The following input will simulate a 1:1 array of GRIN rods (see Figure 2): P��DQ�C^2Z
&x6Z=�|Ers
|�s��[k�Y�
�GcN[bH(�@
RDM;LEN ,l/~epx4v)
TIT 1:1 GRIN ARRAY 8�g0By;h�;
NAO 0.1 W�O$�9Svh8
TEL ! Telecentric ~2u~}v�5m7
DIM M D=Ia$O�0.�
WL 633 <%�w)EQf4m
YOB -5 5 0 -10 10 Y3@\uM�`2#
PRV ! GRIN material (SELFOC form) gS{hfDpk,h
PWL 633 �SNqw�2f�5
'SLSPRV' 1.5 u��~SvR~OE
SEL 1 ! Grin step size c��1 a�CN
SEL C1 .076 ! First coeff. of SELFOC formula xPMTm�x?�2
END 7|Z=#�3INw
So 0 10.222 �7�^1yZ1�(
RED -1 4@ ��EY�+p
S 0 0 s�
�z�BlyT
S 0.0 60.0 'SLSPRV' ! GRIN rod (array channels) ��6r������
STOP ~nYp�*t C'
CIR 1.25 ! Aperture of each channel ~*"�]XE�?M
! (applies to entire length p�T3p!/pl3
! of GRIN rod) ]^aO�YtK�X
! Array definition �#9{�N[�t�
`;KU^�dH�
! ARR x_spacing y_spacing y_offset max_x max_y F<FNZQ@<U�
ARR 2.5 2.5 0 0 0 Mn$�w_�Z?
S 0 0 ����ZqT8G�
EAR ! End array j��w6�3s�n
S 0 10.222 �.�quui\I3
PIM DD 8uG��`<
SI 0 0 w7Fz�(`\��
LAY;SUR So..i;GO )@lZ�~01~d
y[QQo�py4:
�st~
1[in�
Figure 2. 1:1 GRIN array
