1. Introduction

1.1. Analyzing the Dimensionality of O*NET Cognitive Ability Ratings to Inform Assessment Design

The Occupational Information Network (O*NET) is a program sponsored by the U.S. Department of Labor that provides information about occupations in the United States (See https://www.onetcenter.org/overview.html accessed on 20 September 2024). A key component of the program is the O*NET database, which contains standardized descriptions of approximately 1000 occupations across the U.S. For each occupation, the database includes descriptions of worker characteristics, job requirements, and information about the knowledge, skills, and abilities required for success on the job (Donsbach et al. [1]). As Haigler [2] described, O*NET represents “a free online resource for employers and educators to benchmark job requirements against data derived from job analysis” (p. 272).

O*NET provides a “content model”, which is a framework that integrates the most important types of information about work into a theoretically and empirically sound system that can be used to understand the knowledge and characteristics associated with a wide variety of jobs (Tippins and Hilton [3]). The model contains 277 descriptors, both worker-oriented (i.e., worker characteristics, worker requirements, and experience requirements) and job-oriented (i.e., occupational requirements, workforce characteristics, and occupation-specific information). These descriptors characterize the knowledge, skills, experience, and other assets needed for success across numerous occupations.

In the present study, we analyze 45 of these descriptors—21 cognitive abilities and 24 basic skills—to understand how these abilities and skills can best be measured along one or more continua related to job success. Our interest in measuring these abilities and skills stems from our involvement in the Adult Skills Assessment Program (ASAP) (see https://blogs.umass.edu/asap/ 29 October 2024) which focuses on identifying the critical aspects of literacy and numeracy that bridge the adult education and workforce communities. Like many educators working with adults in academic and workplace settings, we are interested in assessing the critical abilities and skills adults need to meet their academic and occupational goals. Our analysis of the dimensionality of these O*NET cognitive abilities and basic skills seeks to provide valuable information for understanding the constructs to be measured that are relevant to a variety of contemporary occupations.

To investigate the dimensionality of these O*NET data, we investigated two primary research questions, as follows:

• (a). What dimensions can be used to characterize the O*NET cognitive ability and basic skill descriptors? Can a single dimension be used to summarize these descriptors or are they multidimensional? Specifically, will we uncover separate dimensions for the cognitive abilities and basic skills?

• (b). Do these ability/skill dimensions vary across O*NET job zones? That is, is the dimensionality of the data invariant across jobs that differ with respect to skills and experience or are separate dimensions needed for each job zone?

Our investigation of the first research question aims to refine our understanding of the underlying structure of the data to understand whether the cognitive and basic skills deemed important for various jobs represent multidimensional or unidimensional constructs. By conducting dimensionality analyses, we lay the groundwork for robust conceptualization and construct definition, which are necessary to accurately and authentically measure and assess workforce skills and competencies.

Our second research question focuses on identifying potential variations across O*NET job zones. This analysis is important in determining whether the dimensionality of the data remained consistent across diverse jobs characterized by varying skill sets and levels of experience. Understanding whether separate dimensions were required for each job zone or if a consistent dimensionality could be applied across all zones is important for understanding how assessments may need to be tailored to specific occupational contexts.

1.2. Use of O*NET Data in Previous Research

To address these questions, we built on previous research conducted using O*NET data to better understand characteristics of occupations in the U.S. Although a full review of the O*NET literature is beyond the scope of the current article, we note O*NET data have been used to relate job characteristics to health outcomes (Cifuentes et al. [4]); improve the predictive validity of personality assessments used in work settings [5]; cluster occupations based on their knowledge characteristics and identify regional trends in occupational knowledge [6,7]; develop machine learning models to predict changes in employment and skill demands over time [8]; and investigate sex differences in labor attrition [9]. As Lewandowski et al. [10] put it when they analyzed international work trends, “no other sources offer as rich and detailed data on occupations as O*NET” (p. 2).

Haigler [2], for example, described how O*NET was used to align knowledge, skills, and abilities (KSAs) in adult education with competencies needed in the workplace. Thompson and Koys [11] demonstrated how programs could leverage O*NET data to empirically define learning outcomes for learners similar to how they are defined for business management curricula. Homan and Sandall [12] similarly performed an undergraduate curriculum needs assessment that leveraged O*NET data. In the context of informing English language adult education, Oliveri and McCulla [13] used O*NET data to identify the English communication tasks common within different levels of preparation required for employment.

With respect to understanding the structure of O*NET data, Burrus et al. [14] used principal components analysis (PCA) to analyze the dimensionality of the 136 variables included in the database that described worker characteristics (abilities, work styles, skills, and knowledge). They found 15 factors relevant for describing the dimensionality of the data, and concluded that the following five factors were most important for all occupations: problem-solving (e.g., complex problem-solving), fluid intelligence (e.g., category flexibility), teamwork (e.g., cooperation), achievement/innovation (e.g., persistence), and communication skills (e.g., oral expression). Their findings underscore the importance of these core competencies in driving success and effectiveness across diverse job roles and industries. Few studies of this kind have been conducted. In the current study, we address this paucity in the literature by examining the structure of a subset of O*NET to provide valuable insights into the key dimensions that underpin workforce contexts, in order to inform more authentic and relevant assessment practices.

Our study also sought to determine if our analysis would uncover dimensions akin to those identified in prior research (e.g., problem-solving, fluid intelligence, achievement, teamwork, and communication; see Burrus et al. [14]), using multidimensional scaling (MDS), which is known to capture data structure in fewer dimensions than traditional factor analysis [15]. If our findings replicate those of previous studies, it suggests a robustness in the fundamental dimensions crucial for workplace success and provides empirical support for integrating these dimensions into task design aimed at assessing similar KSAs vital for effective cross-industry workplace performance.

2. Method

In this section, we describe some characteristics of the O*NET database and how we extracted occupational data for analysis. We then describe the analyses conducted.

2.1. Description of O*NET Data

The data analyzed here come from the O*NET 26.1 Database [16]. The O*NET database specifies various kinds of KSAs and their required competency levels and relative importance in over 800 occupations. The O*NET Data Collection Program starts with occupational definitions from the Standard Occupational Classification system, a United States federal framework for classifying workers and occupations [17]. To gather information about each occupation, the program polls samples of workers in those occupations and subject matter experts (e.g., members of trade associations and analysts), asking them to rate how important various KSAs are to the occupation, and at what level the occupation requires. The level rating indicates the degree, or point along a continuum, to which a particular descriptor is required or needed to perform the occupation. The importance rating indicates the degree of importance a particular descriptor is to the occupation. For our focus on importance, the possible ratings range from “Not Important” (1) to “Extremely Important” (5). Additional information is collected about the work context, activities, and worker respondent’s background [18].

In the most recent O*NET data file release [16], the experts’ ratings of 120 KSAs across 873 occupational roles are summarized. Of those KSAs, there are 21 cognitive abilities and 24 basic skills, which are the focus of this study. The cognitive skills are presented in Table 1, and the basic skills are presented in Table 2, along with a brief description of each. We selected these abilities and skills given our interest in developing numeracy and literacy assessments that bridge adult education and workplace settings. These selected cognitive abilities and basic skills are paramount in adult education curricula, job training programs, and workforce development. Thus, assessments of these abilities and skills are necessary for upskilling adult learners. Moreover, the dimensionality of these targeted abilities and skills must be known for assessment design and result reporting, given that O*NET has identified these cognitive abilities and basic skills as important for and relevant to different classes of jobs in the U.S. A better understanding of how these abilities relate to one another across substantively different occupations should inform the development of assessment frameworks for measuring important numeracy and literacy competencies relevant to both adult educators and employers.

O*NET also classifies the 873 occupations according to five “job zones”. The job zones range from 1 to 5, with occupations needing no or little preparation coded as 1, and occupations needing extensive preparation coded as 5. The job zone descriptions are presented in Table 3. These job zones are very helpful for broadly classifying the huge number of occupations across the U.S. into categories that are similar with respect to requisite KSAs, experience, and other requirements.

2.2. Data Extraction

For each cognitive ability and basic skill (Table 1 and Table 2), the O*NET database provides the mean importance and level ratings across experts. We used the mean importance rating for each cognitive ability to compute a dissimilarity matrix across these 45 skills and abilities. Euclidean distances were computed across each pair of ability/skill by summing the squared differences in the mean importance ratings for each pair across all occupations, as follows:

(1)${\delta }_{j{j}^{\prime }}=\sqrt{{\sum }_{i=1}^N{(u_{ij}-{u_{ij}}^{\prime })}^2}$

As indicated in the second research question, we were interested in the consistency of the dimensionality of the ability/skill space across job zones. Thus, in addition to computing an overall dissimilarity matrix across all job zones, we computed a separate matrix for each of the five job zones. There were 32 jobs in job zone 1, 278 in job zone 2, 208 in job zone 3, 200 in job zone 4, and 155 in job zone 5. Given the number of jobs in each zone differed across zones, we divided the summed differences across job zones to put the distances on the same scale, as follows:

(2)${\delta }_{j{jk}^{\prime }}=\sqrt{{\displaystyle \frac{{\sum }_{i=1}^{N_k}{(u_{ij}-{u_{ij}}^{\prime })}^2}{N_k}}}$

2.3. Weighted Multidimensional Scaling Analyses

We analyzed the ability/skill dissimilarity matrices using multidimensional scaling (MDS). MDS is a non-linear, exploratory procedure that can be used for single- or multi-group analyses. When applied to a single group, the matrix of observed item dissimilarities is modeled in 1, 2, …, or R-dimensional space as follows:

(3)$d_{{jj}^{\prime }}=\sqrt{{\sum }_{r=1}^R{\left(x_{jr}-x_{j^{\prime }r}\right)}^2}$

To analyze the data simultaneously across all five job zone matrices, we used the INDSCAL model [19], which incorporates a weight on each dimension for each matrix, as follows:

(4)$d_{{jj}^{\prime }}=\sqrt{{\sum }_{r=1}^R{w}_{kr}{\left(x_{jr}-x_{j^{\prime }r}\right)}^2}$

Weighted MDS solutions provide a multidimensional configuration that best fits the data for all groups when considered simultaneously, and a matrix of group weights (with elements $w_{kr}$) that represent how this configuration should be adjusted to best fit the data for a particular group (k). Thus, the weights ($w_{kr}$) contain the information regarding differences in dimensionality (if any) across job zones. If a similar pattern of weights is observed across job zones, the same dimensions can be used to account for the dimensionality of the cognitive abilities. That is, similar weights across groups suggest invariance in the dimensionality of the data across groups, while differences between group weights indicate differences in dimensionality across groups. Using simulated data, Sireci, Bastari, and Allalouf [20] found that, when structural differences existed across groups, one or more groups had weights near zero on one or more dimensions relevant to at least one other group.

Two- through five-dimensional weighted MDS solutions were applied to the data across the five job zones (using SPSS version 28.0). Weights are not relevant to a one-dimensional model; therefore, a replicated MDS analysis [21] was used to fit a one-dimensional solution across the job zones.

To assess the fit of the MDS solutions we used the following fit measures: Stress, which is a normalized measure of misfit ranging from zero (perfect fit) to one, and R², which represents the proportion of variance accounted for in the (transformed) inter-cognitive ability distances by the MDS solution. Smaller values of Stress and larger values of R² indicate a better fit. A key criterion in evaluating fit is a relatively large decrease in Stress across adjacent solutions [22].

3. Results

The mean ratings for each of the 45 cognitive abilities and basic skills for each job zone are presented in Table 4, in descending order according to mean ratings for job zone 1. These ratings come from the samples of workers and subject matter experts involved in rating the importance of these knowledge and skills in the creation of the O*NET database [16].

Fit and Selection of Dimensionality

Table 5 presents the Stress and R² fit measures for the overall solution and for each job zone matrix. The largest improvement in fit occurred between the unidimensional solution and the two-dimensional solution. Only job zone 3 appears to adequately fit in the 1D solution. The two-dimensional solution fit the data well overall, accounting for 92% of the variation in the transformed dissimilarity data. All job zones had Stress values under 2.0 and R² at or above 0.89. We inspected the higher-dimensional solutions and noted some differentiation in the weights associated with job zones 4 and 5 in the four-dimensional solution, but we ultimately concluded the two-dimensional solution was best in terms of parsimoniously capturing the substantive dimensionality across job zones. Therefore, the two-dimensional solution was selected as the best representation of the data. We now turn to interpreting the stimulus (cognitive ability and skill) space, as well as the weight (job zone) space.

Figure 1 displays the skill space for the two-dimensional weighted MDS solution. The horizontal dimension separates skills and abilities that deal with some kind of social interaction (e.g., oral communication, oral expression) from skills and abilities that are more associated with more independent reasoning (e.g., science, spatial orientation, management). It also pulls cognitive abilities and skills rated very low for job zones 1 and 2 (e.g., science, management of financial resources) away from those rated more important for these job zones. The vertical dimension orders the skills and abilities along a verbal (e.g., written comprehension, reading comprehension) versus non-verbal (e.g., spatial orientation, visualization) continuum. Interestingly, separate dimensions for the cognitive abilities and skills did not emerge. These results suggest the general areas of social interaction, reasoning, verbal, and non-verbal information would be important constructs to measure (and to teach!) for adults seeking employment.

The job zone weight space for the two-dimensional solutions is presented in Figure 2. The weight vectors for job zones 1 and 2 indicate dimension 1 (Social Interaction vs. Reasoning), which essentially accounts for all of the variation in the (transformed) similarities among the mean skill importance ratings. For job zones 4 and 5, it is dimension 2 (Verbal vs. Non-Verbal) that accounts for almost all of the variation in the data. Job zone 3 appears to be the only one that requires both dimensions to account for the variation in mean skill importance ratings.

To facilitate the interpretation of the dimensions, we correlated the MDS coordinates with the mean importance ratings of the cognitive abilities and skills presented in Table 4. These correlations are presented in Table 6. The mean ratings for job zones 3, 4, and 5 exhibited extremely large negative correlations with the dimension 1 coordinates, ranging from −0.92 (job zone 3) to −0.99. This reflects the fact that the cognitive abilities and skills most related to “social interaction” (the negative or left side of the figure) were rated more highly in these job zones. The coordinates of dimension 2 exhibited extremely large negative correlations with job zones 1 and 2 (r = −0.99), as well as job zone 3 (r = −0.92). This finding suggests that the cognitive abilities and skills more related to verbalization and language-based skills had relatively high mean ratings.

4. Discussion

In this study, we analyzed the mean importance ratings for 45 cognitive abilities and basic skills across 873 jobs listed in the O*NET database. We were interested in the dimensionality of these data; specifically, what dimensions could be used to summarize these skills and how these dimensions might differ across job zones.

The results suggested that two dimensions—Social Interaction/Reasoning and Verbal/Non-Verbal—sufficiently characterized the structure of these data across all five job zones. Interestingly, the importance of these dimensions in capturing the structure was not consistent across job zones. The Social Interaction/Reasoning dimension accounted for the structure of the mean importance ratings for job zones 1 and 2, which makes sense because those job zones require less education and experience (see Table 3), which likely require more reasoning skills. The structure of the mean importance ratings for job zones 4 and 5 was essentially accounted for by the Verbal/Non-Verbal dimension, meaning the differences between ratings were best described by the extent to which skills were language-based. This observation corroborates the intuition that these job zones require the acquisition and application of skills such as scientific knowledge and other specialized information-processing skills, which are typically acquired through post-secondary and post-college academic training. Job zone 3, which requires training and experience that is more “on-the-job” than academic, required both dimensions to adequately fit the mean importance ratings.

These results suggest assessments targeted at KSAs associated with job zones 1 and 2 should focus on basic social interactive and reasoning skills, while assessments focused on job zones 4 and 5 would need to assess verbal and non-verbal skills that are likely to fall into advanced math, science, and specialized areas. Assessments for job zone 3 would likely require measurement of communicating, reasoning, and more specialized processing skills.

Burrus et al. [14] used principal components analysis to analyze the dimensionality of 136 O*NET worker characteristic variables and concluded that the following five factors were most important for all occupations: problem-solving, fluid intelligence (e.g., category flexibility), teamwork, achievement/innovation, and communication skills. Our analyses involved only a subset of O*NET variables related to cognitive abilities and basic skills, but the dimensions we uncovered similarly distinguished skills related to problem-solving, fluid intelligence, achievement, and communication. These dimensions reflect skills essential for workplace readiness and preparation (e.g., problem-solving, fluid intelligence, achievement, and communication), which are broader than basic math and literacy skills. Although automation may transform the world of work for routine tasks, it is less helpful for non-routine abstract tasks, such as creative problem-solving. Thus, these findings underscore the importance of skills aligned with completing non-routine tasks.

One interesting finding is that our analysis of both cognitive abilities and selected skills did not yield a dimensional solution that differentiated these abilities and skills from each other. This outcome likely reflects the fact that the basic skills we selected from O*NET draw upon these cognitive abilities.

MDS illustrates the potential for advancing our understanding of the nuanced relationships between various dimensions of workplace competencies and devising more effective assessment strategies tailored to the evolving demands of the modern workforce. To illustrate, for numeracy assessments, recognizing multiple dimensions beyond basic arithmetic could enable the inclusion of several related yet unique dimensions associated with an expanded construct model, which might require assessing additional skills (e.g., data interpretation, problem-solving, and decision-making skills). Assessments solely focused on arithmetic operations would overlook these critical competencies essential for successful workplace functioning. By incorporating multiple dimensions, numeracy assessments become more comprehensive, providing a holistic evaluation of workers’ abilities to analyze and apply numerical information in diverse contexts.

Similarly, in literacy assessments, acknowledging multiple dimensions beyond reading and writing could help ensure assessments reflect the multifaceted literacy skills needed in the workplace. Tasks that solely measure reading comprehension may overlook workers’ abilities to interpret technical documents, follow instructions, communicate effectively, and collaborate with colleagues. By assessing multiple dimensions, literacy assessments encompass a broader range of skills essential for navigating complex workplace environments.

Overall, by identifying and incorporating multiple dimensions into literacy and numeracy assessments, we ensure assessments accurately reflect the diverse skill sets needed for effective workplace performance, leading to better alignment between assessed skills and job requirements.

5. Limitations and Suggestions for Future Research

This study analyzed O*NET data for the purpose of understanding the dimensionality of the worker characteristic space underlying various jobs. Our study had several limitations, perhaps the most significant of which was restricting our selection to only 45 skills, which is a small subset of the 136 knowledge, skills, abilities, aspirations, and other variables included in the O*NET database. However, our exclusion of physical skills and abilities helped focus the dimensional scaling for the purpose of cognitive assessment. That is, uncovering where physical, psychomotor, and sensory abilities are in relation to cognitive abilities would not be of interest for inclusion where assessment is not intended or equipped to assess physical ability. Nevertheless, future research may benefit from incorporating all O*NET descriptor variables into the analysis, especially for those interested in comprehensively understanding the overall structure of these descriptors rather than solely focusing on those amenable to educational intervention. Additionally, exploring alternative methodologies, such as simulations, virtual reality environments, and job task simulations, could provide richer insights into the multidimensional nature of workplace skills. Moreover, longitudinal studies tracking the development and evolution of skills over time, as well as cross-cultural comparisons, could offer further depth to our understanding of workforce competencies. By embracing diverse approaches and methodologies, future research can advance our understanding of multidimensional skills and inform the design of more effective interventions and assessment strategies tailored to the complex demands of the contemporary workplace.

Footnotes

Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

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Figure 1. Two-dimensional MDS solution for cognitive ability and skill space. Notes: ActLrn = active learning, ActLstn = active listening, CatFlex = category flexibility, Coor = coordination, CPS = complex problem-solving, CrTh = critical thinking, DedR = deductive reasoning, FlexCl = flexibility of closure, IdeaFlu = fluency of ideas, IndR = inductive reasoning, InfOr = information ordering, Instr = instructing, JDM = judgment and decision-making, LrnStr = learning strategies, MathR = mathematical reasoning, Maths = mathematics, Mem = memorization, MFR = management of financial resources, MMR = management of material resources, Mntr = monitoring, MPR = management of personnel resources, Neg = negotiation, NumFac = number facility, OralCo = oral comprehension, OralEx = oral expression, Orig = originality, PercSp = perceptual speed, Pers = persuasion, ProbSen = problem sensitivity, RC = reading comprehension, Sci = science, SelAtt = selective attention, SoPer = social perceptiveness, SpClosr = speed of closure, Speak = speaking, SpO = spatial orientation, SrvOr = service orientation, SysA = systems analysis, SysE = systems evaluation, TimeM = time management, TmShr = time sharing, WrCo = written comprehension, WrEx = written expression, Write = writing, Viz = visualization.

Enlarge this image.

Figure 2. Job zone weight space from two-dimensional MDS solution.

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