An insect 5.25 mmmm tall is placed 25.0 cmcm to the left of a thin planoconvex...

An insect 3.60 mm tall is placed 22.8 cm to the left of a thin planoconvex...

An insect 3.60 mm tall is placed 22.8 cm to the left of a thin planoconvex lens. The left surface of this lens is flat, the right surface has a radius of curvature of magnitude 12.8 cm, and the index of refraction of the lens material is 1.64. (a) Calculate the location of the image this lens forms of the insect. distance cm location ---Select--- to the left of the lens to the right of the lens Calculate the size...

A 3.75mm tall object is located 22.5cm to the left of a planoconvex lens, oriented such...

A 3.75mm tall object is located 22.5cm to the left of a planoconvex lens, oriented such that the flat surface faces the object. The second surface of the lens has a radius of curvature with magnitude 13cm. The lens' index of refraction is 1.7. (a) find the location and size of the image. Real? Inverted? (b) repeat the calculation if the lens is reversed, with the convex side now facing the object.

An object 0.300 cm tall is placed 15.0 cm to the left of the vertex of...

An object 0.300 cm tall is placed 15.0 cm to the left of the vertex of a concave spherical mirror having a radius of curvature of 24.0 cm. Is the image real, or virtual, is it erect or inverted, and how tall is it?

The cornea behaves as a thin lens of focal length approximately 1.80 cm , although this...

The cornea behaves as a thin lens of focal length approximately 1.80 cm , although this varies a bit. The material of which it is made has an index of refraction of 1.38, and its front surface is convex, with a radius of curvature of 5.00 mm . (Note: The results obtained here are not strictly accurate, because, on one side, the cornea has a fluid with a refractive index different from that of air.) Part A: If this focal...

An object 0.440 cm tall is placed 18.5 cm to the left of the vertex of...

An object 0.440 cm tall is placed 18.5 cm to the left of the vertex of a convex spherical mirror having a radius of curvature of 22.5 cm. A. Calculate the position of the image. B. Calculate the size of the image. (Express your answer in centimeters to three significant figures) C. Find the orientation (upright or inverted) and the nature (real or virtual) of the image.

A 1.8 cm tall object is placed 5 cm to the left of a converging lens...

A 1.8 cm tall object is placed 5 cm to the left of a converging lens (lens #1) with a focal length of 1.3 cm. To the right of this converging lens is a diverging lens (lens #2) that has a focal length of 2.6 cm. The diverging lens is placed 22.4 cm from the converging lens. Where is the final image, is it real or virtual, and is it upright or inverted?

An object of size 4.0 cm is located 14 cm to the left of a thin...

An object of size 4.0 cm is located 14 cm to the left of a thin biconvex lens with a focal length of +6.5 cm. A second, thin biconcave lens is located 35 cm to the right of the first lens and has a focal length of -6.5 cm. Object and lenses are aligned on a common optical axis. (a) Sketch the resulting final image by using principal rays. (b) Is the final image real or virtual, erect or inverted?...

An object which is 1.23 cm high is placed 10.00 cm to the left of a...

An object which is 1.23 cm high is placed 10.00 cm to the left of a lens. It is not known if the lens is converging or diverging. An image forms 3.20 cm to the left of the lens. (a) Determine if the lens is converging or diverging by calculating the focal length of the lens. (b) Calculate the height of the image. (c) Describe the image. Is it real or virtual, upright or inverted and enlarged or diminished?

A converging lens of focal length f1 = +22.5 cm is placed at a distance d...

A converging lens of focal length f1 = +22.5 cm is placed at a distance d = 60.0 cm to the left of a diverging lens of focal length f2 = −30.0 cm. An object is placed on the common optical axis of the two lenses with its base 45.0 cm to the left of the converging lens. (The thin-lens approximation may be assumed to hold.) (a) Calculate the location of the final image and its overall magnification with respect...

1. A beam of light in water (n = 1.33) enters a transparent medium at an...

1. A beam of light in water (n = 1.33) enters a transparent medium at an angle of incidence of 47.0o, and is refracted at an angle of refraction 37.0o to the normal. What is the refractive index of the medium? 2. If a converging lens forms a real, inverted image 18.0 cm to the right of the lens when the object is placed 44.0 cm to the left of a lens, determine the focal length of the lens in...