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Transcript
Journal of Babylon University/Pure and Applied Sciences/ No.(6)/ Vol.(21): 2013
Study of Resolution Power and Intensity
Distribution for Optical System Using Synthetic
Square Aperture
Azhr A. Raheem
University of Kerbala/College of science/Department of physics
Abstract:
In this research effect of square synthetic aperture(apertures are distributed alternately as checker
board ) has been studied on intensity of the line object in comparison with square aperture for ideal
optical system or contain focus error (W20=0.5λ,1λ,2λ) or spherical aberrations (W40=0.5λ,1λ) or coma
aberrations (W31=0.5λ) with rotation angle (ψ=0,90,180) .
The total number of sub apertures are depending on number of rows and columns in square synthetic
aperture and the numbers of rows and columns have been chosen are similar which values are
)T=2,4,6,8,10(
The results showed that increasing the number of synthetic sub apertures lead to increasing resolution
power in ideal optical system and increasing intensity whatever the aberrations amount was high in the
optical system and so work to decrease the secondary peaks in the intensity distribution of line image.
:‫الخالصة‬
‫تممف مما اممحث ثراسممت ث ثي م تم ي ثرفتس م ثربية م ثربي(ام اثرفتس م ب بل مم ا مم( بتة م لط ب م رلسم ثر م ية )ملم ثر ممثل ررممليل‬
‫) ل يممر (مميلل‬W20=0.5λ,1λ,2λ‫ج ممف ي مما لبه يةتل م ا رفتس م ثربية م رةظ م ف ارمميل ب م را ل ىستمملل مل م ي م م يل بهممثثي ا‬
‫إ( ممثث ثرفتسم ب ثر ةلىم ى تبمث ملم ممثث ثررممفل‬.)Ψ =0,90,180‫) ثلىم ثليث( ا‬W31=0.5λ‫) ل يمر ام را ا‬W40=0.5λ,1λ‫ا‬
‫ ةمب ثرةتم إ إ( يم ثل مممثث‬. )T=2,4,6,8,10‫ب م لل ر مثث ثألمبممثل لاهممىف ا‬
‫لثألمبمثل مما ثرفتسم ثربي(ام لاممث تممف ثيتىم ي مممثث ثررممفل‬
‫رلةظ ف ثراريل ثرب را ل يم ثل ثر مثل ستم لث( ( ةمب (بىم ثر يملة م رىم ما ثرةظم ف‬
‫ي ثل اثيل ثرتسل‬
.‫ثرهبف ثر ةلى ا تل يع ثر ثل ررليل ثرج ف ثري ا‬
‫ثل إر‬
‫ثرفتس ب ثر ةلى ثربي(ا‬
‫ثراريل ل(حرك ت ب مل تهل‬
Introduction:
The image that is formed by the optical systems will be approximately corrected
from the aberrations, but there isn't ideal image correspond to the object dimensions
because of the wave nature of the light diffraction which almost affects with several
factors like the type of illumination that be used (incoherent, coherent and partial
coherent), the object shape and the aperture shape [K. H. Al-Lamy, 2008].
The diffraction is a phenomena or effect resulting from the interaction of the
radiation waves with the limiting edges of the aperture stop of an optical system
[M. J. Riedl, 2001, R.E.Fischer and B. Tadic-Galeb, 2000] .
The rims of the lenses present in an optical system restrict the light cone and hence
the brightness of the image which formed by the optical system, in addition, stop
apertures are deliberately introduced either outside or within the optical system to
minimize aberrations, to identify the aperture which ultimately limits the cone of the
light rays emanating from an on-axis object and making its way through the optical
system, each aperture or stop present in the optical system is imaged in the object
space by the lenses which lie on the object side of it, the aperture image which
subtends the smallest angle at the axial object is the entrance pupil and the physical
aperture which gives rise to this image (real or virtual) is the aperture Stop or the
limiting iris[K. K. Sharma, 2006].
The synthetic aperture is technique used in field of effect aperture shape on the
image formed by optical beams entering the aperture ,a synthetic (square) aperture has
been used which is appear when optical system consists of a number of relatively
small-aperture systems that work together to achieve a resolution comparable to that
2195
of a single(square) aperture system, the resolution enhancement is only achieved if the
optical path lengths for rays traveling through each aperture are equal [Samuel T.
Thurman and James R. Fienup, 2003].
Thus, multi-aperture systems typically have some mechanism for controlling the
optical path delay of each aperture, such mechanisms also can be used to intentionally
introduce optical path differences (or time delays) between apertures and perform
Fourier transform spectroscopy[Samuel T. Thurman and James R. Fienup, 2003].
The researchers have been evaluated the performance of optical system by the
variation the aperture shape and found the effect on image formed by different object
for optical system ideal or contain aberrations, Kendrick et. al. [R. L. Kendrick, E. H.
Smith, and A.L.Duncan,2003] demonstrated such fourier transform spectroscopy
experimentally with a multi aperture telescope, the researcher Reddy [K. L. Reddy
,1995] indicates that the resolution limits increased with presence lanczos filters,
Alqazzaz [ Alqazaz H.H.,1995] has studied the line spread function of optical system
has obstructed square aperture for different values of obstruction, in the field of
synthetic aperture Aljebory [Aljebory.A.F, 2007] performed the effect of the Gaussian
filter on the synthetic aperture, as well as (Raheem) [Azhr.A.Raheem,2009] studied
the effect of synthetic aperture on line object.
In this research take an interest in study the effect of a aperture shape on the line
object image by studying synthetic square aperture on line spread function (LSF), the
number of rows and columns which used (T=2,4,6,8,10),the system has been used
ideal or containing the different values of the focus error or aberrations.
Theoretical:
There are several means of evaluation the performance of a complete system,
such as signal-to-noise ratio (S/N) and intensity distribution on formed image and
resolving power of optical system, the line spread function is one of the most
functions for describing the performance of an optical system and can be extended to
include the effects of an obstructed aperture, apodization and any factor external to
the optical system, line spread function is the distribution of light produced on the
imaging it is usually measured by recording the amount of light entering a thin slit
parallel to the image of the line as a function of slit position.
The intensity of line image for incoherent line source located at the coordinates (u,v)
in the image plane can found by using fourier transformations [Born M.,wolf E.
,1984] as :
L(u , v)   G (u , v)dv..........(1)
v
where: G(u,v) is intensity of point image which can be expressed by multiplying of
the amplitude function and its complex form [Born M.,wolf E. ,1984, K.D. M¨oller,
2003] thus :
2
L(u , v)  
  f ( x, y )  e
i 2 ( ux  vy )
dxdy dv..........(2)
v y x
f ( x, y ) : is the pupil function which equal to[Born M.,wolf E. ,1984] :
f ( x, y )   ( x, y )  eikW ( x , y ) ..........(3)
2196
Journal of Babylon University/Pure and Applied Sciences/ No.(6)/ Vol.(21): 2013
k: wave number which is equal to (2π/λ), λ: a wavelength of light used,  ( x, y ) :
function permeability its equal to (1) of the symmetric aperture, while the other term
of equation represents serial aberration which for spherical and com aberrations is
[J.D.Gaskill,1970]:
w( x, y )  w20 ( x 2  y 2 )  w40 ( x 2  y 2 ) 2  ......
w(x, y)1w 31 (x 2  y 2 )(xsinΨ  ycos ) w51 (x 2  y 2 ) 2 (xsinΨ  ycos )  ....
1
Where w20,w40,w31,w51: represents the spherical aberrations and coma aberrations
terms respectively, Ψ: represent rotation angle .
The boundary of each sub aperture can be found from location of each sub aperture
which the equation of them is:
x  x  x\
n ……..(4)
y  y  y\
m
Thus the eq.(2) can be write :
L(u , v) 
T1
2
T2
    f ( x, y)  e
v m1 n 1
\
i 2 ( u ( x  xn\ )v ( y  ym
))
dxdy dv..........(5)
y x
or:
2
L(u , v)  
  f ( x, y )e
i 2 ( ux  vy )
T1
T2
dxdy dv   e
2
\
i 2 ( uxn\  vym
)
...........(6)
m 1 n 1
v y x
or :
2
L(u , v)  NOR 
 f ( x, y )e
i 2 ( ux )
T1
T2
dx dy  e
2
i 2 ( uxn \  vym \ )
.........(7)
m 1 n 1
y x
Let ) m  2v , z  2u (,we can study the intensity distribution on one axis thus we
can put )m=0( ,then the eq.(7) becomes :
2
L( z )  NOR 
y
 f ( x, y )e
izx
T1
T2
dx dy   e
2
i ( zx n \ )
.........(8)
m 1 n 1
x
Where (NOR): a constant normalization of function is calculated by make ((L(0)=1)
for the free system[Born M.,wolf E. ,1984].
The integration limits given by the aperture shape, then the equation (8) for square
aperture (figure 1) with area (A=π) and side ( L   ) will be :
2197


2
2

L( z )  NOR


2
e

2
ikW ( x ', y ')
dx dy........(9)

2
The suggested synthetic aperture (figure 2) come out of divide the square aperture
into sub apertures work to allow passing light at sub aperture and don’t passing light
at neighboring sub aperture by alternation continually (as checker board), base on the
number of row and column inside synthetic aperture, thus location of sub apertures
depend on angle between center of each sub aperture and center of original square
aperture, then the values of xn\ , ym\ for sub aperture at position with number of row
(n) and number of column (m) are :


1
2
2

T
1
T
1  2


  2 n 
1
( 1) m (G )    m 

  
2
2
2
2 





xn\


T
1


m 

2
2

cos 

2
T
1

 
m
2
n


1

(

1
)
(
G
)



 
2
2






1
2
T
1  2

 m 

 
2
2 










… (10)
1
y
\
m
2
2

T
1
T
1 2


  2n 
1 
( 1) m (G )    m 

  
2
2
2
2 







T
1


1 
( 1) m (G ) 
 2n 

2
2


sin 
1

2
2
T
1
T
1 2
 


m
2n 
1 
( 1) (G )    m 

 
 
2
2
2
2 













Where: (T): represents total number of rows or columns, (G): represents number equal
to (1) when we want to make the first up sub square from left side allow light and
when (G=-1) the reverse case happen.
The limits of integration for each sub aperture depend on side of this sub aperture will
be similar to others, so that when the area of origin square aperture is (π) and length of
side  , so the area of combined sub square apertures are equal to (π) and the side
of each one will equal to :
 L  n l  m l 
Area  L  L  L2  n 2  l 2 
  L2  n 2  l 2 
l

n
2198
Journal of Babylon University/Pure and Applied Sciences/ No.(6)/ Vol.(21): 2013
But the number of sub square aperture that allow to light passing are the half,
therefore the area of all sub apertures equal to (π/2) , so we let sub side
2
equal to
which make the total area of opening apertures is (π) ,then the
n
equation (9) will be as finally form :
 2
 2n
L( z )  NOR   
 2
  2 n
2
2
2n
 f ( x, y )e

izx
T1
T2
dx dy   e i ( zxn
m 1 n 1
2
2n
2
\
)


.........(11)


The term (T1,T2) depend on number of rows and columns which is define as :
T1  n
T2 
T
 [0.5  (1) m  G  0.5  (1) m  (G)  0.5  (1) m  G  D
2
Where D: digit when D=1 the number of rows and columns will be odd, if D=0 the
number of rows and columns will be even.
The last equation (11)go back to equation (9) when number of rows and columns
(T=1), and the length of sub side is  , in this case the result agreement with the
previous research [Azhr.A.Raheem,2009] .


2199
L
L
Figure )1(
Square aperture
n
m
\

\
xn
Figure )2(
Synthetic square apertures (T=8)
2200
ym
Journal of Babylon University/Pure and Applied Sciences/ No.(6)/ Vol.(21): 2013
Results and Discussion:
The line spread function has been solved by using the program (MathCAD) for the
ideal optical system or contains focus error (W20=0.5λ,1λ,2λ) and when contains
spherical aberration (W40=0.5λ,1λ) or coma aberration (W31=0.5λ) with different
value of rotation angle (Ψ=0,90,180).
The apertures which taking are square aperture and synthetic square aperture, the
number of rows and columns are choosing (T=2,4,6,8,10),that mean the apertures
allow light to pass through it are (2,8,18,32,50) .
The two cases (G=1,G=-1) are solved , the result appear similar in two cases at ideal
system or contain focus error and aberrations which are chosen in research.
Figure (3) show the intensity distribution of line object for ideal system, we notice the
all curve of intensity begin from point with value (1),this case agree with Airy disk for
distribution of intensity ,but increasing the number of sub apertures lead to increment
resolution power of optical system because of decrease in half width of the curves
whenever number of rows and columns are increase.
The figures (4,5,6) describe the effect of the focus error (W20=0.5λ, 1λ, 2λ)
respectively in the optical system ,this state cause to lessening of the central intensity
so that it reach to (0.57016, 0.10622, 0.09291), while the intensity for optical system
use synthetic square aperture stay at the best values and whenever increase number of
sub apertures lead to increase the intensity at the image plane in spite of the effect of
focus error, where the intensity reach to (0.99978, 0.99913, 0.99654) when the focus
error (W20=0.5λ, 1λ, 2λ) respectively at (T=10) .
The effect of focus error (W20=1λ) with spherical aberration (W40=0.5λ, 1λ) is
explaining in figures (7,8), the intensity despite effect this case of aberration on
optical system the sub apertures try to stay the central intensity as the ideal system and
it reach to (0.99911, 0.99909) when the aberrations are (W20=1λ ,W40=0.5λ, 1λ)
respectively, while it reach at one square aperture to (0.14163, 0.11738) in the same
cases .
The effect of sub apertures dexterous on system when the optical system have many
kind of aberrations such as spherical and coma aberrations and focus error as shown
in figures (9,10,11) when optical system contain focus error and spherical aberration
(w20=w40=1) and coma aberration (w31=0.5) with rotation angle (Ψ=0,90,180)
respectively, the LSF be (0.0662,0.04927,0.0662) for square aperture at (Ψ=0,90,180)
respectively and the shape of image appear deformed ,while the intensity when the
synthetic aperture used become (0.99909) approximate at any value of rotation angle
when (T=10) ,therefore the synthetic square aperture stay the image clear, sharp and
this specifications increase whenever increase the number of rows and columns .
In all figures the synthetic square aperture woke very well at high number of rows and
columns specially (T=10) ,but the case (T=2) cannot get over effect of aberration
rather be good in comparison with square aperture but isn't the better from other case
in search.
The increase intensity and resolution power at the image plane for optical system
which uses synthetic aperture goes back to the distribution field of Fraunhofer
diffraction pattern for any distribution of aperture similar in shape and direction itself
will equal to Fourier transformation for any function aperture individually (that is the
distribution of diffraction field) multiplied by the outcome of the output total
diffraction pattern of the source points, therefore intensity appear centering and high .
Also noticing at all figures the increasing (T) lead to decrease the secondary peak in
LSF for all states aberrations presence in the optical system which make to increasing
clearness of line image and lessening of noise in image .
2201
1.1
1.0
one square
T=2
T=4
T=6
T=8
T=10
0.9
Normlization Intensity
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
0.0
0
1
2
3
4
5
6
7
8
9
10
11
Z
Figure (3)
Intensity distribution of line object image for ideal optical system
1.1
1.0
one square
T=2
T=4
T=6
T=8
T=10
0.9
Normlization Intensity
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
0.0
0
1
2
3
4
5
6
7
8
9
10
11
Z
Figure (4)
Intensity distribution of line object image for optical system contain focus error
(w20=0.5)
2202
Journal of Babylon University/Pure and Applied Sciences/ No.(6)/ Vol.(21): 2013
1.1
1.0
one square
T=2
T=4
T=6
T=8
T=10
0.9
Normlization Intensity
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
0.0
11
10
9
8
7
6
5
4
3
2
1
0
Z
Figure (5)
Intensity distribution of line object image for optical system contain focus error
(w20=1)
1.1
1.0
one square
T=2
T=4
T=6
T=8
T=10
0.9
Normlization Intensity
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
0.0
0
1
2
3
4
5
6
7
8
9
10
11
Z
Figure (6)
Intensity distribution of line object image for optical system contain focus error
(w20=2)
2203
1.1
1.0
one square
T=2
T=4
T=6
T=8
T=10
0.9
Normlization Intensity
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
0.0
0
1
2
3
4
5
6
7
8
9
10
11
Z
Figure (7)
Intensity distribution of line object image for optical system contain focus error
(w20=1) and spherical aberration (w40=0.5)
1.1
1.0
one square
T=2
T=4
T=6
T=8
T=10
0.9
Normlization Intensity
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
0.0
0
1
2
3
4
5
6
7
8
9
10
11
Z
Figure (8)
Intensity distribution of line object image for optical system contain focus error
(w20=1) and spherical aberration (w40=1)
2204
Journal of Babylon University/Pure and Applied Sciences/ No.(6)/ Vol.(21): 2013
1.0
one square
T=2
T=4
T=6
T=8
T=10
Normlization Intensity
0.8
0.6
0.4
0.2
-10 -9
-8
-7
-6
-5
-4
-3
-2
0.0
-1 0
1
2
3
4
5
6
7
8
9
10
Z
Figure (9)
Intensity distribution of line object image for optical system contain focus error and
spherical aberration (w20=w40=1) and coma aberration (w31=0.5) with rotation angle
(Ψ=0)
1.0
one square
T=2
T=4
T=6
T=8
T=10
Normlization Intensity
0.8
0.6
0.4
0.2
-10 -9
-8
-7
-6
-5
-4
-3
-2
0.0
-1 0
1
2
3
4
5
6
7
8
9
10
Z
Figure (10)
Intensity distribution of line object image for optical system contain focus error and
spherical aberration (w20=w40=1) and coma aberration (w31=0.5) with rotation angle
(Ψ=90)
2205
1.0
one square
T=2
T=4
T=6
T=8
T=10
Normlization Intensity
0.8
0.6
0.4
0.2
-10 -9
-8
-7
-6
-5
-4
-3
-2
0.0
-1 0
1
2
3
4
5
6
7
8
9
10
Z
Figure (11)
Intensity distribution of line object image for optical system contain focus error and
spherical aberration (w20=w40=1) and coma aberration (w31=0.5) with rotation angle
(Ψ=180)
Conclusions:
1- The synthetic square aperture are excellent technique for high resolution power in
line image compared with square aperture .
2- Increasing number of sub aperture lead to increasing the resolution power in ideal
optical system
3- Increasing number of sub aperture cause high and explicit central intensity and good
apodization despite the effect of aberrations in optical system .
4- Increasing number of sub aperture lead to decreasing of secondary peak intensity of
image.
5- From the above Conclusions we choose (T=10) as better from other cases in this
search .
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Journal of Babylon University/Pure and Applied Sciences/ No.(6)/ Vol.(21): 2013
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