Elementary Algebraic thinking with patterns in two variables

Adam Scharfenberger, Leah M. Frazee
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Abstract

Usiskin (1999) described four conceptions of algebra: Algebra as Generalized Arithmetic, Algebra as a Study of Procedures for Solving Certain Kinds of Problems, Algebra as the Study of Relationships among Quantities, and Algebra as the Study of Structures. The Algebra as the Study of Relationships among Quantities conception relates to the NCTM (2000) Algebra Standard expectation that students “understand patterns, relations, and functions” (p. 37). Algebraic thinking “includes being able to think about functions and how they work, and to think about the impact that a system’s structure has on calculations” (Driscoll, 1999, p. 1). Analyzing students’ algebraic thinking with patterning tasks in two variables allows researchers to understand how students think about functions, how they work, and how the representation provided in the question impacts student thinking about the structure of the problem. In this study, one elementary student solved patterning problems in two variables with different representations during a task-based interview (Goldin, 2000). Preliminary findings suggest that this student used different reasoning strategies when given pattern problems in two different representations. On a task consisting of a visual pattern of figures growing in an arithmetic sequence, the student visualized how the growth occurred in each successive figure. The student used the rate of growth to compute the size of the figure at future iterations. In the context of this task, the evidence suggests that the student was thinking covariationally (Confrey & Smith, 1994) about the relationship between the increase in figure size and increase in figure number. When presented with a task showing a linear relationship between values in an input-output table of numbers, the student was asked to determine the output value when the input value was 38. Upon receiving this question, the student intensely looked at the problem before stating: Oh, I see it now. Okay, so I see if you multiply this by – each number [points at all the numbers in the left input column] by two and add 1, that’s the number on this side [points at all the numbers in the right output column]. So take 15 for example. 15 times 2 is 30, plus 1 is 31 and that is in the out. [15 and 31 correspond to each other in the table. 15 being in the input column and 31 being in the output column]. The student used this mapping between the numbers in the input column and the output column to determine 38 corresponds to 77. In this context, the student used a correspondence approach (Confrey & Smith, 1994) to determine the output when the input was 38. In conclusion, both tasks contained the same structure as linear functions. However, the student thought differently about how the functions “worked” when given a visual pattern of growth as opposed to when given an input-output table. This student showed the capacity to reason through covariation and correspondence while the context of the problem may have influenced the approach. The poster presentation will provide evidence and vignettes from the task-based interview.
二元模式的初等代数思维
Usiskin(1999)描述了代数的四个概念:代数是广义算术,代数是研究解决某些问题的过程,代数是研究数量之间的关系,代数是研究结构。作为量之间关系研究的代数概念与NCTM(2000)代数标准期望学生“理解模式、关系和函数”有关(第37页)。代数思维“包括能够思考函数及其工作方式,以及思考系统结构对计算的影响”(Driscoll, 1999, p. 1)。通过两个变量的模式任务分析学生的代数思维,研究人员可以了解学生如何思考函数,它们如何工作,以及问题中提供的表示如何影响学生对问题结构的思考。在本研究中,一名小学生在任务型访谈中解决了两个不同表征变量的模式问题(Goldin, 2000)。初步研究结果表明,该学生在两种不同表征的模式问题中使用了不同的推理策略。在一项由等差数列增长的数字的视觉模式组成的任务中,学生想象每个连续数字的增长是如何发生的。学生使用增长率来计算未来迭代时图形的大小。在这个任务的背景下,有证据表明,学生正在协变地思考图形大小增加和图形数量增加之间的关系(Confrey & Smith, 1994)。当学生被要求完成一项任务,显示数字输入输出表中值之间的线性关系时,学生被要求确定输入值为38时的输出值。接到这个问题后,学生认真地看了看问题,然后说:哦,我现在明白了。好了,如果你把这个乘以——每个数字[指向左边输入列的所有数字]乘以2,再加上1,这就是这边的数字[指向右边输出列的所有数字]。以15为例。15乘以2等于30,加上1等于31,这是在外面。[15]和[31]在表中相互对应。15在输入列,31在输出列]。该学生使用输入列和输出列中的数字之间的这种映射来确定38对应于77。在这种情况下,该学生使用对应方法(Confrey & Smith, 1994)来确定输入为38时的输出。总之,这两个任务都包含相同的线性函数结构。然而,当给出一个可视化的增长模式时,与给出一个输入输出表时,学生对函数如何“工作”的看法不同。该学生表现出通过协变和对应进行推理的能力,而问题的背景可能影响了方法。海报展示将提供基于任务的面试的证据和小插曲。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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