فعالية التدريب القائم على حل المشكلات في تحسين الذاكرة العاملة لدى ذوي صعوبات التعلم = The Effectiveness of Training-Based on Problem Solving in Improving Working Memory in Children with Learning Disabilities

The student's criterion for being diagnosed with MLD (Mathematics Learning Disabilities) can be classified as low arithmetic skills and poor working memory. The goal of this research is to understand students' process of thinking through the Polya stages when tackling arithmetic problems, as it has been expounded by Dr. Polya For students who have mathematics learning difficulties, the information is gathered by administering math problems to both females and males that ask the correct questions and have to be answered in their heads. the data gathered from the study concluded that students exhibit degrees of mental disorder that are caused by 3 distinct stages in which they must be addressed: problem-solving underachievement, when they are overreaching, and cognitive imbalance when they are overcommitted. to arrive at equilibrium, the more significant expansions must be coupled with an extensive assimilation and assimilation process As students with moderate to severe learning disability were completing multi-digit addition and multiplication, they underwent assimilation. Because of this, the cognitive fluidity present at this moment, the students have already found themselves in their present-looking-backward state of mind.

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The Prediction of Problem-Solving Assessed Via Microworlds

European Journal of Psychological Assessment ◽

10.1027/1015-5759/a000263 ◽

2016 ◽

Vol 32 (4) ◽

pp. 298-306 ◽

Cited By ~ 7

Author(s):

Samuel Greiff ◽

Katarina Krkovic ◽

Jarkko Hautamäki

Keyword(s):

Working Memory ◽

Problem Solving ◽

Complex Problem ◽

Two Dimensions ◽

Assessment Instruments ◽

Complex Problem Solving ◽

Visual Spatial ◽

Rule Knowledge ◽

Rule Application ◽

Fluid Reasoning

Abstract. In this study, we explored the network of relations between fluid reasoning, working memory, and the two dimensions of complex problem solving, rule knowledge and rule application. In doing so, we replicated the recent study by Bühner, Kröner, and Ziegler (2008) and the structural relations investigated therein [ Bühner, Kröner, & Ziegler, (2008) . Working memory, visual-spatial intelligence and their relationship to problem-solving. Intelligence, 36, 672–680]. However, in the present study, we used different assessment instruments by employing assessments of figural, numerical, and verbal fluid reasoning, an assessment of numerical working memory, and a complex problem solving assessment using the MicroDYN approach. In a sample of N = 2,029 Finnish sixth-grade students of which 328 students took the numerical working memory assessment, the findings diverged substantially from the results reported by Bühner et al. Importantly, in the present study, fluid reasoning was the main source of variation for rule knowledge and rule application, and working memory contributed only a little added value. Albeit generally in line with previously conducted research on the relation between complex problem solving and other cognitive abilities, these findings directly contrast the results of Bühner et al. (2008) who reported that only working memory was a source of variation in complex problem solving, whereas fluid reasoning was not. Explanations for the different patterns of results are sought, and implications for the use of assessment instruments and for research on interindividual differences in complex problem solving are discussed.

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Working Memory and Number Sense as Predictors of Mathematical (Dis-)Ability

Zeitschrift für Psychologie ◽

10.1027/2151-2604/a000208 ◽

2015 ◽

Vol 223 (2) ◽

pp. 102-109 ◽

Cited By ~ 13

Author(s):

Evelyn H. Kroesbergen ◽

Marloes van Dijk

Keyword(s):

Working Memory ◽

Learning Disabilities ◽

Spatial Working Memory ◽

Number Sense ◽

Mathematical Learning ◽

Visual Spatial ◽

Mathematical Learning Disabilities ◽

Visual Spatial Working Memory ◽

And Mathematics

Recent research has pointed to two possible causes of mathematical (dis-)ability: working memory and number sense, although only few studies have compared the relations between working memory and mathematics and between number sense and mathematics. In this study, both constructs were studied in relation to mathematics in general, and to mathematical learning disabilities (MLD) in particular. The sample consisted of 154 children aged between 6 and 10 years, including 26 children with MLD. Children performing low on either number sense or visual-spatial working memory scored lower on math tests than children without such a weakness. Children with a double weakness scored the lowest. These results confirm the important role of both visual-spatial working memory and number sense in mathematical development.

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A Complexity Theory Model in Science Education Problem Solving: Random Walks for Working Memory and Mental Capacity

PsycEXTRA Dataset ◽

10.1037/e538732010-001 ◽

2003 ◽

Author(s):

D. Stamovlasis ◽

G. Tsaparlis

Keyword(s):

Working Memory ◽

Science Education ◽

Problem Solving ◽

Random Walks ◽

Complexity Theory ◽

Theory Model ◽

Mental Capacity

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Working Memory, Fluid Reasoning, and Complex Problem Solving: Different Results Explained by the Brunswik Symmetry

Journal of Intelligence ◽

10.3390/jintelligence9010005 ◽

2021 ◽

Vol 9 (1) ◽

pp. 5

Author(s):

André Kretzschmar ◽

Stephan Nebe

Keyword(s):

Working Memory ◽

Problem Solving ◽

Cognitive Abilities ◽

Latent Variables ◽

Complex Problem ◽

Equation Modeling ◽

Complex Problem Solving ◽

Symmetry Principle ◽

Fluid Reasoning ◽

The Impact

In order to investigate the nature of complex problem solving (CPS) within the nomological network of cognitive abilities, few studies have simultantiously considered working memory and intelligence, and results are inconsistent. The Brunswik symmetry principle was recently discussed as a possible explanation for the inconsistent findings because the operationalizations differed greatly between the studies. Following this assumption, 16 different combinations of operationalizations of working memory and fluid reasoning were examined in the present study (N = 152). Based on structural equation modeling with single-indicator latent variables (i.e., corrected for measurement error), it was found that working memory incrementally explained CPS variance above and beyond fluid reasoning in only 2 of 16 conditions. However, according to the Brunswik symmetry principle, both conditions can be interpreted as an asymmetrical (unfair) comparison, in which working memory was artificially favored over fluid reasoning. We conclude that there is little evidence that working memory plays a unique role in solving complex problems independent of fluid reasoning. Furthermore, the impact of the Brunswik symmetry principle was clearly demonstrated as the explained variance in CPS varied between 4 and 31%, depending on which operationalizations of working memory and fluid reasoning were considered. We argue that future studies investigating the interplay of cognitive abilities will benefit if the Brunswik principle is taken into account.

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Reasoning, problem solving, attention/vigilance, and working memory are candidate phenotypes of non-suicidal self-injury in Chinese Han nationality

Neuroscience Letters ◽

10.1016/j.neulet.2021.135878 ◽

2021 ◽

Vol 753 ◽

pp. 135878

Author(s):

Zhizhong Hu ◽

Xin Yuan ◽

Yanyan Zhang ◽

Zihang Lu ◽

Jinyuan Chen ◽

...

Keyword(s):

Working Memory ◽

Problem Solving ◽

Chinese Han ◽

Han Nationality ◽

Self Injury ◽

Reasoning Problem

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Integrated Learning: Explicit Strategies and Their Role in Problem-Solving Instruction for Students with Learning Disabilities

Council review ◽

10.1177/001440299305900507 ◽

1993 ◽

Vol 59 (5) ◽

pp. 444-455 ◽

Cited By ~ 19

Author(s):

Maurice Hollingsworth ◽

John Woodward

Keyword(s):

Computer Simulation ◽

Learning Disabilities ◽

Problem Solving ◽

Secondary Students ◽

Comparison Group ◽

Strategy Group ◽

Integrated Learning ◽

Students With Learning Disabilities ◽

Simulation Games ◽

Experimental Group

This study investigated the effectiveness of an explicit strategy as a means of linking facts, concepts, and problem solving in an unfamiliar domain of learning. Participants were 37 secondary students with learning disabilities. All students were taught health facts and concepts, which they then applied to problem-solving exercises presented through computer-simulation games. Students in the experimental group were taught an explicit strategy for solving the problems; the comparison group was given supportive feedback and encouraged to induce their own strategies. The explicit strategy group performed significantly better on two transfer measures, including videotaped problem-solving exercises.

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Student Perception, Mathematical Problem Solving, and Learning Disabilities

Remedial and Special Education ◽

10.1177/074193259701800108 ◽

1997 ◽

Vol 18 (1) ◽

pp. 46-53 ◽

Cited By ~ 17

Author(s):

Marjorie Montague

Keyword(s):

Learning Disabilities ◽

Problem Solving ◽

Student Perception ◽

Mathematical Problem ◽

Mathematical Problem Solving ◽

Problem Difficulty ◽

Students With Learning Disabilities ◽

Affect And Cognition ◽

Perception Of Performance

The purpose of this article is to discuss student perception of mathematical problem solving. Findings from five studies measuring attitude toward mathematics, perception of performance, perception of the importance of mathematical problem solving, and perception of problem difficulty are presented and discussed. Additionally, the interaction of affect and cognition and the implications of this interaction for assessing and teaching mathematical problem solving to students with learning disabilities are discussed.

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