no weight
To draw an object at infinity for a concave mirror reflection, draw a parallel line to the principal axis passing through the focal point. This line represents the path of light rays coming from infinity. It's not necessary to physically draw an object at infinity, but understanding how the rays behave from afar helps in analyzing the image formation for concave mirrors.
When an object is at infinity from a convex lens, the image will be formed at the focal point of the lens. The image will be a real and inverted point of light.
The image produced is a real image if the object is located at infinity and the lens is a convex lens. The produced image can actually be placed on a screen and photographed.
Any value, from -Infinity to +Infinity -- normally used in variables, cycles, etc.
The buoyant force on a floating object depends on the weight of the fluid displaced by the object, not on the weight of the object itself. This is known as Archimedes' principle.
To draw an object at infinity for a concave mirror reflection, draw a parallel line to the principal axis passing through the focal point. This line represents the path of light rays coming from infinity. It's not necessary to physically draw an object at infinity, but understanding how the rays behave from afar helps in analyzing the image formation for concave mirrors.
Placing an object inside an infinity mirror creates the illusion of infinite reflections, making the object appear to be surrounded by an endless series of identical images.
When an object is at infinity from a convex lens, the image will be formed at the focal point of the lens. The image will be a real and inverted point of light.
you take the weight of a house and multiply it by infinity then multiply by infinity again
The image produced is a real image if the object is located at infinity and the lens is a convex lens. The produced image can actually be placed on a screen and photographed.
A ray.
A ray.
Any value, from -Infinity to +Infinity -- normally used in variables, cycles, etc.
Zero.
The mass of an object does not change , but its weight can vary.
The buoyant force on a floating object depends on the weight of the fluid displaced by the object, not on the weight of the object itself. This is known as Archimedes' principle.
Buoyancy force is determined by comparing the weight of the fluid displaced by an object to the weight of the object itself. If the weight of the fluid displaced is greater than the weight of the object, the object will float. If the weight of the fluid displaced is less than the weight of the object, the object will sink.