Magnitude comparison with different types of rational numbers.

An important issue in understanding mathematical cognition involves the similarities and differences between the magnitude representations associated with various types of rational numbers. For single-digit integers, evidence indicates that magnitudes are represented as analog values on a mental number line, such that magnitude comparisons are made more quickly and accurately as the numerical distance between numbers increases (the distance effect). Evidence concerning a distance effect for compositional numbers (e.g., multidigit whole numbers, fractions and decimals) is mixed. We compared the patterns of response times and errors for college students in magnitude comparison tasks across closely matched sets of rational numbers (e.g., 22/37, 0.595, 595). In Experiment 1, a distance effect was found for both fractions and decimals, but response times were dramatically slower for fractions than for decimals. Experiments 2 and 3 compared performance across fractions, decimals, and 3-digit integers. Response patterns for decimals and integers were extremely similar but, as in Experiment 1, magnitude comparisons based on fractions were dramatically slower, even when the decimals varied in precision (i.e., number of place digits) and could not be compared in the same way as multidigit integers (Experiment 3). Our findings indicate that comparisons of all three types of numbers exhibit a distance effect, but that processing often involves strategic focus on components of numbers. Fractions impose an especially high processing burden due to their bipartite (a/b) structure. In contrast to the other number types, the magnitude values associated with fractions appear to be less precise, and more dependent on explicit calculation.

[1]  S. Vosniadou,et al.  Understanding the structure of the set of rational numbers: a conceptual change approach , 2004 .

[2]  Stanislas Dehaene,et al.  Development of Elementary Numerical Abilities: A Neuronal Model , 1993, Journal of Cognitive Neuroscience.

[3]  Robert S. Siegler,et al.  Fractions: the new frontier for theories of numerical development , 2013, Trends in Cognitive Sciences.

[4]  Clarissa A. Thompson,et al.  An integrated theory of whole number and fractions development , 2011, Cognitive Psychology.

[5]  Dana Ganor-Stern,et al.  Automaticity of two-digit numbers. , 2007, Journal of experimental psychology. Human perception and performance.

[6]  Dawn Chen,et al.  The discovery and comparison of symbolic magnitudes , 2014, Cognitive Psychology.

[7]  Yujing Ni,et al.  Teaching and Learning Fraction and Rational Numbers: The Origins and Implications of Whole Number Bias , 2005 .

[8]  K. Holyoak,et al.  Teaching the Conceptual Structure of Mathematics , 2012 .

[9]  R. Siegler,et al.  Early Predictors of High School Mathematics Achievement , 2012, Psychological science.

[10]  James W. Stigler,et al.  What Community College Developmental Mathematics Students Understand about Mathematics. , 2010 .

[11]  David F. Marks,et al.  Relative judgment: A phenomenon and a theory , 1972 .

[12]  Hilary Barth,et al.  Abstract number and arithmetic in preschool children. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[13]  Marco Zorzi,et al.  The mental representation of numerical fractions: real or integer? , 2007, Journal of experimental psychology. Human perception and performance.

[14]  Elizabeth M. Brannon,et al.  The Development of Ordinal Numerical Competence in Young Children , 2001, Cognitive Psychology.

[15]  Michael Schneider,et al.  Representations of the magnitudes of fractions. , 2010, Journal of experimental psychology. Human perception and performance.

[16]  S. Dehaene,et al.  Is numerical comparison digital? Analogical and symbolic effects in two-digit number comparison. , 1990, Journal of experimental psychology. Human perception and performance.

[17]  Arava Y. Kallai,et al.  A generalized fraction: an entity smaller than one on the mental number line. , 2009, Journal of experimental psychology. Human perception and performance.

[18]  Klaus Willmes,et al.  Decade breaks in the mental number line? Putting the tens and units back in different bins , 2001, Cognition.

[19]  Brian Butterworth,et al.  Rapid Communication: Understanding the Real Value of Fractions and Decimals , 2011, Quarterly journal of experimental psychology.

[20]  Keith J Holyoak,et al.  Comparative judgments with numerical reference points , 1978, Cognitive Psychology.

[21]  Elizabeth M Brannon,et al.  The development of ordinal numerical knowledge in infancy , 2002, Cognition.

[22]  S. Vosniadou,et al.  The development of students’ understanding of the numerical value of fractions , 2004 .

[23]  Tom Verguts,et al.  Two-digit comparison: decomposed, holistic, or hybrid? , 2005, Experimental psychology.

[24]  ROBERT S. MOYER,et al.  Time required for Judgements of Numerical Inequality , 1967, Nature.

[25]  Dale J Cohen,et al.  Evidence for direct retrieval of relative quantity information in a quantity judgment task: decimals, integers, and the role of physical similarity. , 2010, Journal of experimental psychology. Learning, memory, and cognition.

[26]  B. Rittle-Johnson,et al.  Developing Conceptual Understanding and Procedural Skill in Mathematics: An Iterative Process. , 2001 .

[27]  James V. Hinrichs,et al.  Two-digit number comparison: Use of place information. , 1981 .