Abstract
Problem-posing is well known as an effective activity to learn problem-solving methods. Although the activity is considered in contributing to the understanding of the problem’s structure, it is not clear how learners could understand it through the activity. This study proposes a method to offer a visual representation for analyzing the problem-posing activity sequence in MONSAKUN, a digital learning environment for problem-posing of arithmetic word problems via sentence integration. This system requires users to pose a problem through combinations of given simple sentences based on the requirement. The system writes every single action into logs as sequences of problem-posing activity. The sequences are considered to represent the thinking processes of learners. The thinking process reflects their understanding and misunderstanding about the structure of the problems. This study created visualizations of learners’ problem-posing processes from the data obtained through the practical use of MONSAKUN, including the states in which many learners had difficulties finding the correct answer. In this study, we refer to such states as “trap states.” In MONSAKUN, a trap state is a combination of simple sentences where many learners tend to make and need relatively more actions to obtain the correct answer. As the result of the visualization and analysis of the data, some trap states have been identified, and they changed for each trial in the same problem.
Highlights
The importance of problem-posing activity in mathematics Problem-posing is considered to be an essential part of mathematical activity (Brown and Walter 1993)
The current study presented visualizations that externalized the activity of learners in a problem-posing learning environment, where students posed problems based on the requirements of an assignment
The support graph provides the number of states that were visited by learners
Summary
The importance of problem-posing activity in mathematics Problem-posing is considered to be an essential part of mathematical activity (Brown and Walter 1993). Providing students with an opportunity to pose their own problems can foster flexible thinking, enhance problem-solving skills, broaden their perception of mathematics, and enrich and consolidate basic concepts (Brown and Walter 1993; English 1996). The development of problem-posing skills for learners is one of the principal aims of mathematics learning, and it should occupy a central role in mathematics activities (Crespo 2003). Problem-posing activities could provide us with valuable insights into children’s understanding of mathematical concepts and processes, as well as Supianto et al Research and Practice in Technology Enhanced Learning (2016) 11:14 their perceptions of, and attitudes toward, problem-solving and mathematics in general (Brown and Walter 1993). The more information that can be obtained about what learners know and how they think, the more opportunities could be created for the enhancement of learners’ success (Cai 2003)
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