The object should be placed farther than the focal point of the concave mirror along the principal axis. This will result in a real inverted image that is larger than the object and located beyond the center of curvature of the mirror.
The object should be placed beyond the focal point of the concave mirror, between the focal point and the center of curvature. This positioning will result in the formation of a real, inverted, magnified image that is located beyond the object's initial position.
Concave lenses can produce either smaller or larger images, depending on the object's distance from the lens and the characteristics of the lens itself. The image produced by a concave lens can be virtual, upright, and smaller, or it can be real, inverted, and larger.
No, a concave lens actually diverges light rays, causing them to spread apart. This results in the image appearing smaller and farther away than the actual object.
A concave mirror can give a virtual and larger image than the object when the object is placed within the focal length of the mirror. When the object is placed beyond the focal point, a real, inverted, smaller image is formed.
In a concave mirror, the image is formed when light rays converge at a point behind the mirror, known as the focal point. If the object is beyond the focal point, the image is real, inverted, and smaller in size. If the object is between the mirror and the focal point, the image is virtual, upright, and larger in size.
The object should be placed beyond the focal point of the concave mirror, between the focal point and the center of curvature. This positioning will result in the formation of a real, inverted, magnified image that is located beyond the object's initial position.
Concave lenses can produce either smaller or larger images, depending on the object's distance from the lens and the characteristics of the lens itself. The image produced by a concave lens can be virtual, upright, and smaller, or it can be real, inverted, and larger.
No, for a concave mirror the object will become larger. it is virtual the right way up and it is behind the mirror
No, a concave lens actually diverges light rays, causing them to spread apart. This results in the image appearing smaller and farther away than the actual object.
The four characteristics used to describe an image seen in a concave mirror are: 1) Size, which can be larger or smaller than the object; 2) Orientation, which can be upright or inverted depending on the object's distance from the mirror; 3) Type, which can be real (formed in front of the mirror) or virtual (formed behind the mirror); and 4) Location, which refers to the position of the image relative to the mirror (closer or farther from the mirror).
A concave mirror can give a virtual and larger image than the object when the object is placed within the focal length of the mirror. When the object is placed beyond the focal point, a real, inverted, smaller image is formed.
In a concave mirror, the image is formed when light rays converge at a point behind the mirror, known as the focal point. If the object is beyond the focal point, the image is real, inverted, and smaller in size. If the object is between the mirror and the focal point, the image is virtual, upright, and larger in size.
A plane mirror produces an upright and laterally inverted image that is the same size as the object. A concave mirror produces a real or virtual, inverted or upright image that can be larger or smaller than the object depending on the object's position relative to the mirror. A convex mirror produces a virtual, upright, and smaller image compared to the object, regardless of the object's position relative to the mirror.
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.
you see an inverted real image of yourself
If a concave mirror is made flatter, its focal length will increase. This is because a flatter mirror has a larger radius of curvature, resulting in light rays converging at a point farther away from the mirror.
If you move an object closer to a concave lens, the image produced would get larger, virtual, and upright. The image distance would increase, and the image would appear farther away from the lens compared to the object.