Misconceived Causal Explanations for Emergent Processes

Michelene, T. H.; Roscoe, Rod D.; Slotta, James D.; Roy, Marguerite; Chase, Catherine C.

doi:10.1111/j.1551-6709.2011.01207.x

Cited by 227 publications

(281 citation statements)

References 76 publications

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“…Thus, introducing and emphasizing threshold concepts in parallel with key concepts in natural selection education may be essential, but this raises questions about the optimal way(s) to do this, which we address in the following sections. Natural selection is an extremely complex probabilistic phenomenon that involves random processes, or at least processes with varying degrees of stochasticity (e.g., mutation, mating, and accidental death) that lead to profound self-organizing and emergent changes in populations of organisms over vast (and diverse) scales of space and time (Chi et al 2012). The complexity is illustrated by the interactions among genetic changes, physiological and developmental processes involved in phenotypic expression, myriads of environmental factors, fitness, survival, and (hence) selection pressures, all of which involve highly complex processes and vary massively over space and time.…”

Section: Temporal and Spatial Scalesmentioning

confidence: 99%

Biological Principles and Threshold Concepts for Understanding Natural Selection

2017

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Modern evolutionary theory is both a central theory and an integrative framework of the life sciences. This is reflected in the common references to evolution in modern science education curricula and contexts. In fact, evolution is a core idea that is supposed to support biology learning by facilitating the organization of relevant knowledge. In addition, evolution can function as a pivotal link between concepts and highlight similarities in the complexity of biological concepts. However, empirical studies in many countries have for decades identified deficiencies in students' scientific understanding of evolution mainly focusing on natural selection. Clearly, there are major obstacles to learning natural selection, and we argue that to overcome them, it is essential to address explicitly the general abstract concepts that underlie the biological processes, e.g., randomness or probability. Hence, we propose a twodimensional framework for analyzing and structuring teaching of natural selection. The first-purely biological-dimension embraces the three main principles variation, heredity, and selection structured in nine key concepts that form the core idea of natural selection. The second dimension encompasses four so-called thresholds, i.e., general abstract and/or nonperceptual concepts: randomness, probability, spatial scales, and temporal scales. We claim that both of these dimensions must be continuously considered, in tandem, when teaching evolution in order to allow development of a meaningful understanding of the process. Further, we suggest that making the thresholds tangible with the aid of appropriate kinds of visualizations will facilitate grasping of the threshold concepts, and thus, help learners to overcome the difficulties in understanding the central theory of life. Sci & Educ (2017) 26:953-973 https://doi

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Section: Temporal and Spatial Scalesmentioning

confidence: 99%

Biological Principles and Threshold Concepts for Understanding Natural Selection

2017

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“…The other rule looks for dependencies between connectors and results, looking at 7 types of dependencies. 3 In fact, 25 -30% of the student essay sentences had an LSA cosine greater that 0.75 with some sentence from the relevant document set. Ironically, this facilitates our job of classifying the student sentences.…”

Section: Inferring Causal Connectionsmentioning

confidence: 99%

“…Student sentences associated with these items tend to bear a striking similarity to the original texts that they came from. 3 The machine learning techniques have had a much more difficult time identifying conceptual material related to inferences between documents. Examples of these items are rather infrequent in the students' essays (explaining why we need a system like this).…”

Section: Concept Identificationmentioning

confidence: 99%

Toward Automatic Inference of Causal Structure in Student Essays

Hastings

Hughes

Britt

et al. 2014

Intelligent Tutoring Systems

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Abstract. With an increasing focus on science and technology in education comes an awareness that students must be able to understand and integrate scientific explanations from multiple sources. As part of a larger project aimed at deepening our understanding of student processes for integrating multiple sources of information, we are developing machine learning and natural language processing techniques for evaluating students' argumentative essays. In previous work, we have focused on identifying conceptual elements of the essays. In this paper, we present a method for inferring the causal structure of student essays. We used a standard parser to derive grammatical dependencies of the essay and converted them to logic statements. Then a simple inference mechanism was used to identify concepts linked to syntactic connectors by these dependencies. The results suggest that we will soon be able to provide explicit feedback that enables teachers and students to improve comprehension.

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“…Designing in this complex landscape requires appropriate methods and tools that embrace the dynamic nature of the design object. This is a challenge, as students might have difficulties dealing with emergent processes (Chi et al, 2011). The development of dynamic design media, such as simple simulation models (i.e.…”

Section: Future Challengesmentioning

confidence: 99%

Teaching urbanism: the Delft approach

Nijhuis

Stolk

Hoekstra

2017

Proceedings of the Institution of Civil Engineers - Urban Desig

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Technology has a long tradition in educating generations of internationally oriented designers, planners and researchers in urbanism. Here the domain of urbanism is defined as an interdisciplinary approach that engages in real-world sociocultural, ecological and technological issues affecting urban landscapes, from the perspective of spatial planning and design. Specifically, it combines the disciplines of spatial planning, urban design and landscape architecture, having their own theories, methods and techniques, but also sharing common grounds and being complementary. Urbanism education focuses on specific context-related design tasks, in which knowledge from different disciplines is synthesised into coherent multiscale proposals. This paper aims to elaborate on the foundations of the Delft approach to urbanism education that focuses on the urban landscape as a scale continuum, uses design research and research through design as important teaching and research strategies, and regards mapping and drawing as important tools for thinking. The typical Dutch geographic context and spatial planning traditions are the foundation for this approach. The paper addresses the backgrounds and describes the principles of the present education strategies, learning tactics and examination, and identifies their challenges.

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Misconceived Causal Explanations for Emergent Processes

Cited by 227 publications

References 76 publications

Biological Principles and Threshold Concepts for Understanding Natural Selection

Biological Principles and Threshold Concepts for Understanding Natural Selection

Toward Automatic Inference of Causal Structure in Student Essays

Teaching urbanism: the Delft approach

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