This bending of light is called refraction and is responsible for many optical phenomena. In this case, the light can reach the observer by two different paths, and so the fish seems to be in two different places. Law of Refraction: Looking at the fish tank as shown, we can see the same fish in two different locations, because light changes directions when it passes from water to air. Refraction is responsible for a tremendous range of optical phenomena, from the action of lenses to voice transmission through optical fibers. The changing of a light ray’s direction (loosely called bending) when it passes through variations in matter is called refraction. This is because light coming from the fish to us changes direction when it leaves the tank, and in this case, it can travel two different paths to get to our eyes. For example, you may see the same fish appearing to be in two different places. It is easy to notice some odd things when looking into a fish tank. Formulate the relationship between the index of refraction and the speed of light.Reflection: A brief overview of reflection and the law of reflection. When the moon reflects off the surface of a lake, a combination of these effects takes place. A mirror, on the other hand, has a smooth surface (compared with the wavelength of light) and reflects light at specific angles. Many objects, such as people, clothing, leaves, and walls, have rough surfaces and can be seen from all sides. Diffused light is what allows us to see a sheet of paper from any angle. However, light strikes different parts of a rough surface at different angles, and it is reflected in many different directions (“diffused”). We expect to see reflections off a smooth surface. The angles are measured relative to the perpendicular to the surface at the point where the ray strikes the surface. Law of Reflection: The law of reflection states that the angle of reflection equals the angle of incidence: θr = θi. The image appears to come from the direction the rays are coming from when they enter the viewer’s eyes. The two rays shown are those that strike the mirror at just the correct angles to be reflected into the eyes of the viewer. Mirror Reflection: An image in a mirror appears as though it is behind the mirror. The angles are such that our image appears exactly the same distance behind the mirror as we stand away from the mirror. When we see our reflection in a mirror, it appears that our image is actually behind the mirror - we see the light coming from a direction determined by the law of reflection. The law of reflection is very simple: The angle of reflection equals the angle of incidence. The law of reflection is illustrated in, which also shows how the angles are measured relative to the perpendicular to the surface at the point where the light ray strikes. In fact, the only way we can see an object that does not itself emit light is if that object reflects light. Large telescopes use reflections to form images of stars and other astronomical objects. When you look at the text in a book, you are actually seeing the light that is reflected from it. Whenever you look into a mirror or squint at sunlight glinting off a lake, you are seeing a reflection. Formulate the relationship between the angle of reflection and the angle of incidence.Theory of relativity:Inertial and non inertial frame and fictitious force, Michelson Moreley experiment and postulates of special theory of relativity, Galilean and Lorentz transformations of space and time - Length contraction, time dilation, relativistic velocity, equivalence of mass and energy Dynamics of fluid:Continuity equation, Bernoullis theorem and its application,Torcellis theorem, Viscosity flow of liquid through a capillary tube, capillaries in series and parallel, poiseuilles equation Stokes formula, application of stokes theorem, effect of temperature and pressure on viscosity Acoustics:Propagation and superposition of sound waves, reflection, diffraction and refraction of sound waves, production and application of ultrasonics, acoustics of buildings Thermal Physics:Kinetic theory of gases - Maxwellian dist.\)
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