Factors Affecting Learning in Technology in the Early Years at School

The nature of progression in technology is still a matter of debate in technology education. While there is a growing research-based literature exploring the elements of technological literacy that might be appropriate measures of progression, little has been written about the factors that may influence both group and individual development of technological literacy. This article reports the findings of a longitudinal ethnographic study of the progression in technological literacy of 20 children during their first 3 years at school. It focuses on the factors that affected their learning in technology, and identifies a number of personal and systemic factors that affected progression in technological literacy. The implications of these findings for teaching, and for further research are then explored.     

A path model of factors affecting secondary school students’ technological literacy

Technological literacy defines a competitive vision for technology education. Working together with competitive supremacy, technological literacy shapes the actions of technology educators. Rationalised by the dictates of industry, technological literacy was constructed as a product of the marketplace. There are many models that visualise different dimensions of technological literacy, but clear empirical evidence on how these interact is still lacking. A measurement method that comprehensively evaluates technological literacy is missing. Insights into the stem structure and interaction of technological literacy dimensions could be useful for technology education curriculum design and its implementation. In this study, the multifaceted nature of technological literacy was measured using a new assessment method, and dimensions of secondary school students’ technological literacy were empirically investigated. A total of 403 students participated in the quasi-experimental research design. The treatment group consisted of 121 students taught optional subjects relating to technology education. The control group consisted of 282 students. Results from variance analysis showed that optional technology subjects enhance technological literacy, especially students’ technological capacity where a large effect size (η ²  = 0.14) was noted. Results from a path analysis revealed critical thinking and decision-making as the most important dimensions of technological literacy while the predictor of active participation in out-of-school technical activities and technology homework was a key independent influencing factor. A large effect size (R ²  = 0.4) for career path orientation predictors was detected. Technological capacity was revealed as a decisive predictor for a career path in vocational education and technical high school.     

An epistemological framework for nanoscience and nanotechnology literacy

The need for a new literacy that will allow for meaningful participation in the rapidly evolving field of nanotechnology is very critical to national development. This need is important for nanotechnology to achieve its full potential. This paper describes and analyzes some contemporary philosophical interpretations of the concept of technological literacy. The paper then focuses on some of the metaphysical assumptions underpinning the techno-scientific literacy framework; and theories governing public understanding of science and technology, as the basis to propose a new technological literacy framework suitable in the era of nanotechnology. A case is made that the new technological literacy framework proposed is a suitable and essential pedagogic endeavour which should be seen as yielding a perspective through which meaning may be infused into the importance of nanotechnology development–a perspective as essential to the informed lay person as it is to the truly literate technologist. The paper concludes by analyzing the implications of the proposed epistemological framework on nanotechnology workforce development and makes recommendations based on this new framework to achieve a ‘nanoliterate’ society.     

Conceptual and Procedural Knowledge

The ideas that underlie the title of this chapter have been part of a familiar debate in education, namely that of the contrast of content and process. In both science and mathematics similar arguments have taken place, and these debates represent a healthy examination of, not only the aims of science and mathematics education, but the teaching and learning issues, and as such they reflect the relative maturity of these subject areas. Even in technology education, which is still in its infancy as a subject, echoes of these debates exist and there are contrasts of approaches to the balance of process and content across the world. The 'debate' in technology is evangelical in nature, with for example, proponents making claims for problem-solving approaches as a basis for teaching with few accounts and almost no empirical research of what actually happens in classrooms. There is insufficient consideration of the learning issues behind this, or other proposals, and it is timely to turn our attention to student learning. This article examines the nature of technological knowledge and what we know about learning related to it. The article argues that learning procedural and conceptual knowledge associated with technological activity poses challenges for both technology educators and those concerned with research on learning.     

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.     

Technological literacy reconsidered: a model for enactment

This paper presents a model to describe technological literacy as enacted by indiviudals in the course of shaping their lives and the world around them. The model has two interrelated facets—the potential for and enactment of technological literacy—where enactment and potential mutually constitute each other. This potential is made up of knowledge of a particular situation, personal engagement with a situation, and social engagement in the world. Enactment requires a particular set of competencies in action, which together helps shape the situation: recognizing needs; articulating problems; contributing towards the technological process; and analysing consequences. The implications of this model for technological literacy in the context of the individual and society, and the role of technology education in developing technological literacy, are discussed.     

Discerning technological systems related to everyday objects: mapping the variation in pupils’ experience

Understanding technology today implies more than being able to use the technological objects present in our everyday lives. Our society is increasingly integrated with technological systems, of which technological objects, and their function, form a part. Technological literacy in that context implies understanding how knowledge is constituted in technology, and in particular how concrete (objects) and abstract levels (systems) are linked. This article has an educational focus concerning systems in technology education. Using a phenomenographic approach, the study explores pupils’ experiences of technological systems as embedded in four everyday objects. We identify five qualitatively different ways of understanding systems, ranging from a focus on using the particular objects, over-focussing on the function of objects, seeing objects as part of a process, and seeing objects as system components, to understanding objects as embedded in systems. As a conclusion, we suggest an educational strategy for teaching about systems in technology education.     

The Politics of Technological Literacy

Technological literacy has been given official sanction; it is the end of technology education in the United States. For most technology educators, the construct is neutral, and something nobody could be ‘against’. This article situates technological literacy in its ideological context of competitive supremacy and conservative politics. In opposition to a ‘neutral’ notion of this construct, a turn toward critical technological literacy is negotiated. Critical technological literacy represents an overtly political turn toward overcoming forms of power that sustain inequities in the built world. To engage in these politics, it is argued that technology educators will necessarily have to resituate their practice within cultural studies.     

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.     

Teaching and learning the nature of technical artifacts

Artifacts are probably our most obvious everyday encounter with technology. Therefore, a good understanding of the nature of technical artifacts is a relevant part of technological literacy. In this article we draw from the philosophy of technology to develop a conceptualization of technical artifacts that can be used for educational purposes. Furthermore we report a small exploratory empirical study to see to what extent teachers’ intuitive ideas about artifacts match with the way philosophers write about the nature of artifacts. Finally, we suggest a teaching and learning strategy for improving (student) teachers’ concepts of technical artifacts through practical activities.     

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 technological knowledge used by technology education students in capability tasks

Since technology education is, compared to subjects such as mathematics and science, still a fairly new subject both nationally and internationally, it does not have an established subject philosophy. In the absence of an established subject philosophy for technology education, one can draw on other disciplines in the field, such as engineering and design practice, for insights into technological knowledge. The purpose of this study is to investigate the usefulness of an epistemological conceptual framework chiefly derived from engineering, to be able to describe the nature of technological knowledge, in an attempt to contribute towards the understanding of this relatively new learning area. The conceptual framework was derived mainly from Vincenti’s (What engineers know and how they know it. Johns Hopkins University Press, Baltimore, 1990) categories of knowledge based on his research into historical aeronautic engineering cases. Quantitative research was used to provide insight into the categories of knowledge used by students at the University of Pretoria during capability tasks and included an analysis of a questionnaire administered to these students. Findings suggest that the conceptual framework used here is useful in technology education and that the categories of technological knowledge apply to all the content areas, i.e. structures, systems and control, and processing, in technology education. The study recommends that researchers and educators deepen their understanding of the nature of technological knowledge by considering the categories of technological knowledge presented in the conceptual framework.     

The Politics of Technological Literacy

Technological literacy has been given official sanction; it is the end of technology education in the United States. For most technology educators, the construct is neutral, and something nobody could be ‘against’. This article situates technological literacy in its ideological context of competitive supremacy and conservative politics. In opposition to a ‘neutral’ notion of this construct, a turn toward critical technological literacy is negotiated. Critical technological literacy represents an overtly political turn toward overcoming forms of power that sustain inequities in the built world. To engage in these politics, it is argued that technology educators will necessarily have to resituate their practice within cultural studies. This revised version was published online in July 2006 with corrections to the Cover Date.     

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.     

Working around technologies—invisible professionalism?

This study discusses how professionalism and work ethics influence how health care professionals work around new technologies. When people avoid using technologies, they are not necessarily ceasing to engage in their work activities. The workaround strategies presented here are rather practical expressions of professionals’ active encounter with the complexity of work situations, and can therefore be important signs of professional ethical judgement. Drawing on science and technology studies and the concept of invisible work, the study discusses workaround situations that arise in health care work in Denmark. The aim and contribution of the study is twofold. First, it attempts to revitalise the discussion on technology workaround strategies as responsible professionalism. Second, it will direct attention to and contribute to an understanding of how the normativity embedded in technological development in the health care sector is central to the work of health care professionals.     

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.     

The study of technology as a field of knowledge in general education: historical insights and methodological considerations from a Swedish case study, 1842–2010

Today, technology education in Sweden is both a high-status and a low-status phenomenon. Positive values such as economic growth, global competitiveness and the sustainability of the welfare state are often coupled with higher engineering education and sometimes even upper secondary education. Negative values, on the other hand, are often associated with primary and lower secondary education in this subject. Within the realm of technology education at such lower levels of schooling in Sweden, different actors have often called for reformed curricula or better teacher training, owing to the allegedly poor state of technology education in schools. Recurring demands for a change in technology education are nothing unique from an historical point of view, however. In fact, the urge to influence teaching and learning in technology is much older than the school subject itself. The aim of this article is to describe and analyse some key patterns in technology education in Swedish elementary and compulsory schools from 1842 to 2010. This study thus deals with how technological content has developed over time in these school forms as well as how different actors in and outside the school have dealt with the broader societal view of what is considered as important knowledge in technology as well as what kind of technology has particular significance. The long period of investigation from 1842 to 2010 as well as a double focus on technology as scattered educational content and a subject called Technology make it possible to identify recurring patterns, which we have divided into three overarching themes: Technological literacy and the democratic potential of technological knowledge, The relationship between school technology and higher forms of technology education and The relationship between technology and science.     

AI narratives and unequal conditions. Analyzing the discourse of liminal expert voices in discursive communicative spaces

The stories told by expert activists about the relationship between AI and inequality are the focus of this article. It explores internet governance discourse in two fora - RightsCon and Sweden's Internet Days - which, it is argued, comprise a communicative space that is both global and liminal. Narrative analysis is used to map how 30 expert activists from around the world, whose engagement is bound neither to state nor corporate interests, talk about how AI can be understood as a boon or a bane to inequality, both social and communicative. While common themes are in evidence (such as the need to safeguard people's right to own their own data), some noteworthy dissonances are also discernible (such as whether such people should be envisaged as individuals or collectivities). The narratives are critical in that they resist the impetus of rapid, and in some cases unfettered, technological advancement while at the same time pushing back against the apocalyptic AI narratives familiar from popular culture. The study contributes to an understanding of the socio-technico imaginaries of a category of actors who merit more attention than they have been paid by scholars to date. Their expertise grants them authority, and the stories they tell speak of agency.