Measurement error correlation within blocks of indicators in consistent partial least squares: Issues and remedies

1. Introduction

Structural equation modeling (SEM) is a versatile, widely used analytical technique to statistically examine relationships between theoretical concepts. In SEM these concepts are predominantly operationalized by latent variables, the so-called common factors assumed to be measured by a set of observable indicators within the measurement model framework.

To estimate the measurement model parameters as well as the postulated structural relationship between latent variables, two conceptually different estimation approaches have been established: covariance-based (CB) estimation (e.g. Jöreskog, 1978) and variance-based (VB) estimation (e.g. Lohmöller, 1989). CB parameter estimates are obtained by minimizing a distance measure of the empirical covariance matrix of the indicators and its theoretical counterpart implied by the model. VB estimators, on the other hand, use linear combinations of the indicators to build proxies as stand-ins for the constructs and, subsequently, estimate the model parameters based on these proxies.

Among VB estimators, partial least squares path modeling (PLS) is arguably most wide-spread. It has been used for research in numerous fields, including strategic management (e.g. Hair, Sarstedt, Pieper and Ringle, 2012), marketing (e.g. Hair, Sarstedt, Ringle and Mena, 2012), information systems (e.g. Ringle et al., 2012), tourism research (e.g. Müller et al., 2018) and internet research (e.g. Chiang and Hsiao, 2015; Yan et al., 2017; Wu and Li, 2018). For a recent overview of the methodological research on PLS see Khan et al. (forthcoming).

However, despite its popularity, PLS has been subject to intense debate in recent years (see e.g. Rigdon et al., 2017, for a recent stocktaking of the debate) that helped show its limitations. Most notably, PLS is only consistent at large (e.g. Dijkstra, 1981; Schneeweiss, 1993), hence yielding generally inconsistent parameter estimates for common factor models. In fact, unless all measurement errors are zero in the population, proxies cannot generally be expected to be a perfect substitute for the underlying common factor. As a consequence, the probability limit of the estimated correlation between proxies is smaller than the population correlation between their corresponding common factors. Hence, path coefficients and factor loadings based on estimated proxy correlations are inconsistent estimates for their underlying latent variable counterpart (Dijkstra and Henseler, 2015a).

To correct for these shortcomings, consistent partial least squares (PLSc) has been introduced as an enhancement of PLS that essentially maintains all the advantages of PLS while yielding consistent and asymptotically normally distributed parameter estimates for common factor models in line with Wold’s (1975) basic design (Dijkstra, 1981; Dijkstra and Henseler, 2015a, b). As one of the defining assumptions of the basic design, uncorrelated measurement errors within and across blocks of indicators are thus necessary in theory for PLSc to maintain consistency.

Practically, however, there are a number of cases in empirical research in which uncorrelatedness of measurement errors may not hold (e.g. Gerbing and Anderson, 1984; Rubio and Gillespie, 1995; Chin et al., 2003; Saris and Aalberts, 2003; Henseler and Chin, 2010; Brown, 2015). Depending on the magnitude of the unobserved correlation between measurement errors, the number of indicators and their quality, ignoring measurement error correlations leads to inconsistent structural parameter estimates and, therefore, to potentially erroneous conclusions (e.g. Podsakoff et al., 2012; Westfall et al., 2012; Gu et al., 2017).

Different remedies have been proposed to prevent correlated measurement errors through a careful study design (e.g. MacKenzie and Podsakoff, 2012; Podsakoff et al., 2012). However, in practice, aspects such as study design, item quality and wording are often beyond the researchers’ control, essentially leaving modeling approaches as the only alternative. Several researchers therefore suggest addressing the problem indirectly, e.g., by means of bifactor models and associated hierarchical reliability indices (e.g. McNeish, 2018). Others propose explicitly specifying the measurement error correlation structure in the model (e.g. Rubio and Gillespie, 1995; Brown, 2015, pp. 162–175) – although there is some controversy as to the conceptual justification of such an approach (e.g. Landis et al., 2009; Hermida, 2015).

Against this background, we follow Sarstedt et al.’s (2014) call for a continuous improvement of PLS and contribute to the literature by extending PLSc to yield consistent parameter estimates for population models whose indicator blocks contain a subset of correlated measurement errors. Based on an idea outlined in Dijkstra (2013) and mentioned in Dijkstra and Henseler (2015a), this is achieved by modifying the calculation of the correction factors as defined by PLSc to include a priori assumptions on the structure of the within-block measurement error correlations.

The remainder of the paper is structured as follows: Section 2 briefly reviews the PLS algorithm and its consistent version PLSc. Section 3 presents the methodological contribution to obtain consistent and asymptotically normally distributed parameter estimates if within-block measurement error correlation is present. The design and results of a Monte Carlo simulation to assess the approach are described in Sections 4 and 5. The paper closes with a discussion and an outline for potential future research in Section 6.

2. PLS path modeling

PLS was developed by Herman O.A. Wold (1975) for the analysis of high-dimensional data in a low-structure environment but has been extended and modified in recent years to accommodate a wide variety of analytical needs. PLS, which may be regarded as similar to generalized canonical correlation analysis, is capable of emulating several of Kettenring’s (1971) techniques for the canonical correlation analysis of several sets of indicators (Tenenhaus et al., 2005). In its most developed form, known as PLSc, it may best be understood as a fully developed SEM approach that includes a global goodness-of-fit test for linear models and the ability to consistently estimate recursive, non-recursive and non-linear common factor models (Dijkstra, 2011; Dijkstra and Schermelleh-Engel, 2014; Dijkstra and Henseler, 2015a, b).

The following section briefly reviews the notation and main aspects of PLS and PLSc as well as their underlying model setup, known as the basic design.

Consider a model with J latent variables η₁, η₂, …, η_J with unit variance related via a set of structural equations and the existence of corresponding vectors of indicators x₁, x₂, …, x_J defined as measurement error-prone manifestations of their respective latent variable:

and:

3. Correlated measurement errors

As suggested by Equation (15), the consistency of original PLSc was established based on the assumptions of the basic design, including measurement errors that are uncorrelated across and within blocks of indicators; i.e., Θ_jj is indeed a diagonal matrix. In fact, if measurement errors in the population are correlated within blocks of indicators, then original PLSc using the correction factor from Equation (13) leads to inconsistent parameter estimates for both factor loadings and path coefficients, where the magnitude of the inconsistency is positively related to the strength of the measurement error correlation and negatively affected by the composite reliability. However, taking into account measurement errors are straightforward provided that the correlation is confined to be within the indicator blocks.

Given a presumption on the measurement error correlation structure, define the set of uncorrelated measurement error pairs as U_j :={(k, m)|θ_km;jj=0}, where θ_km;jj denotes the population covariance between the k-th and m-th measurement error of block j. An immediate extension to original PLSc is to minimize the squared Euclidean distance between the off-diagonal elements of the empirical covariance matrix S_jj and the matrix ( c j w ˆ j ) ( c j w ˆ j ) ′ with respect to c_j, including only those elements contained in the set U_j:

Because of the continuity of the functions involved, the consistency of the sample moments, and the fact that the probability limits of the PLS weight vectors, as given in Dijkstra (1981), are effectively independent of the assumed structure within the blocks, the probability limit of the estimated adjusted squared correction factor is again equal to λ j ′ Σ j j λ j . Indeed, replacing the terms in Equation (18) by their population counterparts yields:

4. Monte Carlo simulation

To assess the efficacy of the modification, a Monte Carlo simulation is conducted.

To this end, six population models are investigated[6]. The baseline population model to be considered is illustrated in Figure 1. The structural population model contains three latent variables:

For each population model, the exogenous latent variable η₁ and the two endogenous latent variables η₂ and η₃ are each connected to three indicators, the minimum requirement for our approach to be feasible since the additional indicator ensures that U_j≠∅ if a correlation between any two measurement errors is allowed. Factor loadings for η₂ and η₃ are fixed at λ₁₂=0.7, λ₂₂=0.85, λ₃₂=0.8 and λ₁₃=0.8, λ₂₃=0.75, λ₃₃=0.8, reflecting average indicator reliabilities. Furthermore, the first two loadings of η₁ are set to λ₁₁=0.65 and λ₂₁=0.8, respectively. To investigate how different composite reliabilities affect parameter estimates, both the number of indicators per block and the size of the loadings may be varied. Here, we chose the latter by varying λ₃₁ within a range of 0.5 to 0.9 in steps of 0.2.

All measurement errors (ε_kj) have a mean of 0 and are uncorrelated across and within blocks except for the first and the second measurement errors of the first indicator block: θ 12;11 = 0.360 ⋅ 0.578 ⋅ ρ 12;11 , where ρ_12;11 denotes the correlation between ε₁₁ and ε₂₁. To assess how the strength of the correlation affects parameter estimates, we include a case with comparatively low (ρ_12;11=0.1) and high correlation (ρ_12;11=0.6).

The simulation is conducted in the statistical software environment R (R Core Team, 2017). The data sets for each of the six resulting population models (=3 different loading magnitudes × 2 different measurement error correlations) are drawn according to the following baseline population indicator correlation matrix using the MASS package (Venables and Ripley, 2002). Samples of size n=100, 200 and 1,000 are drawn from a multivariate normal distribution with the mean of each indicator set to 0 and the covariance matrix displayed in Equation (24):

The number of replications per population model is set to 1,000, resulting in a total of 18,000 data sets (6 population models×3 sample sizes×1,000 replications).

To estimate the underlying population parameters for each data set, two models were specified. The first model M₁ correctly reflects the corresponding underlying population model in terms of the structural and the measurement model but does not explicitly account for the correlation between the measurement errors ε₁₁ and ε₂₁. Here, estimation by traditional PLSc is expected to yield estimates that systematically deviate from their corresponding population values. The second model M₂ is similar to the first model but acknowledges the measurement error correlation as present in the population models. Estimation is performed using our contributed modification. To this end, we use the MoMpoly function provided by the MoMpoly package (Schuberth et al., 2017), which implements the procedure as described in this paper[7]. Here, the enhanced procedure is expected to yield estimates close to the corresponding population parameters. However, this is likely to come at the cost of a loss in precision, as the calculation of the correction factor is based on less information. In addition to the estimations based on the simulated data sets, we retrieve the parameters for each population model using the population covariance matrix as input. This serves to verify Fisher consistency, i.e., whether a given estimator is in fact able to yield population parameters if supplied by the population covariance matrix.

To compare the estimates across the different designs, two common quality measures are considered: the estimated bias and the root mean squared error (RMSE). The bias is estimated as follows:

Consistency of our modification is essentially achieved by discarding information. Hence, finite sample comparisons between modified PLSc and original PLSc should take the expected trade-off between bias and variability into account. A well-established measure in this respect is the (estimated) RMSE given by:

The population RMSE essentially combines standard deviation and bias. For an unbiased estimator, it equals to the standard deviation.

5. Results

Below, we present the results of the simulation study. We report the results for the path coefficients γ₁, γ₂ and β and the factor loadings λ₂₁ and λ₃₁ of the indicator block affected by measurement error correlation. In addition, the share of Heywood cases and the share of outliers are given for each setup. Omission of the other loadings is justified because the results for λ₁₁ are virtually identical to those of λ₂₁ and λ₃₁, while the loadings of those indicator blocks whose measurement errors are assumed to be uncorrelated are by construction unaffected by the correlated measurement errors of other blocks within the structural model.

Tables I and II summarize the results. Each major column contains the results for a given population factor loading λ₃₁ (i.e. 0.5, 0.7, 0.9) spread across two minor columns representing the varying population measurement error correlation ρ_12;11, where ρ_12;11∈{0.1, 0.6}. Each major-minor combination is again split by model (i.e. model M₁ and model M₂) to facilitate the comparison.

Table I displays the simulation results with respect to the estimated bias. Each row displays the average deviation of the estimated parameters from their corresponding population values split by sample size n=100, 200, 1000 (across rows), population and estimated model (across columns). In the presence of unmodeled measurement error correlation within a block of indicators, parameter estimates obtained by PLSc using the traditional correction factor (model M₁) systematically deviate on average from their pre-specified population value, where the deviation per population model and parameter is stable across sample sizes. This finding is in line with the fact that original PLSc is indeed unable to retrieve population parameters when supplied with the corresponding population indicator covariance matrix, as displayed at the bottom of Table I. Comparing results for a given sample size, the magnitude of the deviations varies between virtually no bias (e.g. for λ₃₁=0.9 and ρ_12;11=0.1) and values of up to 0.1 (e.g. for λ₃₁=0.5 and ρ_12;11=0.6), depending on the strength of the measurement error correlation ρ_12;11 and the size of the population loading λ₃₁. In this respect, the effect of the strength of the correlation between measurement errors on the estimated bias is most pronounced with higher error correlations leading to increased deviation.

Looking across columns for a given measurement error correlation, deviations vary only marginally, although an increasing reliability – as induced by the higher loadings – slightly decreases bias overall. These findings are again supported by the parameters obtained based on the corresponding population covariance matrix shown in the last four rows of Table I: deviations for all parameters are lowest for estimates based on population models with a higher composite reliability, i.e., λ₃₁=0.9.

In contrast to Model M₁, population model parameters are retrieved when errors are taken into account along the lines described in Section 3 (model M₂). The finite sample results for model M₂ are largely in line with these findings, although small deviations are found; e.g., with values of 0.04 and 0.05, the estimated bias for path coefficient γ₂ is comparatively high.

For a given parameter, the sign of the deviations is relatively stable across sample sizes, population model and estimated model. The results show a small but almost consistently negative deviation for γ₁ and γ₂, while β, the path coefficient connecting the two endogenous latent variables η₂ and η₃, as well as the loadings λ₂₁ and λ₃₁ are uniformly overestimated.

Overall, the difference between M₁ and M₂ is most pronounced for the estimated loadings, while deviations for the path coefficients are generally small, with modified PLSc outperforming original PLSc for large samples sizes and strong measurement error correlation only.

Table II reports the results for the RMSE. Here, the picture is mixed. For medium (λ₃₁=0.7) and high (λ₃₁=0.9) composite reliability, the RMSE for both loading and path coefficient estimates is virtually identical for M₁ and M₂. In contrast to the results in Table I, the RMSE does not differ systematically with the magnitude of the error correlation. For λ₃₁=0.5, however, original PLSc is superior to the modified approach in small samples (n=100, 200). Only for a large sample size and a high composite reliability does M₂ produce strictly smaller RMSEs compared to the values produced by M₁.

Regarding Heywood cases and outliers, no significant difference between M₁ and M₂ is visible. While the number of Heywood cases is close to 0 or is 0 for large samples, roughly 300 of the 1,000 replications were discarded for a sample size of n=100. In each instance, Heywood cases occur because of the loading estimates that are larger than one in absolute value.

6. Discussion and future research

Correlated measurement errors are a common feature in SEM. However, research regarding issues and potential remedies related to measurement error correlations in the context of VB estimation is scarce. While prior research papers (e.g. Charles, 2005; Zimmerman, 2007; Padilla and Veprinsky, 2012; Raykov et al., 2014) have discussed and addressed the issue of correlated measurement errors in the common factor framework, none of these are based on a VB approach like PLS. Against this background, we contribute to the ongoing development and assessment of VB estimation approaches by filling two gaps in the literature.

First, this study enhanced PLSc to yield consistent parameter estimates for population models whose indicator blocks contain a subset of correlated measurement errors – provided that all correlated errors are accounted for in the estimated model. Since PLS and PLSc are viable options for estimating interactions and other non-linear relationships between constructs (e.g. Dijkstra and Henseler, 2011; Dijkstra and Schermelleh-Engel, 2014), our findings may help in advancing current approaches in this field. Notable examples of this kind would be the product-indicator approach (Chin et al., 2003) and the orthogonalizing approach (Henseler and Chin, 2010) – both of which rely on indicators whose errors can safely be assumed to be correlated for technical reasons. The proposed correction can help to make these two approaches consistent.

Second, initial evidence on the implications of neglecting measurement error correlation in PLSc was provided. To this end, a Monte Carlo simulation was conducted to investigate the average difference between estimated parameters and their respective population counterpart as well as the RMSE across a range of pre-specified population models for original and modified PLSc.

For original PLSc, the simulation results showed a generally small yet persistent average deviation between the estimated parameters and their corresponding population value (estimated bias) across all population models if measurement error correlation was neglected in the estimated model (model M₁). For our proposed approach (model M₂), the average deviation between the estimated parameters and their corresponding population value was virtually 0 across all samples sizes, indicating that the procedure works well in finite samples. These findings were in line with theoretical considerations regarding the inconsistency of original PLSc when measurement errors within indicator blocks are ignored. Overall, however, differences were generally rather small. In particular, when efficiency is considered with respect to the RMSE, M₁ and M₂ produce virtually identical results unless both the sample size and the population error correlation are high and the population composite reliability is low.

Regarding the magnitude of the estimated bias, we found a positive relation with the strength of the measurement error correlation, while higher composite reliability can be seen as a catalyst that essentially mitigates the effect of a given neglected measurement error correlation. The latter is intuitively appealing since an increase in composite reliability implies a decrease in attenuation of the latent variable correlation. Hence, correction for attenuation and, by the same token, any inconsistency caused by unmodeled measurement error correlation becomes less and less influential. Regarding the RMSE, the relation is less clear, although the RMSE for both the modified approach and original PLSc is higher when the population measurement error is comparatively high.

These findings are regarded as initial evidence that – although our approach is theoretically superior – original PLSc is comparatively robust with respect to misspecification of the structure of the measurement error correlations within blocks of indicators. Indeed, some preliminary simulation results by the authors confirm that PLSc outperforms common CB estimators (including maximum likelihood) in terms of bias if measurement error correlation within blocks of indicators is neglected. However, a generalization of these findings requires separate attention.

The observed tendency of PLSc to produce Heywood cases (loadings larger than one in absolute value), or incorrect signs of regression coefficients in PLS, should be addressed. We chose the simplest method to demonstrate our modification, but more robust approaches for estimating the correction factor may be applied. In fact, initial Monte Carlo evidence confirms that using, e.g., Equation (11) of Dijkstra (2013), does indeed improve the share of admissible results by roughly 10 percentage points without affecting any of the results described above. Whether these findings hold in general, however, is an open question. Furthermore, we have developed a simple approach – essentially empirically Bayes – where we use a posterior mean, median or mode that does lie in the appropriate range to address these issues. The merits of this approach, however, are not yet fully investigated (Dijkstra, 2018).

This study provided initial evidence on the implications of neglecting measurement error correlation in terms of parameter accuracy. Clearly, this is of limited scope. Future research should investigate the consequences of our modified approach for model fit. Critics have repeatedly cautioned against pre-specifying measurement error correlations, claiming that these correlations often lack a substantive meaning, which would in turn only obfuscate a meaningful interpretation of the specified model. In fact, for CB estimators such as maximum likelihood freeing, one or more measurement error correlations naturally leads to an increase in model fit, as the estimated model-implied covariance matrix is closer to its empirical counterpart. Similarly, common fit indices based on the distance between the estimated model-implied and empirical covariance matrix – such as the standardized root mean squared residual or the geodesic distance – generally indicate a better fit.

The focus of this paper was on within indicator block measurement error correlation only. In the presence of unmodeled population measurement errors across blocks, the modification does not yield consistent estimates because the proportionality between weights and loadings as used to derive the correction factor no longer holds. As a consequence, loadings, reliabilities and path coefficients pertaining to the blocks affected by measurement error correlation are generally inconsistent. Strategies to address unmodeled population measurement errors across blocks within the PLS/PLSc framework are thus needed.