Research Byte: Lets hear it (again) for #visual-spatial (#Gv) #workingmemory (#Gwm) and math #reasoning (#Gf-RQ) — #CHC #SPED #EDPSY #schoolpsychology #schoolpsychologist #WJV

From Spatial Construction to Mathematics: Exploring the Mediating Role of Visuospatial Working Memory.  Developmental Psychology.  An open access article that can be downloaded—Click here.

Yuxin Zhang, Rebecca Bull, and Emma C. Burns.

Abstract

This study examined the longitudinal pathways from early spatial skills at 5 and 7 years to their mathematics reasoning abilities at 17 years in a large cohort sample (N = 16,338) from the Millennium Cohort Study. Children were assessed at four time points: Sweep 3 (Mage = 5.29), Sweep 4 (Mage = 7.23), Sweep 5 (Mage = 11.17), and Sweep 7 (Mage = 17.18), with measures including spatial construction skills, visuospatial working memory, mathematics achievement, and mathematics reasoning skills. Path analyses revealed that spatial construction at age 5 directly predicted mathematics achievement at age 7 after accounting for sex, age, socioeconomic status, vocabulary, and nonverbal reasoning ability. Furthermore, spatial construction at 5 and 7 years was directly associated with mathematics reasoning skills at 17, and spatial working memory at age 11 partially mediated this relationship. Notably, the direct effects of spatial construction on mathematics reasoning at age 17 remained significant and robust after accounting for the mediator and covariates. These findings highlight the potential value of early spatial construction skills as predictors of subsequent mathematical development over the long term.

Public Significance Statement.Children with stronger spatial skills at age 5 are more likely to achieve higher scores in mathematics at ages 7 and 17. Visuospatial working memory partly explained this link, and early spatial skills showed a direct and robust association with later mathematics. This study identified early spatial skills as an important long-term predictor of mathematics from preschool through adolescence. The findings highlight the potential of infusing spatial thinking and using spatial strategies to better understand and solve mathematics problems.

Click on image for easier viewing

Comment:  I recently made a post regarding research that demonstrated the importance of visual-spatial working memory abilities for spatial navigation where I also mentioned the new (not yet online as far as I know) WJ V Visual Working Memory test, which was decades in development—an interesting test development “back story”.  

Research Byte: Development of #Arithmetic Across the #Lifespan: A Registered Report. - #Gq #CHC #Gwm #EF #Gs #schoolpsychology #SPED #SLD

Click on image to enlarge for easy viewing

Development of Arithmetic Across the Lifespan: A Registered Report.  

Open access paper available at Developmental Psychology journal.  Click here to access

Abstract

 

Arithmetic skills are needed at any age. In everyday life, children to older adults calculate and deal with numbers. The processes underlying arithmetic seem to change with age. From childhood to younger adulthood, children get better in domain-specific numerical skills such as place-value processing. From younger to older adulthood, domain-general cognitive skills such as working memory decline. These skills are needed for complex arithmetic such as addition with carrying and subtraction with borrowing. This study investigates how the domain-specific (number magnitude, place-value processing) and domain-general (working memory, processing speed, inhibition) processes of arithmetic change across the lifespan. Thereby, arithmetic effects (carry and borrow effects), numerical effects (distance and compatibility effects), and cognitive skills were assessed in children, younger and older adolescents, and younger, middle-aged and older adults. The results showed that numerical and arithmetic skills improve from childhood to young adulthood and remain relatively stable throughout adulthood, even though domain-general pro-cesses, particularly working memory and processing speed, decline with age. While number magnitude and place-value processing both develop until adulthood, number magnitude processing shows deficits during aging, whereas place-value processing remains intact even in old age. The carry effect shifts from a categorical all-or-none decision (whether or not a carry operation is needed) to a more continuous magnitude process in adulthood, reflecting increasing reliance on domain-specific skills. In contrast, the borrow effect remains largely categorical across all age groups, depending on general cognitive processes. These results provide critical insights into how arithmetic skills change over the lifespan, relying on both domain-specific and domain-general processes.

Public Significance Statement 

Numerical and arithmetic skills improve significantly during school and are mostly preserved throughout adulthood—despite a decline in cognitive skills such as working memory and processing speed during aging. When facing complex arithmetic, all—from children up to older adults—need longer to calculate, but lifelong experience helps in dealing with arithmetic complexity. Throughout the lifespan, arithmetic requires both cognitive skills as well as numeric skills.

Research Byte: Beyond Individual #Tests: Youths’ #Cognitive Abilities, Basic #Reading, and #Writing—relevant to #schoolpsychologists #CHC

An impressive multiple test-battery CHC theory cognitive and achievement (cross-battery) confirmatory factor analysis study based on a research design first conceptualized by Jack McArdle (planned missing data reference variable design) that finds that multiple broad CHC abilities are important in explaining reading and writing achievement above and beyond psychometric g.  Of course, the results would be different if a bi-factor model were run (see McGrew et al., 2023 for discussion of three major classes of cognitive-achievement CFA/SEM research designs).  

Click here to download/read this open access articles. 

This research group, IMHO, does some of the best CFA/SEM modeling in the assessment and school psychology literature.

Click on images to enlarge for easier viewing.

Beyond Individual Tests: Youths’ Cognitive Abilities, Basic Reading, and Writing 

by 

Jacqueline M. Caemmerer

 1,*, 

Audrey M. Scudder

 1, 

Timothy Z. Keith

 2 and 

Matthew R. Reynolds

 3

1

Department of Educational Psychology, University of Connecticut, Storrs, CT 06268, USA

2

Department of Educational Psychology, University of Texas at Austin, Austin, TX 78712, USA

3

Department of Educational Psychology, University of Kansas, Lawrence, KS 66045, USA

*

Author to whom correspondence should be addressed. 

J. Intell. 2024, 12(11), 120; https://doi.org/10.3390/jintelligence12110120

Abstract

Broadly, individuals’ cognitive abilities influence their academic skills, but the significance and strength of specific cognitive abilities varies across academic domains and may vary across age. Simultaneous analyses of data from many tests and cross-battery analyses can address inconsistent findings from prior studies by creating comprehensively defined constructs, which allow for greater generalizability of findings. The purpose of this study was to examine the cross-battery direct effects and developmental differences in youths’ cognitive abilities on their basic reading abilities, as well as the relations between their reading and writing achievement. Our sample included 3927 youth aged 6 to 18. Six intelligence tests (66 subtests) and three achievement tests (10 subtests) were analyzed. Youths’ general intelligence (g, large direct and indirect effects), verbal comprehension–knowledge (large direct effect), working memory (large direct effect), and learning efficiency (moderate direct effect) explained their basic reading skills. The influence of g and fluid reasoning were difficult to separate statistically. Most of the cognitive–basic reading relations were stable across age, except the influence of verbal comprehension–knowledge (Gc), which appeared to slightly increase with age. Youths’ basic reading had large influences on their written expression and spelling skills, and their spelling skills had a large influence on their written expression skills. The directionality of the effects most strongly supported the direct effects from the youths’ basic reading to their spelling skills, and not vice versa.

Keywords: 

intelligence; academic; achievement; spelling; moderation; mediation

CHC taxonomy of human cognitive abilities v 2.5: A silent movie animationed presentation

 An oldie but goodie prior post.

 

Implications of 20 Years of CHC Cognitive-Achievement Research: Back-to-the-Future and Beyond CHC

[Click image to enlarge]

 

The key slides from my presentation at the first Richard Woodcock Institute on Cognitive Assessment are now posted at SlideShare.  I thought I had posted these before, but I can't seem to find them.  So here they are for the first (or second) time.  Below is the abstract for the paper that I also submitted--to be published eventually by the WMF Press.

Much has been learned about CHC CHC COG-->ACH relations during the past 20 years (McGrew & Wendling’s, 2010).  This paper built on this extant research by first clarifying the definitions of abilities, cognitive abilities, achievement abilities, and aptitudes.  Differences between domain-general and domain-specific CHC predictors of school achievement were defined.   The promise of Kafuman’s “intelligent” intelligence testing approach was illustrated with two approaches to CHC-based selective referral-focused assessment (SRFA).  Next, a number of new intelligent test design (ITD) principles were described and demonstrated via a series of exploratory data analyses that employed a variety of data analytic tools (multiple regression, SEM causal modeling, multidimensional scaling).  The ITD principles and analyses resulted in the proposal to construct developmentally-sensitive CHC-consistent scholastic aptitude clusters, measures that can play an important role in contemporary third method (pattern of strength and weakness) approaches to SLD identification. 

The need to move beyond simplistic conceptualizations of COG COG-->ACH relations and SLD identification models was argued and demonstrated via the presentation and discussion of CHC COG-->ACH causal SEM models.  Another example was the proposal to identify and quantify cognitive-aptitude-achievement trait complexes (CAATCs).  A revision in current PSW third-method SLD models was proposed that would integrate CAATCs.  Finally, the need to incorporate the degree of cognitive complexity of tests and composite scores within CHC domains in the design and organization of intelligence test batteries (to improve the prediction of school achievement) was proposed.  The various proposals presented in this paper represented a mixture of (a) a call to return to old ideas with new methods (Back-to-the-Future) or (b) the embracing of new ideas, concepts and methods that require psychologists to move beyond the confines of the dominant CHC taxonomy of human cognitive abilities (i.e., Beyond CHC).

AP101 Brief # 16: Beyond CHC: Within-CHC Domain Complexity Optimized Measures

[Note:  This is a working draft of a larger paper (Implications of 20 years of CHC Cognitive-Achievement Research:  Back-to-the-future and Beyond CHC) that will be presented at the first Inaugural Session of the Richard Woodcock Institute for Advancement of Contemporary Cognitive Assessment at Tufts University (Sept, 29, 2012):  The Evolution of CHC Theory and Cognitive Assessment).]   Working knowledge of the WJ III test batery will make this brief easier to understand, but is not necessary.

Beyond CHC:  ITD—Within-CHC Domain Complexity Optimized Measures

            Optimizing Cognitive Complexity of CHC measures

I have recently begun to recognize the contribution that The Brunswick Symmetry derived Berlin Intelligence Structure (BIS) model can make in applied intelligence research, especially for increasing predictor-criteria relations by maximizing these relations via matching the predictor-criteria space on the dimension of cognitive complexity.  What is cognitive complexity?  Why is it important?  More important, what role should it play in designing intelligence batteries to optimize CHC COG-ACH relations?

Cognitive complexity is often operationalized by inspecting individual test loadings on the first principal component from principal component analysis (Jensen, 1998).  The high g-test rationale is that performance on tests that are more cognitively complex “invoke a wider range of elementary cognitive processes (Jensen, 1998; Stankov, 2000, 2005)” (McGrew, 2010b, p. 452).  High g-loading tests are often at the center of MDS (multidimensional scaling) radex models (click here for AP101 Brief Report #15:  Cognitive-Aptitude-Achievement Trait Complexes example)—but this isomorphism does not always hold.   David Lohman, a student of Richard Snow’s, has made extensive use of MDS methods to study intelligence and has one of the best grasps of what cognitive complexity, as represented in the hyperspace of MDS figures, contributes to understanding intelligence and intelligence tests.  According to Lohman (2011), those tests closer to the center are more cognitively complex due five possible factors—larger number of cognitive component processes; accumulation of speed component differences: more important component processes (e.g., inference); increased demands of attentional control and working memory; and/or or more demands on adaptive functions (assembly, control, and monitoring).  Schneider’s (in press) level of abstraction description of broad CHC factors is similar to cognitive complexity.  He uses the simple example of 100 meter hurdle performance.  According to Schneider (in press), one could independently measure 100 meter sprinting speed and then standing still and jumping over a hurdle (both examples of narrow abilities).  However, running a 100 meter race is not the mere sum of the two narrow abilities and as is more of a non-additive combination and integration of narrow abilities.  This analogy captures the essence of cognitively complexity—which, in the realm of cognitive measures, are tasks that have more of the five factors listed by Lohman involvedduring successful task performance.

Of critical importance is the recognition that factor or ability domain breadth (i.e., broad or narrow) is not synonymous with cognitively complexity.  More important, cognitive complexity has not always been a test design concept (as defined by the Brunswick Symmetry and BIS model) explicitly incorporated into "intelligent" intelligence test design (ITD).  A number of tests have incorporated the notion of cognitive complexity in their design plans, but I believe this type of cognitive complexity is different than the within-CHC domain cognitive complexity discussed here.

For example, according to Kaufman and Kaufman (2004), “in developing the KABC-II, the authors did not strive to develop ‘pure’ tasks for measuring the five CHC broad abilities.  In theory, Gv tasks should exclude Gf or Gs, for example, and tests of other broad abilities, like Gc or Glr, should only measure that ability and none other.  In practice, however, the goal of comprehensive tests of cognitive ability like the KABC-II is to measure problem solving in different contexts and under different conditions, with complexity being necessary to assess high-level functioning” (p. 16; italics emphasis added).  Although the Kaufman’s address the importance of cognitively complex measures in intelligence test batteries, their CHC-grounded description defines complex measures as those that are factorially complex or mixed measures of abilities from more than one broad CHC domain.  The Kaufman’s also address cognitive complexity from the non-CHC neurocognitve three-block functional Luria neurocognitive model when they indicate that it is important to provide measurement that evaluates the “dynamic integration of the three blocks” (Kaufman & Kaufman, 2004, p.13).   This emphasis on neurocognitive integration (and thus, complexity) is also an explicit design goal of the latest Wechsler batteries.  As stated in the WAIS-IV manual (Wechsler, 2008), “although there are distinct advantages to the assessment and division of more narrow domains of cognitive functioning, several issues deserve note.  First, cognitive functions are interrelated, functionally and neurologically, making it difficult to measure a pure domain of cognitive functioning” (p. 2).  Furthermore, “measuring psychometrically pure factors of discrete domains may be useful for research, but it does not necessarily result in information that is clinically rich or practical in real world applications (Zachary, 1900)” (Wechsler, p. 3).   Finally, Elliott (2007) similarly argues for the importance of recognizing neurocognitive-based “complex information processing” (p. 15; italics emphasis added) in the design of the DAS-III, which results in tests or composites measuring across CHC-described domains, as important in test design.

The ITD principle explicated and proposed here is that of striving to develop cognitively complex measures within broad CHC domains—that is, not attaining complexity via the blending of abilities across CHC broad domains and not attempting to directly link to neurocognitive network integration.[1]   The Brunswick Symmetry based BIS model provides a framework for attaining this goal via the development and analysis of test complexity by paying attention to cognitive content and operations facets. 

Figure 12 presents the results of a 2-D MDS Radex model of most all key WJ III broad and narrow CHC cognitive and achievement clusters (for all norm subjects from approximately 6 years of age thru late adulthood). [2]   The current focus of the interpretation of the results in Figure 12 is only on the degree of cognitive complexity (proximity to the center of the figure) of the broad and narrow WJ III clusters within the same domain (interpretations of the content and operations facets are not a focus of this current material).  Within a domain the broadest three-test parent clusters are designated by black circles.[3]  Two-test broad clusters are designed by gray circles.  Two test narrow offspring clusters within broad domains are designated by white circles.  All clusters within a domain are connected to the broadest parent broad cluster by lines.  The critically important information is the within-domain cognitive complexity of the respective parent and sibling clusters as represented by their relative distances from the center of the figure.  A number of interesting conclusions are apparent. [Click on image to enlarge]

First, as expected, the WJ III GIA-Ext cluster is almost perfectly centered in the figure—it is clearly the most cognitively complex WJ III cluster.   In comparison, the three WJ III Gv clusters are much weaker in cognitive complexity than all other cognitive clusters with no particular Gv cluster demonstrating a clear cognitive complexity advantage.    As expected, the measured reading and math achievement clusters are primarily cognitively complex measures.  However, those achievement clusters that deal more with basic skills (Math Calculation—MTHCAL; Basic Reading Skills—RDGBS) are less complex that the application clusters (Reading Comprehension-RDGCMP; Math Reasoning-MTHREA). 

The most intriguing findings in Figure 12 are the differential cognitive complexity patterns within CHC domains (with at least one parent and at least one offspring cluster).  For example, the narrow Perceptual Speed (Gs-P) offspring cluster is more cognitively complex than the broad parent Gs cluster.  The broad Gs cluster is comprised of the Visual Matching (Gs-P) and Decision Speed (Gs-R9; Glr-NA) tests, tests that measure different narrow abilities.  In contrast the Perceptual Speed cluster (Gs-P) is comprised of two tests that are classified as both measuring the same narrow ability (perceptual speed).  This finding appears, on first blush, counterintuitive as one would expect a cluster comprised of tests that measure different content and operations (Gs cluster) would be more complex (as per the above definition and discussion) than one comprised of two measures of the same narrow ability (Gs-P).  However, one must task analyze the two Perceptual Speed tests to realize that although both are classified as measuring the same narrow ability (perceptual speed), they differ in both stimulus content and cognitive operations.  Visual Matching requires processing of numeric stimuli.  Cross Out requires the processing of visual-figural stimuli.  These are two different content facets in the BIS model.  The Cross Out visual-figural stimuli are much more spatially challenging than the simple numerals in Visual Matching.  Furthermore, the Visual Matching test requires the examinee to quickly seek out and discover and mark two digit pairs that are identical.  In contrast, in the Cross Out test the subject is provided a target visual-figural shape and the subject must then quickly scan a row of complex visual images and mark two that are identical to the target.  Interesting, in other unpublished  analyses I have completed, the Visual Matching test often loads on or groups with quantitative achievement tests while Cross Out has frequently show to load on a Gv factor.  Thus, task analysis of the content and cognitive operations of the WJ III Perceptual Speed tests suggests that although both are classified as narrow indicators of Gs-P, they differ markedly in task requirements.  More important, the Perceptual Speed cluster tests, when combined, appear to require more cognitively complex processing than the broad Gs cluster.  This finding is consistent with Ackerman, Beier and Boyle’s (2002) research that suggests that perceptual speed has another level of factor breadth via the identification of four subtypes of perceptual speed (i.e., pattern recognition, scanning, memory and complexity; see McGrew 2005 and Schneider & McGrew, 2012 for discussion of a hierarchically organized model of speed abilities).  Based on Bruinswick Symmetry/BIS cognitive complexity principles, one would predict that a Gs-P cluster comprised of two parallel forms of the same task (e.g., two Visual Matching or two Cross Out tests) would be less cognitively complex than broad Gs.  A hint of the possible correctness of this hypothesis is present in the inspection of the Gsm-MS-MW domain results.

The WJ III Gsm cluster is the combination of the Numbers Reversed (MW) and Memory for Words (MS) tests.  In contrast, the WJ III Auditory Memory Span cluster (AUDMS; Gsm-MS) cluster is much less cognitively complex when compared to Gsm (see Figure 12).  Like the Perceptual Speed (Gs-P) cluster described in the context of the processing speed family of clusters, the Auditory Memory Span cluster is comprised of two tests with the same memory span (MS) narrow ability classification (Memory for Words; Memory for Sentences).  Why is this narrow cluster less complex than its broad parent Gsm cluster while the opposite held true for Gs-P and Gs?  Task analysis suggests that the two memory span tests are more alike than the two perceptual speed tests.  The Memory for Words and Memory Sentences tests require the same cognitive operation—simply repeating back, in order, words or sentences spoken to the subject.  This differs from the WJ III Perceptual Speed cluster as the similarly classified narrow Gs-P tests most likely invoke both common and different cognitive component operations.  Also, the Memory Span cluster tests are comprised of stimuli from the same BIS content facet (i.e., words and sentences; auditory-linguistic/verbal).  In contrast, the Gs-P Visual Matching and Cross Out tests involve two different content facets (numeric and visual-figural).

In contrast, the WJ III Working Memory cluster (Gsm-MW) is more cognitively complex than the parent Gsm cluster.  This finding is consistent with the prior WJ III Gs/Perceptual Speed and WJ III Gsm/Auditory Memory Span discussion.  The WJ III Working Memory cluster is comprised of the Numbers Reversed and Auditory Working Memory tests.  Numbers Reversed requires the processing of stimuli from one BIS content facet—numeric stimuli.  In contrast, Auditory Working Memory requires the processing of stimuli from two BIS content factors—numeric and auditory-linguistic/verbal; numbers and words).  The cognitive operations of the two tests also differ.  Both require the holding of the presented stimuli in active working memory space.  Numbers Reversed then requires the simple reproduction of the numbers in reverse order.  In contrast, the Auditory Working Memory test requires the storage of the numbers and words in separate chunks, and then the production of the forward sequence of each respective chunk (numbers or words), one chunk before the other.  Greater reliance on divided attention is most likely occurring during the Auditory Working Memory test. 

In summary, the results presented in Figure 12 suggest that it is possible to develop cluster scores that vary by degree of cognitively complexity within the same broad CHC domain.  More important is the finding that the classification of clusters as broad or narrow does not provide information on the measures cognitive complexity.  Cognitively complexity, as defined in the classification of clusters as broad or narrow does not provide information on the measures cognitive complexity.  Cognitive complexity, as in the Lohman sense, can be achieved within CHC domains without resorting to mixing abilities across CHC domains.  Finally, narrow clusters can be more cognitively complex, and thus likely better predictors of complex school achievement, than broad clusters or other narrow clusters. 

Implications for Test Battery Design and Assessment Strategies

The recognition of cognitive complexity as an important ITD principle suggests that the push to feature broad CHC clusters in contemporary test batteries, or in the construction of cross-battery assessments, fails to recognize the importance of cognitive complexity.  I plead guilty to contributing to this focus via my role in the design of the WJ III which focused extensively on broad CHC domain construct representation—most WJ III narrow CHC clusters require the use of the third WJ III cognitive book (the Diagnostic Supplement; Woodcock, McGrew, Mather & Schrank, 2003).  Similarly, guilty as charged in the dominance of broad CHC factor representation in the development of the original cross-battery assessment principles (Flanagan & McGrew, 1997; McGrew & Flanagan, 1998). 

It is also my conclusion that the narrow is better conclusion of McGrew and Wendling (2010) may need modification.   Revisiting the McGrew and Wendling (2010) results suggest that the narrow CHC clusters that were more predictive of academic achievement likely may have been so not necessarily because they are narrow, but because they are more cognitively complex.  I offer the hypothesis that a more correct principle is that “cognitively complex measures” are better.   I welcome new research focused on testing this principle.

In retrospect, given the universe of WJ III clusters, a broad+narrow hybrid approach to intelligence battery configuration (or cross-battery assessment) may be more appropriate.  Based exclusively on the results presented in Figure 12, the following clusters would appear those that might better be featured in the “front end” of the WJ III or a selective testing constructed assessment—those clusters that examiners should consider first within each CHC broad domain:  Fluid Reasoning (Gf)[4], Comprehension-Knowledge (Gc), Long-term Retrieval (Glr), Working Memory (Gsm-MW), Phonemic Awareness 3 (Ga-PC), and Perceptual Speed (Gs-P).  No clear winner is apparent for Gv, although the narrow Visualization cluster is slightly more cognitively complex than the Gv and Gv3 clusters.  The above suggests that if broad clusters are desired for the domains of Gs, Gsm and Gv, then additional testing beyond the “front end” or featured tests and clusters would require administration of the necessary Gs (Decision Speed), Gsm (Memory for Words) and Gv (Picture Recognition) tests.

Utilization of the ITD test design principle of optimizing within-CHC cognitively complexity of clusters suggests that a different emphasis and configuration of WJ III tests might be more appropriate.  It is proposed that the above WJ III cluster complexity priority or feature model would likely allow practitioners to administer the best predictors of school achievement.  I further hypothesize that this cognitive complexity based broad+narrow test design principle most likely applies to other intelligence test batteries that have adhered to the primary focus on featuring tests that are the purest indicators of two or more narrow abilities within the provided broad CHC interpretation scheme.  Of course, this is an empirical question that begs research with other batteries.  More useful with be similar MDS Radex cognitive complexity analysis of cross-battery intelligence data sets.[5]

References (not included in this post.  The complete paper will be announced and made available for reading and download in the near future)

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[1] This does not mean that cognitive complexity may not be related to the integrity of the human connectome or different brain networks. I am excited about contemporary brain network research (Bressler & Menon, 2010; Cole, Yarkoni, Repovs, Anticevic & Braver, 2012; Toga, Clark, Thompson, Shattuck, & Van Horn, 2012; van den Heuvel & Sporns, 2011), particularly that which has demonstrated links between neural network efficiency and working memory, controlled attention and clinical disorders such as ADHD (Brewer, Worunsky, Gray, Tang, Weber & Kober, 2011; Lutz, Slagter, Dunne, & Davidson, 2008; McVay & Kane, 2012). The Parietal-Frontal Integration (P-FIT) theory of intelligence is particularly intriguing as it has been linked to CHC psychometric measures (Colom, Haier, Head, Álvarez-Linera, Quiroga, Shih, & Jung, 2009; Deary, Penke, & Johnson, 2010; Haier, 2009; Jung & Haier, 2007) and could be linked to CHC cognitively-optimized psychometric measures.

[2] Only reading and math clusters were included to simplify the presentation of the results and the fact, as reported previously, that reading and writing measures typically do not differentiate well in multivariate analysis—and thus the Grw domain in CHC theory.

[3] GIA-Ext is also represented by a black circle.

[4] Although the WJ III Fluid Reasoning 3 cluster (Gf3) is slightly closer to the center of the figure, the difference from Fluid Reasoning (Gf) is not large and time efficiency would argue for the two-test Gf cluster.

[5] It is important to note that the cognitive complexity analysis and interpretation discussed here is specific to within the WJ III battery only. The degree of cognitive complexity in the WJ III cognitive clusters in comparison to composite scores from other intelligence batteries can only be ascertained by cross-battery MDS complexity analysis.

Clarification of Intellectual Ability Construct Terminology

      The terms ability, cognitive ability, achievement, aptitude, aptitude-achievement are tossed around in contemporary psychological and educational assessment circles, often without a clear understanding of the similarities and differences between and among the terms.  For example, what does an “aptitude-achievement” discrepancy, in the context of contemporary models of SLD identification (see Flanagan & Fiorrello, 2010), mean?  Where are the aptitudes in the CHC  model?  It is argued here that it is critical that intelligence assessment professionals and researchers begin to use agreed upon terms to avoid confusion and to enhance collaboration and to facilitate research synthesis.  In this spirit, the figure below illustrates the conceptual distinction between abilities, cognitive abilities, achievement abilities and aptitudes.  These conceptual distinctions are drawn primarily from Carroll (1993)and the work of Snow and colleagues (Corono et al., 2001).    [Click on image to enlarge]

            As reflected in the figure, all constructs in the CHC model are abilities.  As per Carroll (1991), “as used to describe an attribute of individuals, ability refers to the possible variations over individuals in the liminal levels of task difficulty (or in derived measurements based on such luminal levels) at which, on any given occasion in which all conditions appear favorable, individuals perform successfully on a defined class of tasks” (p. 8, italics in original).[1]  In more simple language,“every ability is defined in terms of some kind of performance, or potential for performance (p. 4).”  The overarching domain of abilities includes cognitive and achievement abilities as well as aptitudes (see figure).  Cognitive abilities are abilities on tasks “in which correct or appropriate processing of mental information is critical to successful performance” (p. 10; italics in original).  The key component to the operational definition of cognitive abilities is the processing of mental information (Carroll, 1993).  Achievement abilities “refers to the degree of learning in some procedure intended to produce learning, such as an informal or informal course of instruction, or a period of self study of a topic, or practice of a skill” (p. 17).  As reflected in the above figure, the CHC domains of Grw and Gq are consistent with this definition and Carroll’s indication that these abilities are typically measured with achievement tests.  Most assessment professionals use the terms cognitive and achievement abilities in accordance with these definitions.  However, the term aptitude is often misunderstood.

            Carroll (1993) uses a narrow definition of aptitude—“to refer to a cognitive ability that is possibly predictive of certain kinds of future learning success” (p. 16; emphasis added).  The functional emphasis on prediction is the key to this narrow definition of aptitude and is so indicated by the two horizontal arrows in the figure.  These arrows, which connect the shaded CHC narrow abilities that are combined to predict an achievement ability outcome domain, are the definition of aptitude used in this paper.

 This definition of aptitude is much narrower than the broader notion of aptitude as reflected in the work of Richard Snow.   Snow’s notion of aptitude includes both cognitive and non-cognitive (conative) characteristics of individuals (Corno et al., 2002; Snow et al., 1996).  This broader definition of aptitude focuses on human aptitudes which represent “the characteristics of human beings that make for success or failure in life's important pursuits. Individual differences in aptitudes are displayed every time performance in challenging activities is assessed” (Corno et al., 2002, p. xxiii). Contrary to many current assumptions, aptitude is not the same as ability.  According to Corno et al. (2002), ability is the power to carry out some type of specific task and comes in many forms—reading comprehension, mathematical reasoning, spatial ability, perceptual speed, domain-specific knowledge (e.g., humanities), physical coordination, etc.  This is consistent with Carroll’s definition of ability.  According to Snow and colleagues, aptitude is more aligned with the concepts of readiness, suitability, susceptibility, and proneness, all which suggest a “predisposition to respond in a way that fits, or does not fit, a particular situation or class of situations. The common thread is potentiality—a latent quality that enables the development or production, given specified conditions, of some more advanced performance” (Corno et al., 2002, p. 3; see Scheffler, 1985).  This broader definition includes non-cognitive characteristics such achievement motivation, freedom from anxiety, self-concept, control of impulses, and other (see Beyond IQ project). 

As reflected in the model in the above figure, cognitive and achievement abilities differ primarily in the degree of emphasis on degree of mental information processing (cognitive) and the degree which the ability is an outcome acquired more from informal and formal instruction (achievement).  Here, aptitude is defined as the combination, amalgam or complex of specific cognitive abilities that when combined best predict a specific achievement domain.  Cognitive abilities are always cognitive abilities.  Some cognitive abilities contribute to academic or scholastic aptitudes, which are pragmatic functional measurement entities—not trait-like cognitive abilities.  Different academic or scholastic aptitudes, depending on the achievement domain of interest, likely share certain common cognitive abilities (domain-general) and also include cognitive abilities specific to certain achievement domains (domain-specific).  A simple and useful distinction is that cognitive abilities and achievements are more like unique abilities in a table of human cognitive elements while different aptitudes represent combinations of different cognitive elements to serve a pragmatic predictive function.  For the quantoid readers, the distinction between factor-analysis based latent traits (cognitive abilities) and multiple regression based functional predictors of achievement outcomes (cognitive aptitude) may help clarify the sometimes murky discussion of cognitive and achievement abilities and aptitudes.

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[1] As noted by Carroll (1993), luminal refers to specifying threshold values used “in order to take advantage o the fact that the most accurate measurements are obtained at those levels” (p. 8).

CHC COG-ACH Relations: Visual-graphic summary

In preparation of a manuscript, I have developed the following visual-graphic summary of Established Narrow CHC-->Rdg/Math Ach Relations Abridged Summary.  It is based on the review of McGrew & Wendling (2010).  Click on image to enlarge.

AP101 Brief # 13: CHC-consistent scholastic aptitude clusters: Back to the Future

This is a continuation of a set of analyses previously posted under the title  Visual-graphic tools for implementing intelligent intelligence testing in SLD contexts:  Formative concepts and tools.  It is recommended that you read the prior post to obtain the necessary background and context, which will not be repeated here.

The third  method approach to SLD identification (POSW; pattern of strengths and weaknesses) has been advanced primarily by Flanagan and colleagues, as well as Hale and colleagues and Naglieri (see Flanagan & Fiorrello, 2010 for an overview and discussion).  A central concept to these POSW third method SLD models is that an individual with a possible SLD must show cognitive deficits that have been empirically or theoretically demonstrated to be the most relevant cognitive abilities for the achievement domain where the person is deficient.  That is, the individual's cognitive deficits are consistent or concordant with the persons academic deficits, in the context of other cognitive/achievement strengths that suggest strengths in non-SLD areas.  I have often referred to this as a domain-specific constellation or complex of abilities and achievements.

Inherent in these models is the operationalization of the notion of  aptitude-achievement consistency or concordance.  It is important to note that aptitude is not the same as general intelligence or IQ.  Aptitude in this contexts draws on the historical/traditional notion of aptitude that has been around for decades.  Richard Snow and colleagues have (IMHO) written the best information regarding this particular definition of aptitude.  Aptitude includes both cognitive and conative characteristics of a person (see Beyond IQ Project).  But for this specific post, I am only focusing on the cognitive portion of aptitude--which would, in simple terms, represent the best combination of particular CHC narrow or broad cognitive abilities that are most highly correlated with success within a particular narrow or broad achievement domain.

What are the CHC narrow or broad abilities most relevant to different achievement domains?  This information has been provided in a narrative research synthesis form by Flanagan and colleagues (in their various cross-battery books and chapters) and more recently in a structured empirical research synthesis by McGrew and Wendling (2010).  These CHC-based COG--ACH relations summaries provide assessment professionals with information on the specific broad or narrow CHC abilities most associated with sudomains in reading and math, and to a lessor extent writing.  Additionally, the McGrew and Wendling's (2010) synthesis provides information on developmental considerations--that is, the relative importance of CHC abilities for different achievement domains varies as a function of age.  McGrew and Wendling (2010) presented their results for three broad age groups (6-8; 9-13; 14-18 years of age).

Given this context, I presented a series of analysis (see the first post mentioned above as recommended background reading) that took the findings of the McGrew and Wendling (2010) as an initial starting point and used logical, empirical, and theoretical considerations to identify the best set of WJ III cognitive test predictors in the same three age groups for two illustrative achievement domains.  I have since winnowed down the best set of cognitive predictors in the two achievement domains (basic reading skills-BRS; math reasoning-MR).  I then took each set of carefully selected predictor tests and ran multiple regression models for each year of age from ages 6 thru 18 in the WJ III NU norm data.  I saved the standardized regression coefficients for each predictor and  plotted them by age. The plotted raw standardized coefficients demonstrated clear systematic developmental trends, but with noticeable "bounce" due to sampling error.  I thus generated smoothed curves using a non-linear smoothing function...with the smoothed curve representing the best estimate of the population parameters.  This technique has been used previously in a variety of studies that explored the relations between WJ-R/WJ III clusters and achievement (see McGrew, 1993 and McGrew and Wrightston, 1997 for examples and description of methodology).  Below is a plot of the raw standardized coefficients and the smoothed curve two of the significant predictors (Verbal Comprehension; Visual-Auditory Learning) for the prediction of the WJ III Basic Reading Skills cluster. [click on images to enlarge]. It is clear that the relative importance of Verbal Comprehension and Visual-Auditory Learning increase/decrease (respectively) systematically with age.

The next two figures present the final smoothed results for the CHC-based aptitude clusters for the prediction of the WJ III Basic Reading Skills and Math Reasoning clusters.

There is much that could be discussed after looking at the two figures.  Below are a few comments and thoughts.

• The composition of what I am calling CHC-consistent scholastic aptitude clusters make theoretical and empirical (CHC-->ACH research synthesis) sense. For example, in both BRS and MR, Gc-LD/VL abilitiy (Verbal Comprehension) is salient at all ages and systematically increases in importance with age.  In BRS, visual-auditory associative memory (Glr-MA; Vis-Aud. Learning) is very important during the early school years (ages 6-9), but then disappears from being important in the prediction model.  This ability (test) is not found in the MR model.  Gf abilities (quantitative reasoning-RQ, Number Matrices; general sequential reasoning-RG, Analysis-Synthesis) are important throughout all ages for predicting math reasoning achievement.  In fact, both increase in relative importance with age, particularly for the measure of Gf-RQ (Number Matrices).  These two Gf tests are no where to be found in the BRS plot.  Instead, measures of  Ga abilities (Sound Blending; Sound Awareness) are important in the BRS model.  Gs and Gsm-WM (domain-general cognitive efficiency variables) are present in both the BRS and MR models.

• The amount of explained variance (multiple R squared; Tables in figures) is higher for the CHC-consistent scholastic aptitude clusters when compared to the WJ III General Intellectual Ability (GIA-Std) clusters.  This is particularly true at the oldest ages for MR.  Of course, these values capitalize on chance factors due to the nature of multiple regression and would likely shrink somewhat in independent sample cross-validation (yes...I could have split the sample in half to develop and then cross-validate the models..but I didn't). 

• These age-by-age plots provide a much more precise picture of the developmental nature of the relations between narrow CHC abilities and achievement than the McGrew & Wendling (2010) and Flanagan and colleagues reviews.  These findings suggest that when selecting tests for referral-focused selective assessment (see McGrew & Wendling, 2010) it is critical that examiners know the developmental nature of CHC--ACH relations research.  The fact that some specific narrow CHC tests show such dramatic changes across the ages suggests that those who implement a CHC-based aptitude-achievement consistency SLD model must be cautious and not use a "one size fits all" approach when determining which CHC abilities should be examined for the aptitude portion of the consistency model.  An ability that may be very important certain age levels may not be important at other age levels (e.g., Vis-Aud. Learning in the WJ III BRS aptitude cluster).  

• The above results further reinforce the conclusion of McGrew & Wendling (2010) that development of more "intelligent" referral-focused selective assessment strategies requires a recognition that this process requires an understanding of the 3-way interaction of CHC abilities X Ach domains X Age (developmental status)

These results suggest that the field of intellectual assessment, particularly in the context of educational-related assessments, should go "Back to the Future."  The 1977 WJ and 1989 WJ-R batteries both included scholastic aptitude clusters (SAPTs; click here to read relevant select text from McGrew's two WJTCA books) as part of the WJ/WJ-R pragmatic decision-making discrepancy model.  In particular, see the Type I aptitude-achievement discrepancy feature in the second figure.  

The WJ and WJ-R SAPT's were differentially weighted combinations of the four best predictive tests across the norms sample.  See the two figures below which show the weighting schemes used.  Due to the lack of computerized norm tables and scoring that is now possible, a single set of average test weights were used for all ages.

[WJ SAPT weights]

 As I wrote in 1986, "because of their differential weighting system, the WJTCA Scholastic Aptitude clusters should provide some of the best curriculum-specific expectancy information available in the field of psychoeducational assessment" (p. 217).  Woodock (1984), in a defense of the SAPTs in School Psychology Review, made it clear that the composition of these clusters was to make the best possible aptitude-achievement comparison.  He stated that "the mix of cognitive skills included in each of the four scholastic aptitude clusters represents the best match with those achievement skills that could be obtained from the WJ cognitive subtests" (p.359).  However, the value of the WJ SAPTs were not fully appreciated at the time and was largely due to the IQ-ACH discrepancy model that constrained assessment professionals from using these measures as intended (McGrew, 1994).  This, unfortunately, led to their elimination in the WJ III and their replacement with the Predicted Achievement (PA) option which provided achievement domain-specific predictions of achievement based on the age-based optimal weighting of the seven individual tests that comprised the WJ III GIA-Std cluster.  Although effective and stronger predictors of achievement than the GIA-Std, the PA option never captured the attention of many assessment professionals...for a number of reasons (not covered here).

As I reiterated in 1994, when discussing the WJ-R SAPTs (same link as before), "The purpose of the WJTCA-R differential aptitude clusters is to provide predictions of current levels of achievement.  If a person obtains low scores on individual tests that measure cognitive abilities related to a specific achievement area and these tests are included in the aptitude cluster, then the person's current achievement expectancies should also be lowered.   This expectancy information will be more accurately communicated by the narrower WJTCA-R different aptitude clusters than by any broad-based score from the WJTCA-R or other tests" (p. 223).

The original WJ and WJ-R SAPTs were not presented as part of an explicitly defined comprehensive SLD identification model based on the concepts of consistency/concordance as was eventually advanced by Flanagan et al, Hale et al and Naglieri.  They were presented as part of a more general psychoeducational pragmatic decision making model.  However, it is clear that the WJ and WJ-R SAPTs were ahead of their time as they philosophically are in line with the aptitude portion of the aptitude-achievement consistency/concordance component of contemporary third method  SLD models.  In a sense, the field has now caught up with the WJ/WJ-R operationalization of aptitude clusters and they would now serve an important role in the aptitude-consistency SLD models.  It is my opinion that they represented the best available measurement approach to operationalizing domain-specific aptitudes for different achievement domains, which is at the heart of the new SLD models.

It is time to bring the SAPT's back...Back to the Future...as the logic of their design is a nice fit with the aptitude component of the aptitude-achievement consistency/concordance SLD models.  The field is now ready for this type of conceptualized and developed measure.

However, the original concept can now be improved upon via the methods and analyses presented in this (and the prior) post.  They can be improved upon via two methods:

1.  CHC-consistent aptitude clusters (aka, CHC designer aptitudes).  Creating  4-5 test clusters that are the bests predictors of achievement subdomains should utilize the extant CHC COG-->ACH relations literature when selecting the initial pool of tests to include in the prediction models.  This extant research literature should also guide the selection of variables in the final models...the models should not allowed to be driven by the raw empiricism of prediction.  This varies from the WJ and WJ-R SAPTS which were designed primarily based on empirical criteria (which combination predicted the most achievement variance), although their composition often made considerable theoretical sense when viewed via a post-hoc CHC lens.

2.  Provide age-based developmental weighting of the tests in the different CHC SAPTs.  The authors of the WJ III provided the necessary innovation to make this possible when they implemented an approach to constructing age-based differentially-weighted GIA g-scores via the WJ III computer scoring software.  The same technology can readily be applied to the development of CHC-designed SAPTS with developmentally shifting weights (as per the smoothed curves in the models above).  The technology is available.

Finally, I fully recognize that there are significant limitations in using an incremental partitioning of variance multiple regression approach to develop CHC-based SAPT's.  In other papers (g+specific abilities research using SEM causal models) I have been critical of this method.  The method was used here in an "intelligent" manner.....the selection of the initial pool of predictors was guided by the CHC COG-ACH extant literature and variables were not allowed to enter blindly into the final models.  The purpose of this (and the prior post) is to demonstrate the feasibility of designing CHC-consistent scholastic aptitude clusters.  I am pursuing other analyses with different methods to expand and improve upon this set of formative analyses and results.

Build it and they shall come.