Reflections of future kindergarten teachers on the design of a mathematical instruction process didactic sequences with the use of robots

Seckel, María José; Breda, Adriana; Farsani, Danyal; Parra, José Hernán

doi:10.29333/ejmste/12442

Cited by 7 publications

(16 citation statements)

References 35 publications

(35 reference statements)

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“…The integration of ER in ITT should therefore include: space for sharing and discussing ideas and experiences; observing peers managing classes that integrate ER; continuous teaching support during the stages of training, planning, and performance; a specific theoretical, practical, reflective and didactic component (Schina et al, 2021a); and, similar to any training program focused on technology integration, the application of lesson plans in a real classroom setting and subsequent reflection (Pedro et al, 2019;Schina et al, 2021a;Song, 2018). Since competency in lesson plan creation influences the integration of ER in PST teaching practices (Tankiz & Uslu, 2022) ITT programs that integrate ER should enable PST to create lesson plans that integrate ER (Kim et al, 2015;Seckel et al, 2022) and implement them during their teaching practices (Kucuk & Sisman, 2017;Luciano et al, 2019;.…”

Section: Theoretical Backgroundmentioning

confidence: 99%

“…In light of the above, and as further explained in the next section, this study aims to create conditions for PST to: experience the integration of ER in practical and contextualized situations (Casler-Failing, 2021;Huang & Zbiek, 2017), contacting with different ER platforms (Anwar et al, 2019;Schina et al, 2021b), aiming at increasing their acceptance of ER with the purpose of facilitating proper integration into their teaching practices (Davis, 1989;Rafique et al, 2020), allowing PST to participate in collaborative tasks that integrate ER with their peers (Anwar et al, 2019;You et al, 2021), create and implement learning scenarios in real classroom setting (Tankiz & Uslu, 2022;You et al, 2021), and reflect on this process (Schina et al, 2021b;Seckel et al, 2022). To adjust the intervention design we collected PST perceptions of ER regarding:…”

Section: Theoretical Backgroundmentioning

confidence: 99%

“…This was followed by the exploration of the design process of the learning scenarios created by the teacher/researcher for each didactic sequence through a set of written tasks. This learning scenario would then be adapted by the groups to the respective practicum context (Kim et al, 2015;Pedro et al, 2019;Seckel et al, 2022) with the design of a hypothetical learning scenario.…”

Section: Pedagogical Interventionmentioning

confidence: 99%

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Pre-service teachers’ perceptions towards integrating educational robotics in the primary school

Silva,

Costa,

Martins

2024

EURASIA J Math Sci Tech Ed

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This paper seeks to understand the impact of a training program on 19 pre-service primary school teachers’ perceptions towards educational robotics (ER). The training program is based on a reflective process of design and implementation of a learning scenario during the practicum, using a pre-experimental design. Quantitative data were collected through a questionnaire applied at three moments of the intervention: pre-intervention, post-intervention 1 (19 weeks after), and post-intervention 2 (37 weeks after). The results show that the features of the proposed training program positively influenced the pre-service teachers’ (PST) perceptions towards ER. Experiencing curricular integration of ER and participation in a reflective process of learning scenario design positively influenced their perceptions in post-intervention 1. After experiencing the integration of ER in the practicum class, PST adjusted their positive perceptions in post-intervention 2. PST also displayed a decrease in neutrality in their perceptions in post-intervention 1 and post-intervention 2. Given the limited sample, it’s not possible to generalize these results, however they have implications for initial teacher training programs dedicated to technology integration. PST must be allowed to confront their preconceived perceptions of integrating technology into teaching and learning processes with the reflective process of designing and implementing a lesson plan that integrates technology during the practicum.

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Section: Theoretical Backgroundmentioning

confidence: 99%

Section: Theoretical Backgroundmentioning

confidence: 99%

Section: Pedagogical Interventionmentioning

confidence: 99%

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Pre-service teachers’ perceptions towards integrating educational robotics in the primary school

Silva,

Costa,

Martins

2024

EURASIA J Math Sci Tech Ed

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“…As Seckel and colleagues [15] pointed out, the majority of teachers, regardless of age, gender, and time spent in education, support the introduction of educational robotics. However, it is also important to highlight the inherent difficulties in teaching robotics [7] and to take feedback from teachers into account [16].…”

Section: Theoretical Framework 21 the Role Of Computational Thinkingmentioning

confidence: 99%

“…There is an annual competition organized in more than 50 countries for primary and secondary education students. The tasks based on grades and ages are split into five categories: Mini (grades three to four, ages 8-10), Benjamin (grades five to six, ages 10-12), Cadet (grades seven to eight, ages [12][13][14], Junior (grades nine to ten, ages 14-16), and Senior (grades eleven to twelve, ages [16][17][18]. The tasks are composed in a manner that they can be solved without any previous computer sciences knowledge [33].…”

Section: Materials 431 Beaver Cardsmentioning

confidence: 99%

Employing Robotics in Education to Enhance Cognitive Development—A Pilot Study

2022

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(1) Background: Info-communication technology (ICT) offers opportunities for innovations in teaching and learning methods, bringing significant changes in the world of pedagogy. The field called educational robotics is both a motivational basis for teaching and learning coding and programming, and a tool for linking STEM (Science, Technology, Engineering, and Mathematics) fields. Moreover, it might contribute to the development of cognitive and social skills. The aim of the present paper is to report on a pilot study at the intersection of neurodiversity and educational robotics. (2) Methods: The pilot study was part of a larger project, namely Robotics for the Inclusive Development of Atypical and Typical Children (RIDE). A pre-test/post-test design was used to examine the development of different cognitive processes in sixth-grade students, such as computational thinking (CT), spatial relations, visuo-constructive ability, attention, and reading ability, in relation to a robotics development program employed in the classroom. (3) Results: The results suggest a general improvement on nearly all measures. Specifically, participants’ performance improved significantly from pre-test to post-test in the visuo-constructive abilities test, they made significantly fewer reading errors, and improved substantially in their reading comprehension. (4) Conclusions: The RIDE project’s curriculum development has resulted in a highly innovative, sustainable, and inclusive package of pedagogical methods, and the pilot research shows promising results regarding the implementation of robotics in education.

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Computational thinking and repetition patterns in early childhood education: Longitudinal analysis of representation and justification

Acosta,

Alsina,

Pincheira

2023

Educ Inf Technol

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This paper provides a longitudinal analysis of the understanding of repetition patterns by 24 Spanish children ages 3, 4 and 5, through representation and the type of justification. A mixed quantitative and qualitative study is conducted to establish bridges between algebraic thinking and computational thinking by teaching repetition patterns in technological contexts. The data are obtained using: a) participant observations; b) audio-visual and photographic records; and c) written representations, in drawing format, from the students. The analysis involves, on the one hand, a statistical analysis of the representations of patterns, and on the other, an interpretive analysis to describe the type of justification that children use in technological contexts: “elaboration”, “validation”, “inference” and “prediction or decision-making”. The results show that: a) with respect to the representation of patterns, errors decreased by 27.3% in 3-to-5-year-olds, with understanding and correct representation of repetition patterns gaining prominence in more than 50% of the sample from the age of 4; b) on the type of justification used, it is evident that in 3-and-4-year-olds, “elaboration” predominates, and at 5, progress is made towards “validation”. We conclude that it is necessary to design learning sequences connected with theory and upheld through practice, and that foster the active role of the teacher as a promoter of teaching situations that help spur the beginning of computational and algebraic thinking.

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Reflections of future kindergarten teachers on the design of a mathematical instruction process didactic sequences with the use of robots

Cited by 7 publications

References 35 publications

Pre-service teachers’ perceptions towards integrating educational robotics in the primary school

Pre-service teachers’ perceptions towards integrating educational robotics in the primary school

Employing Robotics in Education to Enhance Cognitive Development—A Pilot Study

Computational thinking and repetition patterns in early childhood education: Longitudinal analysis of representation and justification

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