reflection
When a figure is flipped over a line, it undergoes a transformation known as reflection. The result is a mirror image of the original figure, where each point on the figure is mapped to a corresponding point on the opposite side of the line at an equal distance. This transformation preserves the shape and size of the figure but reverses its orientation. For example, if the original figure is oriented to the right, the reflected figure will be oriented to the left.
A type of transformation where an original figure is flipped over a line onto its image is called reflection. In this process, each point of the original figure is mapped to a corresponding point on the opposite side of the line, maintaining equal distance from the line of reflection. This creates a mirror image of the original figure.
A reflection in a graph occurs when a shape or figure is flipped over a specified line, creating a mirror image. Common lines of reflection include the x-axis, y-axis, or any line defined by a specific equation. This transformation maintains the shape and size of the figure but alters its orientation. For example, reflecting a point across the y-axis changes its x-coordinate to its negative while keeping the y-coordinate the same.
A symetry line is like a mirror line, if you put it in the middle of something, the other side will have to be the same thing, flipped. if you take the letter V, you can put a vertical symetry line in the middle of it, and both sides will be exactally the same, but just flipped.
A transformation that changes the orientation of a figure is called a reflection. In a reflection, the figure is flipped over a line, known as the line of reflection, resulting in a mirror image that has a reversed orientation. Other transformations, such as rotations and translations, do not change the orientation of the figure.
When a figure is flipped over a line, it undergoes a transformation known as reflection. The result is a mirror image of the original figure, where each point on the figure is mapped to a corresponding point on the opposite side of the line at an equal distance. This transformation preserves the shape and size of the figure but reverses its orientation. For example, if the original figure is oriented to the right, the reflected figure will be oriented to the left.
A type of transformation where an original figure is flipped over a line onto its image is called reflection. In this process, each point of the original figure is mapped to a corresponding point on the opposite side of the line, maintaining equal distance from the line of reflection. This creates a mirror image of the original figure.
A transformation that creates a mirror image of the original image is called a reflection. This transformation flips the image across a line called the axis of reflection, creating a mirror image that is a flipped version of the original.
You do a flip in geometrey when you do transformations. Flip is a transformation in which a plane figure is flipped or reflected across a line, creating a mirror image of the original figure.
A symetry line is like a mirror line, if you put it in the middle of something, the other side will have to be the same thing, flipped. if you take the letter V, you can put a vertical symetry line in the middle of it, and both sides will be exactally the same, but just flipped.
A transformation that changes the orientation of a figure is called a reflection. In a reflection, the figure is flipped over a line, known as the line of reflection, resulting in a mirror image that has a reversed orientation. Other transformations, such as rotations and translations, do not change the orientation of the figure.
Well, honey, a reflection doesn't change the orientation of a shape. It simply flips it over a line, like checking yourself out in a mirror. So, if you're looking for a quick fix to change things up, a reflection is your go-to move.
To find the invariant line of a stretch, identify the direction in which the stretch occurs. The invariant line is typically the line that remains unchanged during the transformation, often along the axis of the stretch. For example, if stretching occurs along the x-axis, the invariant line would be the y-axis (or any line parallel to it). You can confirm this by observing that points on the invariant line do not change their position under the stretch transformation.
When a translation is followed by a reflection across a line parallel to the direction of translation, the resulting transformation is a glide reflection. This transformation involves moving the shape in a specified direction (translation) and then flipping it over (reflection) across a parallel line. The combination results in the shape being both translated and reflected.
It depends on the form of transformation.
You can flip the traced version along various lines. If the flipped shape matches the original then the that is a line of symmetry. Alternatively, if you can find a fold such that the two halves of the tracing match then the fold line is a line of symmetry.
It is a line of symmetry