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Beyond rating accuracy: unpacking frame-of-reference assessor training effectiveness

Published online by Cambridge University Press:  12 March 2024

C. Allen Gorman ,
Duncan J. R. Jackson ,
John P. Meriac ,
Joseph R. Himmler  and
Tanya F. Contreras
C. Allen Gorman*
Affiliation:
University of Alabama at Birmingham, Birmingham, USA
Duncan J. R. Jackson
Affiliation:
King’s College London, London, UK
John P. Meriac
Affiliation:
University of Missouri-St Louis. St-Louis, USA
Joseph R. Himmler
Affiliation:
Auburn University, Auburn, USA
Tanya F. Contreras
Affiliation:
University of Alabama at Birmingham, Birmingham, USA
*
Corresponding author: C. Allen Gorman; Email: cagorman@uab.edu
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Abstract

Evidence from previous research suggests that frame-of-reference (FOR) training is effective at improving assessor ratings in many organizational settings. Yet no research has presented a thorough examination of systematic sources of variance (assessor-related effects, evaluation settings, and measurement design features) that might influence training effectiveness. Using a factorial ANOVA and variance components analyses on a database of four studies of frame-of-reference assessor training, we found that (a) training is most effective at identifying low levels of performance and (b) the setting of the training makes little difference with respect to training effectiveness. We also show evidence of the importance of rater training as a key determinant of the quality of performance ratings in general. Implications for FOR training theory and practice are discussed.

Keywords

Assessment centersassessor trainingframe-of-reference trainingvariance partitioning
Type
Focal Article
Information
Industrial and Organizational Psychology , First View , pp. 1 - 14
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of Society for Industrial and Organizational Psychology

Introduction

Training raters, or assessors, is fundamental to a number of HR activities, including job analysis, personnel selection, performance management, and employee development (Aguinis & Kraiger, Reference Aguinis and Kraiger2009; Dierdorff et al., Reference Dierdorff, Surface and Brown2010). Assessor training has been demonstrated as an effective means of improving rating accuracy in assessment center (AC) and performance appraisal contexts, particularly approaches such as frame-of-reference (FOR) training (Bernardin & Buckley, Reference Bernardin and Buckley1981). However, less is known about the influence of factors associated with assessor training, such as the training setting, trainer characteristics, ratee performance level, training protocols utilized, training stimulus materials, rating instruments utilized, or even training duration. All of these factors are theoretically relevant considerations that may impact rating quality, yet no research has emerged that has made any meaningful comparisons among them. Although there are a number of factors that can potentially impact AC ratings, this study was undertaken as a first step at disentangling some of the common sources of variance associated with assessor training that may influence trainees’ performance ratings. Specifically, using a database of four previously conducted studies of FOR training, we examine four factors common to all of the studies in the database: training condition, performance level, performance dimension, and setting.

Research on FOR assessor training

FOR training has emerged as the preferred method of assessor training due to the robust evidence indicating FOR training’s effectiveness at improving rating accuracy (Chirico et al., Reference Chirico, Bucley, Wheeler, Facteau, Bernardin and Beu2004; Roch et al., Reference Roch, Woehr and Mishra2012). Bernardin and Buckley (Reference Bernardin and Buckley1981) originally proposed FOR training as an alternative to rater error training in response to the inconsistent results produced by rater error training. FOR training focuses on providing raters with performance standards for each dimension to be rated (Woehr & Huffcutt, Reference Woehr and Huffcutt1994), with the ultimate goal of raters sharing and using common conceptualizations of performance (Athey & McIntyre, Reference Athey and McIntyre1987; Gorman & Rentsch, Reference Gorman and Rentsch2009, Reference Gorman and Rentsch2017; Woehr, Reference Woehr1994). Although the majority of FOR training research has been conducted in the performance appraisal domain, recent applications of FOR training have been effectively utilized in other domains such as ACs (Jackson et al., Reference Jackson, Atkins, Fletcher and Stillman2005), job analysis (Aguinis et al., Reference Aguinis, Mazurkiewicz and Heggestad2009), competency modeling (Lievens & Sanchez, Reference Lievens and Sanchez2007), and job interviews (Melchers et al., Reference Melchers, Lienhardt, Aarburg and Kleinman2011).

Despite the impressive evidence in support of the efficacy of FOR training for increasing rating accuracy, there are theoretical and operational issues with traditional estimates of rating accuracy. Such estimates include Cronbach’s (Reference Cronbach1955) accuracy components (elevation, differential elevation, stereotype accuracy, and differential accuracy), distance accuracy (McIntyre et al., Reference McIntyre, Smith and Hassett1984), and Borman’s differential accuracy (1977). First, all of these accuracy indices involve a direct comparison between assessor ratings and a set of “true score” or expert ratings. This essentially results in a set of difference scores. Problems inherent in the use of difference scores have been well documented (Edwards, Reference Edwards1995, Reference Edwards2001), foremost being the typical lack of reliability in difference scores. Second, scholars have raised concerns over “true score” development, including: (a) variation in how “true scores” are operationally defined, (b) lack of agreement among expert ratings, and (c) lack of congruence between conceptual and operational definitions of “true scores” (Sulsky & Balzer, Reference Sulsky and Balzer1988). Recognizing issues surrounding true scores, researchers have begun to recognize the benefits of considering alternative indicators of rating quality besides rating accuracy (Greguras et al., Reference Greguras, Robie, Schleicher and Goff2003; Hoffman et al., Reference Hoffman, Gorman, Blair, Meriac, Overstreet and Atchley2012). Responding to the call from several researchers for alternative approaches that move beyond traditional accuracy measures, this research incorporates multiple sources of variance in examining the psychometric quality of performance ratings (Murphy & Cleveland, Reference Murphy and Cleveland1995; Roch et al., Reference Roch, Woehr and Mishra2012; Sulsky & Balzer, Reference Sulsky and Balzer1988). Accordingly, we utilize a quasi-experimental design to examine psychometric characteristics associated with AC ratings.

Variance partitioning and FOR training effectiveness

Variance partitioning approaches based on factorial ANOVA and variance components analyses have been applied to assessor training research and have been used to establish, following training, assessors’ capacity to distinguish among different AC dimensions and to determine behavioral consistency within AC dimensions across exercises (Lievens, Reference Lievens2001a; 2001b). For example, using generalizability analyses, Lievens (Reference Lievens2001a) found that FOR-trained assessors differentiated more effectively among dimensions and provided more reliable ratings than raters who received data-driven or control training. In a similar study utilizing generalizability analyses, Lievens (Reference Lievens2001b) found that after training, assessors were able to reliably differentiate AC candidate performance among multiple dimensions.

However, one hallmark of FOR training is the ability of FOR-trained assessors to categorize performance information as either positive (i.e., high level of performance) or negative (i.e., low level of performance; Gorman & Rentsch, Reference Gorman and Rentsch2009, Reference Gorman and Rentsch2017). For example, Melchers et al. (Reference Melchers, Lienhardt, Aarburg and Kleinman2011) found a large performance level effect in a study of FOR training effects on interview ratings. However, previous studies have not examined performance level Footnote 1 as a between-subjects factor, which is important for establishing the extent to which FOR training plays a role in fostering assessor sensitivity to performance variability. Prior research has shown that evaluators may be more attuned to negative performance information (e.g., Fiske, Reference Fiske1980), suggesting that raters may not evaluate performance in equally effective ways at high and low levels of the performance continuum. Currently, it is not clear whether the effects of FOR training help raters evaluate performance effectively at all levels of performance. Accordingly, we investigate the following research question:

Research Question 1: Does training condition (FOR vs. control) interact with ratee performance level (high vs. low) to influence assessor ratings?

Despite the findings reviewed above, training location may also represent a design consideration that impacts training effectiveness. Some scholars have recognized that training characteristics may differ across settings, even if FOR training is still implemented. As noted by Cheng and Ho (Reference Cheng and Ho2001), by testing variables in different training settings, “a more consistent view of their functions on training transfer [can] be obtained” (p. 110). According to Orpen (Reference Orpen1999), both individual and organizational aspects of the training environment can impact its effectiveness. Even if training is implemented in identical ways, individual differences may be present in motivation or other considerations in how they approach and plan to utilize the training. Although the core elements of FOR training may be present, different aspects of the training environment may potentially impact training effectiveness.

In the present study, we tested for rating differences in training sessions conducted by different trainers at different universities in different regions of the United States. Although these differences in settings could potentially lead to meaningful differences in the effectiveness of the training, meta-analytic studies by both Roch et al. (Reference Roch, Woehr and Mishra2012) and Woehr and Huffcutt (Reference Woehr and Huffcutt1994) found evidence for the effectiveness of FOR training regardless of setting. Based on these empirical findings, we offer the following research question for the present study:

Research Question 2: What proportion of variance in ratee performance is accounted for by the effect of the setting in which the FOR or control training occurred?

In addition, it is commonly found that FOR training increases assessors’ ability to recognize patterns (or levels) of performance in the assessor training literature. For instance, Woehr (Reference Woehr1994) found that FOR training improves assessors’ knowledge of performance-related information, and Schleicher and Day (Reference Schleicher and Day1998) found that FOR training produced less idiosyncratic representations of performance in assessors. Building on these findings, Gorman and Rentsch (Reference Gorman and Rentsch2009) found that FOR-trained assessors possessed performance schemas that were more similar to an expert schema (compared to control-trained assessors), and the accuracy of their schemas accounted for a significant amount of incremental variance in rating accuracy over that of declarative knowledge alone.

In a meta-analysis of methodological factors in AC ratings, Woehr and Arthur (Reference Woehr and Arthur2003) found evidence that assessor training directly enhances assessors’ ability to process the vast amount of performance information presented in typical AC exercises. These results are supported by the FOR training literature that suggests that performance information is recalled in accordance with how the information is categorized, such as dimension level and performance level (Day & Sulsky, Reference Day and Sulsky1995; Schleicher & Day, Reference Schleicher and Day1998; Woehr, Reference Woehr1994). Thus, the evidence indicates that FOR training works by training assessors how to recognize and interpret performance behaviors as either generally positive (high level of performance) or generally negative (low level of performance) and then further categorizing those behaviors into the appropriate performance dimension.

Despite the improvements shown through FOR training, research has established that attention to negative performance information may be weighed more heavily than positive information (Fiske, Reference Fiske1980). Although FOR training aims to assist in the identification of relevant behaviors and scaling of behaviors, it is unclear whether it is equally effective in doing so for both high and low levels of performance. Accordingly, we offer the following research question:

Research Question 3: What proportion of variance in ratee performance is accounted for by performance level in the FOR training condition?

One commonly reported finding in the AC literature is that exercise effects tend to emerge as dominant sources of variance relative to dimension effects (e.g., Lance et al., Reference Lance, Lambert, Gewin, Lievens and Conway2004; Lance, Reference Lance2008). In part, exercise effects entail large intercorrelations among the same dimensions sampled within exercises. While we do not use exercises in the present study, we do, however, employ the use of differing performance levels, which could offer an explanation for what have historically been labeled exercise effects but could, in part, be performance-level effects (e.g., one exercise might be more challenging than another). Given previous findings on exercise effects, we expect that dimensions are unlikely to vary significantly within performance levels.

It is important to recognize however, that the design of ACs is inherently complex, potentially involving several nested and crossed effects as well as interactions among AC design features. Rather than expecting that the aforementioned AC features operate in the same way across ACs, it is possible that interactions may exist between performance levels and AC settings. In ACs, participants are rated by assessors on the basis of dimensions that could be scored high or low. This evaluation could be affected by the setting in which the evaluation takes place. These factors (participants, dimensions, levels of performance, assessors, evaluation setting) could furthermore interact and affect the ratings generated for each participant. The purpose of the current research is to determine where and how much meaningful variance exists in FOR training situations. Thus, in keeping with the discussion about performance levels, we offer the following research question regarding interactions involving settings:

Research Question 4: What proportion of variance in ratee performance is attributable to (a) dimensions nested within levels, (b) setting by level interactions, (c) setting by dimension interactions nested within levels, and (d) assessor by level interactions nested within setting?

Method

Participants

The database for the present study was compiled from archival data from four previous studies of FOR assessor training conducted between 2007-2012. Three of the datasets have been published (Gorman & Rentsch, Reference Gorman and Rentsch2009, Reference Gorman and Rentsch2017; Hoffman et al., Reference Hoffman, Gorman, Blair, Meriac, Overstreet and Atchley2012) and one is unpublished (Gorman & Meriac, Reference Gorman and Meriac2022). The total dataset consisted of 471 participants from 3 different locations (144 undergraduate participants from a large southeastern US university, 240 undergraduate participants from a regional southwestern US university, and 87 undergraduate participants from a regional southeastern US university). All participants completed the study in exchange for extra course credit at their respective university. The same standardized protocol and procedures were used at all locations (see Procedure below). For the large southeastern US university location, the mean age of participants was 21.44 years (SD = 3.73) and most held part-time jobs (60%). This sample was predominantly Caucasian (90%) and male (56%), and 77% of the sample reported that they had no experience rating the performance of another person. For the regional southwestern US university location, the mean age of participants was 20.37 years (SD = 3.66) and most held part-time jobs (60%). This sample was predominantly Caucasian (64%) and female (61%), and 60% of the sample reported that they had no experience rating the performance of another person. For the regional southeastern US university location, the mean age of participants was 20.00 years (SD = 4.09) and 33% held part-time jobs. This sample was predominantly Caucasian (79%) and female (55%), and 75% percent of the sample reported that they had no experience rating the job performance of another person.

Procedure

All training procedures and materials can be located on the Open Science Framework (https://osf.io/8tq5r/?view_only=85a74d720eb6461c827741603a51a8ce). In all studies, participants were randomly assigned to either a FOR training condition (n = 302) or a control training condition (n = 169). The attendance at each session ranged from 3-10 participants. Before each session, participants received a brief introduction. Next, participants received either FOR training or control training. Participants then viewed two videotaped performance episodes (described below), presented in random order. The participants watched the first video, made notes regarding the behaviors they observed on a rating form, then provided summary ratings for each of the five dimensions. After observing and making ratings for the first video, the process was then repeated for the second video. During the presentation of the videotapes, participants recorded behaviors on a rating form. At the conclusion of each performance episode, participants wrote their ratings on the form.

Stimulus materials

The performance episodes that served as the stimuli in the present study consisted of two videotaped AC exercises featuring actual participants in an operational developmental AC for senior-level executives. These videos have been utilized in prior FOR training research (Gorman & Rentsch, Reference Gorman and Rentsch2009, Reference Gorman and Rentsch2017; Hoffman et al., Reference Hoffman, Gorman, Blair, Meriac, Overstreet and Atchley2012). One of the videos featured a candidate that had been rated by the AC assessors as below average across most dimensions (low performance), and the other video featured a candidate that had been rated as above average across most dimensions (high performance). Performance was not uniform across all dimensions, but differed somewhat within each candidate’s evaluation in the videos, performing differently on each specific dimension. Consistent with other assessor training studies (Sulsky & Day, Reference Sulsky and Day1992, Reference Sulsky and Day1994; Schleicher & Day, Reference Schleicher and Day1998), the videos depicted a scenario in which an executive played the role of a sales manager that is holding a one-on-one meeting with a subordinate. In each video, the executive meets with a role player in the exercise that was designed to elicit behaviors relevant to the following dimensions: analysis, decisiveness, leadership, confrontation, and interpersonal sensitivity. Each of these dimensions are routinely rated across multiple exercises in the operational AC, and each dimension is designed to capture specific candidate behaviors relevant to the scenario (e.g., stating the goals and purposes for the meeting and soliciting input from the employee are behavioral examples indicative of leadership).

The videos were selected for use in prior research (see Gorman & Rentsch, Reference Gorman and Rentsch2009) by a research team based on the ease of observability of specific behaviors, the clarity of the video, the quality of the audio, and clear and unambiguous demonstration of specific positive and negative behaviors relevant to each dimension. Each video was approximately 15 minutes long. Using procedures outlined by Sulsky and Balzer (Reference Sulsky and Balzer1988), each video exercise was rated by a team of three upper-level graduate students industrial and organizational psychology who had been trained as AC assessors and had an average of 3 years of AC experience. The experienced raters independently observed and rated each video, and then the raters met to achieve consensus on a final set of scores for each video. The final consensus ratings for the overall low-performance video were as follows: analysis = 2.7, decisiveness = 2.7, leadership = 2.7, confrontation = 2.7, and sensitivity = 3.5. The final consensus ratings for the overall high-performance video were as follows: analysis = 4.0, decisiveness = 3.5, leadership = 3.7, confrontation = 4.0, and sensitivity =73.7.

Conditions

All sessions were conducted by trained graduate students using a standard written set of procedures.

FOR training

Consistent with previous FOR training research (Gorman & Rentsch, Reference Gorman and Rentsch2009, Reference Gorman and Rentsch2017; Woehr, Reference Woehr1994), the FOR training proceeded according to the following protocol outlined by Pulakos (Reference Pulakos1984, Reference Pulakos1986). First, participants were told that they would evaluate the performance of AC candidates on separate performance dimensions and were given rating scales and instructed to read them as the trainer read the dimension definitions and scale anchors aloud. The trainer discussed ratee behaviors that illustrated different performance levels for each scale. Then, participants were shown a video of a practice vignette featuring a mixed level of performance (some dimensions were above average and some were below average). Participants were asked to evaluate the example ratee using the scales provided, and the ratings were written on a whiteboard and discussed by the group of participants. Finally, the trainer provided feedback to participants explaining why the ratee should receive a particular rating (target score) on a given dimension. The training session lasted approximately 45 minutes.

Control training

Participants in the control training were also instructed that they would be evaluating AC candidate performance on the five performance dimensions. They were also presented with the rating form, and the trainer read over each of the dimension definitions. However, no other specific training was provided. Rather, a broad training video on assessing performance in organizations was shown. The control training session also lasted approximately 45 minutes.

Rating form

Consistent with previous research (Gorman & Rentsch, Reference Gorman and Rentsch2009, Reference Gorman and Rentsch2017; Woehr, Reference Woehr1994), the rating form listed dimensions, provided space for participants to take notes regarding the manager’s behavior and make ratings for each dimension. Participants recorded behaviors on their forms as they observed them. For each behavior that was recorded, participants were instructed to place either a +, -, or 0 next to the behavior to indicate whether the behavior was a positive, negative, or neutral behavior. After reviewing their notes for each video, participants recorded their rating for each dimension in the spaces provided. Each dimension was rated using an 11-point scale (1.0 = extremely weak to 5.0 = exceptional).

Analyses

All analyses were performed in this study using SPSS. In the factorial ANOVA, all effects were treated as fixed, except the effect for assessors, which was treated as random. In the variance components analyses, all effects were treated as random, as is common in this type of analysis (Brennan, Reference Brennan2001b; Putka & Hoffman, Reference Putka and Hoffman2013; Searle et al., Reference Searle, Casella and McCulloch2006). Variance components were estimated using restricted maximum likelihood procedures (e.g., Marcoulides, Reference Marcoulides1990). For interested readers, we recommend Brennan (Reference Brennan2001a, Reference Brennan2001b), Howell (Reference Howell2007), Searle et al. (Reference Searle, Casella and McCulloch2006), and Shavelson and Webb (Reference Shavelson and Webb1991, Reference Shavelson, Webb, Green, Camilli and Elmore2005) for excellent primers on the basics of factorial ANOVA and variance components analyses.

Results

Table 1 shows intercorrelations among high performance versus low performance dimension observations for the FOR-trained group. Table 2 shows the same analyses for the control group. As expected, low performance was associated with lower mean dimension scores and higher performance with higher mean scores. Generally, standard deviations were marginally smaller in the trained versus the control group. Dimensions were intercorrelated to some extent for both the trained (M r = .42, SD r = .16) and the control (M r = .39, SD r = .15) groups, and these estimates were lower than those reported elsewhere. For instance, Bowler and Woehr (Reference Bowler and Woehr2006) reported a meta-analytic estimate of .79, suggesting more discriminability among dimensions here. Coefficients alpha for all low- and high-performance dimensions approached .80. We present the standardized version of coefficient alpha (Kline, Reference Kline1999), because the overall rating may have been conceptualized by assessors in a manner that was slightly different from the other dimensions. Nevertheless, the regular alpha estimates were almost identical to those of the standardized estimates.

Table 1. Dimension Intercorrelations—FOR-Trained Group

Note. Dimensions included: A = Analysis, D = Decisiveness, L = Leadership, C = Confrontation, IS = Interpersonal Sensitivity, O = Overall dimension. Coefficients alpha were estimated at .81 (low dimensions) and .79 (high dimensions). All correlations were significant (p < .05).

Table 2. Dimension Intercorrelations—Control-Trained Group

Note. Dimensions included: A = Analysis, D = Decisiveness, L = Leadership, C = Confrontation, IS = Interpersonal Sensitivity, O = Overall dimension. Coefficients alpha were estimated at .81 (low dimensions) and .78 (high dimensions). All correlations were significant (p < .05).

To gain an understanding about FOR-trained versus control assessor behavior, Table 3 shows the results of a factorial ANOVA. This analysis included effects for conditions, assessors nested in conditions, high versus low levels of performance, dimensions nested in levels, interaction effects, and residual error. Significant effects (p < .01) were observed for all main effects and interactions in the model. Addressing Research Question 1, the results indicated that a significant interaction was present between training condition and performance level. Because the factorial ANOVA suggested that higher-level interactions were present, marginal means were plotted incorporating different levels and conditions with respect to assessment on the dimensions under scrutiny. Figure 1 shows that, in relative terms, high versus low examples of performance were correctly identified by the assessor group. With respect to examples of high performance, the presence of training did not appear to make much difference to the pattern of ratings observed. Both trained and untrained assessors evaluated high performance similarly. However, when considering low performance, ratings from trained versus untrained assessors differed on five of the six dimensions evaluated. Specifically, untrained assessors tended to produce higher ratings than trained assessors for low-performing assessees.

Figure 1. Marginal mean ratings plotted with relation to dimension observations from FOR-trained versus control-trained assessors. Dimension ratings are distinguished by being relevant to videos of low versus high performance. Since dimensions, as presented here, are nominal, lines are shown for clarity only.

Table 3. Factorial Analysis of Variance Comparing FOR-Trained versus Control-Trained Assessors

Note. Conditions = FOR-trained versus control-trained assessors; level = high versus low performance observations.

In addition to an overall view of mean differences among effects, the magnitude of various effects within each assessor subgroup (trained versus control) was also of interest. Table 4 shows two separate variance components analyses, for the FOR-trained group and the control group. For each of the conditions, eight effects are presented with associated variance components and the percentage of total variance explained by each effect. To address Research Question 2, the main effect for setting appeared to have little effect on variation among scores (.3% of variance explained in the FOR-trained group and 1.4% of variance explained in the control group). This suggests that the effects of FOR training did not vary across the different settings in which the data were collected. In the trained group, assessor variance also explained a minimal amount of the total variation in scores (1.7%). In response to Research Question 3, the results indicated that assessors distinguished between high and low performance levels, as indicated by the effect for l, and the FOR-trained group was considerably more sensitive to performance differences (54.6% of variance) than the untrained control group (33.5%).

Table 4. Variance Components Analyses Comparing FOR-Trained versus Control-Trained Assessor Subgroups

Note. Restricted maximum likelihood (REML) estimates are presented above. VC = variance component, % = percent of total variance explained.

Research Question 4a asked what proportion of variance was attributable to dimensions nested within levels, d:l. As shown in Table 4, a modest proportion of variance was explained by the d:l effect for trained assessors (3%) and assessors in the control group (2.3%). With regard to interactions, sl represents the extent to which distinctions between performance levels are contingent on different settings (Research Question 4b). Ordinarily, such effects would be indicative of the setting interfering with or contributing to fluctuations in measurement and the ultimate aim would be to minimize them (Brennan, Reference Brennan2001a). Here, the effect for sl was negligible across both the trained (1.7% of variance explained) and control groups (.2%). The next interaction (Research Question 4c), sd:l, is similar to that for sl, except that it takes error associated with dimensions into account. Again, the effects associated with sd:l were negligible (.2% for the trained group, .3% for the control group), suggesting that different settings did not contribute substantially to performance level distinctions when dimension error was taken into account.

Finally, to address Research Question 4d, the effect for al:s, shown in Table 4, is suggestive of whether the distinction between performance levels was bound by error associated with assessors nested in different settings. Thus, the al:s effect simultaneously takes performance level distinction, assessor error, and different settings into account. The aim here, again, is to minimize this effect as a source of error, because settings and assessors have the potential to interfere with useful distinctions among performance levels. Table 4 shows that this effect was notably lower for the trained (13.0% of variance explained) relative to the control group (22.8% of variance explained). The final effect, that for ad:sl,e, represents the highest order effect confounded with residual error. The ad:sl,e effect was also somewhat lower for the trained group (25.91% of variance explained) relative to the control group (39.32% of variance explained).

Discussion

Organizations rely on assessor training for a variety of purposes (Dierdorff et al., Reference Dierdorff, Surface and Brown2010), yet assessor training effectiveness research has historically relied on a limited set of criteria with serious theoretical and operational shortcomings (Sulsky & Balzer, Reference Sulsky and Balzer1988). Moreover, no research has examined the extent to which assessor training generalizes across settings in which the training is conducted. A factorial ANOVA revealed that FOR-trained assessors were more sensitive to distinguishing low levels of performance than control-trained assessors on five of the six dimensions rated (including an overall performance rating; see Figure 1). The variance components analyses indicated that: (a) the setting had little effect on the total variation in ratings in both conditions, (b) performance level accounted for substantially more variation in ratings than assessor idiosyncrasy effects (i.e., assessor and residual error effects) in the FOR training condition (but assessor idiosyncrasy effects were larger than the performance level effect in the control training condition), and (c) assessor x level interaction nested within setting error and random error effects were larger in the control training condition than the FOR training condition.

Does the level of performance matter?

The factorial ANOVA results suggest that FOR training is most effective at helping assessors identify low levels of performance. At high performance levels, differences between FOR-trained and control ratings were negligible. Because assessors in both conditions appeared to have little difficulty distinguishing high levels of performance, FOR training programs might be tailored to focus more on negative behaviors. For example, additional practice examples of negative performance might be given during a training session since the ability to recognize negative behaviors appears to be driving the distinction between FOR and control training. Alternatively, it could also be argued that FOR training should focus additional efforts on recognizing high levels of performance since there was little difference in the ratings at high performance levels. However, we support the former interpretation, as it has been found in previous research that rating accuracy tends to be higher at low levels of performance (Gorman & Rentsch, Reference Gorman and Rentsch2009, Reference Gorman and Rentsch2017). These findings are consistent with the person perception literature, where raters tend to weigh negative information more heavily than positive information (Fiske, Reference Fiske1980). Overall, our results suggest that to judge low-level performance with any degree of sensitivity, assessors must first be trained.

Additionally, the generally higher ratings provided by control-trained assessors at low performance levels could partially explain the widespread problem of rating inflation in performance appraisals (e.g., Jawahar & Williams, Reference Jawahar and Williams1997). In fact, Bernardin and Buckley (Reference Bernardin and Buckley1981) proposed FOR training to help alleviate this and other rating distribution problems. It could be that, in the absence of training, assessors provide higher ratings for low performers because they cannot or do not distinguish negative performance at lower levels. This hypothesis has yet to be tested empirically. Finally, these results could point to an ability factor in the assessment process in that, without training, assessors may lack the ability to distinguish low levels of performance. This ability component could be an important contextual factor in the performance appraisal domain, in addition to other factors such as politics and motivation (Levy & Williams, Reference Levy and Williams2004).

Which design elements matter?

Our results showed that the effect of setting was negligible, across different geographic locations and demographics such as age, gender, race/ethnicity, and job status. This finding is consistent with a recent meta-analysis of FOR training which found no significant moderator effects of protocol differences (such as type of participants, purpose of training, and type of training material) on FOR training effectiveness (Roch et al., Reference Roch, Woehr and Mishra2012). We also found that the assessor-nested-within-setting effect accounted for a negligible amount of variance in ratings, where differences among assessors (within settings) had little impact on the total variation in ratings. This is consistent with previous research that has found that FOR training works by imparting a shared schema of performance on trainees (Gorman & Rentsch, Reference Gorman and Rentsch2009, Reference Gorman and Rentsch2017). Our results suggest that the shared schema among FOR-trained assessors acts as a buffer that minimizes the influence of assessor idiosyncrasies on ratings. This result further strengthens the evidence in support of the efficacy of FOR training.

Further support for the suppressing effect of FOR training on assessor idiosyncrasies was evidenced in our finding that the performance level effect accounted for more variance than the combined assessor and random error effects in the FOR training condition. However, in the control training condition, the combination of assessor and random error effects accounted for more variance than the performance level effect. Again, this is consistent with scores of previous studies of FOR training effectiveness and provides additional evidence in support of the shared schema hypothesis.

Limitations and future directions

As with any study, there are possible limitations to consider. It is still possible that unmodeled variance sources may still be worth considering. For instance, the FOR training procedure implemented here were all systematic and contained the same design consistent with the extant research (Pulakos, Reference Pulakos1984; Reference Pulakos1986). However, it is unclear to what extent complete FOR procedures are implemented in practice, and which components of FOR training have the greatest effect (e.g., examples of high and low performance, practice, etc.). In addition, assessor experience could also be modeled as another factor. It is possible that more experienced assessors could provide very different ratings compared with inexperienced assessors, as were used in the present study.

Moreover, an anonymous reviewer pointed out that because we only used two stimulus episodes (one above average performance and one below average performance), there are other confounding characteristics of the managers in the videos, such as attractiveness or age, that could be responsible for our findings. Additionally, it is possible that different performance scenarios or candidates may facilitate increased sensitivity in identifying high levels of performance. Thus, future studies should model these factors using a wide variety of stimulus episodes. Another anonymous reviewer noted that sensitivity in identifying low levels of performance would be particularly helpful in a developmental AC context, but might be much less useful in a selection or promotion context, where the goal would be to differentiate among candidates with relatively high levels of performance. The implication here would be that FOR training may not be necessary in situations such as promotions, where the focus is on high performing candidates.

We also thank an anonymous reviewer for pointing out that the results of the present study raise several questions that lay the groundwork for a potentially fruitful research agenda on FOR training, including examining how FOR training influences differentiation among performance dimensions, testing whether FOR-trained assessors consistently draw lager distinctions between high and low levels of performance as a result of training, and conducting studies to determine if FOR-trained assessors are better at distinguishing among candidates with generally high levels of performance. We also thank an anonymous reviewer for pointing out that the lack of a practice video in the control condition could potentially explain why assessors in the control condition gave higher ratings for the low performance assessee. Although this procedure was consistent with prior research (Gorman & Rentsch, Reference Gorman and Rentsch2009, Reference Gorman and Rentsch2017; Hoffman et al., Reference Hoffman, Gorman, Blair, Meriac, Overstreet and Atchley2012), we cannot rule this explanation out, and we recommend that future research carefully and systematically examine the impact of different training procedures and protocols. Finally, the purpose of performance ratings could also be examined along with the aforementioned factors. For instance, administrative ratings have long been shown to be more lenient than ratings made for feedback/developmental purposes (Jawahar & Williams, Reference Jawahar and Williams1997). However, it is possible that FOR training may serve to minimize the performance appraisal purpose effect.

General conclusions

Despite several robust findings on the effectiveness of FOR assessor training, the time has come for research to move beyond questioning whether FOR training works to uncovering the boundary conditions of its effectiveness. Using a variance partitioning approach, we discovered that FOR training is most effective at helping assessors evaluate low levels of performance. We found very little difference in the ratings made by FOR-trained and control-trained assessors when the performance level of the stimulus ratee was high. This is an important and unique finding because no previous FOR training studies have explicitly modeled performance level as a factor. Our results suggest that performance level is a meaningful factor that should not only be modeled, but training protocols might also need to be tailored to focus more on negative performance and stimulus episodes should likely include a target ratee whose performance was generally negative across all dimensions. Taken together, these findings suggest that recognizing poor performance may be what makes FOR training so effective compared to other interventions.

Author note

C. Allen Gorman, Department of Management, Information Systems and Quantitative Methods and Department of Health Services Administration, University of Alabama at Birmingham. Duncan J. R. Jackson, King’s Business School, King’s College London. John P. Meriac, Department of Global Leadership and Management, University of Missouri-St. Louis. Joseph R. Himmler, Department of Psychology, Auburn University. Tanya F. Contreras, Department of Management, Information Systems and Quantitative Methods, University of Alabama at Birmingham.

A version of this paper was presented at the 2012 conference of the Society for Industrial and Organizational Psychology, San Diego, CA.

We thank Katy Gaddis, Steven Apodaca, Josh Collins, Lauren Felton, Garolyn Jergins, Ashley McIntyre, Ben Overstreet, Kenneth Smith, Jessica Stoner, Jennifer Thorndike, Soniya Lonkar, Caitlin Nugent, Erin Carroll, Jeanne Donaghy, Megan Poore, and Dave Sharrer for their assistance with data collection.

Footnotes

1 Because there were only two ratees in our analyses, one representing high performance and the other representing low performance, it was not reasonable to estimate reliability based on the results of the variance components analyses.

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Figure 0

Table 1. Dimension Intercorrelations—FOR-Trained Group

Figure 1

Table 2. Dimension Intercorrelations—Control-Trained Group

Figure 2

Figure 1. Marginal mean ratings plotted with relation to dimension observations from FOR-trained versus control-trained assessors. Dimension ratings are distinguished by being relevant to videos of low versus high performance. Since dimensions, as presented here, are nominal, lines are shown for clarity only.

Figure 3

Table 3. Factorial Analysis of Variance Comparing FOR-Trained versus Control-Trained Assessors

Figure 4

Table 4. Variance Components Analyses Comparing FOR-Trained versus Control-Trained Assessor Subgroups