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.     

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).     

Technology education for children in primary schools in Finland and Germany: different school systems, similar problems and how to overcome them

Even if the results of international student assessment studies such as PISA or TIMSS show that girls have been catching up in mathematics and natural sciences, there are still remarkable gender differences in the number of males and females studying and working in the technological fields after basic education. Technology is still a male-dominated area. This is true for the German and Finnish societies. Results of the studies conducted in the UPDATE project show that influences on interest in technological themes take place already in early childhood. Therefore, efforts should be put in developing early childhood education and elementary school education, to raise girls’ interests and motivation towards technology. This article reports the results of the UPDATE-WorkPackage3-project mainly in Finland and in Germany. It concentrates on studying elementary school pupils’ (age 6–12), particularly girls’ motivation towards the contents and methods of technology education. Various curriculum documents and national learning conditions are discussed and suggestions for the gender equitable technology education are made.     

Teachers’ views about technical education: implications for reforms towards a broad based technology curriculum in Malawi

Internationally there has been concern about the direction of technical education and how it is positioned in schools. This has also been the case in Malawi where the curriculum has had a strong focus on skills development. However, lately there has been a call for enhancing technological literacy of students, yet little support has been provided for teachers to achieve this goal. This paper reports from a wider study that looked at teachers’ existing views and practices in technical education in Malawi. The article focuses on the findings from interviews that were conducted with six secondary school teachers to find out about their understanding of the meaning and rationale for technical education. It is also discussed how the teachers view technical education as involving skills development for making things and their thoughts on the benefits of such knowledge. It is argued that teachers’ views about technical education were strongly linked to the goals of the curriculum vacationalization policies adopted at the dawn of political independence. Besides skills training they saw the potential to impart thinking skills related to design and problem solving, and the need for essential pedagogical techniques to support learning in technical education. Examination requirements, inadequate opportunities to conduct practical activities and a lack of supportive policy were seen as limiting factors. This article claims that teachers’ views were shaped by their expectations and beliefs about the nature of technical education and what they perceived students may gain from such learning. Their views were also influenced by contextual factors which may have implications on reforms towards broader notions of technology education.     

Technology education in South Africa since the new dispensation in 1994: An analysis of curriculum documents and a meta-synthesis of scholarly work

Technology education was introduced as a successor to various forms of craft or technical education in some parts of the world in the 1980s. In South Africa (SA) the implementation of technology education was in more than one sense unique. Not only was it a new subject within the South African educational context, but it coincided with the dawn of a new political dispensation in which the new government favoured outcomes-based education (OBE). This has resulted in a series of curriculum documents over the past two decades which made certain demands on and held challenges for the teachers who were responsible for the implementation of technology. The purpose of this conceptual article is to investigate the demands and challenges that various curriculum documents have made on the technology teachers concerned. The research question that underpinned the research was: What were the demands and the challenges various curriculum documents had on technology teachers? The research methodology was desktop research in the form of a critical analysis of various intended or specified curriculum documents. The research also included a qualitative meta-synthesis of other scholarly work on the challenges posed by the implementation of curricula both in SA and other international contexts. The South African experience may hold important insights for ministries of education, curriculum developers and technology teachers that form part of the broader international technology fraternity. It was found that the underlying political ideology of a new government impacts and steers the country’s education in a particular direction. Soon after the dawn of the new political dispensation in SA in 1994 there was a move away from a content-based curriculum (CBC) towards an OBE curriculum. However, it was mainly contextual and practical factors at chalk level that placed major demands on and posed challenges to the implementation of a new education system, aligned with a new ideology. Due to these challenges the country now finds itself moving back towards content-based education just more than ten years later. In a developing context, in particular with insufficient logistical resources and where teachers are inadequately trained (and therefore have less competence) a more specified and fixed CBC rather than an open, flexible OBE curriculum seems more feasible. Subsequently, the effects of a CBC as opposed to an OBE curriculum in technology education need to be researched in future, specifically which approach would be conducive to a general design-driven subject or a fragmented vocationally-oriented technology subject.

     

Enhancing teachers’ technological pedagogical knowledge and practices: a professional development model for technology teachers in Malawi

This paper reports on a professional development that was designed and implemented in an attempt to broaden teachers’ knowledge of the nature of technology and also enhance their technological pedagogical practices. The professional development was organised in four phases with each phase providing themes for reflection and teacher learning in subsequent phases. On-going support, reflection and feedback underpinned the professional development processes to enhance teachers’ prospects of putting aside old traditions and culture to implement new practices in their classrooms. The teachers collaboratively explored new concepts through readings of selected scholarly papers, making presentations of their views generated from the readings and engaging with peers in discussing learning, curriculum issues and concepts related to the nature of technology and technology education. A qualitative analysis of the teachers’ journey through the phases of the professional development showed the teachers’ enhanced knowledge of technology and technology education. However, their classroom practices showed technological pedagogical techniques that reflected their traditional strategies for teaching technical subjects. It is argued that although the teachers’ conceptualisation of learning in technology was still fragile at this point, attempts to shift teachers’ beliefs and practices require deep theoretical grounding and transferring that into technological practices. A professional development built on existing ideas and context helps expand the teachers’ views about the nature of technology and technology education.     

New Zealand secondary technology teachers’ perceptions: “technological” or “technical” thinking?

Technology education in the New Zealand context has seen significant change since it’s inception as a technical subject. The changing nature of the subject in New Zealand secondary schools is influenced by some teachers’ preoccupation with the making of quality product outcomes, rather than their enactment of the curriculum, which conceptualises a wider remit. Research into the perceptions of technology teachers’ interpretation and enactment of the curriculum suggests that to enable change, teachers need to adopt a form of “technological thinking”, in support of their “technical thinking”. Technological thinking is a notion presented to support teachers to explore a range of differing pedagogical approaches and learning outcomes, reflective of the intent of the New Zealand curriculum, which aims to foster learning environments that are innovative and responsive to students’ social and academic needs.     

Robotics in the early childhood classroom: learning outcomes from an 8-week robotics curriculum in pre-kindergarten through second grade

In recent years there has been an increasing focus on the missing “T” of technology and “E” of engineering in early childhood STEM (science, technology, engineering, mathematics) curricula. Robotics offers a playful and tangible way for children to engage with both T and E concepts during their foundational early childhood years. This study looks at N = 60 children in pre-kindergarten through second grade who completed an 8-week robotics curriculum in their classrooms using the KIWI robotics kit combined with a tangible programming language. Children were assessed on their knowledge of foundational robotics and programming concepts upon completion of the curriculum. Results show that beginning in pre-kindergarten, children were able to master basic robotics and programming skills, while the older children were able to master increasingly complex concepts using the same robotics kit in the same amount of time. Implications for developmentally appropriate design of technology, as well as structure and pace of robotics curricula for young children are addressed.     

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.     

Technological knowledge in early childhood education: provision by staff of learning opportunities

International Journal of Technology and Design Education - Developments in early childhood education (ECE) over the last two decades have for many countries meant a change towards a more...     

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.     

Creativity in technology education: providing children with glimpses of their inventive potential

This article examines the claims of the school subject technology education (called Design and Technology in some countries) as a vehicle for inculcating creativity in the curriculum, by introducing children to the world of problem solving and invention. Core foundational underpinnings of the subject are explored, including its hands-on nature, its open-endedness, and its encouragement of generative cognitive processes. Issues relating to the teaching of problem solving are discussed. Examples of curricular approaches to the subject are set forth and their merits as bases for encouraging creative thinking are examined. Research on creativity in the subject is reflected upon briefly. The paper concludes by offering problem solving; and analogical, metaphorical, combination, and divergent thinking, as possible bases for pedagogy in technology education, and calls attention to the subject as a possible fruitful area of research based on creativity in the school curriculum.     

Architectural theory in the undergraduate curriculum: a pedagogical alternative

The study of architectural theory remains absent from many undergraduate design programs, or, if present, the structure of many curricula place “theory” as an autonomous, peripheral course. Theory, however, as it is in other disciplines, is the foundation of the discipline of architecture. To regain the importance and vitality of architectural theory amidst an evolving and highly crowded set of courses, creative pedagogies are much needed. This article, therefore, discusses the development of a pedagogical alternative to traditional architectural theory courses. The course is conceived according to the concept of the dialectic and is a required part of the Bachelor of Architecture curriculum at a public university in the United States.     

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.     

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.     

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.     

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.     

The planning of technology education for South African schools

One of the recommendations made in the discussion document,A Curriculum Model for Education in South Africa (CUMSA), which was released by the Department of National Education in 1991, is that technology education should be offered for the first nine years of pre-tertiary education as a compulsory subject and for the last three years as an optional subject. This paper aims to locate technology education in the context of the sociopolitical and economic background to education in South Africa and to assess to what extent it meets the emerging aims and needs of education. Further aims are to propose a rationale for the teaching of technology at school level in South Africa, to suggest possible broad aims for the teaching of technology, to outline the nature and character of technology education relevant to the South African situation and to propose a possible methodology for technology education in South Africa. The conclusion is reached that technology education can make an important contribution to South African education if the so-called technological process is the major emphasis as this can be transformative and promote quality education.Dr Piet Ankiewicz (M Sc, D Ed, HED) is a Senior Lecturer in Education at the Rand Afrikaans University. He is responsible for teacher education programmes in the field of Science, and for an M Ed course in technology education. His areas of research include education policy and curriculum development for technology education.     

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.     

Technology in the rear-view mirror: how to better incorporate the history of technology into technology education

The history of technology can play an important role in illuminating the fundamentals of technological change, but it is important that technology teachers, teacher educators, curriculum developers and researchers can be provided with good analytical tools for this purpose. In this article, we propose a model of techno-historical interplay, as a help in deciding what historical artefacts and systems should be included in technology curricula and teaching as well as in analyzing and conveying to students the fundamental issues of technological change. We want to emphasize particularly three points of importance in employing the model as a tool of analysis. First of all, it is crucial to decide what one wants the technologically literate student to know about technology and technological change. This should include an awareness of the historical and geographical contingency of any technology. Second, on the basis of this decision one should adapt the model as a tool for selecting relevant technologies. Third, the model should be applied as an instrument of analysis of the history of the selected technological artefacts or systems as well as theories of technological development.