Translation in mathematics refers to the process of moving a shape or an object from one position to another without changing its size, shape, or orientation. This movement can be done in any direction - left, right, up, or down - and by a specified distance.
Key Concepts
When dealing with translations, it's important to understand the following key concepts:
Vector: A vector is a quantity that has both magnitude and direction. In the context of translations, a vector represents the direction and distance of the movement of the shape.
Coordinate Notation: Translations can be described using coordinate notation, where the original coordinates of the points of the shape are shifted according to the specified vector.
Describing Translations: Translations can be described using words, vectors, or coordinate notation.
Example
Consider a triangle with vertices at points A(1, 2), B(4, 3), and C(2, 5). If we want to translate this triangle 3 units to the right and 2 units down, we can describe this translation as a vector v = (3, -2). Using coordinate notation, the new coordinates of the vertices after the translation would be:
A'(1 + 3, 2 - 2) = A'(4, 0)
B'(4 + 3, 3 - 2) = B'(7, 1)
C'(2 + 3, 5 - 2) = C'(5, 3)
Study Guide
Here's a study guide to help you understand and practice translations:
Explore real-world applications of translations, such as in geography or computer graphics.
Review and master the properties of translations, such as the fact that the size and shape of the object remain unchanged.
By mastering the concept of translation and practicing related problems, you'll be well-prepared to handle any translation-based questions in mathematics.
Underlying Processes and Mathematical Tools: These skills will not be listed under a separate recording category. Instead, they will be incorporated into at least 75% of the test questions in reporting categories 1-5 and will be identified along with content standards.
Underlying processes and mathematical tools. The student communicates about Grade 6 mathematics through informal and mathematical language, representations, and models. The student is expected to:
Communicate mathematical ideas using language, efficient tools, appropriate units, and graphical, numerical, physical, or algebraic mathematical models. (STAAR)