Optics

Optics is a National trial lab event that will become an official event for Division B during the 2011 season. This event deals with geometric and physical optics, such as reflection, refraction, critical angle, electromagnetic and visible spectrum, lenses, and mirrors. Competitors for this event may bring any type of calculator and should have knowledge of SI units, as all answers will require a student to know and understand them. Some aspects of optics are similar to the former event Crave the Wave, though optics focuses on light while Crave the Wave was about waves in general.

Introduction to optics
Optics is a science which studies light. Optics is usually divided into two 'subfields': geometric and physical optics. Geometric optics studies how light travels, and includes concepts of reflection and refraction. In geometric optics, light is thought of as rays which travel in a straight line (for the most part; I'll talk about refraction later).

Physical optics studies the nature of light, as well as phenomena which cannot be explained by the ray approximation used in geometric optics. Physical optics includes the visible and electromagnetic spectrum, and concepts such as interference.

Geometric Optics
When waves of light (or electromagnetic waves in general) hit the boundary between two mediums, there are several ways that the light can react. Namely, it can reflect, refract, or be absorbed into the second medium. These will be explained below.

Reflection
The law of reflection states:


 * The angle of incidence of a wave or stream of particles reflecting from a boundary, conventionally measured from the normal to the interface, is equal to the angle of reflection, measured from the same interface.

This may seem very complicated, but it really isn't that hard to understand. For reflection to occur, you need a "wave or stream of particles" and an interface. Light, of course, takes the former role. For our purposes, let's assume that the interface is a mirror.

Figure 1 is a convenient example of reflection. In the diagram, PO is an incoming ray of light about to reflect off a mirror. OQ is the ray after it has hit the mirror. You also can see a new line, called the "normal". This is an imaginary line through point O, which is perpendicular to the mirror. The angle of incidence is the angle labeled θi, and the angle of reflection is the one labeled θr.

From this, we can represent the law of reflection by the following simple equation: θi = θr

You can also conclude that the complimentary angles to θi and θr will be congruent.

Sample Questions
Example Station 1: Measure the focal length of convex and/or concave lenses and/or mirrors

Example Station 2: Using ray-tracing techniques, find the image/object locations of one and/or two lens and/or mirror systems. Specify the image/object characteristics (real/virtual, magnification, erect/inverted, object/image distances, lens/mirror focal lengths).

Example Station 3: Set up mirrors and/or lenses to direct a beam of light on to a target around an obstacle. The object is to have the student set up the problem, but the supervisor turns on a light such as a Maglite (or laser). For the first year prisms are not to be used!

Example Station 4: The object is to align a beam from a light source provided by the officials to bounce off all given mirrors (Division C only may also include lenses and refraction) to strike a given target. Students will begin with a set number of points and then points will be deducted for the time it takes to set up the devices and the distance that the light ends up from the center point of the target.