The following input will simulate a 1:1 array of GRIN rods (see Figure 2): H�*=cw<���
A�yE*1 F�D
.9J^\%��JD
.?Eb{W)^br
RDM;LEN L!�}!k N:?
TIT 1:1 GRIN ARRAY �*:%&z?<Fw
NAO 0.1 S\�GWMB!oF
TEL ! Telecentric s= Fp[>qA
DIM M @:N8�V�[*u
WL 633 *C_A(n5"�V
YOB -5 5 0 -10 10 �S;~eI8gQ"
PRV ! GRIN material (SELFOC form) m?�e/�MQ�r
PWL 633 K#R]�of~/
'SLSPRV' 1.5 �LU�6R"c11
SEL 1 ! Grin step size �2F4<3k!�&
SEL C1 .076 ! First coeff. of SELFOC formula �k�Wr1>})'
END �'uu*Dg�Er
So 0 10.222 ��de:@/�-|
RED -1 ��1eI*.pt�
S 0 0 Rhc�:s�zDU
S 0.0 60.0 'SLSPRV' ! GRIN rod (array channels) \BHZRy�tQF
STOP pDS�[ec��x
CIR 1.25 ! Aperture of each channel �4C;;V m4~
! (applies to entire length /~,*D�H$)�
! of GRIN rod) Cl0�kR�3Y�
! Array definition d{�fd5jv;
72�n�Z`u��
! ARR x_spacing y_spacing y_offset max_x max_y �9�qap#A��
ARR 2.5 2.5 0 0 0 �
2E*=EjGV
S 0 0 "6U0
!.ro@
EAR ! End array �um9&f~�M
S 0 10.222 Ej(BE@6>s�
PIM oCT,v�0+4O
SI 0 0 a6���Vfd�&
LAY;SUR So..i;GO |4�+�'YgO
7Z>vQ�f B�
>Na.�C(�DZ
Figure 2. 1:1 GRIN array
