SNC2D1: Optics

Going towards the one point.

Separating, leaving one point into many different directions.

The process of light 'bouncing off' an object.

θᵢ = θᵣ

The angle of incidence is equal to the angle of reflection. Measured at the normal.

The ray moving towards the mirror.

The ray moving away from the mirror that was reflected.

The point were the light is reflected.

The line perpendicular to the mirror where the Point of Incidence is.

Represented as 'i', the angle between the ray of incidence and the normal.

Represented as "r", the angle between the ray of reflection and the normal.

Size, Attitude, Location, Type.

Bigger, smaller, or same size relative to object.

Upright or Inverted relative to object.

Same Side (Where—F, C 2F', between O + F'), Behind Mirror

Real or Virtual.

An image that is formed by rays of light and can be seen/projected onto a surface.

An image that is formed by 'fake' rays of light and cannot be seen/projected onto a surface.

Cause parallel light rays rays to come to a point.

Concave mirrors

Converging Mirrors

Cause parallel lights to spread apart from a point

Convex Mirrors

Diverging Mirrors

C

Twice the distance of F, the centre of the sphere of the mirror.

C

V

The point at which the mirror intersects the Principle Axis.

PA

The line drawn through the vertex, perpendicular to the mirror.

The point halfway between the Centre of Curvature and the Vertex

F

Concave, Convex.

Parallel to PA & reflected through F, Through F & reflected parallel to PA, Through C & reflected along same path

Parallel to PA & reflected backwards with virtual line through F, Towards virtual F & reflected parallel to PA with parallel virtual line parallel to PA, Towards virtual C & reflected on same path with virtual line to C.

Diverging/Convex Mirror

Converging/Concave Mirror

Image is virtual

Image is real

Image is inverted

Image is upright

n

The ratio of the speed of light in a vacuum to the speed of light in the medium

V

c

3.00 • 10^8 m/s

Bends towards normal

Bends away from normal.

Where light reflects in a medium instead of exiting out of it.

The greatest angle light is able to exit a medium with.

The angle of incidence must be greater than the critical angle. The light must be travelling from a more to less dense medium.

Lenses that cause parallel light rays to go towards one point.

Lenses that cause parallel light rays to disperse from one point.

Converging Lenses

Diverging Lenses

Convex Lenses

Concave Lenses

A ray parallel to the Primary Focus and is refracted so it passes through F. A ray that passes through F' and is refracted as a parallel line. A ray that passes through the optical centre without bending.

The condition where someone can see far away but not close. Caused because the focal point is too far away to the retina.

Farsightedness

The condition where someone can see close but not far away. The focal point is too close to the retina.

Nearsightedness

Convex/Converging Lens

Concave/Diverging Lens.

The light produced by hot objects. Most energy is given off as heat.

Light given off by objects that have not been heated.

Tubes that contain mercury vapour that emit UV light until it is coated in phosphos. Some energy is given off as heat.

Light emitted by phosphor that glow in the dark.

Neon Lights, produced by an electric current when their energy is released

LED. Very durable, small electric current required.

Light released during chemical reactions. When it occurs in organisms it is called Bioluminescence.