1. Consider a 1 mm bug located at your nearpoint, 25 cm away from your left...

1) The distance from the lens to the retina is 3.1 cm, what is the effective...

1) The distance from the lens to the retina is 3.1 cm, what is the effective focal length of the lens when staring at an object infinitely far away? 2) An object is moved to 40cm from the eye. What must the focal length of the eye be to focus the image on the retina? 3) In the near sighted eye, images focus before hitting the retina. Suppose the focal length of the lens is 1.9 cm, while the distance...

a) A 50 mm lens is 51.3 mm away from a piece of film, where the...

a) A 50 mm lens is 51.3 mm away from a piece of film, where the image is formed in a photograph. How far away should the subject of the photograph stand in order to take an in-focus picture? b)A thin lens has a focal length of f = -63 cm. If the image created by the lens is located a distance 13 cm away from the center of the lens, what is the magnification of the lens? (c) A...

A bug which is 4.8 mm in diameter flies in front of a converging (convex) lens...

A bug which is 4.8 mm in diameter flies in front of a converging (convex) lens with a focal length of 6.0 cm. Take the lens to be located at x = 0 cm. a. Does the lens have a positive focal length or a negative focal length? b. At the moment the bug is located at x = 7.0 cm, where is its image? c. At the moment the bug is located at x = 7.0 cm, how big...

Consider a convex mirror with an object placed 20 cm away and a virtual image 15...

Consider a convex mirror with an object placed 20 cm away and a virtual image 15 cm into the mirror. The image appears to be 2 cm tall a) What is the focal length of the mirror? b) How large is the object? c) Adding a convex convex lens at a distance of 10 cm from the object (halfway between the object and the mirror), with a focal length of 6 cm, where would the final image appear? d) Removing...

A. You are looking at an object 1.75 m tall 30 m away from you. Assuming...

A. You are looking at an object 1.75 m tall 30 m away from you. Assuming the eye is completely relaxed and that the nodal point of the eye is 1.65 cm in front of the retina, calculate the height of the image of the object on the retina, assuming that it is in focus. What is the focal length and the refractive power of the eye under these conditions? B. You have shifted your focus to a nearby object...

An object is placed 4 cm away from a concave lens of focal length 3 cm....

An object is placed 4 cm away from a concave lens of focal length 3 cm. A convex lens of focal length 5 cm is placed 4 cm away from the concave lens in the same direction (so the distance between convex lens and the object is 8 cm). Use any method to figure out if the final image is real/virtual, upright/inverted and find its distance from the convex lens. Explain in thorough detail. draw a proper ray diagram for...

An object is held 82.7 cm away from a lens. The lens has a focal length...

An object is held 82.7 cm away from a lens. The lens has a focal length of -31 cm. A.) Determine the image distance B.) Determine the magnification. C.) If the object is 4 cm long, determine the image height D.) Which of the following are true about the image? The image is virtual the image is upright the image is inverted the image is real E) Which is true about the lens? The lens is concave the lens is...

2. Correcting vision: quantitative. Corrective lenses work because the lens bends light such that it, combined...

2. Correcting vision: quantitative. Corrective lenses work because the lens bends light such that it, combined with the eye itself, light forms a clear image on the retina. Another way to think about this is that the corrective lens (glasses) form an image of the object at a location where the eye can see clearly without corrective lenses. For a nearsighted person viewing an object very far away (object at infinity), the lens corrective lens creates an image at the...

A converging lens with a focal length of 4.8 cm is located 24.8 cm to the...

A converging lens with a focal length of 4.8 cm is located 24.8 cm to the left of a diverging lens having a focal length of -15.0 cm. If an object is located 9.8 cm to the left of the converging lens, locate and describe completely the final image formed by the diverging lens. Where is the image located as measured from the diverging lens? What is the magnification? Also determine, with respect to the original object whether the image...

The uncorrected eye. For the following questions, assume that the distance between the eye lens and...

The uncorrected eye. For the following questions, assume that the distance between the eye lens and the retina is 1.70 cm. In other words, since the image is always formed on the retina, the distance between the lens and the image is always 1.70 cm. Also note that, as is seen in the ray diagram, since the eye lens is converging and the image is on the opposite side of the lens compared to the object, the image is always...