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1. Impact of prompts on students’ mathematical problem posing

   https://doi.org/10.1016/j.jmathb.2023.101087  

   Cai, Jinfa; Ran, Hua; Hwang, Stephen; Ma, Yue; Han, Jaepil; Muirhead, Faith (December 2023, The Journal of Mathematical Behavior)

   This study used three pairs of problem-posing tasks to examine the impact of different prompts on students’ problem posing. Two kinds of prompts were involved. The first asked students to pose 2–3 different mathematical problems without specifying other requirements for the problems, whereas the second kind of prompt did specify additional requirements. A total of 2124 students’ responses were analyzed to examine the impact of the prompts along multiple dimensions. In response to problem-posing prompts with more specific requirements, students tended to engage in more in-depth mathematical thinking and posed much more linguistically and semantically complex problems with more relationships or steps required to solve them. The findings from this study not only contribute to our understanding of problem-posing processes but also have direct implications for teaching mathematics through problem posing. 

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2. Exploring middle school teachers’ views about problem-posing tasks

   https://doi.org/10.1016/j.jmathb.2024.101140  

   Han, Jaepil; Hwang, Stephen; Muirhead, Faith; Cai, Jinfa (March 2024, The Journal of Mathematical Behavior)

   It is important to understand teachers’ views about problem-posing (PP) tasks and the prompts that are used in such tasks to engage students in posing problems. In this study, we explored 15 middle school mathematics teachers’ views about PP prompts. We found that the teachers’ views were motivated by their curricular reasoning around engaging and challenging their students and addressed five main prompt characteristics: openness, promoting critical thinking, providing scaffolding, more or less intimidating, and allowing for differentiation. The teachers’ reasoning suggested they attended to how PP can create opportunities for sensemaking, deepen students’ learning of mathematics, and foster students’ identities as creative doers of mathematics. How- ever, they did not address connecting students’ life experiences to mathematics, another key goal of teaching mathematics through PP. The findings have implications for curriculum developers and researchers regarding the design of PP tasks and the implementation of such tasks in the classroom, and they suggest several directions for future research. 

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3. On understanding mathematical problem-posing processes

   https://doi.org/10.1007/s11858-023-01536-w  

   Cai, Jinfa; Rott, Benjamin (February 2024, ZDM – Mathematics Education)

   Problem posing engages students in generating new problems based on given situations (including mathematical expressions or diagrams) or changing (i.e., reformulating) existing problems. Problem posing has been at the forefront of discussion over the past few decades. One of the important topics studied is the process of problem posing as experienced by students and teachers. This paper focuses on problem-posing processes and models thereof. We first provide an overview of previous research and then present the results of a scoping review regarding recent research on problem-posing processes. This review covers 75 papers published between 2017 and 2022 in top mathematics education research journals. We found that some of the prior research directly attempted to examine problem-posing processes, whereas others examined task variables related to problem-posing processes. We conclude this paper by proposing a model for problem-posing processes that encompasses four phases: orientation, connection, generation, and reflection. We also provide descriptions of the four phases of the model. The paper ends with suggestions for future research related to problem-posing processes in general and the problem-posing model proposed in particular. 

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4. Investigating problem-posing during math walks in informal learning spaces

   https://doi.org/10.3389/fpsyg.2023.1106676  

   Wang, Min; Walkington, Candace (March 2023, Frontiers in Psychology)

   Informal mathematics learning has been far less studied than informal science learning – but youth can experience and learn about mathematics in their homes and communities. “Math walks” where students learn about how mathematics appears in the world around them, and have the opportunity to create their own math walk stops in their communities, can be a particularly powerful approach to informal mathematics learning. This study implemented an explanatory sequential mixed-method research design to investigate the impact of problem-posing activities in the math walks program on high school students' mathematical outcomes. The program was implemented during the pandemic and was modified to an online program where students met with instructors via online meetings. The researchers analyzed students' problem-posing work, surveyed students' interest in mathematics before and after the program, and compared the complexity of self-generated problems in pre- and post-assessments and different learning activities in the program. The results of the study suggest that students posed more complex problems in free problem-posing activities than in semi-structured problem-posing. Students also posed more complex problems in the post-survey than in the pre-survey. Students' mathematical dispositions did not significantly change from the pre-survey to post-survey, but the qualitative analysis showed that they began thinking more deeply, asking questions, and connecting school content to real-world scenarios. This study provides evidence that the math walks program is an effective approach to informal mathematics learning. The program was successful in helping students develop problem-posing skills and connect mathematical concepts to the world around them. Overall, “math walks” provide a powerful opportunity for informal mathematics learning. 

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5. Understanding the cognitive processes of mathematical problem posing: evidence from eye movements

   https://doi.org/10.1007/s10649-023-10262-9  

   Zhang, Ling; Song, Naiqing; Wu, Guowei; Cai, Jinfa (November 2023, Educational Studies in Mathematics)

   This study concerns the cognitive process of mathematical problem posing, conceptualized in three stages: understanding the task, constructing the problem, and expressing the problem. We used the eye tracker and think-aloud methods to deeply explore students’ behavior in these three stages of problem posing, especially focusing on investigating the influence of task situation format and mathematical maturity on students’ thinking. The study was conducted using a 2×2 mixed design: task situation format (with or without specific numerical information)×subject category (master’s students or sixth graders). Regarding the task situation format, students’ performance on tasks with numbers was found to be significantly better than that on tasks without numbers, which was reflected in the metrics of how well they understood the task and the complexity and clarity of the posed problems. In particular, students spent more fixation duration on understanding and process- ing the information in tasks without numbers; they had a longer fixation duration on parts involving presenting uncertain numerical information; in addition, the task situation format with or without numbers had an effect on students’ selection and processing of information related to the numbers, elements, and relationships rather than information regarding the context presented in the task. Regarding the subject category, we found that mathematical maturity did not predict the quantity of problems posed on either type of task. There was no significant main group difference found in the eye-movement metrics. 

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