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/*******************************************************************************
* McStas instrument definition URL=http://www.mcstas.org
*
* Instrument: Test_Rotator
*
* %Identification
* Written by: Peter Willendrup
* Date: October 2023
* Origin: ESS
* %INSTRUMENT_SITE: Tests_optics
*
* Unittest for Rotator/Derotator
*
* %Description
* Unittest for Rotator/Derotator
*
* Example: mcrun test.instr <parameters=values>
*
* %Parameters
* nu: [Hz] Rotation frequency
* phase: [deg] Rotatoion phase
* dir: [int] Rotation axis direction x=1, y=2, z=3
*
* %Link
* A reference/HTML link for more information
*
* %End
*******************************************************************************/
DEFINE INSTRUMENT Test_Rotator(nu=10,phase=5,int dir=2)
/* The DECLARE section allows us to declare variables or small */
/* functions in C syntax. These may be used in the whole instrument. */
DECLARE
%{
%}
/* The INITIALIZE section is executed when the simulation starts */
/* (C code). You may use them as component parameter values. */
INITIALIZE
%{
%}
/* Here comes the TRACE section, where the actual */
/* instrument is defined as a sequence of components. */
TRACE
/* The Arm() class component defines reference points and orientations */
/* in 3D space. Every component instance must have a unique name. Here, */
/* Origin is used. This Arm() component is set to define the origin of */
/* our global coordinate system (AT (0,0,0) ABSOLUTE). It may be used */
/* for further RELATIVE reference, Other useful keywords are : ROTATED */
/* EXTEND GROUP PREVIOUS. Also think about adding a neutron source ! */
/* Progress_bar is an Arm displaying simulation progress. */
COMPONENT Origin = Progress_bar()
AT (0,0,0) ABSOLUTE
COMPONENT source_simple = Source_simple(
lambda0=5,
dlambda=1, dist=1, focus_xw=0.01, focus_yh=0.01)
AT (0, 0, 0) RELATIVE PREVIOUS
EXTEND %{
t=rand01();
%}
COMPONENT Sphere0 = PSD_monitor_4PI(restore_neutron=1)
AT (0, 0, 0) ABSOLUTE
COMPONENT Incoming = Event_monitor_simple()
AT (0, 0, 0) RELATIVE PREVIOUS
COMPONENT R0=Rotator(nu=nu, phase=phase, direction=dir)
AT (0,0,1) RELATIVE source_simple
COMPONENT Sphere1 = PSD_monitor_4PI(restore_neutron=1)
AT (0, 0, 0) ABSOLUTE
COMPONENT Rot = Event_monitor_simple()
AT (0, 0, 0) RELATIVE PREVIOUS
COMPONENT DR=Derotator(rotator="R0")
AT (0,0,0) RELATIVE R0
COMPONENT Sphere2 = PSD_monitor_4PI(restore_neutron=1)
AT (0, 0, 0) ABSOLUTE
COMPONENT Derotated = Event_monitor_simple()
AT (0, 0, 0) RELATIVE PREVIOUS
/* This section is executed when the simulation ends (C code). Other */
/* optional sections are : SAVE */
FINALLY
%{
%}
/* The END token marks the instrument definition end */
END
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