Effect of apperture diffraction and fourier plane

Click For Summary
SUMMARY

The discussion focuses on the principles of diffraction, specifically regarding the role of apertures and the Fourier transform in wave propagation. It is established that any finite wave diffracts, and diffraction occurs even when the aperture is smaller than the wavelength. The Fourier transform is relevant in the Fraunhofer region, where the diffracted wavefront can be approximated as expanding plane waves. Recommended texts for further study include "Introduction to Fourier Optics" by Goodman and "Linear Systems, Fourier Transforms, and Optics" by Gaskill.

PREREQUISITES
  • Understanding of wave propagation principles
  • Familiarity with Huygens' principle
  • Knowledge of Fourier transforms in optics
  • Basic concepts of diffraction and aperture effects
NEXT STEPS
  • Study "Introduction to Fourier Optics" by Goodman for foundational knowledge on Fourier optics.
  • Research "near-field scanning optical microscopy" to understand diffraction in near-field scenarios.
  • Explore the relationship between diffraction and the Fraunhofer region in wave optics.
  • Investigate the effects of free space on wave propagation and diffraction.
USEFUL FOR

Students and professionals in optics, physicists, and engineers interested in understanding diffraction phenomena and Fourier imaging techniques.

taimoortalpur
Messages
10
Reaction score
0
Dear All,
I appreciate the efforts and support of members/admin here toward the goodness of education.

I am confusing a few concepts regarding diffraction, kindly help me out. I came up with following questions,

1. Is apperture required for diffraction or any finite wave will diffract?
To me considering finite wave will have somewhere an apperture, it should diffract.
2. If apperture is smaller than wavelength do we get diffraction?
3. By huygens principle the wave diffract and must enlarge, how do we get Fourier transform (smaller in size usually for plane or spherical wave) in fresnel or franhofer plane.
4. Free space only add phase to propagation or also cause wave to diffract. (I think it do both)

Kindly also recommend any good book on diffraction that covers diffraction due to free space and Fourier imaging.
 
Science news on Phys.org
taimoortalpur said:
I am confusing a few concepts regarding diffraction, kindly help me out. I came up with following questions,

1. Is apperture required for diffraction or any finite wave will diffract?
To me considering finite wave will have somewhere an apperture, it should diffract.
2. If apperture is smaller than wavelength do we get diffraction?
3. By huygens principle the wave diffract and must enlarge, how do we get Fourier transform (smaller in size usually for plane or spherical wave) in fresnel or franhofer plane.
4. Free space only add phase to propagation or also cause wave to diffract. (I think it do both)

Kindly also recommend any good book on diffraction that covers diffraction due to free space and Fourier imaging.

1) yes. And you are also correct, any finite wave is equivalent to an infinite wave that has passed through an aperture.

2) yes. There may not be propagating modes, tho. Look up "near-field scanning optical microscopy".

3) The Fourier transform emerges only in the Fraunhofer region: the far-field. This is because the diffracted wavefront can be approximated as a (spectrum of) expanding plane waves, and in the far-field limit, the diffraction integral reduces to the Fourier transform.

The standard textbook is Goodman "Introduction to Fourier Optics". As a primer, I also suggest Gaskill's "Linear Systems, Fourier transforms, and Optics", colloquially known as "Introduction to Goodman".
 
Many Thanks For the reply it cleared a lot of concepts...
 

Similar threads

Graduate Diffraction theory, power density and angle of incidence
  • · Replies 5 ·
Replies
5
Views
3K
Graduate Fourier optics model of a 4f system
  • · Replies 1 ·
Replies
1
Views
4K
Undergrad How Can One Derive the Diffraction Pattern Formula from a 1D Aperture?
  • · Replies 2 ·
Replies
2
Views
2K
Graduate Diffraction integral : incident field is FT?
  • · Replies 9 ·
Replies
9
Views
2K
Graduate Fourier transform fallacy? (Optics)
  • · Replies 29 ·
Replies
29
Views
4K
Graduate Abbe theory: diffraction pattern to primary image
  • · Replies 12 ·
Replies
12
Views
3K
Undergrad Diffraction Definition & Common Examples
  • · Replies 1 ·
Replies
1
Views
5K
Graduate Diffraction pattern's dependency on wavelength
  • · Replies 2 ·
Replies
2
Views
3K
Undergrad Questions About Bragg's Law of X-Ray Diffraction
  • · Replies 54 ·
2
Replies
54
Views
11K
Graduate Diffraction of Light: Explaining Interference & Huygens' Principle
  • · Replies 22 ·
Replies
22
Views
8K