How Does Huygens' Wave Theory Explain Blurriness in Pinhole Images?

AI Thread Summary
Huygens' wave theory explains that light behaves as a circular wave with wavelets at each point, allowing light to take multiple paths from one point to another. When a pinhole is too small, diffraction occurs, leading to interference patterns that create a blurry image instead of a simple reduction in brightness. The resulting diffraction pattern consists of a bright central peak surrounded by smaller peaks, which contributes to the overall blurriness. As the pinhole size decreases, the intensity of these peaks increases, further complicating the image clarity. Therefore, the blurriness in pinhole images is a result of the diffraction effects rather than just a decrease in brightness.
T@P
Messages
274
Reaction score
0
i just learned this in physics, and i don't quite understand something:

according to Huygens, (i think) light is a ciruclar wave, and at everypoint on the wave there are wavelets. because there are so many ways for the wavelets to form, light takes every possible path from point a to point b. that parts sort of makes sense. then, all the really weird paths get cancelled, out and you are left with essentially a cone of light.

the above (if i got it right) sort of makes sense. but what doesn't is that this is supposed to explain why when you make a pinhole that's too small you get blurryness. shouldn't you just get the image to be not as bright? i don't quite see where the blurry part comes in.
 
Science news on Phys.org
If you have a small pinhole, you can get a diffraction from opposite edges.
So, if you ahe a single source, you will get a bright central (main) peak and a lot of small peaks resulting from the diffraction. http://upload.wikimedia.org/wikipedia/en/e/e1/Diffraction1.png

The smaller the hole the stronger will be peaks. For a circular hole , I guess, you have additional rings. So your total image, produced by multiple sources will be blurred.
 
Last edited by a moderator:
Thread 'A quartet of epi-illumination methods'

Thread 'A quartet of epi-illumination methods'

Well, it took almost 20 years (!!!), but I finally obtained a set of epi-phase microscope objectives (Zeiss). The principles of epi-phase contrast is nearly identical to transillumination phase contrast, but the phase ring is a 1/8 wave retarder rather than a 1/4 wave retarder (because with epi-illumination, the light passes through the ring twice). This method was popular only for a very short period of time before epi-DIC (differential interference contrast) became widely available. So...
View full post »

Thread 'Effective absorption coefficient of gold nanoparticles'

I am currently undertaking a research internship where I am modelling the heating of silicon wafers with a 515 nm femtosecond laser. In order to increase the absorption of the laser into the oxide layer on top of the wafer it was suggested we use gold nanoparticles. I was tasked with modelling the optical properties of a 5nm gold nanoparticle, in particular the absorption cross section, using COMSOL Multiphysics. My model seems to be getting correct values for the absorption coefficient and...
View full post »

Similar threads

Deriving the Law of Reflection from Huygens Principle
Replies
5
Views
2K
Online lecture about treatise on light by Huygens
Replies
9
Views
2K
Optics: Huygens' principle and bending of light
Replies
2
Views
2K
Diffraction of Light: Explaining Interference & Huygens' Principle
Replies
22
Views
7K
How can a single slit diffraction create an interference pattern?
Replies
17
Views
2K
Question about dark fringe in diffraction
Replies
1
Views
2K
B Does light ever go from the eye to the image?
Replies
17
Views
3K
A Huygens Principle - how to explain this with classical language?
Replies
2
Views
1K
Applying Huygens's principle to light propagation
Replies
2
Views
4K
I Huygen's principle in practical sense
Replies
3
Views
1K

Hot Threads

Recent Insights

Back
Top