Conceptual and Procedural Knowledge

The ideas that underlie the title of this chapter have been part of a familiar debate in education, namely that of the contrast of content and process. In both science and mathematics similar arguments have taken place, and these debates represent a healthy examination of, not only the aims of science and mathematics education, but the teaching and learning issues, and as such they reflect the relative maturity of these subject areas. Even in technology education, which is still in its infancy as a subject, echoes of these debates exist and there are contrasts of approaches to the balance of process and content across the world. The 'debate' in technology is evangelical in nature, with for example, proponents making claims for problem-solving approaches as a basis for teaching with few accounts and almost no empirical research of what actually happens in classrooms. There is insufficient consideration of the learning issues behind this, or other proposals, and it is timely to turn our attention to student learning. This article examines the nature of technological knowledge and what we know about learning related to it. The article argues that learning procedural and conceptual knowledge associated with technological activity poses challenges for both technology educators and those concerned with research on learning.     

Enhancing Practicing Primary School Teachers' Pedagogical Content Knowledge in Technology

This paper describes the frameworks and cognitive tools that have been developed to enhance practising teachers' pedagogical content knowledge in primary school technology education. The frameworks evolved from our research that firstly examined existing teaching practices, secondly enhanced formative interactions and thirdly enhanced summative assessment strategies. The evidence gained over the three years demonstrated how the effective use of frameworks could be utilised to enhance teacher pedagogical content knowledge (PCK). How we see learning is of prime importance in examining the development of teacher pedagogical content knowledge. A sociocultural view of learning is taken where human mental processes are situated within their historical, cultural and institutional setting. In the research project we strongly emphasised the need for teachers to build a knowledge base for teaching technology. Critical aspects identified as enhancing PCK included: negotiated intervention, planning frameworks, reflection on case studies, workshops and support in classrooms, appropriate resources, teacher agreement meetings, portfolios of student work and summative profiles. The increased PCK resulted in: enhanced teacher knowledge about technology including the nature of technology, areas of technology and specific technological knowledge, changed pedagogical approaches, enhanced teacher student interaction, refinement of appropriate learning outcomes, critical decision making, improved teacher confidence, and enhanced student learning. Seven characteristics or features of pedagogical content knowledge that we believe are important for effective teaching and learning in technology are presented. This revised version was published online in July 2006 with corrections to the Cover Date.     

Developing Technological Stance: Children's Learning in Technology Education

Following a review of current research in children's learning in technology education, and an examination of the kinds of knowledge demanded in contemporary technology education programs in elementary schools, I argue that what is needed in early technology education programs is the scaffolding of what I am calling technological stance. This construct acknowledges the socio-cultural character of technology as a human endeavor. In contrast to programs which are oriented to application of conceptual and procedural knowledge or to programs in which knowledge is generated through interpretation of interactions with materials and tools, programs which support technological stance position learners as critical inquirers into both tool-related and discursive practices of technology.     

Recent Research in Learning Technological Concepts and Processes

This paper examines recent research in student learning of technological concepts and processes. To explore this area three inter-related aspects are considered; existing concepts of technology, technological knowledge and processes. Different views of technology and technology education are reflected in both research outcomes and curriculum documents. Teacher and student perceptions of technology impact on the way in which technology is undertaken in the classroom. Teacher's perceptions of technology influence what they perceive as being important in learning of technology. student's perceptions of technology and technology education influence what knowledge and skills they operationalise in a technological task and hence affect student technological capability. Technological concepts and processes are often defined in different ways by particular groups. Subject subcultures are strongly held by both teachers and students. The influence of subject subcultures and communities of practice will be discussed in terms of defining and operationalising technological concepts and processes. Technological concepts are not consistently defined in the literature. For students to undertake technological activities, knowledge and processes cannot be divorced. Recent research highlights the problems when processes are emphasised over knowledge. This paper will examine different technological concepts in an attempt to create a critical balance between knowledge and process. Much of the literature in technology education has rightly emphasised definitions, curriculum issues, implementation and teacher training. This paper argues that it is now time to place a great emphasis on in-depth research on student understanding of technological concepts and processes and ways in which these can be enhanced.     

The technological knowledge used by technology education students in capability tasks

Since technology education is, compared to subjects such as mathematics and science, still a fairly new subject both nationally and internationally, it does not have an established subject philosophy. In the absence of an established subject philosophy for technology education, one can draw on other disciplines in the field, such as engineering and design practice, for insights into technological knowledge. The purpose of this study is to investigate the usefulness of an epistemological conceptual framework chiefly derived from engineering, to be able to describe the nature of technological knowledge, in an attempt to contribute towards the understanding of this relatively new learning area. The conceptual framework was derived mainly from Vincenti’s (What engineers know and how they know it. Johns Hopkins University Press, Baltimore, 1990) categories of knowledge based on his research into historical aeronautic engineering cases. Quantitative research was used to provide insight into the categories of knowledge used by students at the University of Pretoria during capability tasks and included an analysis of a questionnaire administered to these students. Findings suggest that the conceptual framework used here is useful in technology education and that the categories of technological knowledge apply to all the content areas, i.e. structures, systems and control, and processing, in technology education. The study recommends that researchers and educators deepen their understanding of the nature of technological knowledge by considering the categories of technological knowledge presented in the conceptual framework.     

Knowledge Types in Technology

Starting with the distinction of natural science, engineering science ("technology") and engineering practice ("technics"), the paper will stress the difference between technological and technical knowledge. The first part will discuss the relationship between science and technology, arguing that technology is a genuine type of knowledge rather than "applied science". In technics, however, even technological laws, as transformations of scientific laws, cover a certain part of knowledge only. The greater part of technical knowledge includes technical know-how, functional rules, structural rules, and socio-technological understanding, which is just developing in our times. The classification of knowledge types will be used for determining which kind of knowledge may seem appropriate to general technological education.     

Knowledge and Values in Technology Education

This paper addresses two closely interrelated issues in Technology Education: knowledge and values. The starting point for the discussion is analysis of the nature of knowledge in technology education. Approaches for theorising knowledge will be analysed in this paper as well as problems associated with them. Three major types of problems are identified: problems with finding an appropriate approach for the analysis of technological knowledge; problems with a technocratic interpretation of technological knowledge for the purpose of its classification; and problems with establishing a consistent approach to distinguish common features of technological knowledge. A model that represents knowledge in technology education and the place of values in it is presented as a way of overcoming the problems specified. The claim is made that understanding of knowledge/values relationships can improve theoretical understanding of how technology education can be constructed.     

Delivering technological literacy to a class for elementary school pre-service teachers in South Korea

This study was conducted with the aim of creating a new introductory course emphasizing the development of technological literacy for elementary school pre-service teachers. This study also aimed to investigate elementary school pre-service teachers’ attitudinal transition toward elementary school technology education (ESTE) and its implementation. An introductory ESTE program within Practical Arts Education was developed through a procedure consisting of preparation, development, and improvement. The program was implemented among 127 elementary school pre-service teachers for 7 weeks in South Korea. The learning contents based on the ESTE research and national curriculum included (1) technology learning units in the Practical Arts textbooks, (2) technology and invention, (3) drawing and design, (4) wood products, (5) basic electricity and electronics, and (6) integrative science, technology, engineering, and mathematics/science, technology, engineering, arts, and mathematics education. These contents were delivered via an instructor’s lecture, hands-on activities on technological design, and cooperative learning. A pre- and post-test on the study participants’ attitudes toward ESTE and on their knowledge, competency, and anxiety in relation to the six learning contents were conducted. The research results indicated a stable improvement in the study participants’ attitudes toward ESTE, their level of knowledge about ESTE, and their competency to teach ESTE. The developed program also decreased their anxiety in relation to teaching ESTE. The study findings may provide useful insights into the professional development of elementary school teachers in connection with ESTE, and into the implementation of technology education in the elementary school setting.     

The study of technology as a field of knowledge in general education: historical insights and methodological considerations from a Swedish case study, 1842–2010

Today, technology education in Sweden is both a high-status and a low-status phenomenon. Positive values such as economic growth, global competitiveness and the sustainability of the welfare state are often coupled with higher engineering education and sometimes even upper secondary education. Negative values, on the other hand, are often associated with primary and lower secondary education in this subject. Within the realm of technology education at such lower levels of schooling in Sweden, different actors have often called for reformed curricula or better teacher training, owing to the allegedly poor state of technology education in schools. Recurring demands for a change in technology education are nothing unique from an historical point of view, however. In fact, the urge to influence teaching and learning in technology is much older than the school subject itself. The aim of this article is to describe and analyse some key patterns in technology education in Swedish elementary and compulsory schools from 1842 to 2010. This study thus deals with how technological content has developed over time in these school forms as well as how different actors in and outside the school have dealt with the broader societal view of what is considered as important knowledge in technology as well as what kind of technology has particular significance. The long period of investigation from 1842 to 2010 as well as a double focus on technology as scattered educational content and a subject called Technology make it possible to identify recurring patterns, which we have divided into three overarching themes: Technological literacy and the democratic potential of technological knowledge, The relationship between school technology and higher forms of technology education and The relationship between technology and science.     

A conceptual framework for developing the curriculum and delivery of technology education in early childhood

The purpose of this article is to provide an overview of the analysis of the Early Childhood Education (ECE) curriculum in six countries involved in the UPDATE-project, and on that basis, propose a conceptual foundation for technology education in ECE that aims to enhance gender sensitive technology education in the continuum from early years to adulthood. The existing ECE curricula in the participating countries were analysed according to the general pedagogical approach as well as the contents specific to technology education. In many cases technology education was presented generally or implicitly, embedded in various curriculum content areas, and the existing curricula did not offer much support for teachers to figure out the nature, aims and pedagogical means of early childhood technology education. The comparison of the curricula raised some common key-issues which are important to construe more theoretically. In consequence, the article also focuses on the contemporary view of child-centred pedagogy and the conceptualisation of technology education fitting into the scope of ECE. Play is highlighted as a fundamental way of learning seldom studied in the context of technology education. In addition, a gender perspective on technology education deals with equal possibilities of both sexes to acquire knowledge, abilities and attitudes needed in technological agency.     

Technology learning 2: Towards reawakening the technologists within primary teachers

We begin by setting out a view of learning as framework-building; enabling learners to shift their perspectives. For us, this expresses the essential unity of many human endeavours — in particular, for our purposes, children's learning, teachers' theory-building and the evolution of scientific understanding. We identify two frameworks which, we contend, are currently limiting the vision of teachers in fundamental ways and with serious consequences for their students. One is a transmission perspective on learning (in which New South Wales schooling has traditionally been steeped) and the other, a limiting conception of and anxious approach to technology (significantly impeding its meaningful penetration into schools). To learn how to help teachers break free of these restraints, we provided an opportunity for our teachers to become learners themselves in a technological context based on developmentalist views of learning and teaching. Here they became self-directing, challenged and fulfilled, gaining feelings of control over the technology, and each developed a powerful and personal appreciation of another framework for learning and teaching. In what they did, we can identify approaches which enabled a plurality of epistemologies to flourish. In conclusion, we predict a key role for these kinds of technological contexts in learning.Mark Cosgrove teaches in teacher education programs in the Faculty of Education at the University of Technology, Sydney. He studies the history and development of ideas in science and technology and their roles in cultures, and is exploring the notion that learning and technology are natural, biological phenomena. Lynette Schaverien is a research scholar investigating the learning and teaching of science and technology in primary schools. She is interested in developing teaching approaches which foster and sustain children's natural curiosity, and styles of mentoring which will regenerate teachers' powers to exploit that curiosity in classrooms.     

知识网络视角下虚拟科技园区发展模式研究

虚拟科技因区作为一种新型的产学研合作网络组织形式备受关注.本文从知识网络这一视角出发,分析虚拟科技园区知识网络的构成要素和相互作用关系,构建了虚拟科技园区知识循环创造模型,提出虚拟科技园区建立学习型组织的发展模式,在构建学习型组织的过程中应充分考虑虚拟化运营中合作伙伴文化背景复杂、合作意图差异及缺乏足够的相互信任所引发的学习智障,建立科学健全的基于组织层面和网络层面的学习机制,并以云南省大学科技园为案例进行分析.     

The Nature of Technology for Design

This paper reviews ideas from design and technology and science education and discusses knowledge, values and skills as aspects of technology in order to demonstrate that technology for design cannot be simply associated with a knowledge component of technology. The paper highlights the linguistic challenges in expressing issues in this area and the philosophical difficulty that the nature of cognitive modelling means that some aspects may be impossible to express using language. Values and a designerly way of knowing and the nature of technological skills are discussed in order to establish their relationship to technology for design. Prior studies concerning technology and designing have focused on engineering and science-based design areas. A research agenda in relation to the proposed broader interpretation of technology for design is discussed, which demonstrates that such research must ultimately be interdisciplinary. Nevertheless, initial steps which could be taken by design researchers are suggested.     

Attitudes towards science, technology, engineering and mathematics (STEM) in a project-based learning (PjBL) environment

Many scholars claimed the integration of science, technology, engineering and mathematics (STEM) education is beneficial to the national economy and teachers and institutes have been working to develop integrated education programs. This study examined a project-based learning (PjBL) activity that integrated STEM using survey and interview methods. The participants were 30 freshmen with engineering related backgrounds from five institutes of technology in Taiwan. Questionnaires and semi-structured interviews were used to examine student attitudes towards STEM before and after the PjBL activity. The results of the survey showed that students’ attitudes to the subject of engineering changed significantly. Most of the students recognized the importance of STEM in the science and engineering disciplines; they mentioned in interview that the possession of professional science knowledge is useful to their future career and that technology may improve our lives and society, making the world a more convenient and efficient place. In conclusion, combining PjBL with STEM can increase effectiveness, generate meaningful learning and influence student attitudes in future career pursuit. Students are positive towards combining PjBL with STEM.     

The senior high school students’ learning behavioral model of STEM in PBL

The purpose of the study was to explore a learning behavioral model of project-based learning (PBL) for senior high school students in the context of STEM (science, technology, engineering, and mathematics). Using “audio speakers” as the project theme, a series of tasks were designed to be solved using STEM knowledge via an online platform and student group discussions. A total of 84 volunteer students from a senior high school and a vocational school in Pingtung, Taiwan, were divided into 21 groups. Text analysis and questionnaire survey were administered. Data sources were the participants’ information collected via the STEM online platform and the questionnaire survey regarding STEM in PBL. The findings of the study are as follows: (1) the learning behavioral model for STEM in PBL showed a positive influence on students’ behavior in the form of cognition and behavioral intentions. In addition, cognition and behavioral intentions were positively influenced by attitude. The overall model fit was positive and could effectively explain senior high school and vocational school students’ learning behavior as related to STEM in PBL; (2) according to the results of the analysis of STEM from the online platform, students displayed a positive attitude, attained integrated conceptual and procedural knowledge, and demonstrated active behavioral intentions through STEM in PBL. In addition, the students’ creative and organized project outcomes revealed the effects of their behavior.     

Shaping Concepts of Technology: What Concepts and How to Shape Them

Philosophy of technology is a discipline that has much to offer for technology education. Insights into the real nature of technology and its relationship with science and society can help technology educators to build a subject that helps pupils get a good concept of technology and to learn to understand and use concepts in technology. Here the way science educators have gained from the philosophy of science, for example in the idea of the way pupils learn concepts by reconstructing pre-concepts that they picked up from daily-life experiences. Research has shown that the learning of concepts and the learning of process skills have to be connected.     

The use of design practice to teach mathematics and science

Relatively low participation in the hard sciences (mathematics, science, engineering and technology) has become a concern with respect to the capacity of Australia to meet critical infrastructure projects. This problem has its roots in poor student attitudes towards and perceptions about the study of prerequisite subjects including mathematics and science. Perception formation commences early in students’ education where students have claimed that mathematics was not intrinsically useful and was difficult to understand. With this mind, an intervention was planned and implemented in which technology and design practice was used to integrate the study of mathematics so students could produce and explain a useful artefact. The integrated design project included a focus upon instructional and regulatory discourse. Useful integration tools were developed that facilitated positive cognitive discourses such that students demonstrated a functional understanding of mathematical concepts, reported a broader and more applied understanding of the nature of mathematics and a belief that integration had helped them to make more sense of mathematics.     

The impact of problem-based learning strategies on STEM knowledge integration and attitudes: an exploratory study among female Taiwanese senior high school students

This study was designed to explore the effects of problem-based learning (PBL) strategies on the attitudes of female senior high school students toward integrated knowledge learning in science, technology, engineering, and mathematics (STEM). Content analysis and focus group methods were adopted as the research processes. Data and information about the STEM internet platform, an attitude scale and the contents of interviews were also collected for analysis. The subjects were 10th grade students at a girls’ senior high school who volunteered to organize teams for a Solar Electric Trolley Contest. A total of 40 students were grouped into 18 teams. The results of the study indicate: (1) that PBL strategies can be helpful in enhancing students’ attitudes toward STEM learning and the exploration of future career choices; (2) that the PBL teaching strategy helped to lead students step by step toward completing the contest’s mission and to experience the meaning of integrated STEM knowledge; (3) that not only that students can actively apply engineering and science knowledge, but also that students tend to gain more solid science and mathematics knowledge through STEM learning in PBL; and (4) that PBL can enhance students’ abilities and provide them experiences related to knowledge integration and application. Therefore, it is recommended that the curriculum at the girls’ senior high school include more content related to specialty subjects to enhance their technological capabilities. In addition, a learning mechanism should be offered to aid advisers or teachers in strengthening students’ integrated and systematic knowledge about STEM.     

The experiential domain: developing a model for enhancing practice in D&T education

Creativity and innovation are leading topics for the twenty-first century, not only in individual, cultural or social contexts but also within a wider perspective in business or economic development. For that reason, creative and innovative activities have started to feature in many design-based programs in second level education. Design and Technology (D&T) education has a special importance in promoting creativity and innovation, particularly when conceptual and material aspects of the design process reciprocally support one another. In the classroom, it is common for pupils to take part in creative and innovative activities in pairs or small groups. However, the complex and non-linear nature of these design-based activities calls for dynamic, collaborative problem solving. While collaborative settings and virtual learning environments in D&T education are receiving considerable attention in current research literature, we know very little about shared interactions in design-based activity. Accordingly, there is a need to examine both the collaborative and individual evidence of design-based activity by turning our attention to the interactions around that evidence as teachers and pupils engage in these activities. The purpose of this paper is to examine a pedagogical approach focusing on the social and cognitive interaction of teachers and pupils which is supported by technology and situated in the context of design-based activity. This research found that such interactions not only augmented the design process but led to a conceptual model which demonstrates evidence-based progress through the active configuration of knowledge and understanding.     

STEM education in the twenty-first century: learning at work—an exploration of design and technology teacher perceptions and practices

Teachers’ knowledge of STEM education, their understanding, and pedagogical application of that knowledge is intrinsically linked to the subsequent effectiveness of STEM delivery within their own practice; where a teacher’s knowledge and understanding is deficient, the potential for pupil learning is ineffective and limited. Set within the context of secondary age phase education in England and Wales (11–16 years old), this paper explores how teachers working within the field of design and technology education acquire new knowledge in STEM; how understanding is developed and subsequently embedded within their practice to support the creation of a diverse STEM-literate society. The purpose being to determine mechanisms by which knowledge acquisition occurs, to reconnoitre potential implications for education and learning at work, including consideration of the role which new technologies play in the development of STEM knowledge within and across contributory STEM subject disciplines. Underpinned by an interpretivist ontology, work presented here builds upon the premise that design and technology is an interdisciplinary educational construct and not viewed as being of equal status to other STEM disciplines including maths and science. Drawing upon the philosophical field of symbolic interactionism and constructivist grounded theory, work embraces an abductive methodology where participants are encouraged to relate design and technology within the context of STEM education. Emergent findings are discussed in relation to their potential to support teachers’ educational development for the advancement of STEM literacy, and help secure design and technology’s place as a subject of value within a twenty-first Century curriculum.