On the exploration, expansion and expression of experiencing technological systems across contexts: learning

technology in the Swedish compulsory

school

Åke Ingerman, Maria Svensson & Anders Berglund, Shirley Booth, Jonas EmanuelssonContact: ake.ingerman@gu.se or maria.svensson@ped.gu.se

Phenomenography and variation theory

Pedagogical situations

Systems thinking

Compulsory technology education

Classroom teaching and

learning

Project nodes

Research questionsOverall questions:

What does it take to learn, and what does it mean to teach for learning, Technological Systems, their constituent parts and the relations between them when the systems are embedded in different contexts and encountered in different pedagogical structures?

Specific questions:

What do students in the lower secondary school understand of technological systems in terms of their constituent parts when given opportunities to explore systems in different contexts?

What can teachers offer as a platform for developing a general understanding of Technological Systems with recourse to different systems set in different contexts?

How are Technological Systems expressed in different contexts in different pedagogical structures in the classroom arena?

Technological systems in compulsory school

‘technological systems’ form an important part of the school subject Technology in Swedish schools, focusing aspects such as components, subsystems, risks, advantages in the context of electricity, internet, transport etc.

Our working definition of technological systems - encompass much of what characterises technology - goal-directed, delivering both to society and to individuals, but have also unwanted effects- may concern detrimental influence on the environment- not tangible, thus less supported by informal learning than other themes in technology

Basic designDesign of teaching and learning events

Audio and video documentation of such events. Focus how learning of technological systems manifest in 1) different system contexts 2) different pedagogical conditions (e.g. Lecture, group discussion, problem solving, pratical work).

Analytical ”tracing” of ways in which critical aspect manifest in these different context, and putting that in relation to content and pedagogical conditions. Phenomenography and variation theory.

=> Outcome of productive ways of teaching and learning technological systems, how such learning is constituted and ways in which it manifests in different context (important for e.g. Assessment). Both process and product descriptions.

Three major pedagogical contexts

Analysing problems, such as considering how the systemic nature of a particular system changes when a central component or aspect of the framework of relationships changes. Examples are the break of power wires connecting northern and southern Sweden and the merging of the mobile and land-line phone communication systems that is underway.

Working with representations. Examples are the tram time-tables in conjunction with the map of destinations, or a flow chart of normal mail distribution, and diagrams of power usage across different times of the year and times of day.

Experiencing systems, coming into physical as well as conceptual contact with systems. Examples involve visiting central components in different systems, such as airports, sewage works, or inspecting a power generator.

Tentative patterns of variation

Based on 1) variation theory design principles (contrast, separation and fusion), 2) empirical descriptions of key challenges in understanding complex systems, and 3) empirical descriptions of aspects that are critical for learning technological systems in the targeted educational level

In each dimension – distinct contrast between systems characteristics and non-systems characteristics

Double attention on intertwined levels: general concept of technological systems and specific manifestation

ResourceSpecific resource in contrast to systems resource

Exemplify resources of distinct different character – only matter, energy or information

Matter

Energy

Information

IntentionSpecific person seeing the need and ascribing technological artefact to meet that need

In contrast to recurrent need, and establishing a community to sustain a shared intention

Internal structure of system

Components organised linearly

In contrast to components organised in a network

Differentiate components and their relationships – transform and transport, relation to system intention

TransportationTransformati

on

External structureLess central for core understanding of systems

Limits of systems – other possible systems (”arbitrary”)

Interaction with surrounding – consequences and dependencies

Challenges

Dual focus: design for teaching – expressions of knowing technological systems

Low level of knowledge and tradition on teaching and learning technological systems.

Delimit the object of learning – discernment and continuity across manifestations

Inherent tension between concept and the tradition of problem solving and practical work in technology

Analytical tools for identifying variation and invariance of expressions of technological systems in pedagogical contexts of different character