Rectilinear propagation: Difference between revisions

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Rectilinear propagation describes the tendency of electromagnetic waves (light) to travel in a straight line. Light does not deviate when travelling through a homogeneous medium, which has the same refractive index throughout; otherwise, light experiences refraction. Even though a wave front may be bent, (e.g. the waves created by a rock hitting a pond) the individual rays are moving in straight lines. Rectilinear propagation was discovered by Pierre de Fermat.^[1]

Rectilinear propagation is only an approximation.^{[citation needed]} The rectilinear approximation is only valid for short distances, in reality light is a wave and have a tendency to spread out over time. The distances for which the approximation is valid depends on the wavelength and the setting being considered. For everyday usages, it remains valid as long as the refractive index in the medium is constant.

The more general theory for how light behaves is described by Maxwell's equations.

Proof

Take three cardboard A, B and C, of the same size. Make a pin hole at the centre of each of three cardboard. Place the cardboard in the upright position, such that the holes in A, B and C are in the same straight line, in the order. Place a luminous source like a candle near the cardboard A and look through the hole in the cardboard C. We can see the candle flame. This implies that light rays travel along a straight line ABC, and hence, candle flame is visible. When one of the cardboard is slightly displaced, candle light would not be visible. It means that the light emitted by the candle is unable to bend and reach observers eye. This proves that light travels along a straight path, as well proving the rectilinear propagation of light.

References

^ "Fermat's principle". Oxford Reference. Retrieved 2024-01-01.

This electromagnetism-related article is a stub. You can help Wikipedia by expanding it.

[1] "Fermat's principle". Oxford Reference. Retrieved 2024-01-01.

[1]

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-<!-- Image with unknown copyright status removed: [[Image:rectilinear_propagation.jpg|thumb|250px|Light travels in straight lines.]] -->
-'''Rectilinear propagation''' is a wave property which states that waves [[:wikt:propagate|propagate]] (move or spread out) in straight lines. This property applies to both [[transverse wave|transverse]] and [[longitudinal wave]]s as well as [[electromagnetic waves]] (light). Even though a [[wave front]] may be bent (e.g., the [[Surface wave|waves]] created by a rock hitting a pond) the individual waves are moving in straight lines.  In the sense of the scattering of waves by an inhomogeneous medium, this situation corresponds to the case '''n ≠ 1''', where '''n''' is the [[refractive index]] of the material.
+'''Rectilinear propagation''' describes the tendency of [[electromagnetic waves]] (light) to travel in a straight line. Light does not deviate when travelling through a homogeneous medium, which has the same [[refractive index]] throughout; otherwise, light experiences ''[[refraction]]''. Even though a [[wave front]] may be bent, (e.g. the [[Surface wave|waves]] created by a rock hitting a pond) the individual [[Ray (optics)|rays]] are moving in straight lines. Rectilinear propagation was discovered by [[Pierre de Fermat]].<ref>{{Cite web |title=Fermat's principle |url=https://www.oxfordreference.com/display/10.1093/oi/authority.20110803095815400 |access-date=2024-01-01 |website=Oxford Reference |language=en }}</ref>
+Rectilinear propagation is only an ''approximation''.{{cn|date=October 2024}} The rectilinear approximation is only valid for short distances, in reality light is a wave and have a tendency to spread out over time. The distances for which the approximation is valid depends on the wavelength and the setting being considered. For everyday usages, it remains valid as long as the refractive index in the medium is constant.
+The more general theory for how light behaves is described by [[Maxwell's equations]].
+== Proof ==
+Take three cardboard A, B and C, of the same size. Make a pin hole at the centre of each of three cardboard. Place the cardboard in the upright position, such that the holes in A, B and C are in the same straight line, in the order. Place a luminous source like a candle near the cardboard A and look through the hole in the cardboard C. We can see the candle flame. This implies that light rays travel along a straight line ABC, and hence, candle flame is visible. When one of the cardboard is slightly displaced, candle light would not be visible. It means that the light emitted by the candle is unable to bend and reach observers eye. This proves that light travels along a straight path, as well proving the rectilinear propagation of light.
+==See also==
+*[[Diffraction]]
+*[[Plane wave]]
+==References==
+{{Reflist}}
-This can be proven by setting up an experiment in which you align three cardboard squares with a small hole in the centre of each. You then set up a light behind the cardboard and look through all three holes from the other side to see the light. If you moved any one of the cardboard squares even a tiny bit, you would no longer be able to see the light. This proves that waves travel in straight lines and this helps to explain how humans see things, among other uses. It has a number of applications in real-life as well.
 [[Category:Waves]]
-{{physics-stub}}
+{{electromagnetism-stub}}