{"title":"统一的整数、分数和小数运算模式。","authors":"David W Braithwaite, Robert S Siegler","doi":"10.1037/rev0000440","DOIUrl":null,"url":null,"abstract":"<p><p>This article describes UMA (Unified Model of Arithmetic), a theory of children's arithmetic implemented as a computational model. UMA builds on FARRA (Fraction Arithmetic Reflects Rules and Associations; Braithwaite et al., 2017), a model of children's fraction arithmetic. Whereas FARRA-like all previous models of arithmetic-focused on arithmetic with only one type of number, UMA simulates arithmetic with whole numbers, fractions, and decimals. The model was trained on arithmetic problems from the first to sixth grade volumes of a math textbook series; its performance on tests administered at the end of each grade was compared to the performance of children in prior empirical research. In whole number arithmetic (Study 1), fraction arithmetic (Study 2), and decimal arithmetic (Study 3), UMA displayed types of errors, effects of problem features on error rates, and individual differences in strategy use that resembled those documented in the previous studies of children. Further, UMA generated correlations between individual differences in basic and advanced arithmetic skills similar to those observed in longitudinal studies of arithmetic development (Study 4). The results support UMA's main theoretical assumptions regarding arithmetic development: (a) most errors reflect small deviations from standard procedures via two mechanisms, overgeneralization and omission; (b) between-problem variations in error rates reflect effects of intrinsic difficulty and differential amounts of practice; and (c) individual differences in strategy use reflect underlying variation in parameters governing learning and decision making. 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Whereas FARRA-like all previous models of arithmetic-focused on arithmetic with only one type of number, UMA simulates arithmetic with whole numbers, fractions, and decimals. The model was trained on arithmetic problems from the first to sixth grade volumes of a math textbook series; its performance on tests administered at the end of each grade was compared to the performance of children in prior empirical research. In whole number arithmetic (Study 1), fraction arithmetic (Study 2), and decimal arithmetic (Study 3), UMA displayed types of errors, effects of problem features on error rates, and individual differences in strategy use that resembled those documented in the previous studies of children. Further, UMA generated correlations between individual differences in basic and advanced arithmetic skills similar to those observed in longitudinal studies of arithmetic development (Study 4). 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引用次数: 0
摘要
本文介绍了 UMA(统一算术模型),这是一种作为计算模型实现的儿童算术理论。UMA 建立在儿童分数算术模型 FARRA(分数算术反映规则和关联;布雷斯怀特等人,2017 年)的基础之上。FARRA 与之前所有的算术模型一样,只关注一种类型数字的算术,而 UMA 则模拟整数、分数和小数的算术。该模型是根据数学系列教科书中一至六年级各册的算术问题进行训练的;在每个年级结束时进行的测试中,该模型的成绩与先前实证研究中儿童的成绩进行了比较。在整数运算(研究 1)、分数运算(研究 2)和小数运算(研究 3)中,UMA 显示了错误类型、问题特征对错误率的影响,以及策略使用上的个体差异,这些都与之前的儿童研究中记录的相似。此外,UMA 在基本算术技能和高级算术技能的个体差异之间产生的相关性与算术发展纵向研究中观察到的相关性相似(研究 4)。研究结果支持 UMA 关于算术发展的主要理论假设:(a) 大多数错误反映了通过过度概括和遗漏这两种机制对标准程序的微小偏差;(b) 不同问题之间错误率的变化反映了内在难度和不同练习量的影响;(c) 策略使用的个体差异反映了支配学习和决策的参数的潜在变化。(PsycInfo Database Record (c) 2024 APA, 版权所有)。
A unified model of arithmetic with whole numbers, fractions, and decimals.
This article describes UMA (Unified Model of Arithmetic), a theory of children's arithmetic implemented as a computational model. UMA builds on FARRA (Fraction Arithmetic Reflects Rules and Associations; Braithwaite et al., 2017), a model of children's fraction arithmetic. Whereas FARRA-like all previous models of arithmetic-focused on arithmetic with only one type of number, UMA simulates arithmetic with whole numbers, fractions, and decimals. The model was trained on arithmetic problems from the first to sixth grade volumes of a math textbook series; its performance on tests administered at the end of each grade was compared to the performance of children in prior empirical research. In whole number arithmetic (Study 1), fraction arithmetic (Study 2), and decimal arithmetic (Study 3), UMA displayed types of errors, effects of problem features on error rates, and individual differences in strategy use that resembled those documented in the previous studies of children. Further, UMA generated correlations between individual differences in basic and advanced arithmetic skills similar to those observed in longitudinal studies of arithmetic development (Study 4). The results support UMA's main theoretical assumptions regarding arithmetic development: (a) most errors reflect small deviations from standard procedures via two mechanisms, overgeneralization and omission; (b) between-problem variations in error rates reflect effects of intrinsic difficulty and differential amounts of practice; and (c) individual differences in strategy use reflect underlying variation in parameters governing learning and decision making. (PsycInfo Database Record (c) 2024 APA, all rights reserved).
期刊介绍:
Psychological Review publishes articles that make important theoretical contributions to any area of scientific psychology, including systematic evaluation of alternative theories.