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.     

Issues of Learning and Knowledge in Technology Education

This article examines issues that arise from learning and knowledge in technology education. The issues examined are, first, the definition of technological knowledge and what the nature of that knowledge should be, where the concern is with how we define and think about that knowledge, especially in the context of how students learn and use knowledge in technology education. Second, the relationship between learning and knowledge in particular the inter-relationship between learning and knowledge, focusing on a situated view of learning. The third issue sees learning related to the context within which the learning takes place.This paper will explore these three inter-related issues in four sections. First, an outline of a view of learning that privileges context. Second, there will be a consideration of types of knowledge, namely, procedural and conceptual knowledge. These two types will be elaborated upon through research done at the Open University, particularly on problem solving and design. In discussing conceptual knowledge empirical work in mathematics and science education will be drawn on, along with work on the use of mathematics and science in technology education. Third, it will be argued that qualitative knowledge should become a part of teaching and learning in technology education because it both reflects a view of knowledge stemming from situated learning, and the tasks of technology. The article will end with a research agenda for what we have yet to understand, drawing on the earlier arguments.     

Creative Thinking, Values and Design and Technology Education

The development of Design and Technology curricula has always been premised on the importance of the act of designing and of the value of the contingent activity of creative thinking. Despite this, there has been a great deal of uncertainty about methods for developing creative thinking abilities in design and technology students. However, the results of research from cognitive psychology, engineering and invention suggest some promising strategies for application in design and technology classes. Moreover, these strategies are emerging during a time when issues concerning ethics and values are also being raised. This paper presents a brief summary of the research into problem-solving and design. It then explores a range of creative thinking strategies, and of their possible applications in design, and goes on to argue that the strategies and settings that promote creative thinking in design and technology make the area not only one that is suitable for addressing ethics and values, but that it may be one of the major reasons for including design and technology programs in school curricula.     

Promoting Girls' Interest in Technology through Technology Education: A Research Study

The article summarises the design and outcome of an inquiry into the promotion of interest in technology by technology education. The reason for the present study is the low proportion of women in technical occupations, studies or subjects. Such a marked gender difference leads to different ways of life which discriminate against women. It is necessary, therefore, to search for the underlying causes and to take measures in order to support technological activities. The aim of the German study was to determine differences in the interests of girls and boys in technology and to support interest more widely in technology by technology education. The study was conducted in a class in the third year of elementary education. At first, differences between girls and boys in the intensity and gearing of interest in technology were determined by a survey. After exposure of a `treatment Group' to technology education, the effects of such education were established by mean of a second survey. The results of the first and second survey were compared. The results show that the interests of girls and boys were aroused by technology education. Furthermore, gender differences are reduced significantly. The findings of this study suggest that it is essential to intensify technology education in elementary school because it is the earliest opportunity for curriculum intervention. This revised version was published online in July 2006 with corrections to the Cover Date.     

The Nature of Technological Knowledge: Philosophical Reflections and Educational Consequences

Technological knowledge has a normative component that scientific knowledge does not have. When we have knowledge of a computer, that often comprises normative judgements: it functions well or it does not function well. In knowledge of technical norms, rules and standards as another type of technological knowledge we also find a normative component. This characteristic has consequences for our assessment of knowledge. For scientific knowledge truth is the ultimate condition. For knowledge of norms, rules and standards as a type of technological knowledge this the condition is problematic. They refer to things that do not exist yet, but are still to be designed or made. Nor truth, but effectiveness is the condition here. For technology education the normative component is important. Pupils must learn to make judgements about effectiveness, as this is a prominent characteristic of technological knowledge, that makes it distinct from scientific knowledge. Pupils must also learn to deal with ethical and other values when doing technological project work.     

The Impact of the Implementation of Technology Education on In-Service Teacher Education in South Africa (Impact of Technology Education in the RSA)

In this article the impact of technology education, as a new learning area (subject) in the curriculum, on in-service teacher education in South Africa is described in order to ascertain the extent of the impact. The research on which this article is based draws on a variety of experiences and observations in the field at grassroots level (in particular an outreach project in rural communities). The envisaged impact of technology education on South African schools, communities, teacher educators and teachers, the range of in-service teacher education that is required, and the impacts in urban and rural areas are discussed. Finally a number of concluding remarks are made about the extent of the impact of the inclusion of technology education in the new National Curriculum Statement and whether the situation has changed since the implementation of a pilot technology education project in 1998. This revised version was published online in July 2006 with corrections to the Cover Date.     

技术创新过程中的知识获取路径研究

知识获取作为影响技术创新的关键环节,决定着创新的效率与成败。本文在分析已有知识获取研究成果的基础上,提出了技术创新的知识体系结构,进而依据技术创新过程中的知识获取特点,从知识的识别和转化、知识的转移和共享、知识的流动等方面系统研究了知识获取的路径,为技术创新提供了一种新思路,有利于在提高企业知识获取效率的同时加快其技术创新步伐,以达到最大化组织价值之目的。     

Multidisciplinary Technology Education

Contrary to a tale that is being told in the US, there is no transhistorical, universally pristine organisation of technology. This article resituates technology education in the contested, historico-political terrain to which it belongs. The current, and only, model of the technology discipline is interrogated in order to interrupt a project with roots bound up with a doctrinaire, academic conservatism popularised during the early 1960s. Following a lively critique of the technology mono-discipline, comparative curriculum is used for path-finding and interpretation. Counter to the mono-discipline model of technology, the conceptual parameters of a critical and plural multidiscipline are outlined. ‘Multidisciplinary Technology Education’ (MTE), inspired through efforts in art education, is proposed as a middle path between the technology mono-discipline and Design and Technology. MTE is balanced over four interdisciplines – Practice, Design, Studies and Criticism – with an end in technological sensibility and political sagacity. This revised version was published online in August 2006 with corrections to the Cover Date.     

The Influences of Teacher Knowledge and Authentic Formative Assessment on Student Learning in Technology Education

Students involved in holistic technological practice need to develop an understanding of technological practice outside the classroom and to participate in tasks set as close as practicable to actual technological practice. This paper investigates the context of assessment and its relationship to achievement and the importance of teacher knowledge to student technological practice. I argue that ‘out of context’ assessment tasks do not give an accurate indication of achievement levels of the children assessed. Introduced is the Model of Student Technological Practice, which identifies four constraints that influence student technological practice. A significant factor is teacher knowledge, as it impacts greatly on the quality of feedback given to students by their teachers. Timely teacher intervention and formative assessment feedback will alter student technological practice and should improve the students’ likelihood of developing successful outcomes.     

Authentic Program Planning in Technology Education

This paper reports on the needs identified by three teachers during an investigation into their first experiences of implementing technology in their primary classrooms. One part of one teacher's case is presented in detail to illustrate that the meanings the teachers made of their experiences were related very closely to their beliefs about teaching and learning, to their understanding of technology as a phenomenon and to the place they saw technology having within the whole curriculum. One particular outcome of the investigation was that the teachers experienced a lack of knowledge of the scope and breadth of the technology learning area, and as a consequence, faced challenges in planning for the successful implementation of activities. In response to this particular need and to the many issues emanating from current research literature in technology education, the paper then presents two models for conceptualizing and planning units of work in technology in primary classrooms. The models form frameworks that may be useful to help structure thinking for authentic classroom planning and sequencing of lessons or learning experiences. This revised version was published online in July 2006 with corrections to the Cover Date.     

The Essential Features of Technology and Technology Education: A Conceptual Framework for the Development of OBE (Outcomes Based Education) Related Programmes in Technology Education

It appears that programme development in technology education is emerging from an atheoretical perspective. This could be attributed to the absence/neglect of conceptual frameworks (philosophical underpinning) in the development of programmes in technology education. This article explores the role of the content dimension of the 'essential features' of technology and technology education in OBE (Outcomes Based Education) related programme development. An instructional programme was developed using criteria derived from the essential features of technology and technology education. In order to gauge learners' experience, in relation to these essential features, a qualitative case study involving 20 learners was undertaken at a College of Education. Engagement with theprogramme proved to be an empowering experience for the learners who had hitherto not had the opportunity to experience a formal programme in technology education. Although it could not be proved conclusively that cognitive development had occurred, positive inter-dependence,shared responsibility, social skills and enhanced learning were evident. The study has shown that criteria derived from the 'essential features' of technology and technology education could serve as a reliable yardstick to measure the extent of learning in relation to these essential features     

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.     

Reconstructionism in Technology Education

This paper points out that technology education has historically had many principles and practices which reflect an underlying philosophy, but that the philosophy has not been made explicit by many technology education practitioners. As philosophy helps technology educators understand alternatives, make decisions and take action in both curriculum and instruction, it is important for technology educators to ask philosophical questions at the onset of their work to understand the implications of their actions. A brief discussion about some of the philosophies that inform educational practice in North America provides a background for an analysis of the different philosophies in relation to technology education, and provides insight into the significance of reconstructionism, an outgrowth of pragmatism, as a philosophy in which to frame and describe technology education. This is illustrated through several examples of a reconstructionistic approach to technology education.     

Technology Education and Developing Countries

This article considers the problem of introducing technology education as a school subject in development countries. Should the subject draw inspiration from everyday circumstances in these countries, or should it leapfrog to the space age? Answers depend upon circumstance. Alternative scenarios for how technology can be introduced in these settings are set forth. They include technology as reconstituted industrial arts, and technology across the curriculum. This revised version was published online in July 2006 with corrections to the Cover Date.     

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.     

Developing Inclusive Communities of Learners in Technology Education: Practical Craft Skills - Facilitator or Hindrance

This paper examines the rationale for the Woodworking Skills section of a course on Practical Craft Skills which forms part of the new technology curriculum in Scottish Schools. Introduced with the intention of making technology subjects more accessible to a wider range of pupils, the subject has potential for contributing to a more inclusive environment in secondary schools. The practical nature of the subject, moreover, should, in theory at least, have been able to contribute particularly well to the development of a community of practice (Wenger, 1998).In education, however, practice does not always reflect theory nor reality reflect the rhetoric. This paper examines the assumptions underlying the pedagogy and assessment methods outlined in the rationale for the subject in relation to current theory and concludes that a valuable opportunity for creating an inclusive community of learners has been missed. Whilst the paper focuses on the Woodworking Skills area of the course, other areas reflect a similar framework.     

Improving Technology Education Research on Cognition

In the United States cognitive research about technology education for the general educational purpose of technological literacy has suffered from a lack of a coherent focus. Certainly, there are studies that have addressed cognition, yet analysts of technology education research have been unable to coordinate their findings in any meaningful way (Streichler 1966; Dyrenfurth & Householder 1979; McCrory 1987; Zuga 1994). There are several persistent problems facing technology educators that contribute to the inability to develop clear interpretations or generalizations of the relationship of cognition and technology education. If some of those problems are identified, then, perhaps, we can address them in order to devise directions and strategies for studying cognition in technology education.     

The Grounding of a Discipline: Cognition and Instruction in Technology Education

Technology education has long struggled to establish itself as an equal partner in general education and often struggled to gain recognition for the value of its instruction. Frequently technology educators tout the effectiveness of their programs based on anecdotal evidence gathered from their classroom experiences on how their instructional methods empower students to learn. Although technology education originated without any meaningful input from cognitive science research, it appears that technology education instruction methods are remarkably consonant with findings from cognitive science that define good instruction. Specifically, there is considerable accord between how instruction in technology education and cognitively based instructional models such as collaborative learning, socially distributed expertise, design/engineering, and project-based instruction can be connected. The role of the cognitive research findings on instruction could inform a long over-due theoretical grounding of instruction in technology education. The absence of research on learning and instruction in technology education could be attributed to a lack of theoretical grounding in this relatively new field. This paper examines four cognitively based models of instruction and reviews the relationships between research in the cognitive sciences on learning and instruction in technology education. The consonance between the research recommendations from the cognitive sciences and practice in technology education instruction could serve to stimulate debate on the theoretical grounding of an emerging field of study.     

知识工作设计与知识型员工薪酬策略

从系统性、授权度与自由度三个维度讨论了知识工作设计，基于工作与薪酬的双重激励效用，利用委托代理方法分析了知识工作设计与薪酬机制间的关系．最后讨论了知识型员工的薪酬策略。研究表明，上述三个维度的工作设计可适应知识工作的复杂性、满足知识型员工的需求；增加三个维度的水平．工作的复杂性将增加．并能激励员工付出更高的努力水平，但复杂性不能超出员工的能力范围。否则工作设计将得不偿失：工作的复杂性增加时必须增加薪酬激励强度，并增加效益工资与基本工资的比值．但对于复杂性过高的工作，则应降低其比值；员工的薪酬水平决定于其工作价值。     

Value judgment and social action in technology studies

The paper raises the question: what should educators now be doing to promote informed judgment and responsible action in advanced technological society? After providing a narrative of the development of the context for this question, the paper argues that educators should now be allocating less time and attention to general education and more to projects at specifically targeted learning sites such as environmental and community service programs.