The following input will simulate a 1:1 array of GRIN rods (see Figure 2): ��XS�$#\UQ
�d&�l�T/S�
M8R/a[ -�A
\]0#�j�I/:
RDM;LEN y&V%��xE/�
TIT 1:1 GRIN ARRAY <�v!j�S�=T
NAO 0.1 p�V�M1%n:#
TEL ! Telecentric �:F��_�>`{
DIM M Z��nBGNr��
WL 633 i|rC�Ga�0}
YOB -5 5 0 -10 10 V�4&a+MJ@�
PRV ! GRIN material (SELFOC form) ib�n�\&}1�
PWL 633 \5�-D�p9vG
'SLSPRV' 1.5 Aho-\9/�x%
SEL 1 ! Grin step size w"O{@2B3:H
SEL C1 .076 ! First coeff. of SELFOC formula L�LL�;SN�Y
END D�&x�.io��
So 0 10.222 M8IU[Pz��4
RED -1 a ?\:,5��=
S 0 0 6~l+�wu�<$
S 0.0 60.0 'SLSPRV' ! GRIN rod (array channels) 7m�%[$�X�`
STOP M�Eu�{'[C
CIR 1.25 ! Aperture of each channel :�`>tC�Yy;
! (applies to entire length FNs$k=�*�8
! of GRIN rod) ��"����ZL_
! Array definition G#~U�\QlG-
3
}3�C�*w+
! ARR x_spacing y_spacing y_offset max_x max_y Z_a@,�k:+[
ARR 2.5 2.5 0 0 0 5j�v*C�]�z
S 0 0 Fk�g��%_v$
EAR ! End array 9f�W�R�8iV
S 0 10.222 �RXo�6y(^
PIM uqD|j:~ =k
SI 0 0 QQ=Kj%�R�
LAY;SUR So..i;GO 1,7�
}ah_
$w��yPG�ok
^%m{��yf�#
Figure 2. 1:1 GRIN array
