Teaching Technological Knowledge: determining and supporting student learning of technological concepts

This paper reports on findings related to Technological Knowledge from Stage Two of the Technological Knowledge and Nature of Technology: Implications for teaching and learning (TKNoT: Imps) research project undertaken in 2009. A key focus in Stage Two was the trialing of different teaching strategies to determine how learning related to the components Technological Modelling (TM), Technological Products (TP) and Technological Systems (TS) could be supported. These components fall within the Technological Knowledge (TK) strand of technology in the New Zealand Curriculum (NZC) (Ministry of Education, 2007) and as such, reflect the key generic concepts or ‘big ideas’ of technology. During this stage of the research further exploration was also undertaken to determine how student understanding of these three components of technology education progressed from level 1 to 8 of the NZC (Ministry of Education, 2007). This resulted in a significant review of the Indicators of Progression for TM, TP and TS, providing clarification of the nature of the progression expected of students in each component as well as increased teacher guidance to support such progression. Common misconceptions, partial understandings and alternative concepts related to these components were confirmed and explained and five case studies were developed to illustrate strategies employed by teachers and their impact on student learning related to these three components.     

The road less travelled: a pre-service approach towards the technology teaching profession

This paper presents the findings of a longitudinal study on the effectiveness of an innovative one-year pre-service Graduate Diploma of Teaching (secondary) for teachers of Technology. The timing of this study is significant. Over a decade of review and adjustment to the Technology curriculum, leading to the new learning area of Technology in the New Zealand curriculum, Ministry of Education (2007), has caused many teachers in New Zealand schools to retrench to an earlier approach or make their own interpretation of curricular requirements. This situation in schools created the need for those involved with pre-service teacher education to prepare programmes that signpost pitfalls while building on students’ own strengths and those of the curriculum to cope with the wide variety of interpretation and pedagogical approach of school communities. This paper suggests a way forward.     

Supporting conceptual understandings of and pedagogical practice in technology through a website in New Zealand

This article reports on the up-date and development of an on-line resource to support of teachers’ conceptual understandings and pedagogical practice in New Zealand. Techlink is a website dedicated to supporting technology teachers, students and those with an interest in technology education. This research documents part of a Ministry of Education initiative to develop materials to support teaching and learning in technology education. The research was conducted by educational researchers contracted through Technology Education New Zealand the professional subject association. This research was a component of a larger contract with an overall aim of improving student achievement particularly at Years 12 and 13, the final 2 years of schooling in New Zealand. The aims of the initiative reported in this article were to provide ongoing evaluation of the effectiveness of the materials developed by the writing team, to support teacher shifts in understanding and pedagogical practice. This article gives an overview of the 3 year research study, focussing on teachers and teacher educators perceptions of Techlink as a professional development resource. An iterative process was used to critique and give feedback on existing and developed materials. The article also discusses enhancements made to ensure that the resource reflected the needs of technology teachers and The New Zealand Curriculum (Ministry of Education 2007).     

Nurturing the designerly thinking and design capabilities of five-year-olds: technology in the new entrant classroom

Technology is one of eight learning areas of the New Zealand national curriculum. It aims to develop a broad technological literacy through students participating in programmes in which the practice of technological development is experienced, as is knowledge informing practice, and students gain an understanding of technology as a domain in its own right. In New Zealand children begin school at 5 years of age and this paper describes a classroom research project during which these students design and then construct a photo frame. The inducement for this development arose from students needing to safely transport home and then display a class photograph. This provided the opportunity for developing technological knowledge and skills within a real and relevant context—two key drivers when working with young students (Ministry of Education 2007) [MoE]. The results of this project suggest that teaching technology to five-year-old students is achievable and a valuable addition to other learning opportunities provided in the new entrant classroom. Strategies are suggested that will enable students to successfully achieve their goals whilst gaining a simple understanding of the technological process. By making good use of these it is possible to create a worthwhile and imaginatively challenging activity that reflects the essence of the technology education curriculum.     

Perspectives of authenticity: implementation in technology education

To meet the intentions of the New Zealand Curriculum 2007 teachers must critically reflect on their role and their idea of what defines ‘best practice’ for teaching and learning in the twenty-first century. The teacher’s role has changed considerably over time. There is now, more than ever, a need for much greater transparency, accountability and collaborative practice within education. Famous philosophers and theorists including Plato, Rousseau and Dewey have expounded ideals of authenticity and authentic engagement, but it is only with the spread of constructivism that authenticity has gained more favour. The authors will investigate perspectives of authenticity, authentic learning, and authentic activities (Kreber et al. in Adult Educ Q Am Assoc Adult Contin Educ 58(1):22–43, 2007; Newmann in Authentic achievement: restructuring schools for intellectual quality, Jossey-Bass Publishers, San Fransisco, 1996; Newmann and Wehlage in Educ Leadersh 50(7):8–12, 1993; Reeves et al. in Quality conversations. Paper presented at the 25th HERDSA annual conference, 2002; Splitter in Stud Philos Educ 28(2):135–151, 2008). Through qualitative investigation they identify and summarise key viewpoints and demonstrate how these can be successfully implemented through programmes of technology education. A model of authentic technology for producing quality technological outcomes is presented. The authors show how an activity from an initial teacher education course in technology education uses identified aspects of authentic technological practice through the various dimensions of authenticity to develop enduring learning for students. They consider the role of context in developing learning and introduce some new ideas on successful student engagement in the field of conation (Riggs and Gholar in Strategies that promote student engagement, Corwin Press, California, 2009). Conation is defined as the will, drive and effort behind students’ engagement in learning and is increasingly seen as an integral part of authentic education.     

The developing field of technology education: a review to look forward

This paper attempts to review the development of technology education over the last 20–25 years. The purpose is to reflect on how far the field has come and where it might go to, including what questions need to be considered in its ongoing development. The data for this paper draw on our work in developing The International Handbook of Research and Development in Technology Education (Jones and de Vries 2009). However, the paper is more than a summary of this work, instead representing a synthesis in its own right. The work was not undertaken to report solely on the collective achievement of a large number of people internationally, but rather to use this as a means for setting a sound foundation for future research, development and teaching in technology education. By considering the underlying philosophy, international development of curriculum, relationships of technology education with other subject areas, teaching, learning and assessment as well as teacher education, and educational research, we are able to scope past activities and present an agenda for moving forward in teaching, research and development.     

A review of Technology Education in Ireland; a changing technological environment promoting design activity

In Ireland, Technology Education’s structure and organisation across the levels of education is not delivered or governed in a coherent manner. Technology Education in primary level education, for students between 5 and 12 years of age, does not explicitly exist as a separate subject. In primary level education, Social, Environmental and Scientific Education (Science), encourages a child to examine and appreciate how technology and science impacts on their lives and the environment. It supports children developing design and make skills, and to apply scientific ideas to everyday situations and practical problems (DES in Primary school curriculum, science. Social, environmental and scientific education curriculum, 1999). In addition, various initiatives such as the Junior Lego League, supported by the Galway Education Centre, facilitate various perspectives of Technology Education. In second level education, which this paper primarily focuses on, Technology Education exists as a suite of eight subjects, for students of 12–18 years of age. In third level education students can choose from a wide range of bachelor degree programmes in science, technology, engineering or maths. The degree programmes available at third level also include programmes in initial teacher education (ITE). These programmes in initial teacher education are offered by two institutions, and graduate second level teachers to service the second level system. Technology Education in second level education was first introduced to Ireland in 1885. Since this introduction, revisions and changes have occurred, in both the Irish economy and syllabi. In 2006, Technology Education syllabi were revised to include more design activity at senior cycle. These changes reflect the forward thinking of policy makers in reflection of the progression from the industrial era to the information era to the conceptual era. The scope of second level Technology Education in an Irish context is still perceived by many as vocational, though progressive reformations are advancing towards a design-driven framework, grounded in a strong craft practice. This changing technological environment has resulted in the promotion of design activity in second level Technology Education in Ireland. This paper reviews the establishment of design education in Technology Education in the Irish second level education context, where an epistemological shift towards design activity has occurred.     

The Place of Authenticity in Technology in the New Zealand Curriculum

In 1999 Technology in the New Zealand Curriculum became mandatory. It was developed over a period of approximately four years from conception to publication, with wide consultation. It was first published in October 1995. During the three years between publication and gazetting many teachers were involved in professional development. During this time it became obvious that there was confusion amongst teachers about the meaning of `authenticity' in relation to technology programmes. Do technological problems need to be authentic to the students themselves or to the nature of technological practice? Many learning theories have informed the development of this document. Those selected here indicate quite clearly the meaning and context of authenticity with regard to technology education. By involving our students in activity that is authentic to technological practice or real world technology, teachers are able to provide stimulating and relevant learning for students. This was also the indication in recent communication from the Ministry of Education in New Zealand during the 1999 Technology Education New Zealand (TENZ) conference. By giving academic value to technology and developing our teachers in the fields of technological practice we hope our students will influence the economic status of our country in the future.     

The importance of design thinking for technological literacy: a phenomenological perspective

“We know that progress depends on discovery, inventions, creativity and design, but we have simply supposed that it happens anyway,” de Bono (1999 p. 43). Technology education is ostensibly a foundation for future designers and creative thinking. However evidence of good design or creative thinking in outcomes displayed in school technology studios is limited. Technology is inextricably linked with applied science, but I argue that scientific method couldn’t be further from creativity and designing as technology education based on this premise can confine problem solving to a set of prescribed components that harness teachers to narrowly defined and deeply focused goals. This paper attempts to analyse the nature of this phenomenom, debate the place of creativity, imagination and personal sensitivities as part of designing and demonstrate that although there are inseperable links between design and technology the structure of a technology curriculum could be a barrier to opportunities for effective design thinking.     

Curriculum restructuring in technology in NSW secondary schools — Response to change

This research project aimed to analyse and clarify the impact of the formation of the Technological and Applied Studies (TAS) Key Learning Area (KLA) on school organisation, teachers and teaching method. It further aimed to examine the implications of this change for pre-service teacher education programs. In 1989 the NSW government White paper on curriculum reform mandated the restructuring of primary and secondary schooling. As a part of this restructuring the subjects that had been traditionally taught under the Home Economics and Industrial Arts departments, together with agriculture and computing studies were brought together under the TAS KLA. The government also mandated that every secondary school student would be required to study technology through a newly developed syllabusDesign and Technology Years 7–10. These changes have had significant implications for the organisation and delivery of technology curriculum in secondary schools and there are consequent implications for the provision of teacher education in the field of technology.Ms. Y. McDonald is currently the program director and practicum co-ordinator of the undergraduate bachelor of education secondary home economics: design, technology and health studies program in the Faculty of Education at Sydney University.Mr. J. Gibson is currently the program director and practicum co-ordinator of the undergraduate bachelor of education secondary industrial arts: design and technology program in the Faculty of Education at Sydney University. He has had extensive experience in curriculum development in the technology area through his membership of syllabus committees and the Technological and Applied Studies Key Learning Area Co-ordinating Committee of the NSW Board of Studies.     

Curriculum restructuring in technology in NSW secondary schools — Response to change

International Journal of Technology and Design Education - This research project aimed to analyse and clarify the impact of the formation of the Technological and Applied Studies (TAS) Key Learning...     

Discontinuity in transition: Pupils' experience of technology in year 6 and year 7

International Journal of Technology and Design Education - This paper refers to current work at Goldsmiths University of London (‘Understanding Technological Approaches’, a project...     

Engineering and technology students’ perceptions of courses

As cultural, social, political and economic changes take place, the secondary or high school curriculum should reflect and respond to changing needs and aspirations of students. Technology Education has been proactive in this arena as it has transformed over the decades to meet ever-changing societal needs. The most recent change to the discipline has been to add engineering and, as a result, adopting a new name and curriculum-Engineering and Technology Education. The added component and name change in Technology Education is causing discussions about what the new direction means, what professional preparation changes will be incurred, and what work graduating students will be prepared to do. In light of these changes, this study investigated perceptions of high school students in the United States of America about engineering and technology courses they take. To investigate whether students’ perceptions are in accord with current changes in Engineering and Technology Education, 316 students enrolled in engineering and technology courses in Georgia schools that have an affiliation with the Georgia Engineering and Technology Education Association (GETEA) were surveyed. According to data analyses, students’ perceptions can be divided into two factors. Educational Value of Course (factor 1) was extracted from statements measuring the degree to which the courses prepare students for employment and provide them with information regarding future employment. Personal Relevance of Course (factor 2) was derived from statements measuring students’ perceptions about links between engineering and technology education and their personal lives. Such findings suggest these students valued their engineering and technology courses, planned to continue their education, made good grades, and had varied types of career expectations for jobs such as design engineers and architects.     

Representations of technology in the “Technical Stories” for children of Otto Witt, early 20th century Swedish technology educator

Children’s fiction in school libraries have played and still play a role in mediating representations of technology and attitudes towards technology to schoolchildren. In early 20th century Sweden, elementary education, including textbooks and literature that were used in teaching, accounted for the main mediation of technological knowledge to schoolchildren. An investigation of children’s literature for schools is therefore important in order to understand what was considered worth knowing about technology at the time. The aim of this article is therefore to analyse the representations of technology and attitudes towards technology that were mediated through two children’s fiction books in Swedish elementary school libraries in the 1910s. We have limited the analysis of empirical material to the books Technical Stories for Young and Old (Tekniska sagor för stora och små, 1914) and Technical Stories of the War for Young and Old (Krigets tekniska sagor för stora och små, 1915) by the Swedish inventor, author and technology educator Otto Witt. Gauging Witt’s influence on the schoolchildren and educators of his time is very difficult, but in this first English-language article on his “technical stories” one can conclude that he was in many ways unique and probably fairly well-read in the schools of early 20th century Sweden and onward. He was also a particularly perceptive forerunner of today’s technology and science educators in his use of anthropomorphism as an educational tool.     

Examining the dimensions of technology

The meaning of technology seems simple. Most people have little difficulty expressing some notion of what it is. Technology is machine, automobile, computer, tool ... the list goes on and on.For some, technology is defined in contrast to other academic disciplines such as science or engineering. It is clear that science and technology are woven throughout a larger complex of human activity which is oriented around a mix of economic, political, humanitarian, and cultural means and ends. However, it is also clear that the knowledge base, processes, and goals of technology are distinctly different from science.This paper depicts technology as consisting of four distinct conceptual dimensions. These are (a) artefact, (b) knowledge, (c) process, and (d) volition (Mitcham, 1979). The goals are to clarify and explore the conceptual complexities of technology in order to provide a conceptual foundation for the study of Technology Education for all.A central mission of education should be to orient people to the cultures within which they are living and making decisions. Given that technology and technological systems are important in every culture around the world, it is absolutely essential that they become a primary focus of study.Rodney L. Custer is Assistant Professor of Technology and Industry Education at the University of Missouri-Columbia where he graduated with the Doctor of Philosophy in Practical Arts and Vocational and Technical Education. His research interests include the philosophy of technology, implications of cognitive science for understanding problem-solving, and critical skills for employment in the 21st century. Custer is currently co-editing a book entitled Technology and the Quality of Life, which will be published in 1966 by the Council on Technology Teacher Education. The book will explore the ways in which cultures have influenced the development of technology as well as the positive and negative impacts which technology has had on social and cultural values. He is currently on leave from the University of Missouri for the 1995–96 academic year, working as a Program Officer for the National Science Foundation (NSF) in Washington, DC.Rodney L. Custer, University of Missouri-Columbia, 103 London Hall, Columbia, MO 65211, Fax Number: 314-442-6056, Electronic Mail: PAVTROD@showme.missouri,edu, Work Number: 314-882-3082.     

The Rationality of U.S. Regulation of the Broadcast Spectrum in the 1934 Communications Act

The Federal Radio Commission regulated radio broadcasting, 1927–1934. With the passage of the Communications Act of 1934, the 1927 Radio Act (enabling the Commission) was re-enacted in whole. This congressional endorsement yields key evidence as to what policy outcomes were intended, differentiating competing theories for the origins of spectrum allocation law: Coase (J Law Econ 2(1):1–40, 1959), emphasizing policy error; Hazlett (J Law Econ 33:133–175, 1990), focusing on “franchise rents” in a public choice framework; and the “public interest” hypothesis, reconstructed by Moss and Fein (J Policy Hist 15(4):389–416, 2003). Congress’ revealed preferences prove consistent with the franchise rents theory, while contradicting the other two.     

Insights into the intrinsic and extrinsic challenges for implementing technology education: case studies of Queensland teachers

This study, embedded within the Researching School Change in Technology Education (RSCTE) project in Queensland, Australia, aimed to gain insights into the intrinsic and extrinsic challenges experienced by teachers during the implementation of technology education within primary school settings. The official publication and launch of the Technology years 1–10 syllabus and associated curriculum materials by the Queensland Studies Authority during 2003 saw the first formal Technology curriculum for primary schools in Queensland. The Queensland Government announced that all Queensland schools were to aim for full implementation of this new Key Learning Area (KLA) by 2007. This presented a challenge for Queensland teachers as they began to understand this new KLA and subsequently, were required to implement technology education for the first time. Education Queensland released a number of different strategies that were designed to assist this implementation, including research partnerships with universities. Thus, the RSCTE project, a partnership project between Education Queensland and Griffith University included implementation research within schools. Through the identification of insights into intrinsic and extrinsic challenges, this study, while recognising the limitations of transferability beyond the case studies presented, provides suggestions to assist the implementation of technology education.     

Student teachers of technology and design into industry: a Northern Ireland case study

This paper, based in Northern Ireland, is a case study of an innovative programme which places year 3 B.Ed. post-primary student teachers of Technology and Design into industry for a five-day period. The industrial placement programme is set in an international context of evolving pre-service field placements and in a local context defined by the Northern Ireland Curriculum (CCEA 2007); a rationale for the inclusion of Technology and Design within that curriculum; and the promotion of a STEM (Science, Technology, Engineering and Mathematics) agenda. Undertaken in collaboration with a range of industrial partners, the placements aim to give the student teachers an opportunity to spend time in industry. All the students concerned started their teacher education degree straight from school and therefore are without industrial experience. As a result of the placements the students gained valuable industrial experience and thereby further enhanced their working knowledge and understanding in their main subject area of Technology and Design, in particular, and other curricular areas, in general. The students report many benefits, both personally and professionally, to be gained from the placements typically the opportunity to see a range of industrial processes, many of which they are required to teach, and to gain a better understanding of the link between content of Technology and Design education and the activities of industry. This case study is based on feedback from the 2010 to 2011 cohort of students whose comments confirm the inherent value of exposing student teachers to industrial environments.     

Reflecting on Teacher Development in Technology Education: Implications for Future Programmes

This paper reflects on the outcomes of teacher professional development programmes in technology education. These programmes were based on a model which emphasised the importance of teachers developing an understanding of both technological practice and technology education. Two different programmes have been developed and trialed in the New Zealand context. They are the Facilitator Training programme, and the Technology Teacher Development Resource Package programme. This paper will focus on the outcomes of these programmes. The Facilitator Training programme was a year long programme, and ran in 1995 and 1996. It involved training a total of 30 educators – 15 each year, from all over New Zealand. The Resource Package was trialed in 14 schools over a 3–6 month period in 1996. The evaluations indicate the successful nature of these programmes and the usefulness of the model as a basis for the development of teacher professional development in technology education. The programmes reported on in this paper were developed and evaluated as part of two New Zealand Ministry of Education contracts held by the Centre for Science, Mathematics and Technology Education Research. This revised version was published online in August 2006 with corrections to the Cover Date.