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No.
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Objective
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1.1
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Describes the dual nature of light
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1.2
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Calculates photon's energy, wavelength, and momentum
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1.3
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Distinguishes between the different parts of an electromagnetic spectrum
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2.1
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Define the Hygen's Principle
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2.2
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Describes the Fermat's Principle
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2.3
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Apply Fermat's Principle to reflection
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2.4
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Apply Fermat's Principle to refraction
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2.5
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Computes the image using a plane mirror
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2.6
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Demonstrates the use of Snell's law for refraction through plane surfaces
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2.7
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Demonstrates the use of reflection law of a spherical mirror
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2.8
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Demonstrates the use of refraction laws of a spherical surface
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2.9
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Solve the Len's Maker equation for thin lenses
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2.10
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Computes the refractive power of lenses
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2.11
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Derives Newton's equation for thin lens
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3.1
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Explain the operation of an optical instrument
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4.1
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Derive the one dimensional wave equation
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4.2
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Describe the harmonic wave and its components
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4.3
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Conversion of harmonic wave to complex notation
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4.4
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Differentiate between different typs of waveforms
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4.5
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Computes the energy and power of an electromagnetic wave
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4.6
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Explain the polarization of light and its type
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4.7
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Explain the Doppler effect of light
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5.1
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Define the supersposition principle of waves
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5.2
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Demonstrate the constructive and destructive interference of two waves of the same frequency
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5.3
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Illustrate the use of the phasor method to obtain the superposition in a general case
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5.4
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Distinguish between the random and coherent sources
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5.5
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Derive the standing wave formula and its discription
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5.6
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Describe the beat phenomena
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5.7
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Derive the phase and group velocity
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6.1
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Solve the interference of two mutually incoherent fields
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6.2
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Solve the interference of two mutually coherent fields
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6.3
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Computes the interference from a Young double slit
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6.4
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Computes the interference from a thin dielectric film
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7.1
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Construction of a Michelson interferometer
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8.1
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Derive the formula for diffraction from a single slit
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8.2
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Computes the beam spreading
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8.3
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Derive the formula for diffraction from a rectangular and circular aperatures
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8.4
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Illustrates the effect of diffraction on the resolution of an image
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8.5
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Derive the formula of diffraction from a double slit
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8.6
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Derive the formula of diffraction from many slits
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9.1
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Define polarization and its types
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9.2
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Solve Mauls' law to find the intensity of light through dichoric materials
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9.3
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Derive the absorptivity of a material
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9.4
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Demonstrate the polarization by reflection from diaelectric surfaces
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9.5
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Describe polarization by scattering
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9.6
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Define birefringence and double refraction
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9.10
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Compute the optical activity of a material
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10.1
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Write a short essay on the application of light in life
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