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 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.     

Enhancing Technological Practice: An Assessment Framework for Technology Education in New Zealand

The stated aim of technology education in New Zealand is to develop students' level of technological literacy. This paper introduces the Technology Assessment Framework (TAF) as an organisational tool for the development and delivery of technology programmes that focus on increasing students' technological literacy through the enhancement of their technological practice across technological areas and contexts. The TAF was developed and refined in 1999 and 2000 as part of a two year New Zealand Ministry of Education funded research project, and integrated within a national professional development programme in 2000 designed for preservice and inservice teacher educators in New Zealand.This paper backgrounds the sociocultural theoretical position of the TAF and explains how it reflects and furthers the aim of technology education in New Zealand. The TAF is then presented and explained with the aid of illustrative examples from classroom practice.     

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.     

Teaching the nature of technology: determining and supporting student learning of the philosophy of technology

This paper reports on findings related to the Nature of Technology 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 Characteristics of Technology (CoT) and Characteristics of Technological Outcomes (COTO) could be supported. These components fall within the Nature of Technology (NoT) strand of technology in the New Zealand Curriculum (NZC) (Ministry of Education, 2007) and as such, reflect a philosophical understanding of technology as a discipline. During this stage of the research further exploration was undertaken to determine how student understanding of these two components of technology education progressed from level 1 to level 8 of the NZC (Ministry of Education, 2007). Common misconceptions and partial understandings related to these components are identified and explained and four case studies are presented to illustrate strategies employed by teachers and their impact on student learning related to these two components. The Stage Two outcomes resulted in the revision of the Indicators of Progression for CoT and CoTO in order to clarify the progression expected of students in each component and provide increased teacher guidance to support such progression.     

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).     

Towards a Model for Teacher Development in Technology Education: From Research to Practice

This paper reports on a series of interventions in New Zealand schools in order to enhance the teaching of, and learning in, technology as a new learning area. It details the way in which researchers worked with teachers to introduce technological activities into the classroom, the teachers' reflections on this process and the subsequent development of activities. These activities were undertaken in 14 classrooms (8 primary and 6 secondary).The research took into account past experiences of school-based teacher development and recommendations related to teacher change. Extensive use was made of case-studies from earlier phases of the research, and of the draft technology curriculum, in order to develop teachers' concepts of technology and technology education. Teachers then worked from these concepts to develop technological activities and classroom strategies. The paper also introduces a model that outlines factors contributing to school technological literacy, and suggests that teacher development models will need to allow teachers to develop technological knowledge and an understanding of technological practice, as well as concepts of technology and technology education, if they are to become effective in the teaching of technology.     

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.     

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.     

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.     

A future-focused approach to the technology education curriculum: the disparity between intent and practice

The recently revised New Zealand Curriculum in technology education [Ministry of Education (MoE) Digital technologies: Hangarau Matihiki, Wellington, 2017. https://education.govt.nz/assets/Documents/Ministry/consultations/DT-consultation/DTCP1701-Digital-Technologies-Hangarau-Matihiko-ENG.pdf] presents opportunities for teachers to provide a future-focused approach to learning. Teacher perceptions about the nature of their subject and the discourse within their school however, influence how the curriculum is interpreted, for enactment. This article reports findings from Ph.D. research that explored the disparity between the intent of the technology curriculum and the practice of five technology teachers, in two secondary school settings. There is a focus on the ways that teachers might be supported to navigate challenges and enable change in their practice, if they are motivated to enact technology education in a future-focused way. Teachers’ interpretation and enactment of the New Zealand curriculum are heavily influenced by others’ understanding of their subject, and the organisational structures in their school. A threshold concept is presented as a strategy to transform teachers’ thinking, when making meaning of the curriculum, and to develop their knowledge for practice. Recommendations are made regarding the necessary changes in thinking and practice in technology education in New Zealand, to address a further disparity between what school-based practitioners believe students need and what academic researchers assert is important in contemporary education. Initial Teacher Education Programmes are briefly discussed as a means of addressing this issue from another perspective, to ensure that student teachers are exposed to future-focused conceptions of the curriculum at University, to compensate when such practice is not observed during their school placements.     

Emerging Assessment Practices in an Emergent Curriculum: Implications for Technology

This paper reports on detailed case studies into emerging assessment practices in technology in two New Zealand primary schools (Years 1–6) with nine teachers. This research is part of the two year Research in Assessment of Primary Technology (RAPT) project and formed the basis for the one year New Zealand Ministry of Education funded Learning in Technology Education (Assessment) project.Emerging classroom assessment practices in technology, a new subject area in the national curriculum, are discussed. It was found that the existing subcultures in schools, teachers' subject expertise and the school wide policies impacted on the teachers' assessment practices. Assessment was often seen in terms of social and managerial aspects such as team work, turn taking and information skills, rather than procedural and conceptual aspects. Therefore teachers' formative interactions with students distorted the learning away from procedural and conceptual aspects of the subject, and the learning and the formative assessment interactions focused on generic skills rather than student technological understanding.The importance of developing teacher expertise in three dimensions of knowledge about the subject, knowledge in the subject and general pedagogical knowledge is highlighted. Thus the findings from this research have implications for thinking about teaching, learning and assessment in technology.     

Recent Research in Learning Technological Concepts and Processes

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

Sparking self-sustained learning: report on a design experiment to build technological fluency and bridge divides

In this article we report assessment results from two studies in an ongoing design experiment intended to provide a single school system with a sequence of secondary school level (ages 14–18) computer technology courses. In our first study, we share data on students’ learning as a function of the required introductory course and their pre-course history of technological experience. In order to go beyond traditional assessments of learning we assessed two aspects of students’ “learning ecologies”: their use of a variety of learning resources and the extent to which they share their knowledge about technology with others. In our second study we present patterns of course taking by male and female students who have almost completed their secondary schooling. In addition, we share case studies of students who elected to take more technology classes and leveraged their course experiences for internships, further education, and jobs. The quantitative and qualitative data are consistent with our hypothesis that students would become more technologically fluent and that their learning ecologies would diversify as a result of their project-based experiences.     

The social agenda of education for sustainable development within design & technology: the case of the Sustainable Design Award

The paper explores the adoption of the social dimensions of sustainability in technological design tasks. It uses a lens which contrasts education for sustainability as ‘a frame of mind’ with an attempt to bridge a ‘value-action gap’. This lens is used to analyse the effectiveness of the Sustainable Design Award, an intervention in post-16 technology education in three countries to encourage students and teachers to strengthen design for sustainability in their work. In each country, the intervention project provided varying combinations of teacher professional development, provision of learning resources, in school student support, lobbying of key curriculum policy makers and a student Award. Three types of teacher are identified by reference to their motivation for introducing sustainability into their teaching of design. These teacher types are linked to a hierarchy of teachers’ understanding of the social dimension of sustainability. The consequences for continuous professional development are examined. The findings are then used to critique the value of the lens.     

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.

     

Designers as Teachers and Learners: Transferring Workplace Design Practice into Educational Settings

The nature of the design process and how to develop this skill in novice designers has been of considerable interest to technology educators. The relationship between workplace and school-based design is one area in which a need for further research has been identified by Hill and Anning (2001, International Journal of Technology and Design Education 11, 111–136). The research project described in this article had two aims. The first was to compare the workplace practice of six experienced designers with their practice when working on a technological assessment task as part of a pre-service teacher education programme. The second aim was to investigate their experience on teaching practicum in developing design skills with secondary school students. Findings from the research are described and the paper concludes with a discussion of the implications for teaching technology education.     

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.     

Toward sustainable practices in technology education

This paper discusses the problematic relationship between technology education, consumption and environmental sustainability. The emerging global sustainability crisis demands an educational response that moves beyond mere ‘tinkering’ with classroom practices, toward technology education which embraces life cycle thinking and ‘eco-innovation’. It will argue that the urgent transformation to technology education for sustainability citizenship must begin with a critical examination of existing practices and assumptions which underpin unsustainability. The initial context for this discussion will be technological education in Canada and the United States, in particular a recent national report on the assessment of technological literacy. The paper concludes by suggesting several ‘new paths’ forward to move technology education toward more sustainable practices and more relevance for young people.