Calculate the limiting angle of resolution for the eye, assuming a pupil diameter of 1.75 mm,...

calculate the limiting angle of resolution for the eye, assuming a pupil diameter of 2 mm,...

calculate the limiting angle of resolution for the eye, assuming a pupil diameter of 2 mm, a wavelength of 500 nm in air, and an index of refraction for the eye equal to 1.33. calculate the minimum separation d between two points that the eye can distinguish, if the points are at a distance L = 25 cm from the observer. If the eye is dilated to a diameter of 5 mm, what is the minimum distance between two point...

The resolution of the eye is ultimately limited by the pupil diameter. What is the smallest...

The resolution of the eye is ultimately limited by the pupil diameter. What is the smallest diameter spot the eye can produce on the retina if the pupil diameter is 3.80 mm? Assume light with a wavelength of ? = 550 nm. (Note: The distance from the pupil to the retina is 25.4 mm. In addition, the space between the pupil and the retina is filled with a fluid whose index of refraction is n = 1.336.) Hint: The size...

(a) Take the diameter of the pupil of Cyclops’s eye to be 6.5 mm, and calculate...

(a) Take the diameter of the pupil of Cyclops’s eye to be 6.5 mm, and calculate the resolution angle Theta = 1.22 Lamda/ D (rad) for light of wavelength 550 nm. For two point-objects to be resolvable with light of this wavelength, how far apart must they be (i) at distance 100 m? (ii) on the moon, 400,000 km away? (b) How far apart must they be on the moon to be resolvable with a telescope mirror of diameter 6.5...

The maximum resolution of the eye depends on the diameter of the opening of the pupil...

The maximum resolution of the eye depends on the diameter of the opening of the pupil (a diffraction effect) and the size of the light receptor cells (rods or cones) on the retina. The size of the retinal cells (about 5.0 μm in diameter) limits the size of an object at the near point (25 cm ) of the eye to a height of about 50 μm . (To get a reasonable estimate without having to go through complicated calculations,...

The pupil of an eagle’s eye has a diameter of 6.0 mm. Two field mice are...

The pupil of an eagle’s eye has a diameter of 6.0 mm. Two field mice are separated by 0.010 m. From a distance of 201 m, the eagle sees them as one unresolved object and dives toward them at a speed of 18 m/s. Assume that the eagle’s eye detects light that has a wavelength of 550 nm in vacuum. How much time passes until the eagle sees the mice as separate objects?

The pupil of an eagle’s eye has a diameter of 6.0 mm. Two field mice are...

The pupil of an eagle’s eye has a diameter of 6.0 mm. Two field mice are separated by 0.010 m. From a distance of 176 m, the eagle sees them as one unresolved object and dives toward them at a speed of 21 m/s. Assume that the eagle’s eye detects light that has a wavelength of 550 nm in vacuum. How much time passes until the eagle sees the mice as separate objects?

The pupil (the opening through which light enters the lens) of a house cat's eye is...

The pupil (the opening through which light enters the lens) of a house cat's eye is round under low light but ciliary muscles narrow it to a thin vertical slit in very bright light. Assume that bright light of wavelength 560 nm is entering the eye parallel to the principal axis of the lens and that the pupil has narrowed to a slit that is 0.500 mm wide. What are the three smallest angles on either side to the central...

2. Treat each of your eyes as a circular aperture of diameter 3.5 mm. Light of...

2. Treat each of your eyes as a circular aperture of diameter 3.5 mm. Light of wavelength 625 nm is used to view two point sources that are 10.5 cm apart. How far distance can these sources be and still be marginally resolved by your eye? Assume that the resolution is diffraction limited and use Rayleigh's criterion, and the index of refraction of the fluid in the eye is 1.35. 3. A Michelson interferometer uses light with a wavelength of...

1. Light traveling in air (index of refraction 1.00) falls onto a thin plastic film (index...

1. Light traveling in air (index of refraction 1.00) falls onto a thin plastic film (index of refraction 1.30) of unknown thickness that covers glass (index of refraction 1.50). What minimum non-zero thickness is needed such that wavelengths of 650 nm in air are bright in the reflection? 2. You observe two point sources of light that are spaced 10 cm apart which are each emitting light of wavelength of 590 nm. If the diameter of your pupil is 2...

You see a light approaching you from a distance on the highway. Is it a motorcycle...

You see a light approaching you from a distance on the highway. Is it a motorcycle (one light) or a car (two lights)? You may assume the air is perfectly clear and still, and the headlights emit exclusively blue light (λ = 475 nm). Assume your pupil (the aperture of your eye) is 5 mm in diameter. If a car with two blue headlights that are separated by 1.5 meters is approaching you, at what maximum distance could you still...