How to write a scientific paper/Policy Recommendations
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Мы предложили учитилям различные способы классификации средств начального обучения программированию. | Мы предложили учитилям различные способы классификации средств начального обучения программированию. | ||
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| + | // To develop and validate this framework, we conducted a study asking programming novices to play RoboBuilder, program-to-play game in which writing programs is the main mechanism of gameplay. | ||
[[Taxonomy of programming environments for novices]] | [[Taxonomy of programming environments for novices]] | ||
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== Discussion == | == Discussion == | ||
| + | === Vignettes=== | ||
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| + | Student quotations and vignettes are presented here to describe the /CT4G/ experience, but no claim is made that these data are representative of all students’ experiences with /CT4G/ as a whole. | ||
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| + | These '''brief vignettes''' show examples of how computing can align with, and leverage, existing student interests and ideas to enable new forms of Making and computational participation. | ||
== Examples == | == Examples == | ||
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Средства обучения началам программированию имеют серьезное значение, поскольку они попутно с умением кодировать формируют установки мышления и воздействуют наше поведение | Средства обучения началам программированию имеют серьезное значение, поскольку они попутно с умением кодировать формируют установки мышления и воздействуют наше поведение | ||
| + | === Embending === | ||
| − | === Rewrite it | + | * Additionally, while computer science classrooms might seem the most natural environment for computational thinking, embedding computational thinking practices in mathematics gives this work potential for broader impacts. |
| + | * By situating mathematical learning in a computational microworld, and encouraging learners to employ computational thinking practices in pursuit of mathematical understanding, we demonstrate the mutually supportive nature of computational thinking and the mathematical habits of mind that are the goal of mathematics classrooms. | ||
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| + | === Growing diversity of what CS looks like in the 21st century === | ||
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| + | As part of a yearlong computing course, students engage in Maker activities, participatory simulations, and computing projects that foreground the social and collaborative aspects of CS. Collectively, these activities are designed to introduce learners to the growing diversity of what CS looks like in the 21st century. | ||
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| + | * Using engaging materials and hands-on activities and exploring, introductory computing topics including big data, Web programming, and agent-based modeling, this course provides a wide array of pathways into computing, introducing learners to powerful computing ideas while aiming to shift perceptions of the field of CS. | ||
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| + | === CS & Making === | ||
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| + | * [[digital fabrication]] | ||
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| + | == Rewrite it == | ||
The constitutive role of language and tools on cognition has long been a topic of research. A central theme of Vygotsky’s sociocultural theory of mind was the claim that mental functioning is mediated by tools and signs. “The sign acts as an instrument of psychological activity in a manner analogous to the role of tool in labor” [13, p. 52]. | The constitutive role of language and tools on cognition has long been a topic of research. A central theme of Vygotsky’s sociocultural theory of mind was the claim that mental functioning is mediated by tools and signs. “The sign acts as an instrument of psychological activity in a manner analogous to the role of tool in labor” [13, p. 52]. | ||
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Текущая версия на 12:03, 7 января 2019
Содержание |
[править] Title - Policy Recommendations
[править] Abstract
[править] Key words
[править] Introduction
In formulating our framework for categorizing the ways that novices use block-based languages, we looked to the literature and found two distinct dimensions along which mediational roles differ that could lead to a productive classification that fit our emerging findings.
[править] Methods
Мы предложили учитилям различные способы классификации средств начального обучения программированию.
// To develop and validate this framework, we conducted a study asking programming novices to play RoboBuilder, program-to-play game in which writing programs is the main mechanism of gameplay.
Taxonomy of programming environments for novices
[править] Results
[править] Discussion
[править] Vignettes
Student quotations and vignettes are presented here to describe the /CT4G/ experience, but no claim is made that these data are representative of all students’ experiences with /CT4G/ as a whole.
These brief vignettes show examples of how computing can align with, and leverage, existing student interests and ideas to enable new forms of Making and computational participation.
[править] Examples
- Network science was examined by the National Research Council (NRC), the arm of the US National Academies in charge of offering policy recommendation to the US government.
- These reports not only documented the emergence of a new research field, but highlighted the field’s role for science, national competitiveness and security.
[править] Content
Средства обучения началам программированию имеют серьезное значение, поскольку они попутно с умением кодировать формируют установки мышления и воздействуют наше поведение
[править] Embending
- Additionally, while computer science classrooms might seem the most natural environment for computational thinking, embedding computational thinking practices in mathematics gives this work potential for broader impacts.
- By situating mathematical learning in a computational microworld, and encouraging learners to employ computational thinking practices in pursuit of mathematical understanding, we demonstrate the mutually supportive nature of computational thinking and the mathematical habits of mind that are the goal of mathematics classrooms.
[править] Growing diversity of what CS looks like in the 21st century
As part of a yearlong computing course, students engage in Maker activities, participatory simulations, and computing projects that foreground the social and collaborative aspects of CS. Collectively, these activities are designed to introduce learners to the growing diversity of what CS looks like in the 21st century.
- Using engaging materials and hands-on activities and exploring, introductory computing topics including big data, Web programming, and agent-based modeling, this course provides a wide array of pathways into computing, introducing learners to powerful computing ideas while aiming to shift perceptions of the field of CS.
[править] CS & Making
[править] Rewrite it
The constitutive role of language and tools on cognition has long been a topic of research. A central theme of Vygotsky’s sociocultural theory of mind was the claim that mental functioning is mediated by tools and signs. “The sign acts as an instrument of psychological activity in a manner analogous to the role of tool in labor” [13, p. 52].
- Vygotsky claimed that mental functioning is mediated by tools and signs.
diSessa [1] calls this Material Intelligence, saying “we can instill some aspects of our thinking in stable, reproducible, manipulable, and transportable physical form” (p. 6). Work looking at the relationship between signs (or more broadly representations) and cognition has delineated the particularities of how representations are bound up with knowledge, learning, tasks and uses [1, 11, 12, 14-16]. Similar work focusing on the design of programming languages has shown how various features of the representation, be they visual [17, 18], semantic [19], or syntactic [20], all influence the ease of use of the resulting language.
