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∙ 13y agoSMALLER
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∙ 13y agoAn object seen through a concave lens will appear smaller than its actual size. This is because a concave lens diverges light rays, causing them to spread out, which creates a reduced image size.
A concave mirror has a virtual focus. This is because the rays of light that are incident on a concave mirror are reflected and appear to diverge from a point behind the mirror, creating a virtual focus.
A magnification of 300x means that an object will appear 300 times larger than its actual size when viewed through the microscope or magnifying instrument.
15 x 80 is the magnification of a binocular, which means that an object will appear 15 times closer and larger when viewed through it compared to the naked eye.
A convex lens can change the behavior of light waves by refracting them, causing the light to converge and creating a magnified image of an object. This magnification effect can make an object appear larger than its actual size when viewed through the lens.
A mirror that bows inward is called concave. The opposite, a mirror that bows outward would be called convex. Convex mirrors are used to to increase the field of view around corners and blind spots. Concave mirror serve no purpose other than novelty (making you appear thin or odd)
A diverging lens, also known as a concave lens, makes objects appear smaller when viewed through it. This type of lens causes light rays to spread out, resulting in a reduced image size compared to the actual object.
The image formed by a concave lens is always virtual, upright, and located on the same side as the object. It is also diminished in size compared to the object.
An object seen through a convex lens will appear larger than its actual size. This is because the convex lens converges light rays and brings them to a focus point, magnifying the image.
An object seen through a concave lens will appear smaller, upright, and virtual - meaning it will not project a real image on a screen. The image will be on the same side as the object and its characteristics will depend on the distance of the object from the lens.
A ray parallel to the axis of a concave lens will refract through the lens and appear to have come from the focal point on the same side as the object.
Because a concave lens diverges light rays, they appear to come from a virtual focal point where the rays appear to originate without actually meeting. This property allows concave lenses to create virtual images that are upright and diminished in size compared to the object.
When you look through a concave lens, objects may appear smaller and closer than they actually are. This type of lens causes light rays to diverge, resulting in a virtual image that is upright and reduced in size. However, the image may appear blurry due to the spread of light rays.
As light passes through a concave lens, it refracts outward, causing the light rays to diverge. This is because the concave lens is thinnest at the center, causing the light waves passing through it to spread apart. The point at which the refracted light rays appear to converge is known as the focal point.
Convex glass bulges outwards, causing light rays passing through it to diverge, making objects appear smaller. Concave glass curves inwards, causing light rays passing through it to converge, making objects appear larger.
A concave lens diverges light rays that pass through it, causing them to spread out. This spreading out of light results in the image appearing smaller when it reaches the eye. This is why objects viewed through a concave lens appear smaller than when viewed with the naked eye.
A concave spoon will appear to turn upside down when immersed in a liquid due to the refraction of light. When light passes from air into a denser medium (like water), it bends and changes direction. This bending of light causes the concave spoon to appear inverted when seen through the water.
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.