Description
The PASS Theory of Intelligence posits that cognition is organized in three systems and four processes, based on Luria's (1966) work on modularization of brain activity and validated by decades of neuroimaging data. The first phase is planning, which entails executive functions directing and organizing behavior, selecting and developing strategies, and monitoring performance. The second is the Attention process, responsible for sustaining arousal and alertness and focusing on relevant inputs. Simultaneous and Successive Processing are procedures that encode, transform, and retain data. Simultaneous processing determines the relationship between objects, and integration into entire information units is necessary. Examples include recognizing figures, such as a triangle within a circle vs. a circle within a triangle. Successive processing is required for organizing separate items in a sequence, such as remembering a sequence of words or actions precisely in the order in which they had just been presented. These four processes are hypothesized to function in four areas of the brain. Planning is broadly located in the front part of our brains, theAssessment of PASS processes
The PASS theory provides the theoretical framework for a measurement instrument called the Das-Naglieri Cognitive Assessment System (CAS), published in 1997.Naglieri, J, A., & Das, J. P. (1997). Das-Naglieri Cognitive Assessment System. Itasca, IL: Riverside Publishing. This test, now in a Second Edition (CAS2; 2014, Naglieri, Das & Gold-stein) is designed to provide an assessment of intellectual functioning redefined as four brain-based cognitive processes (Planning, Attention, Simultaneous and Successive), providing information about cognitive strengths and weaknesses of each of the four processes. This emphasis on processes (rather than traditional abilities) is said to make it useful for differential diagnosis; diagnosingLinks to general intelligence
Contemporary theories aboutLinks to brain activity
The core idea that cognitive functions can be organized in terms of broad functions of the brain received some support in a recent study (Okuhata et al.) that investigated the psychophysiology basis of two different types of information processing (simultaneous and successive). The authors investigated EEG coherence patterns during six tasks of the Das-Naglieri Cognitive Assessment System. They analyzed beta (12.5 – 25. Hz) coherence while 18 volunteers performed three simultaneous and three successive tasks. The results revealed two significantly distinguishable coherence patterns corresponding to simultaneous and successive processing. The linking of PASS processes to the brain becomes helpful. For example, in the understanding the loss of sequential and planning functions due to aging in a study of individuals with Down syndrome, using single positron emission topography, Das found that aging individuals with Down syndrome show a bilateral decreased cerebral blood flow in the temporal-parietal region of the brain. The significance of cognitive profiling studies both in impaired and intact brains awaits further discussion in the broader context of the biology of intelligence.Remediation and cognitive enhancement
One unusual property of the P.A.S.S. theory of cognitive processes is that it has been proven useful for both intellectual assessment (e.g. the CAS) and educational intervention. The theory provides the theoretical framework for the PASS Reading Enhancement Program, a remediation curriculum designed to improve the planning, attention and information processing strategies that underlie reading. A related school-readiness program aims at improving the foundations of cognitive processes in preparation for schooling (Das, 2009). Both are evidence-based intervention programs.Challenges
A frequently asked question from the critics of PASS is: are Attention and Planning two distinct factors? Kranzler, Keith & Flanagan (2000) found only a marginal fit for the four-factor model; the attention and planning factors were indistinguishable. Recent research on intelligence tests confirms that the most valid score on, for example, the Wechsler Intelligence Scale for Children – Fifth Edition (Canivez, Watkins, & Dombrowski, 2017), Stanford-Binet Fifth Edition (Canivez, 2008), Differential Abilities Scales (Canivez & McGill, 2016), and the Woodcock-Johnson Fourth Edition (Dombrowski, McGill & Canivez, 2017) is the total score that estimates g. That is, the scores which represent the factor based scales these tests provide do not have enough specific variance to be considered interpretable. In fact, a recent reanalysis of Carroll's survey of factor-analytic studies by Benson, Beaujean, McGill, and Dombrowski (2018) concluded that nearly all of the specified abilities presented by Carroll "have little-to-no interpretive relevance above and beyond that of general intelligence (p. 1028)." The only exception to these finding is research reported by Canivez (2011) regarding the Cognitive Assessment System (Naglieri & Das, 1997). The most recent factor analytic examination of the PASS scales of the CAS Second Edition was conducted by Papadopoulos, Spanoudis and Naglieri (2023) using the standardization sample of the CAS2. The correlated four-factor solution best fits the data above and beyond the one-factor, second-order, bi-factor, and several asymmetrical bi-factor models. These different models, parameterized to allow for indications of the four cognitive factors (i.e., correlated model), a general g factor (i.e., one- and second-order factor models), or a combination of the two (i.e., bi-factors models), revealed that the correlated model accounted for the inter-subtest covariation of the cognitive abilities better than the unitary g factor or the bifactor models. Furthermore, factorial invariance analysis provided evidence that the obtained correlated model, as an index of cognitive processing or intelligence, was the same between genders.References
Further reading
* Alabau-Bofill J. (2003) Estudi dels processos emocionals en nens/nes amb dificultats d'aprenentatge i la seva relació amb els processos cognitius basats en la teoria PASS de la inteligel.lència esi doctoral UdG Girona. * Das, J. P., Kar, R., & Parrilla, R. K. (1996). Cognitive planning. The psychological basis of intelligent behavior. London: Sage Publications Ltd. * Das, J. P., Naglieri, J. A., & Kirby, J. R. (1994). Assessment of cognitive processes. The PASS theory of intelligence. Massachusetts: Allyn & Bacon, Inc. * Das, J.P. (1998). Dyslexia & Reading Difficulties. An interpretation for teachers. Edmonton, Canada: University of Alberta. * Das, J. P., Garrison, M. A., Gonzalez, M., Timoneda, C., & Perez- Alvarez, F. (1999). Dyslexia y difficulty DE lecture. Barcelona: Ediciones Paidós Ibérica SA. * * * Das, J.P., Parrilla, R.K., & Papadopoulos, T.C. (2000). Cognitive education and reading disability. In A. Koulin & Y. Rand (Eds.), Experience of mediated learning (pp. 274–291). Oxford, UK: Pergamon. * Das, J.P. (2004). The Cognitive Enhancement Training Program (COGENT). Edmonton, Canada: Developmental Disabilities Centre, University of Alberta. * * * * * Naglieri, J. A., & Das, J. P. (1997). Cognitive assessment system. Rolling Meadows, IL: Riverside Publishing. * * * * * Pérez-Álvarez F, Timoneda Gallart C. (2004). Learning Both in Attention Deficit Disorder and Dyslexia in the light of PASS Neurocognitive Dysfunction. In: HD Tobias (ed.).Focus on Dyslexia Research. pp. 173–179. Hauppauge, NY: Nova Science Publishers, Inc., * Pérez-Álvarez F, Timoneda Gallart C. (2005). Attention Deficit / Hyperactive Disorder as Impulsivity Disorder according to PASS Neurocognitive Function. In: P. Larimer (ed.) Attention Deficit Hyperactivity Disorder Research Developments. pp 173–184. Hauppauge, NY: Nova Science Publishers, Inc., * * Timoneda C., Pérez-Alvarez F. (2003). DN-CAS en català. Girona: Fundació Carme Vidal Xifre de Neuropsicopedagogia. * Benson, N. F., Beaujean, A. A., McGill, R. J, & Dombrowski, S. C. (2018). Revisiting Carroll's Survey of Factor-Analytic Studies: Implications for the Clinical Assessment of Intelligence. Psychological Assessment, 30, 8, 1028–1038. * Canivez, G. L., Watkins, M. W., & Dombrowski, S. C. (2017). Structural validity of the Wechsler Intelligence Scale for Children–Fifth Edition: Confirmatory factor analyses with the 16 primary and secondary subtests. Psychological Assessment, 29, 458-472. http://dx.doi.org/10.1037/pas0000358 * Canivez, G. L., & McGill, R. J. (2016). Factor structure of the Differential Ability Scales–Second Edition: Exploratory and hierarchical factor analyses with the core subtests. Psychological Assessment, 28, 1475-1488. http://dx.doi.org/10.1037/pas0000279 * Canivez, G. L., & McGill, R. J. (2016). Factor structure of the Differential Ability Scales-Second Edition: Exploratory and hierarchical factor analyses with the core subtests. Psychological Assessment, 28, 1475–1488. https://doi.org/10.1037/pas0000279 * Canivez, G. L. (2008). Orthogonal higher order factor structure of the Stanford-Binet Intelligence Scales-Fifth Edition for children and adolescents. School Psychology Quarterly, 23, 533–541. https://doi.org/10.1037/a0012884. * Dombrowski, S. C., McGill, R. J., & Canivez, G. L. (2017). Exploratory and hierarchical factor analysis of the WJ IV Cognitive at school age. Psychological Assessment, 29, 394-407. http://dx.doi.org/10.1037/pas0000350 {{Human intelligence topics Intelligence Psychological theories