The following input will simulate a 1:1 array of GRIN rods (see Figure 2): V�l�!6�W@g
]P��2"[�y�
;{o|9x��|�
B�IWW���Mg
RDM;LEN ohG�fp9H�
TIT 1:1 GRIN ARRAY g2/8~cn�8z
NAO 0.1 L�`E�Bfz\n
TEL ! Telecentric Gm.]s�E?.�
DIM M LR�M�x<X8�
WL 633 �}XM(:|8J,
YOB -5 5 0 -10 10 NS6:y��X,/
PRV ! GRIN material (SELFOC form) q�c~iQ��SI
PWL 633 ��Clb@�$�,
'SLSPRV' 1.5 �r_;N���t�
SEL 1 ! Grin step size w�e?76t�:-
SEL C1 .076 ! First coeff. of SELFOC formula �.�Twk {�p
END y��
{<9]'�
So 0 10.222 � ?_"ik[w}
RED -1 V���E��w�"
S 0 0 B i<Q=x'Z;
S 0.0 60.0 'SLSPRV' ! GRIN rod (array channels) ��B[?CbU��
STOP @<]E�kkg��
CIR 1.25 ! Aperture of each channel �'��1)$' �
! (applies to entire length ��\qK��&q�
! of GRIN rod) �yw�3�$2EW
! Array definition �-n�<pPau2
g]yBA7�/S"
! ARR x_spacing y_spacing y_offset max_x max_y A;|�D:;x3G
ARR 2.5 2.5 0 0 0 �qXtC^n�@x
S 0 0 �%(G* ���,
EAR ! End array JNU�t��$�h
S 0 10.222 �����!V g`
PIM )$�bS�}��.
SI 0 0 �tlp�@�?(u
LAY;SUR So..i;GO ��3��+�fp2
;<2���G���
M��8b;d}XL
Figure 2. 1:1 GRIN array
