/******************************************************************************* * McStas instrument definition URL=http://mcstas.risoe.dk * * Instrument: ILL_H142 * * %Identification * Written by: FARHI Emmanuel (farhi@ill.fr) * Date: April 7, 2004 * Origin:ILL * Release: McStas 1.8 * Version: $Revision: 1.2 $ * %INSTRUMENT_SITE: ILL * * The H142 S-curved cold guide at the ILL * * %Description * The H142 S-curved cold guide at the ILL feeding IN12, T3 and LADI * * Example: * mcrun -n 1e7 --format=Matlab --dir=WhiteBeam ILL_H142.instr m=1 * mcrun -n 1e7 --format=Matlab --dir=WhiteBeamSt ILL_H142.instr m=1 curved=0 * mcrun -n 1e7 --format=Matlab --dir=WhiteBeam2 ILL_H142.instr m=1 m142=2 * * %Parameters * m: (1) m-value of first curved setion (H14) guide coating * lambda: (AA) central wavelength * dl_percent: (%) percentage from 0 to 100 for d_lambda/lambda * curved: (1) flag true when 2nd guide part is curved, else straight * m142: (1) m-value of second curved setion (H142) guide coating * H: (m) height of 2nd H142 curved section * * %Link * The IN12 TAS at the ILL * * %End *******************************************************************************/ DEFINE INSTRUMENT ILL_H142(m=1, lambda=10, dl_percent=170, H=0.12, curved=1, m142=1) /* The DECLARE section allows us to declare variables or small */ /* functions in C syntax. These may be used in the whole instrument. */ DECLARE %{ /* VCS (H1) source parameters */ double sT1=216.8,sI1=1.24e+13; double sT2=33.9, sI2=1.02e+13; double sT3=16.7 ,sI3=3.0423e+12; double sLambda; /* guide coating parameters */ double gR0 = 1; double gQc = 0.021; double gAlpha = 4.07; double gW = 1.0/300.0; double gMvalue = 1; double gMvalue142 = 1; /* gaps and Al windows parameters */ double Al_Thickness = 0.002; double gGap = 0.001; /* guide curvatures */ double gRh = 2700; /* upwards */ /* guide section parameters (total length/number of elements) */ double gH =0.12; double L_H142_2 =6.0 /6, Rh_H142_2 =0; double L_H142_3 =9.473/10, Rh_H142_3 =0; /* end: d ~ 15.5 moderator at -5.9 */ double L_H142_4 =6.973/7, Rh_H142_4 =0; /* end: d ~ 22.5 ... */ double L_H142_5 =4.75 /5, Rh_H142_5 =0; /* VTE is at the end of this section */ double L_H142_6 =12.5/10, Rh_H142_6 =0; /* end of H142 MAN spec sheet after 2 elements */ double L_H142_7 =12.5/10, Rh_H142_7 =0; double L_H142_8 =12.5/10, Rh_H142_8 =0; double L_H142_9 =12.5/10, Rh_H142_9 =0; double L_H142_10=12.5/10, Rh_H142_10=0; double L_H142_11=12.5/10, Rh_H142_11=0; double L_H142_12=7.5/6, Rh_H142_12=0; /* straight */ double L_H142_13=2.5/2, Rh_H142_13=0; /* straight */ /* capture flux positions from moderator: 21.4 28.4 61.2 */ %} /* The INITIALIZE section is executed when the simulation starts */ /* (C code). You may use them as component parameter values. */ INITIALIZE %{ /* transfert instrument parameters for components */ if (H) gH = H; if (m) gMvalue = m; if (m142) gMvalue142=m142; if (lambda) sLambda = lambda; /* Element rotations = Element length / Curvature Radius * RAD2DEG */ if (gRh) { Rh_H142_2 = L_H142_2 /gRh*RAD2DEG; Rh_H142_3 = L_H142_3 /gRh*RAD2DEG; Rh_H142_4 = L_H142_4 /gRh*RAD2DEG; Rh_H142_5 = L_H142_5 /gRh*RAD2DEG; if (curved) Rh_H142_6 =-L_H142_6 /gRh*RAD2DEG; /* S curved */ Rh_H142_7 =-L_H142_7 /gRh*RAD2DEG; Rh_H142_8 =-L_H142_8 /gRh*RAD2DEG; Rh_H142_9 =-L_H142_9 /gRh*RAD2DEG; Rh_H142_10 =-L_H142_10/gRh*RAD2DEG; Rh_H142_11 =-L_H142_11/gRh*RAD2DEG; } %} /* 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, and even replaced by a Progress_bar */ /* component. Other useful keywords are : ROTATED EXTEND GROUP PREVIOUS */ /* Also think about adding a neutron source ! */ COMPONENT Origin = Arm() AT (0,0,0) ABSOLUTE COMPONENT VCS = Source_gen( h = 0.22, w = 0.14, dist = 2.525, xw = 0.038, yh = 0.2, Lmin = sLambda*(1-dl_percent/100/2), Lmax = sLambda*(1+dl_percent/100/2), T1 = sT1, I1 = sI1, T2 = sT2, I2 = sI2, T3 = sT3, I3 = sI3, verbose = 1) AT (0, 0, 0) RELATIVE Origin COMPONENT Al_window1 = Al_window(win_thick=Al_Thickness) AT (0,0,0.21) RELATIVE VCS COMPONENT Al_window2 = Al_window(win_thick=Al_Thickness) AT (0,0,0.61) RELATIVE VCS COMPONENT Al_window3 = Al_window(win_thick=Al_Thickness) AT (0,0,0.78) RELATIVE VCS COMPONENT Al_window4 = Al_window(win_thick=Al_Thickness) AT (0,0,0.92) RELATIVE VCS COMPONENT Al_window5 = Al_window(win_thick=Al_Thickness) AT (0,0,2.43) RELATIVE VCS /* H142-1: L=3.17 m in 1 element. no curvature */ COMPONENT PinkCarter = Guide_gravity( w1=0.038, h1=0.2, w2=0.032, h2=0.2, l=3.170, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,2.525) RELATIVE VCS COMPONENT FirstObturator = Guide_gravity( w1=0.031, h1=0.2, w2=0.031, h2=0.2, l=0.228, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,3.17+0.02) RELATIVE PinkCarter /* ******************** swiming pool guide ******************** */ /* H142-2: L=5.5 m in 6 elements R horiz=2700 m */ COMPONENT H142_2 = Arm() AT (0,0,3.59) RELATIVE PinkCarter COMPONENT Mon_2_xy = Monitor_nD( xwidth=0.03, yheight=0.2, options="x y, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_2_dxdy = Monitor_nD( xwidth=0.03, yheight=0.2, options="dx dy, all auto, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_2_Phic = Monitor_nD( xwidth=0.03, yheight=0.2, options="x y dx dy, all auto, parallel, per cm2, capture, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_2_L = Monitor_nD( xwidth=0.03, yheight=0.2, options="lambda, limits=[1 21] bins=20, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_2_In = Al_window(win_thick=Al_Thickness) AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_2_1 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_2, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,Al_Thickness+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_2,0) RELATIVE PREVIOUS COMPONENT H142_2_2 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_2, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_2+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_2,0) RELATIVE PREVIOUS COMPONENT H142_2_3 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_2, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_2+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_2,0) RELATIVE PREVIOUS COMPONENT H142_2_4 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_2, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_2+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_2,0) RELATIVE PREVIOUS COMPONENT H142_2_5 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_2, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_2+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_2,0) RELATIVE PREVIOUS COMPONENT H142_2_6 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_2, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_2+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_2,0) RELATIVE PREVIOUS COMPONENT H142_2_Out = Al_window(win_thick=Al_Thickness) AT (0,0,L_H142_2+gGap) RELATIVE PREVIOUS /* gap 0.198 m (VS) */ /* H142-3: L=9.973 m in 10 elements Rh=2700 m. */ COMPONENT H142_3 = Arm() AT (0,0,0.198) RELATIVE H142_2_Out COMPONENT Mon_3_xy = Monitor_nD( xwidth=0.03, yheight=0.2, options="x y, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_3_dxdy = Monitor_nD( xwidth=0.6, yheight=0.2, options="dx dy, all auto, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_3_Phic = Monitor_nD( xwidth=0.03, yheight=0.2, options="x y dx dy, all auto, parallel, per cm2, capture, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_3_L = Monitor_nD( xwidth=0.03, yheight=0.2, options="lambda, limits=[1 21] bins=20, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_3_In = Al_window(win_thick=Al_Thickness) AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_3_1 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_3, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,Al_Thickness+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_3,0) RELATIVE PREVIOUS COMPONENT H142_3_2 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_3, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_3+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_3,0) RELATIVE PREVIOUS COMPONENT H142_3_3 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_3, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_3+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_3,0) RELATIVE PREVIOUS COMPONENT H142_3_4 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_3, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_3+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_3,0) RELATIVE PREVIOUS COMPONENT H142_3_5 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_3, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_3+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_3,0) RELATIVE PREVIOUS COMPONENT H142_3_6 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_3, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_3+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_3,0) RELATIVE PREVIOUS COMPONENT H142_3_7 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_3, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_3+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_3,0) RELATIVE PREVIOUS COMPONENT H142_3_8 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_3, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_3+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_3,0) RELATIVE PREVIOUS COMPONENT H142_3_9 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_3, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_3+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_3,0) RELATIVE PREVIOUS COMPONENT H142_3_10 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_3, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_3+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_3,0) RELATIVE PREVIOUS COMPONENT H142_3_Out = Al_window(win_thick=Al_Thickness) AT (0,0,L_H142_3+gGap) RELATIVE PREVIOUS /* gap 0.03 m */ /* H142-4: L=6.973 m in 7 elements Rh=2700 m. Here d_c ~ 21.4 */ COMPONENT H142_4 = Arm() AT (0,0,0.03) RELATIVE H142_3_Out COMPONENT Mon_4_xy = Monitor_nD( xwidth=0.03, yheight=0.2, options="x y, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_4_dxdy = Monitor_nD( xwidth=0.03, yheight=0.2, options="dx dy, all auto, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_4_Phic = Monitor_nD( xwidth=0.03, yheight=0.2, options="x y dx dy, all auto, parallel, per cm2, capture, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_4_L = Monitor_nD( xwidth=0.03, yheight=0.2, options="lambda, limits=[1 21] bins=20, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_4_In = Al_window(win_thick=Al_Thickness) AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_4_1 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_4, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,Al_Thickness+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_4,0) RELATIVE PREVIOUS COMPONENT H142_4_2 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_4, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_4+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_4,0) RELATIVE PREVIOUS COMPONENT H142_4_3 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_4, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_4+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_4,0) RELATIVE PREVIOUS COMPONENT H142_4_4 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_4, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_4+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_4,0) RELATIVE PREVIOUS COMPONENT H142_4_5 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_4, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_4+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_4,0) RELATIVE PREVIOUS COMPONENT H142_4_6 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_4, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_4+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_4,0) RELATIVE PREVIOUS COMPONENT H142_4_7 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_4, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_4+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_4,0) RELATIVE PREVIOUS COMPONENT H142_4_Out = Al_window(win_thick=Al_Thickness) AT (0,0,L_H142_4+gGap) RELATIVE PREVIOUS /* gap 0.03 m */ /* H142-5: L=4.75 m in 5 elements Rh=2700 m. Here d_c ~ 28.4 */ COMPONENT H142_5 = Arm() AT (0,0,0.03) RELATIVE H142_4_Out COMPONENT Mon_5_xy = Monitor_nD( xwidth=0.03, yheight=0.2, options="x y, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_5_dxdy = Monitor_nD( xwidth=0.03, yheight=0.2, options="dx dy, all auto, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_5_Phic = Monitor_nD( xwidth=0.03, yheight=0.2, options="x y dx dy, all auto, parallel, per cm2, capture, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_5_L = Monitor_nD( xwidth=0.03, yheight=0.2, options="lambda, limits=[1 21] bins=20, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_5_In = Al_window(win_thick=Al_Thickness) AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_5_1 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_5, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,Al_Thickness+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_5,0) RELATIVE PREVIOUS COMPONENT H142_5_2 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_5, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_5+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_5,0) RELATIVE PREVIOUS COMPONENT H142_5_3 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_5, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_5+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_5,0) RELATIVE PREVIOUS COMPONENT H142_5_4 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_5, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_5+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_5,0) RELATIVE PREVIOUS COMPONENT H142_5_5 = Guide_gravity( w1=0.03, h1=0.2, w2=0.03, h2=0.2, l=L_H142_5, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue, W=gW) AT (0,0,L_H142_5+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_5,0) RELATIVE PREVIOUS COMPONENT H142_5_Out = Al_window(win_thick=Al_Thickness) AT (0,0,L_H142_5+gGap) RELATIVE PREVIOUS /* gap .330 m (VTE) */ /* ******************** after the VTE ******************** */ /* H142-6: L=12.5 m in 10 elements Rh=-2700 m. splitting. */ COMPONENT H142_6 = Arm() AT (0,-(0.2-gH)/2,0.330) RELATIVE H142_5_Out COMPONENT Mon_6_xy = Monitor_nD( xwidth=0.03, yheight=gH, options="x y, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_6_dxdy = Monitor_nD( xwidth=0.03, yheight=gH, options="dx dy, all auto, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_6_Phic = Monitor_nD( xwidth=0.03, yheight=gH, options="x y dx dy, all auto, parallel, per cm2, capture, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_6_L = Monitor_nD( xwidth=0.03, yheight=gH, options="lambda, limits=[1 21] bins=20, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_6_In = Al_window(win_thick=Al_Thickness) AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_6_1 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_6, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,Al_Thickness+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_6,0) RELATIVE PREVIOUS COMPONENT H142_6_2 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_6, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_6+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_6,0) RELATIVE PREVIOUS COMPONENT H142_6_3 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_6, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_6+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_6,0) RELATIVE PREVIOUS COMPONENT H142_6_4 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_6, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_6+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_6,0) RELATIVE PREVIOUS COMPONENT H142_6_5 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_6, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_6+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_6,0) RELATIVE PREVIOUS COMPONENT H142_6_6 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_6, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_6+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_6,0) RELATIVE PREVIOUS COMPONENT H142_6_7 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_6, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_6+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_6,0) RELATIVE PREVIOUS COMPONENT H142_6_8 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_6, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_6+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_6,0) RELATIVE PREVIOUS COMPONENT H142_6_9 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_6, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_6+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_6,0) RELATIVE PREVIOUS COMPONENT H142_6_10 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_6, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_6+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_6,0) RELATIVE PREVIOUS COMPONENT H142_6_Out = Al_window(win_thick=Al_Thickness) AT (0,0,L_H142_6+gGap) RELATIVE PREVIOUS /* gap 0.03 m */ /* H142-7: L=12.5 m in 10 elements Rh=-2700 m */ COMPONENT H142_7 = Arm() AT (0,0,0.03+Al_Thickness) RELATIVE PREVIOUS COMPONENT Mon_7_xy = Monitor_nD( xwidth=0.03, yheight=gH, options="x y, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_7_dxdy = Monitor_nD( xwidth=0.03, yheight=gH, options="dx dy, all auto, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_7_Phic = Monitor_nD( xwidth=0.03, yheight=gH, options="x y dx dy, all auto, parallel, per cm2, capture, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_7_L = Monitor_nD( xwidth=0.03, yheight=gH, options="lambda, limits=[1 21] bins=20, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_7_In = Al_window(win_thick=Al_Thickness) AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_7_1 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_7, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,Al_Thickness+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_7,0) RELATIVE PREVIOUS COMPONENT H142_7_2 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_7, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_7+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_7,0) RELATIVE PREVIOUS COMPONENT H142_7_3 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_7, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_7+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_7,0) RELATIVE PREVIOUS COMPONENT H142_7_4 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_7, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_7+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_7,0) RELATIVE PREVIOUS COMPONENT H142_7_5 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_7, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_7+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_7,0) RELATIVE PREVIOUS COMPONENT H142_7_6 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_7, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_7+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_7,0) RELATIVE PREVIOUS COMPONENT H142_7_7 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_7, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_7+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_7,0) RELATIVE PREVIOUS COMPONENT H142_7_8 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_7, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_7+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_7,0) RELATIVE PREVIOUS COMPONENT H142_7_9 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_7, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_7+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_7,0) RELATIVE PREVIOUS COMPONENT H142_7_10 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_7, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_7+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_7,0) RELATIVE PREVIOUS COMPONENT H142_7_Out = Al_window(win_thick=Al_Thickness) AT (0,0,L_H142_7+gGap) RELATIVE PREVIOUS /* gap 0.03 m */ /* H142-8: L=12.5 m in 10 elements Rh=-2700 m. */ COMPONENT H142_8 = Arm() AT (0,0,0.03+Al_Thickness) RELATIVE PREVIOUS COMPONENT Mon_8_xy = Monitor_nD( xwidth=0.03, yheight=gH, options="x y, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_8_dxdy = Monitor_nD( xwidth=0.03, yheight=gH, options="dx dy, all auto, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_8_Phic = Monitor_nD( xwidth=0.03, yheight=gH, options="x y dx dy, all auto, parallel, per cm2, capture, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_8_L = Monitor_nD( xwidth=0.03, yheight=gH, options="lambda, limits=[1 21] bins=20, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_8_In = Al_window(win_thick=Al_Thickness) AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_8_1 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_8, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,Al_Thickness+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_8,0) RELATIVE PREVIOUS COMPONENT H142_8_2 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_8, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_8+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_8,0) RELATIVE PREVIOUS COMPONENT H142_8_3 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_8, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_8+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_8,0) RELATIVE PREVIOUS COMPONENT H142_8_4 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_8, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_8+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_8,0) RELATIVE PREVIOUS COMPONENT H142_8_5 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_8, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_8+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_8,0) RELATIVE PREVIOUS COMPONENT H142_8_6 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_8, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_8+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_8,0) RELATIVE PREVIOUS COMPONENT H142_8_7 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_8, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_8+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_8,0) RELATIVE PREVIOUS COMPONENT H142_8_8 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_8, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_8+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_8,0) RELATIVE PREVIOUS COMPONENT H142_8_9 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_8, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_8+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_8,0) RELATIVE PREVIOUS COMPONENT H142_8_10 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_8, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_8+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_8,0) RELATIVE PREVIOUS COMPONENT H142_8_Out = Al_window(win_thick=Al_Thickness) AT (0,0,L_H142_8+gGap) RELATIVE PREVIOUS /* gap 0.03 m */ /* H142-9: L=12.5 m in 10 elements Rh=-2700 m. */ COMPONENT H142_9 = Arm() AT (0,0,0.03+Al_Thickness) RELATIVE PREVIOUS COMPONENT Mon_9_xy = Monitor_nD( xwidth=0.03, yheight=gH, options="x y, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_9_dxdy = Monitor_nD( xwidth=0.03, yheight=gH, options="dx dy, all auto, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_9_Phic = Monitor_nD( xwidth=0.03, yheight=gH, options="x y dx dy, all auto, parallel, per cm2, capture, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_9_L = Monitor_nD( xwidth=0.03, yheight=gH, options="lambda, limits=[1 21] bins=20, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_9_In = Al_window(win_thick=Al_Thickness) AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_9_1 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_9, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,Al_Thickness+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_9,0) RELATIVE PREVIOUS COMPONENT H142_9_2 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_9, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_9+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_9,0) RELATIVE PREVIOUS COMPONENT H142_9_3 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_9, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_9+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_9,0) RELATIVE PREVIOUS COMPONENT H142_9_4 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_9, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_9+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_9,0) RELATIVE PREVIOUS COMPONENT H142_9_5 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_9, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_9+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_9,0) RELATIVE PREVIOUS COMPONENT H142_9_6 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_9, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_9+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_9,0) RELATIVE PREVIOUS COMPONENT H142_9_7 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_9, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_9+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_9,0) RELATIVE PREVIOUS COMPONENT H142_9_8 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_9, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_9+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_9,0) RELATIVE PREVIOUS COMPONENT H142_9_9 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_9, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_9+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_9,0) RELATIVE PREVIOUS COMPONENT H142_9_10 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_9, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_9+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_9,0) RELATIVE PREVIOUS COMPONENT H142_9_Out = Al_window(win_thick=Al_Thickness) AT (0,0,L_H142_9+gGap) RELATIVE PREVIOUS /* gap 0.03 m */ /* H142-10: L=12.5 m in 10 elements Rh=-2700 m. */ COMPONENT H142_10 = Arm() AT (0,0,0.03+Al_Thickness) RELATIVE PREVIOUS COMPONENT Mon_10_xy = Monitor_nD( xwidth=0.03, yheight=gH, options="x y, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_10_dxdy = Monitor_nD( xwidth=0.03, yheight=gH, options="dx dy, all auto, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_10_Phic = Monitor_nD( xwidth=0.03, yheight=gH, options="x y dx dy, all auto, parallel, per cm2, capture, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_10_L = Monitor_nD( xwidth=0.03, yheight=gH, options="lambda, limits=[1 21] bins=20, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_10_In = Al_window(win_thick=Al_Thickness) AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_10_1 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_10, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,Al_Thickness+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_10,0) RELATIVE PREVIOUS COMPONENT H142_10_2 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_10, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_10+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_10,0) RELATIVE PREVIOUS COMPONENT H142_10_3 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_10, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_10+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_10,0) RELATIVE PREVIOUS COMPONENT H142_10_4 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_10, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_10+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_10,0) RELATIVE PREVIOUS COMPONENT H142_10_5 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_10, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_10+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_10,0) RELATIVE PREVIOUS COMPONENT H142_10_6 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_10, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_10+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_10,0) RELATIVE PREVIOUS COMPONENT H142_10_7 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_10, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_10+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_10,0) RELATIVE PREVIOUS COMPONENT H142_10_8 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_10, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_10+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_10,0) RELATIVE PREVIOUS COMPONENT H142_10_9 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_10, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_10+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_10,0) RELATIVE PREVIOUS COMPONENT H142_10_10 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_10, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_10+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_10,0) RELATIVE PREVIOUS COMPONENT H142_10_Out = Al_window(win_thick=Al_Thickness) AT (0,0,L_H142_10+gGap) RELATIVE PREVIOUS /* gap 0.03 m */ /* H142-11: L=12.5 m in 10 elements Rh=-2700 m. */ COMPONENT H142_11 = Arm() AT (0,0,0.03+Al_Thickness) RELATIVE PREVIOUS COMPONENT Mon_11_xy = Monitor_nD( xwidth=0.03, yheight=gH, options="x y, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_11_dxdy = Monitor_nD( xwidth=0.03, yheight=gH, options="dx dy, all auto, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_11_Phic = Monitor_nD( xwidth=0.03, yheight=gH, options="x y dx dy, all auto, parallel, per cm2, capture, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_11_L = Monitor_nD( xwidth=0.03, yheight=gH, options="lambda, limits=[1 21] bins=20, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_11_In = Al_window(win_thick=Al_Thickness) AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_11_1 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_11, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,Al_Thickness+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_11,0) RELATIVE PREVIOUS COMPONENT H142_11_2 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_11, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_11+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_11,0) RELATIVE PREVIOUS COMPONENT H142_11_3 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_11, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_11+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_11,0) RELATIVE PREVIOUS COMPONENT H142_11_4 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_11, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_11+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_11,0) RELATIVE PREVIOUS COMPONENT H142_11_5 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_11, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_11+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_11,0) RELATIVE PREVIOUS COMPONENT H142_11_6 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_11, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_11+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_11,0) RELATIVE PREVIOUS COMPONENT H142_11_7 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_11, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_11+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_11,0) RELATIVE PREVIOUS COMPONENT H142_11_8 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_11, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_11+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_11,0) RELATIVE PREVIOUS COMPONENT H142_11_9 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_11, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_11+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_11,0) RELATIVE PREVIOUS COMPONENT H142_11_10 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_11, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_11+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_11,0) RELATIVE PREVIOUS COMPONENT H142_11_Out = Al_window(win_thick=Al_Thickness) AT (0,0,L_H142_11+gGap) RELATIVE PREVIOUS /* Here IN12 position. Gap .300 */ /* H142-12: L=7.5 m in 6 elements Rh=0 m. */ COMPONENT H142_12 = Arm() AT (0,0,0.3) RELATIVE PREVIOUS COMPONENT Mon_12_xy = Monitor_nD( xwidth=0.03, yheight=gH, options="x y, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_12_dxdy = Monitor_nD( xwidth=0.03, yheight=gH, options="dx dy, all auto, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_12_Phic = Monitor_nD( xwidth=0.03, yheight=gH, options="x y dx dy, all auto, parallel, per cm2, capture, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_12_L = Monitor_nD( xwidth=0.03, yheight=gH, options="lambda, limits=[1 21] bins=20, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_12_In = Al_window(win_thick=Al_Thickness) AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_12_1 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_12, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,Al_Thickness+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_12,0) RELATIVE PREVIOUS COMPONENT H142_12_2 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_12, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_12+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_12,0) RELATIVE PREVIOUS COMPONENT H142_12_3 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_12, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_12+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_12,0) RELATIVE PREVIOUS COMPONENT H142_12_4 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_12, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_12+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_12,0) RELATIVE PREVIOUS COMPONENT H142_12_5 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_12, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_12+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_12,0) RELATIVE PREVIOUS COMPONENT H142_12_6 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_12, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_12+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_12,0) RELATIVE PREVIOUS COMPONENT H142_12_Out = Al_window(win_thick=Al_Thickness) AT (0,0,L_H142_12+gGap) RELATIVE PREVIOUS /* Here T16/T3 position. Gap .300 */ /* H142-13: L=2.5 m in 2 elements Rh=0 m. */ COMPONENT H142_13 = Arm() AT (0,0,0.3) RELATIVE PREVIOUS COMPONENT Mon_13_xy = Monitor_nD( xwidth=0.03, yheight=gH, options="x y, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_13_dxdy = Monitor_nD( xwidth=0.03, yheight=gH, options="dx dy, all auto, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_13_Phic = Monitor_nD( xwidth=0.03, yheight=gH, options="x y dx dy, all auto, parallel, per cm2, capture, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_13_L = Monitor_nD( xwidth=0.03, yheight=gH, options="lambda, limits=[1 21] bins=20, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_13_In = Al_window(win_thick=Al_Thickness) AT (0,0,0) RELATIVE PREVIOUS COMPONENT H142_13_1 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_13, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,Al_Thickness+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_13,0) RELATIVE PREVIOUS COMPONENT H142_13_2 = Guide_gravity( w1=0.03, h1=gH, w2=0.03, h2=gH, l=L_H142_13, R0=gR0, Qc=gQc, alpha=gAlpha, m=gMvalue142, W=gW) AT (0,0,L_H142_13+gGap) RELATIVE PREVIOUS ROTATED (0,Rh_H142_13,0) RELATIVE PREVIOUS COMPONENT H142_13_Out = Al_window(win_thick=Al_Thickness) AT (0,0,L_H142_13+gGap) RELATIVE PREVIOUS /* LADI position */ COMPONENT Mon_14_xy = Monitor_nD( xwidth=0.03, yheight=gH, options="x y, parallel, per cm2, slit") AT (0,0,0.03) RELATIVE PREVIOUS COMPONENT Mon_14_dxdy = Monitor_nD( xwidth=0.03, yheight=gH, options="dx dy, all auto, parallel, per cm2, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_14_Phic = Monitor_nD( xwidth=0.03, yheight=gH, options="x y dx dy, all auto, parallel, per cm2, capture, slit") AT (0,0,0) RELATIVE PREVIOUS COMPONENT Mon_14_L = Monitor_nD( xwidth=0.03, yheight=gH, options="lambda, limits=[1 21] bins=20, parallel, per cm2, slit") 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