The following input will simulate a 1:1 array of GRIN rods (see Figure 2): \ar.(��J��
y�dBoZ�3�}
I�nr ~9�hz
/X�8�b=�:h
RDM;LEN o��%CBSm�]
TIT 1:1 GRIN ARRAY Vr�z<DB^-e
NAO 0.1 0��Wk}d(�f
TEL ! Telecentric �M��a_! 1Y
DIM M +-xA/nU.c�
WL 633 RU#�Q<QI(�
YOB -5 5 0 -10 10 )��D�(XDN�
PRV ! GRIN material (SELFOC form) `Ol*�"F.+I
PWL 633 C�[&L�h_F\
'SLSPRV' 1.5 A�D~�\/V&+
SEL 1 ! Grin step size JTdK\A��>l
SEL C1 .076 ! First coeff. of SELFOC formula .X�S �rLb?
END utRvE(IbmV
So 0 10.222 w�Gw}�a[�a
RED -1 o#E
�z_D[�
S 0 0 .lRO;���D�
S 0.0 60.0 'SLSPRV' ! GRIN rod (array channels) Lt=#�tu�&d
STOP �nuX��aZRH
CIR 1.25 ! Aperture of each channel o��u��@Dd4
! (applies to entire length w�gI$�'t�I
! of GRIN rod) �E]"ePdZZ/
! Array definition �[L9�e�.n1
5P+��3�D{�
! ARR x_spacing y_spacing y_offset max_x max_y XPb7gd"%�W
ARR 2.5 2.5 0 0 0 �KX�Y�q�|w
S 0 0 ?6~��RG��g
EAR ! End array #y�2="�$�V
S 0 10.222 /pt�I��x�e
PIM <���gJ|Wee
SI 0 0 Y#��C=�k�u
LAY;SUR So..i;GO +5 @8�'�t�
d0IHl�!��X
9KD�2C>d<�
Figure 2. 1:1 GRIN array
