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.     

Towards a pre-service technology teacher education resource for New Zealand

The Pre-service Technology Teacher Education Resource (PTTER) was developed as a cross-institutional resource to support the development of initial technology teacher education programmes in New Zealand. The PTTER was developed through collaboration involving representatives from each of the six New Zealand university teacher education providers, Massey University, University of Auckland, University of Canterbury, University of Otago, Victoria University and University of Waikato, working with the National Technology Professional Development Manager. The framework for PTTER is built on four key elements considered to be essential to the education of technology teachers. The four elements are: philosophy of technology, rationale for technology education, technology in the New Zealand curriculum, and teaching technology. The PTTER is a web-based resource aimed at assisting technology teacher educators in the development of their teacher education programmes. The framework is a statement of shared philosophy, purpose and intent and is located on the Techlink website (www.techlink.org.nz). PTTER contains a range of teaching resources and strategies located within an overall framework for initial technology teacher education programmes. This paper describes the rationale for the PTTER framework, the process through which it was developed, explanation of each of the framework’s elements, and concludes with discussion of the framework’s implementation and future development.     

Education for sustainable development in technology education in Irish schools: a curriculum analysis

This paper explores the integration of Education for Sustainable Development (ESD) in technology education and the extent to which it is currently addressed in curriculum documents and state examinations in technology education at post-primary level in Ireland. This analysis is conducted amidst the backdrop of considerable change in technology education at post-primary level. The analysis of the provision of technology education found, that among the range of technology related subjects offered, the study of Technology and Society is only addressed in one in a comprehensive manner. The paper discusses the implications of this limited integration, examines the factors inhibiting greater integration of ESD and outlines opportunities for future development.     

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.     

The Development of a National Curriculum in Technology for New Zealand

New Zealand under went major curriculum reforms in the early 1990's. These reforms were determined by the New Zealand Curriculum Framework which provides an overarching framework for the development of curricula in New Zealand and which defines seven broad essential learning areas rather than subject areas. Technology is important and should be part of the education of all students. Six grounds for developing technology education were given, namely: economic, pedagogic, motivational, cultural, environmental, and personal. This paper reports on the development of a technology curriculum in schools. The philosophy of the curriculum will be discussed, particularly crucial aspects such as inclusiveness. The way in which the technology curriculum has attempted to meet the needs of a New Zealand technological society will be examined. The general aims of technology education in Technology in the New Zealand Curriculum are to develop: technological knowledge and understanding; an understanding and awareness of the interrelationship between technology and society; technological capability. The development of seven technological areas for all students will be highlighted. This paper will discuss in detail the development of the national technology education policy and the way in which the curriculum was developed. The last section of the paper will consider issues related to teacher development programmes and areas of future research.     

Transitioning Design and Technology Education from physical classrooms to virtual spaces: implications for pre-service teacher education

Technology-mediated teaching and learning enables access to educational opportunities, irrespective of locality, ruruality or remoteness. The design, development and delivery of technology enhanced learning in pre-service teacher education programs is therefore gaining momentum, both in Australia and internationally. Much research regarding online, or blended learning, has focussed on theoretically-founded learning areas, with less attention directed toward fundamentally practical learning areas, such as Design and Technology Education. Situated within the Bachelor of Education (Early Childhood Education, Primary, and Primary/Middle) degrees at the University of South Australia, Australia, this study captures the design, development and delivery of a blended Design and Technology course with first and third year pre-service teachers. Drawing on course learning analytics, pre-service teacher responses, and the reflective practice of teaching academics, this paper highlights the facilitators and challenges in transitioning to a blended model of curriculum delivery that addresses the contexts of the Australian Curriculum: Technologies.     

Learning in DEPTH: developing a graphical tool for professional thinking for technology teachers

In this issue of the International Journal of Technology and Design, we report on a series of case studies from the second phase of an international project—Developing Professional Thinking for Technology Teachers (DEPTH2). The first phase of the project was a study conducted with both primary and secondary technology pre-service teacher education students in a number of different countries who were given the same teacher-knowledge graphical framework as a tool to support reflection on their professional knowledge. We discovered that, despite the different country contexts, student teachers of technology could articulate aspects of their developing teacher knowledge using the same framework for teacher professional development. As previously reported in this journal (Banks et al. International Journal of Technology and Design Education, 14, 141–157, 2004), the common graphical tool enabled them to set out their subject knowledge, pedagogical knowledge and ‘school’ knowledge and was useful in helping them become more self-aware. In this second phase of the project we have developed this line of research in two ways. First, we extended the range of participants to include experienced teachers involved in in-service work connected to curriculum development. Second, we looked at the inter-relationship for pre-service teachers between their developing professional knowledge and their own ‘personal subject construct’. In this article, the theoretical framework for the subsequent papers is described and set in the context of recent debates surrounding the nature and importance of teacher knowledge; and the way such professional knowledge can be articulated by teachers.     

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.     

The relationship between technology and science: Some historical and philosophical reflections. Part II

Dr Paul Gardner was appointed to the Faculty of Education at Monash University in 1967 and is currently a Reader in Education. After graduating from the University of Melbourne with a science degree and teacher qualifications in 1960, he taught physics and chemistry in high schools for six years. He obtained the M. Ed. degree from the University of Melbourne in 1970 for a thesis which involved experimental studies of concept attainment, and in 1972 completed a Ph.D. at Monash for an investigation of student and teacher characteristics which influence students' attitudes to physics. His major field of interest is science education, and he has published extensively on the assessment of cognitive and affective outcomes, the role of language in learning science and (his current major interest) the links between science and technology. He was a founding member of the university's Centre for Science, Mathematics and Technology Education in 1989. He is currently the Editor ofResearch in Science Education, the annual journal of the Australasian Science Education Research Association, of which he was a founding member in 1970. Early in 1993, he presented a paper on science-technology relationships at a UNESCO-sponsored conference in Jerusalem; a revised version of this paper is being published inStudies in Science Education in 1994. He teaches post-graduate courses on statistical analysis, attitude measurement, curriculum issues and science and technology education.     

Hotspots and trends of technology education in the International Journal of Technology and Design Education: 2000–2018

Using visualized bibliographic data and a range of quantitative research methods, the analysis of the International Journal of Technology and Design Education (IJTDE), which is included in the core collection of Social Science Citation Index, reached a number of conclusions. Firstly, IJTDE is an important platform for the exchange of research results in the field of technology education, and has a significant influence. Secondly, De Vries, Williams, Ankiewicz and a number of others are influential and prolific authors in the IJTDE. Authors from the USA, England, New Zealand, Taiwan and Australia make most contributions to the IJTDE, Delft University of Technology, University of Auckland and the University of Waikato are the more prolific institutions in the IJTDE. Thirdly, technology education, education, design, science, creativity, technology, design education, knowledge, student, technological literacy and problem solving are the most frequency keywords in the IJTDE. Creativity, design education, problem solving, curriculum development, design and critical thinking, practice, engineering education, and STEM education are research trends in the IJTDE between 2000 and 2018. Fourthly, the discipline knowledge base mainly focuses on teaching and design methods in the technological environment, and the definitions of technology-related concepts. The results enable a deeper understanding and consideration of the content and influence of IJTDE, and the research hotspots in the field of technology education.

     

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.     

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.     

Teacher Perceptions of Design and Technology: A Study of Disjunction between Policy and Practice

This study examines the curriculum directions being charted by a sample of county secondary school design and technology teachers in England and Wales. The purposes of design and technology are analysed, and the syllabuses and examinations used reviewed, together with how design folios are incorporated into teaching. In addition, teacher reports on student-teacher classroom performance, and student-teacher evaluations of their teaching practice experiences are analysed. It was found that teacher perceptions are highly pragmatic and technical, with the pupils‘ intended learning outcomes largely being defined instrumentally in terms of product output rather than in design process terms. A disjunction is found between the statutory Order on Design and Technology and its implementation, with many teachers ’constructing‘ their design and technology education programmes within a ’craft paradigm‘. The discussion offers possible explanations for this and concludes that it has as much to do with the perceived status of Design and Technology as a school subject as with a ’product – process‘ debate. This revised version was published online in August 2006 with corrections to the Cover Date.     

The validity and value of peer assessment using adaptive comparative judgement in design driven practical education

This paper presents the response of the technology teacher education programmes at the University of Limerick to the assessment challenge created by the shift in philosophy of the Irish national curriculum from a craft-based focus to design-driven education. This study observes two first year modules of the undergraduate programmes that focused on the development of subject knowledge and practical craft skills. Broadening the educational experience and perspective of students to include design based aptitudes demanded a clear aligning of educational approaches with learning outcomes. As design is a complex iterative learning process it requires a dynamic assessment tool to facilitate and capture the process. Considering the critical role of assessment in the learning process, the study explored the relevance of individual student-defined assessment criteria and the validity of holistic professional judgement in assessing capability within a design activity. The kernel of the paper centres on the capacity of assessment criteria to change in response to how students align their work with evidence of capability. The approach also supported peer assessment, where student-generated performance ranks provided an insight into not only how effectively they evidenced capability but also to what extent their peers valued it. The study investigated the performance of 137 undergraduate teachers during an activity focusing on the development of design, processing and craft skills. The study validates the use of adaptive comparative judgement as a model of assessment by identifying a moderate to strong relationship with performance scores obtained by two different methods of assessment. The findings also present evidence of capability beyond the traditional measures. Level of engagement, diversity, and problem solving were also identified as significant results of the approach taken. The strength of this paper centres on the capacity of student-defined criterion assessment to evidence learning, and concludes by presenting a valid and reliable holistic assessment supported by comparative judgements.     

Leadership styles in teacher education and industry

Summary In this paper a curriculum research project in teacher education which was initiated in 1983 and which is meant to be continued until the middle of the 90s is described. In this project student teachers are prepared for and experience two practice periods in industry. The relevance of such programmes to teacher education is described and case studies of the industrial experience presented.In the second part of the paper the development of an inter disciplinary course in leadership styles is described. Student reaction to the course are cited.     

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.     

Reflection on technology in education

Reflection has become a buzzword in the educational profession. Its meaning, however, frequently remains vague. In this paper the meaning of reflection for technology education is elaborated on three levels. The first is a philosophical and educational level. The idea of Bildung, conceived as the formation of an autonomous personality, becomes a central category for instruction about technology. The second level is the realm of curriculum development and teachers' planning. The reference to Bildung implies that technology education should be based on technological key problems that apply to all members of society. On the third level, the meaning of reflection will be elaborated in the context of a qualitative research approach on teacher thinking in technology education. It resorts to the categories of the curriculum model and is illustrated by a case study on teacher planning in computer education.Dr K.-H. Hansen is a researcher at the Institute for Science Education (IPN) in Kiel. After some years of experience as a technician he studied sociology and graduated in education. He has published in computer education with an emphasis on pedagogical, historical, and social aspects. His research work comprises qualitative and quantitative studies of the educational uses of computers. His current research interests are the conceptual role of technology in integrated science and in STS education.     

An evaluation of Technology teacher training in South Africa: shortcomings and recommendations

Compared to other subjects Technology Education (TE) is regarded as a new subject both nationally and internationally. In the absence of an established subject philosophy Technology educators had little alternative than to base their professional teaching and learning practices on approaches from other fields of knowledge and to adapt these. TE is one of the compulsory subjects for learners in South Africa from grade 4–9 since 1998. One of the challenges was the fact that no previous teacher training programmes existed for Technology thus new ones had to be developed. This research described what the necessary knowledge, skills and values are that a qualified Technology teacher should possess and determined if teacher training institutions in South Africa provide opportunities to develop this qualities. Qualitative research was used to provide insight into the nature of pre-service Technology training programmes in South Africa, in order to identify shortcomings in the pre-service training of Technology teachers. The population consisted of senior faculty who have experience in the developing of pre-service training programmes and the training of Technology teachers. Findings of the study suggest a greater focus on the training of Technology teachers as subject specialists by establishing standards that is appropriate for tertiary training in order to enhance the development of subject knowledge; subject specific pedagogical content knowledge by implementing micro lessons; revision of time, planning and facilities for the practising of subject skills; and sufficient opportunities to practise, analyse and reflect on teaching processes to develop appropriate teaching strategies.     

The influence of distributed collaboration in design processes: an analysis of design activity on information,problem, and solution

International Journal of Technology and Design Education - Design education and practices increasingly involve distributed collaboration. However, its effects on students’ design processes,...