As the object is moved closer to a converging lens or mirror, the image distance decreases, and the image becomes larger and more magnified. When the object is moved away from the lens or mirror, the image is formed farther away, becomes smaller, and less magnified.
If the object is moved away from a concave mirror, the image will move closer to the mirror and eventually transition from a real inverted image to a virtual upright image. The image will also become larger and eventually disappear as the object moves beyond the focal point of the mirror.
If the object is moved closer to a convex lens, the image distance will decrease and the image will move closer to the lens. The image size may increase depending on the object distance and object size relative to the focal length of the lens.
As the object is moved beyond the center of curvature (C) towards the focal point (F), the real image will become larger in size. This is because as the object moves closer to the focal point, the diverging rays create a larger image due to their increased divergence.
As the object distance increases, the image distance also increases. This relationship is governed by the lens or mirror equation, which shows that when the object is moved farther from the lens or mirror, the image is also formed farther from the lens or mirror.
The distance between the object and a convex lens affects the size and orientation of the image produced. When the object is moved closer to the lens, the image becomes larger, while moving the object farther away from the lens makes the image smaller. The position of the image also changes, with the image flipping upside down when the object is moved beyond the focal point of the lens.
If the object is moved away from a concave mirror, the image will move closer to the mirror and eventually transition from a real inverted image to a virtual upright image. The image will also become larger and eventually disappear as the object moves beyond the focal point of the mirror.
If the object is moved closer to a convex lens, the image distance will decrease and the image will move closer to the lens. The image size may increase depending on the object distance and object size relative to the focal length of the lens.
As the object is moved beyond the center of curvature (C) towards the focal point (F), the real image will become larger in size. This is because as the object moves closer to the focal point, the diverging rays create a larger image due to their increased divergence.
As the object distance increases, the image distance also increases. This relationship is governed by the lens or mirror equation, which shows that when the object is moved farther from the lens or mirror, the image is also formed farther from the lens or mirror.
The distance between the object and a convex lens affects the size and orientation of the image produced. When the object is moved closer to the lens, the image becomes larger, while moving the object farther away from the lens makes the image smaller. The position of the image also changes, with the image flipping upside down when the object is moved beyond the focal point of the lens.
The object is moved and energy is transferred.
It would be heavier.
As the object was moved closer to the lens from beyond 2 focal lengths, the real image became larger in size. This is because the image distance decreased while the object distance increased, leading to a magnified real image being formed by the lens.
If the object is moved further away from the pinhole, the image would become smaller and dimmer as it is projected onto the screen or surface. The image would also become more focused since light rays from different parts of the object have to travel a longer distance to converge at the pinhole, resulting in a sharper image.
The image will move upwards in the field of view when the slide is moved towards you. This is because the slide is physically closer to the objective lens, resulting in the object on the slide appearing to move in the opposite direction.
Moving a convex lens too far away from an object will cause the image to become blurry and eventually disappear. This occurs because the light rays converge to a point that is beyond the focal point of the lens, creating a virtual image that is not focused.
The shadow's position changes relative to the light source and object. It will move and change in size depending on the direction and distance the object is moved.