Students begin by learning the basic concepts of shape transformations, which include translations (slides), rotations (turns), and reflections (flips). Early lessons focus on identifying these transformations in everyday objects and situations, such as sliding a box across the floor, turning a key, or seeing a reflection in a mirror. As they progress, students practice performing these transformations on simple shapes using grids and tracing paper. By Year 5, they have a solid understanding of how these transformations work and can apply the principles to more complex geometric figures, preparing them for detailed studies in symmetry and congruence.

After grasping the basics, students explore how transformations affect shapes and their properties. They engage in activities that involve transforming various shapes and observing the effects on size, orientation, and position. This includes combining transformations to see the cumulative effect on a single shape. By Year 5, students explore the mathematical rules governing transformations, such as the invariance of angle and distance under certain transformations. They apply these rules to solve problems and create complex designs, enhancing their spatial reasoning and understanding of geometry.

Initially introduced to simple real-life examples of transformations, such as rotating a door or folding paper to make a symmetrical design, students gradually explore more complex applications. These include using transformations in technology (e.g., computer graphics, robotics), art (e.g., tessellations, kaleidoscopes), and other fields like architecture and engineering. By Year 5, students understand how transformations are used to solve practical problems, create aesthetic designs, and develop technological solutions. They apply their knowledge to projects that require precise manipulation of shapes and spaces, linking geometric theory with practical applications in creative and scientific contexts.