$ \begin{align} H_0^{\text{General}}: \mathbf{Y}(\mathbf{x},\mathbf{z}) \overset{d}{=} \mathbf{Y}(\mathbf{x}',\mathbf{z}) \hspace{0.1cm} \text{for all} \ \mathbf{x}, \mathbf{x}' \in \mathcal{X}, \ \text{such that } h(\mathbf{x}) = h(\mathbf{x}')\ \text{and}\ \mathbf{z} \in \mathcal{Z}. \end{align} $$

The condition $h(\mathbf {x}) = h(\mathbf {x}')$ enables the comparison of the factor levels of interest alone. Additionally, $H_0$ is a special case of $H_0^{\text {General}}$ when the coarsening function h is the identity function. Finally, applying the same argument as the one used to prove Theorem 3.1, it can be shown that $H_0^{\text {General}}$ is equivalent to the following conditional independence relation:

(8) $$ \begin{align} \mathbf{Y} \perp \!\!\! \perp \mathbf{X} \mid h(\mathbf{X}), \mathbf{Z}. \end{align} $$

To test this null hypothesis, we first fit the same HierNet with the main and two-way interaction effects. To incorporate the coarsening function h, our test statistic takes the same form as the one given in Equation (5) but is based only on the estimated coefficients that correspond to the factor levels of the group induced by the h function, that is, Mexico and Germany in the above example. Appendix F.1 of the Supplementary Material contains further details of testing the general null hypothesis and the corresponding CRT algorithm. In Section 4, we also provide an example of applying $H_0^{\text {General}}$ that contains more details on this test statistic.

Finally, Appendix C of the Supplementary Material details how to further generalize $H_0^{\text {General}}$ when a researcher is interested in grouping factor levels, that is, combining levels France, Germany, and Poland into one level Europe when testing $H_0^{\text {General}}$ . Although coarsening via h also involved “grouping” levels, the grouping described in Appendix C of the Supplementary Material aggregates factor levels to allow comparison between higher-level categories, while the coarsening function h allows us to focus our hypothesis test only on differences between a subset of factor levels of interest.

3.5. Testing the Regularity Assumptions of Conjoint Analysis

To further demonstrate the flexibility of the CRT, we also show how to use the CRT for testing the validity of several commonly made assumptions of conjoint analysis. Since we are interested in not rejecting the null hypothesis for the hypotheses presented in this section, we propose test statistics that are designed to be reasonably powerful for general settings in conjoint analysis.

3.5.1. Profile Order Effect

The assumption of no profile order effect states that changing the order of profiles, that is, left versus right, does not affect the actual profile chosen (since the value of $\mathbf {Y}$ corresponds to whether the left or right profile is chosen, $\mathbf {Y}$ should be recoded as $\mathbf {1}-\mathbf {Y}$ when the profile order is changed). We denote the potential outcome $Y_{ij}(\mathbf {x}_{ij}^L, \mathbf {x}_{ij}^R, \mathbf {z}_{ij}^L, \mathbf {z}_{ij}^R)$ , which is now a function of left and right profiles. Although not necessary, we assume here no interference between responses for notational clarity (see Appendix F.2 of the Supplementary Material for the general case). Lastly, we use $\mathcal {X}_{\text {ind}}$ and $\mathcal {Z}_{\text {ind}}$ to denote the support of $[\mathbf {x}_{ij}^L; \mathbf {x}_{ij}^R]$ and that of $[\mathbf {z}_{ij}^L; \mathbf {z}_{ij}^R]$ , respectively, representing the support of factors used in each individual’s evaluation (hence “ $\text {ind}$ ” in the subscript).

We formally state the assumption of no profile order effect as the following null hypothesis that reordering of the left and right profiles has no effect on the adjusted response:

$$ \begin{align*} H_0^{\text{Order}}: Y_{ij}(\mathbf{x}_{ij}^L, \mathbf{x}_{ij}^R, \mathbf{z}_{ij}^L, \mathbf{z}_{ij}^R) \stackrel{d}{=} 1 - Y_{ij}(\mathbf{x}_{ij}^R, \mathbf{x}_{ij}^L, \mathbf{z}_{ij}^R, \mathbf{z}_{ij}^L), \hspace{0.1cm} \text{for all} \ i, j, [\mathbf{x}_{ij}^L; \mathbf{x}_{ij}^R] \in \mathcal{X}_{\text{ind}}, \ [\mathbf{z}_{ij}^L; \mathbf{z}_{ij}^R] \in \mathcal{Z}_{\text{ind}}. \end{align*} $$

We modify the HierNet test statistic in Equation (5) with the same HierNet fit on $(\mathbf {X},\mathbf {Y},\mathbf {Z})$ but without enforcing the constraints in Equation (6) as

$$ \begin{align*} T_{\text{HierNet}}^{\text{Order}}(\mathbf{X},\mathbf{Y},\mathbf{Z}) & = \sum_{\ell=1}^p \sum_{k=1}^{K_\ell} \left(\hat\beta_{\ell k}^{L}+\hat\beta_{\ell k}^{R}\right)^{2} + \sum_{\ell=1}^p \sum_{\substack{\ell^\prime=1 \\ \ell^\prime \ne \ell}}^p \sum_{k=1}^{K_\ell} \sum_{k^\prime = 1}^{K_{\ell^\prime} } \left(\hat\gamma_{\ell\ell^\prime kk^\prime}^{L} + \hat\gamma_{\ell\ell^\prime kk^\prime}^{R} \right)^2 \nonumber\\ & \quad + \sum_{\ell=1}^p \sum_{\substack{\ell^\prime=1\\ }}^p \sum_{k=1}^{K_\ell} \sum_{k^\prime = 1}^{K_{\ell^\prime} }\left(\hat\delta_{\ell\ell^\prime kk^\prime}+ \hat\delta_{\ell^\prime \ell k^\prime k} \right)^2. \end{align*} $$

Since the symmetry constraints given in Equation (6) must hold under $H_0^{\text {Order}}$ , a large value of this test statistic indicates a potential violation of the null hypothesis. To conduct the CRT for testing $H_0^{\text {Order}}$ , we resample and recompute our test statistics. Appendix F.2 of the Supplementary Material provides details about the testing procedure.

3.5.2. Carryover Effect

Researchers also often rely on the assumption of no carryover effect (Hainmueller et al. Reference Hainmueller, Hopkins and Yamamoto2014). The assumption states that the order of the J evaluations each respondent performs has no effect on the outcomes. This assumption is violated, for example, if respondents use information from their previous evaluations when assessing a given pair of profiles. To test this carryover effect, we assume no interference across respondents but consider potential interference across evaluations within each respondent.

Let $\mathbf {x}_{i,1:(j-1)}$ represent all the profile attributes that were presented to respondent i from the first evaluation to the $(j-1)$ th evaluation. Then, the potential outcome can be written as a function of both current and previous profiles, that is, $Y_{ij}\left (\mathbf {x}_{i,1:(j-1)}, \mathbf {z}_{i,1:(j-1)}, \mathbf {x}_{ij}, \mathbf {z}_{ij}\right )$ for $j \geq 2$ , where we assume no interference between respondents but allow interference within a respondent. Our null hypothesis is that, for a given evaluation $j \geq 2$ , the response $Y_{ij}$ is independent of all the previous profiles conditional on the current profiles:

$$ \begin{align*} H_0^{\text{Carryover}}: Y_{ij}\left(\mathbf{x}_{i,1:(j-1)}, \mathbf{z}_{i,1:(j-1)}, \mathbf{x}_{ij}, \mathbf{z}_{ij}\right) \stackrel{d}{=} Y_{ij}\left(\mathbf{x}_{i,1:(j-1)}', \mathbf{z}_{i,1:(j-1)}', \mathbf{x}_{ij}, \mathbf{z}_{ij}\right), \end{align*} $$

where for all $\ i\geq 1,\ j \geq 2,\ \mathbf {x}_{i,1:(j-1)}, \mathbf {x}_{i,1:(j-1)}' \in \mathcal {X}_{\text {ind}}^{j-1}, \ \mathbf {z}_{i,1:(j-1)}, \mathbf {z}_{i,1:(j-1)}' \in \mathcal {Z}_{\text {ind}}^{j-1}, \ \mathbf {x}_{ij} \in \mathcal {X}_{\text {ind}}, \ \mathbf {z}_{ij} \in \mathcal {Z}_{\text {ind}}$ with $\mathcal {X}_{\text {ind}}^{j-1}$ and $\mathcal {Z}_{\text {ind}}^{j-1}$ denoting the support of $\mathbf {x}_{i,1:(j-1)}$ and that of $\mathbf {z}_{i,1:(j-1)}$ , respectively.

We test this null hypothesis by using a test statistic that targets whether the immediately preceding evaluation affects the current evaluation. We believe targeting the lag-1 effect in the test statistic is reasonable because if a carryover effect exists, respondents are likely to be affected most by the immediately preceding evaluation. For example, if respondents believe that they have placed too much weight on profiles’ professions in the previous evaluation, they might decide to rely on the current profiles’ “country of origin” factor more than its “profession” factor in order to balance across evaluations. Under this scenario, we would expect a significant interaction between previous profiles’ “profession” factor and current profiles’ “country of origin” factor.

We modify the test statistic given in Equation (5) in the following way. Suppose that J is even (if J is odd, simply consider $J-1$ evaluations). We first define a new response vector $\mathbf {Y}_i^\ast = [Y_{i2}; Y_{i4}; \ldots; Y_{iJ}]$ by taking every other evaluation. Similarly, we can define new factors of interest $\mathbf {X}_i^\ast = [[\mathbf {X}_{i1}; \mathbf {Z}_{i1}]^\top; [\mathbf {X}_{i3}; \mathbf {Z}_{i3}]^\top , \ldots; [\mathbf {X}_{i,J-1}; \mathbf {Z}_{i,J-1}]^\top ]$ and a new set of conditioning variables $\mathbf {Z}_i^\ast = [[\mathbf {X}_{i2}; \mathbf {Z}_{i2}]^\top; [\mathbf {X}_{i4}; \mathbf {Z}_{i4}]^\top , \ldots; [\mathbf {X}_{iJ}; \mathbf {Z}_{iJ}]^\top ]$ . We then fit HierNet with the new response $\mathbf {Y}^\ast = [\mathbf {Y}_1^\ast; \mathbf {Y}_2^\ast; \dots; \mathbf {Y}_n^\ast ]$ on $(\mathbf {X}^\ast ,\mathbf {Z}^\ast )$ , where $\mathbf {X}^\ast = [\mathbf {X}_1^\ast; \mathbf {X}_2^\ast; \dots; \mathbf {X}_n^\ast ]$ and $\mathbf {Z}^\ast $ is defined similarly.

For this particular scenario, HierNet will estimate all main effects and interaction effects of $\mathbf {Z}^\ast $ , and the interaction effects between $\mathbf {X}^\ast $ and $\mathbf {Z}^\ast $ , which are of primary interest. To increase the power of the test, we set all main and interaction effects of $\mathbf {X}^\ast $ to zero since we do not expect the previous profile alone to impact the respondent’s choice. Furthermore, we also do not expect the interaction effects between $\mathbf {X}^\ast $ and $\mathbf {Z}^\ast $ to differ, depending on the ordering (left vs. right) of the relevant factors. Therefore, we enforce all these interaction effects to have equal magnitude as done in Equation (6) (see Appendix E of the Supplementary Material for further details). This leads to the following test statistic:

$$ \begin{align*} T_{\text{HierNet}}^{\text{Carryover}}(\mathbf{X}^\ast,\mathbf{Y}^\ast,\mathbf{Z}^\ast) \ = \ \sum_{\ell=1}^p \sum_{\ell^\prime=1}^p \sum_{k=1}^{K_\ell} \sum_{k^\prime = 1}^{K_{\ell^\prime} } \hat\gamma_{\ell\ell^\prime kk^\prime}^{2}, \end{align*} $$

where $\gamma _{\ell \ell ^\prime kk^\prime }$ represents the coefficient of an interaction term between the kth level of the $\ell $ th factor of the profile used in the previous evaluation and the $k^\prime $ th level of the $\ell ^\prime $ th factor of the profile used in the current evaluation. Appendix F.2 of the Supplementary Material explains how to resample the test statistic in this setting.

3.5.3. Fatigue Effect

Researchers may be concerned that a respondent performing a large number of conjoint evaluations may experience the “fatigue effect,” resulting in a declining quality of responses. Recently, Bansak et al. (Reference Bansak, Hainmueller, Hopkins and Yamamoto2018) conducted an empirical study to examine how the pattern of responses depends on the number of evaluations each respondent performs. Here, we show how to use the CRT to formally test the presence of the fatigue effect.

Similar to the carryover effect, we investigate whether there is a fatigue effect within each respondent’s potential outcome $Y_{ij}(\mathbf {x}_{ij},\mathbf {z}_{ij})$ , where we again assume no interference effect as done when testing no profile order effect. We test the following null hypothesis that the potential outcome is unaffected if respondent i evaluated the same pair of profiles $(\mathbf {x}_{ij}, \mathbf {z}_{ij})$ but at a later or earlier evaluation $j' \neq j$ :

$$ \begin{align*} H_0^{\text{Fatigue}}: Y_{ij}(\mathbf{x}_{ij}, \mathbf{z}_{ij}) \stackrel{d}{=} Y_{ij'}(\mathbf{x}_{ij}, \mathbf{z}_{ij}) \ \text{for all} \ i, j, j', \ \mathbf{x}_{ij} \in \mathcal{X}_{\text{ind}},\ \text{and}\ \mathbf{z}_{ij} \in \mathcal{Z}_{\text{ind}}. \end{align*} $$

We propose a similar HierNet test statistic that reflects a scenario where respondents will only pay attention to a shrinking number of factors as they rate more profiles. In this case, we would expect interactions between the factors and the evaluation order index $\mathbf {F}=(F_1,F_2,\ldots ,F_n)$ , which represents an $nJ$ -dimensional integer vector with $\mathbf {F}_i=(1,2,\ldots ,J)$ for all $i=1,2,\ldots ,n$ . Again, for the sake of statistical power, we impose the absence of profile order effects on HierNet as done in Equation (5). Our proposed test statistic is the following from a HierNet fit of $\mathbf {Y}$ on $(\mathbf {X}, \mathbf {Z}, \mathbf {F})$ :

$$ \begin{align*} T_{\text{HierNet}}^{\text{Fatigue}}(\mathbf{X},\mathbf{Y},\mathbf{Z},\mathbf{F}) \ = \ \sum_{\ell=1}^p \sum_{k=1}^{K_\ell} \hat\gamma_{\ell k }^{2}, \end{align*} $$

where $\hat \gamma _{\ell k}$ represents the coefficient of an interaction term between $\mathbf {F}$ and level k of factor $\ell $ . Appendix F.2 of the Supplementary Material shows how to resample and recompute the test statistics to test $H_0^{\text {Fatigue}}$ .

3.6. Incorporating Respondent Characteristics

In conjoint experiments, researchers often expect factors of interest to interact strongly with respondent characteristics (Hainmueller and Hopkins Reference Hainmueller and Hopkins2015; Newman and Malhotra Reference Newman and Malhotra2019; Ono and Burden Reference Ono and Burden2018). It is possible to exploit this fact when applying the CRT by directly incorporating respondent characteristics, $\mathbf {V}$ , into the test statistic. Doing so can substantially increase the statistical power.

We incorporate respondent characteristics in the CRT procedure by appending $\mathbf {V}$ to $\mathbf {Z}$ and holding both $(\mathbf {Z},\mathbf {V})$ constant. Since respondent characteristics are not randomized factors, unlike $\mathbf {Z}$ , $\mathbf {V}$ is not guaranteed to be independent of the potential outcomes. We can test the following causal null hypothesis that conditions upon $\mathbf {V}$ :

(9) $$ \begin{align} H_{0}: \mathbf{Y}(\mathbf{x},\mathbf{z}) \overset{d}{=} \mathbf{Y}(\mathbf{x}',\mathbf{z}) \mid \mathbf{V} \hspace{0.1cm} \text{ for all } \mathbf{x}, \mathbf{x}' \in \mathcal{X},\ \mathrm{and}\ \mathbf{z} \in \mathcal{Z}. \end{align} $$

Theorem 3.1 can be easily extended to show that this null hypothesis is equivalent to the conditional independence relation $\mathbf {Y} \perp \!\!\! \perp \mathbf {X} \mid \mathbf {Z}, \mathbf {V}$ . Algorithm 1 also stays the same except we sample $\mathbf {X}^{b}$ from the distribution of $\mathbf {X} \mid (\mathbf {Z}, \mathbf {V})$ and our test statistic is now a function of $(\mathbf {X}, \mathbf {Y}, \mathbf {Z}, \mathbf {V})$ .

A major benefit of incorporating respondent characteristics is the ability to capture respondent characteristic interactions into the test statistic. Consequently, we incorporate an additional predictor $\mathbf {V}$ when fitting HierNet and modify the HierNet test statistic in Equation (5) as

(10) $$ \begin{align} \nonumber T_{\text{HierNet}} =& \underbrace{\sum_{k=1}^{K_1} (\hat\beta_{k} - \bar\beta)^2}_{\text{main effects}} + \underbrace{\sum_{\ell = 2}^{p} \sum_{k=1}^{K_1} \sum_{k^\prime = 1}^{K_{\ell}} (\hat\gamma_{1 \ell kk^\prime} - \bar\gamma_{1 \ell k^\prime})^{2}}_{\text{within-profile interaction effects}} \\ &+\underbrace{\sum_{\ell = 1}^{p} \sum_{k=1}^{K_1} \sum_{k^\prime = 1}^{K_{\ell}}(\hat\delta_{1 \ell kk^\prime} - \bar\delta_{1 \ell k^\prime})^{2}}_{\text{between-profile interaction effects}} + \sum_{m=1}^r \sum_{k=1}^{K_1} \sum_{w = 1}^{L_{m} } \underbrace{(\hat\xi_{1 m k w} - \bar\xi_{1 m w})^{2}}_{\text{respondent interaction effects}}, \end{align} $$

where $\hat \xi _{1 m k w}$ represents the interaction between the kth level of our factor of interest $\mathbf {X}$ and the wth level of the mth factor of a respondent characteristic. If a respondent characteristic is a numeric variable, we could either coarsen it into a factor variable or directly include it in the model as a numeric variable.Footnote ⁸ Again, $\bar {\xi }_{1 m w}$ denotes the average of these estimated interaction coefficients. Similar to Equation (10), we add the additional constraint that $\hat \xi _{\ell m k w} = \hat \xi _{\ell m k w}^{L} = \hat \xi _{\ell m k w}^{R}$ , where the superscripts L and R similarly denote the left and right profile effects. Finally, we modify $T^{\text {Order}}_{\text {HierNet}}$ similarly by adding $\sum _{\ell =1}^p \sum _{m=1}^r \sum _{k=1}^{K_\ell } \sum _{w = 1}^{L_{m} } (\hat \xi _{\ell m k w}^{L} + \hat \xi _{\ell m k w}^{R} )^{2}$ to the original test statistic in $T^{\text {Order}}_{\text {HierNet}}$ to account for respondent characteristic interactions. For the empirical applications in Section 4 and Appendix G of the Supplementary Material, we incorporate $\mathbf {V}$ and use the modified test statistics to test $H_0$ and the no profile order effect.