Consider an array of rectangular slits of widths a and b with spacing d in the y direction, illuminated by a plane wave. We want to derive the Fraunhofer diffracted field E ( k x , k y ) E ( k x , k y ) . The simplest way to do this problem is to use Fourier optics: The array is a convolution of a single rectangular slit with an array of Dirac delta functions.

That is the aperture function can be written A = A 0 ( f ⊗ h ) A = A 0 ( f ⊗ h ) where the symbol ⊗ ⊗ represents convolution and f = 1    w h e n   | x | ≤ a / 2   a n d   | y | ≤ b / 2 = 0    o t h e r w i s e f = 1    w h e n   | x | ≤ a / 2   a n d   | y | ≤ b / 2 = 0    o t h e r w i s e h = ∑ n y = 0 N − 1 δ ( y − n y d ) . h = ∑ n y = 0 N − 1 δ ( y − n y d ) . We now have that E = ɛ A R e − i ( k R − ω t ) Ϝ { f } Ϝ { h } E = ɛ A R e − i ( k R − ω t ) Ϝ { f } Ϝ { h } where R R is the distance from the origin to the point of measurement. and F { } F { } represents a Fourier transform. Now we have Ϝ { f } = ∫ − b / 2 b / 2 ∫ − a / 2 a / 2 e i ( k x x ′ + k y y ′ ) ⅆ x ′ ⅆ y ′ Ϝ { f } = ∫ − b / 2 b / 2 ∫ − a / 2 a / 2 e i ( k x x ′ + k y y ′ ) ⅆ x ′ ⅆ y ′ or rearranging, Ϝ { f } = ∫ − b / 2 b / 2 ⅆ y ′ e i k y y ′ ∫ − a / 2 a / 2 ⅆ x ′ e i k x x ′ . Ϝ { f } = ∫ − b / 2 b / 2 ⅆ y ′ e i k y y ′ ∫ − a / 2 a / 2 ⅆ x ′ e i k x x ′ . These are integrals we have done a number of times already: Ϝ { f } = b s i n c ( k y b / 2 ) a s i n c ( k x a / 2 ) Ϝ { f } = b s i n c ( k y b / 2 ) a s i n c ( k x a / 2 ) Next we transform the sums of the delta functions Ϝ { h } = ∑ n y = 0 N − 1 ∫ − ∞ ∞ e i k y y δ ( y − n y d ) ⅆ y , Ϝ { h } = ∑ n y = 0 N − 1 ∫ − ∞ ∞ e i k y y δ ( y − n y d ) ⅆ y , which upon integration becomes Ϝ { h } = ∑ n y = 0 N − 1 e i k y n y d . Ϝ { h } = ∑ n y = 0 N − 1 e i k y n y d . We have also performed this sum before and it gives F { h } = e i k y ( N − 1 ) d / 2 sin ( N k y d / 2 ) sin ( k y d / 2 ) . F { h } = e i k y ( N − 1 ) d / 2 sin ( N k y d / 2 ) sin ( k y d / 2 ) . So we have E = ɛ A R e − i ( k R − ω t ) e i k y ( N − 1 ) d / 2 sin ( N k y d / 2 ) sin ( k y d / 2 ) b s i n c ( k y b / 2 ) a s i n c ( k x a / 2 ) E = ɛ A R e − i ( k R − ω t ) e i k y ( N − 1 ) d / 2 sin ( N k y d / 2 ) sin ( k y d / 2 ) b s i n c ( k y b / 2 ) a s i n c ( k x a / 2 ) or if we define k R c = k R − ( N − 1 ) d k y / 2 k R c = k R − ( N − 1 ) d k y / 2 E = ɛ A a b R e − i ( k R c − ω t ) sin ( N k y d / 2 ) sin ( k y d / 2 ) s i n c ( k y b / 2 ) s i n c ( k x a / 2 ) . E = ɛ A a b R e − i ( k R c − ω t ) sin ( N k y d / 2 ) sin ( k y d / 2 ) s i n c ( k y b / 2 ) s i n c ( k x a / 2 ) .

Content actions

Add module to:

My Favorites Login Required (?)

'My Favorites' is a special kind of lens which you can use to bookmark modules and collections. 'My Favorites' can only be seen by you, and collections saved in 'My Favorites' can remember the last module you were on. You need an account to use 'My Favorites'.

| A lens I own Login Required (?)

Definition of a lens

Lenses

A lens is a custom view of the content in the repository. You can think of it as a fancy kind of list that will let you see content through the eyes of organizations and people you trust.

What is in a lens?

Lens makers point to materials (modules and collections), creating a guide that includes their own comments and descriptive tags about the content.

Who can create a lens?

Any individual member, a community, or a respected organization.

What are tags?

Tags are descriptors added by lens makers to help label content, attaching a vocabulary that is meaningful in the context of the lens.

| External bookmarks

Footer

This work is licensed by Paul Padley under a Creative Commons Attribution License (CC-BY 2.0), and is an Open Educational Resource.

Last edited by Paul Padley on Dec 1, 2005 3:42 pm -0600.