Juan Guerrero, Phuc La

Physics 102

Ray Tracing

Juan Guerrero, Phuc La

April 16, 2006

Abstract

The purpose of this lab is to verify the reflective properties of a plane mirror and locate the focal point of a convex mirror. The lab is also to find the radius of curvature of a concave mirror and the index of refraction of a double convex lens. Finally, it is to find the focal point for a concave lens and the critical angle for total internal reflection in a plano-convex lens.

Data

Flat mirror

The angle of incidence / The angle of reflection
oC / oC
20.05 / 20.06

Convex and Concave mirrors

Focal point of convex mirror / Focal point of concave mirror
cm / cm
2.80 / 2.60

Convex and Concave lens

Focal point of convex lens / Focal point of concave lens
cm / cm
11.70 / 11.70

The plano-convex lens

The critical angle is 44.50o.

Graphs

Diagrams are in attached papers.

Calculations

Flat mirror

In the flat mirror, the angle of incidence is equil to the angle of reflection. In the experiment, the angle of incidence is 20.05o. The angle of reflection is 20.06o and closes to the angle of reflection. So, the angle of incidence should be the same as the angle of reflection.

The difference error is

Should be in the percent error section

Convex mirror

The distance from the focal point to the mirror is 2.80 cm. The radius is two times the focal length.

R = 2f = 2 * 2.80 cm = 5.60 cm

The image is behind the mirror.

Concave mirror

The distance from the focal point to the mirror is 2.60 cm. The radius is two times the focal length.

R = 2f = 2 * 2.60 cm = 5.20 cm

The diameter of the concave mirror is

D = 2R = 2 * 5.20 cm = 10.4 cm

The image is in front of the mirror.

Convex lens

Several tangent lines are drawn to the lens. A perpendicular line from the tangent point is drawn back toward the center of curvature. The distance from the tangent point to where perpendiculars cross is R. R is 10.70 cm. The convex lens has the same curvature so

Ri = Rr = R = 10.70 cm

Also, the focal length is 11.70 cm

using the lensmakers’ equation, the index of refraction is

Diverging lens

Using the diagram for the diverging lens, the focal point of the double concave lens is 11.70 cm

Plano-convex lens

The critical angle is the angle between the incidence ray and the normal line of new flat trace. The critical angle is 44.50o.

Results

Flat mirror

The angle of incidence / The angle of reflection
oC / oC
20.05 / 20.06

Convex mirror

Focal point of convex mirror / Radius
cm / cm
2.80 / 5.60

Concave mirror

Focal point of concave mirror / Radius / Diameter
cm / cm / cm
2.60 / 5.20 / 10.4

Convex lens

Focal point of convex lens / Radius / The index of refraction (n)
cm / cm
11.70 / 10.70 / 1.457

Concave lens

Focal point of convex lens
cm
11.70

Plano-convex lens

The critical angle
oC
44.50

% Error

In the experimentt, the flat mirror has two values to calculate the different error.

The angle of incidence / The angle of reflection / % diff
oC / oC / %
20.05 / 20.06 / 0.05

Questions

1.  Common uses for concave mirrors are in telescopes that uses mirrors to magnify an image onto an eyepiece and satellite dish which is concave mirror to reflect microwave waves onto an antenna.

Common uses for convex mirrors are sometimes used for home decorating, a security mirror in a shop and a wide angle mirror on a bus.

2.  A convex lens is used to obtain a real image of an object like diagram 1.

The concave lens is put in place like diagram 2.

The real image in diagram 1 becomes virtual object in diagram 2. Concave lens uses the virtual object to form a real image. So, the effects of a convex lens can be negated by a concave lens.

3.  Below picture is an illustration.

The air above the water haves index of refraction n2 and the water has an index of refraction n1. Besides, n2 equals 1 and n1 equals 1.33. θ angle is

θ is critical angle and equals 48.8o. The person can see the object that is out of the water if the person looks toward the surface at an angle less than the critical angle. At 48.8o, the person can see the object on the surface of the water. At angles greater than the critical angle, the person sees a reflection of the part of the object in the water.

Conclusion

In flat mirrors, the angle of reflection equals the angle of incidence. Incomimg parallel rays focus to a point on concave mirror and gives real image. The light is reflected from the outer and the reflected light is from the point behind the convex mirror. Diverging lenses always give upright virtual image. In converging lens, when object distance is less than focal length, the image is an upright virtual image. When the object’s distance is greater than the focal length, the image is an inverted real image. In plano-convex lens, the light escapes from the flat side of the lens when the angle is less than the critical angle. The light failed to escape from the flat side of the lens when its angle is greater than the critical angle.

98/100