1 | !---|----1----|----2----|----3----|----4----|----5----|----6----|----7----|----8 |
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2 | !------------------------------------------------------------------------------- |
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3 | ! |
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4 | ! Specifications of field imperfections for LHC v6.-2 |
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5 | ! ----------------------------------- |
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6 | !------------------------------------------------------------------------------- |
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7 | !-------------------------------HISTORY----------------------------------------- |
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8 | ! 06/03/96/afg-jpk 17:15 created following the strategy defined by AP/MA W.G. |
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9 | ! 08/03/96/jpk 14:30 MQX(T) random distribution cut at 2 sigmas (3 before) |
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10 | ! Uncertainties now added quadratically |
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11 | ! ON_BDOT treated like a scaling factor |
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12 | ! SET_ERR_MAX: set worst case for each multipole |
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13 | ! 11/03/96/jpk 12:10 Fix a bug with drawing the systematic per arc: |
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14 | ! No statist. consequence but the random gen. slips |
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15 | ! Improve clarity (selection ranges, names of subroutines) |
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16 | ! Suppress redundancies in the calculation of the sigmas |
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17 | ! of the random components. |
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18 | ! 14/04/96/jpk 13:45 Bug corrected in setting the seed for randoms; before that |
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19 | ! time, all octants had the same suite of randoms. |
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20 | ! 13/08/96/jpk 09:40 Improve the control output of set_err_max |
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21 | ! 06/06/96/jm Converted from v4.3 to v5.0 (THIN Lens) |
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22 | ! 06/06/97/jm Updated to v5.0 (THIN Lens) |
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23 | ! 16/10/98/jm Updated to V6.-2 (THIN Lens) |
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24 | ! 23/02/99/ew,jpk 11;30 Change to "radius=Rr" in SetEfcomp_B & SetEfcomp_Q |
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25 | ! 28/08/01/ew Addition of routine for inverted MQXA and MQXB |
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26 | ! Single_MQXA_inv and Single_MQXB_inv. |
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27 | ! 18/07/02/tr Split MQW into 4 groups: MQWA_l, MQWA_r, MQWB_l, MQWB_r |
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28 | ! 21/10/02/ob Define SetEfcomp_ABS for absolute error definitions |
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29 | ! 06/11/02/tr introduced ON_PERS switch for persistent current errors |
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30 | ! 20/12/02/tr introduced ON_DEC switch for decay of the MBs |
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31 | ! 21.10.04/al mail by Alessandra Lombardi (reference system correction) : |
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32 | ! new SetEfcomp_B, SetEfcomp_Q, SetEfcomp_ABS, SetEfcomp_Qinv |
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33 | ! |
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34 | !------------------------------ENDHISTORY--------------------------------------- |
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35 | ! |
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36 | ! |
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37 | ! |
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38 | !1/ SET ALL IMPERFECTIONS FOR ALL MAGNETS: |
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39 | !--------------- |
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40 | ! ON_ALL ! select all magnets and all multipolar orders |
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41 | ! |
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42 | !2/ SET A SELECTION OF IMPERF. FOR A SELECTION OF MAGNETS: |
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43 | !--------------- |
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44 | ! The selection is carried out thru switches described later. |
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45 | ! <select a class of magnets, e.g. MB's> |
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46 | ! Set, ON_MB, 1; |
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47 | ! <select the imperfections: normal, skew, order for this class> |
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48 | ! Set, ON_B1s, 1; ! normal (B) systematic (s) order 1 |
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49 | ! etc.... |
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50 | ! |
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51 | ! <select another class of magnets, e.g. MQ's> |
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52 | ! Set, ON_MQ, 1; |
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53 | ! <select the imperfections for the MQ's> |
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54 | ! Set, ON_B1s, 0; |
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55 | ! etc.... |
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56 | ! |
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57 | !3/ SET ALL IMPERFECTIONS FOR A SELECTION OF MAGNETS |
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58 | !--------------------------------------------------- |
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59 | ! <select a class of magnets, e.g. MB's> |
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60 | ! Set, ON_MB, 1; |
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61 | ! ON_MULT ! select all imperfection orders |
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62 | ! |
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63 | !--------------------------------SWITCHES---------------------------------------- |
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64 | !SELECTION OF A CLASS OF ELEMENTS (on=1/off=0, default value) |
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65 | ! *Main and Disp. Suppr. Dipoles (MB) : ON_MB |
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66 | ! *Separator: single channel RHIC dipoles (MBX) : ON_MBX |
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67 | ! *Separator: single channel RHIC dipoles lead end (MBX) : ON_MBXLEND |
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68 | ! *Separator: single channel RHIC dipoles return end (MBX) : ON_MBXREND |
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69 | ! *Separator: 2-1 RHIC dipoles (MBRS: D3) : ON_MBRS |
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70 | ! *Separator: 2-1 RHIC dipoles lead end (MBRS: D3) : ON_MBRSLEND |
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71 | ! *Separator: 2-1 RHIC dipoles return end (MBRS: D3) : ON_MBRSREND |
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72 | ! *Separator: 2-1 RHIC dipoles (MBRB: D4) : ON_MBRB |
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73 | ! *Separator: 2-1 RHIC dipoles lead end (MBRB: D4) : ON_MBRBLEND |
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74 | ! *Separator: 2-1 RHIC dipoles return end (MBRB: D4) : ON_MBRBREND |
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75 | ! *Separator: 2-1 RHIC dipoles (MBRC: D2) : ON_MBRC |
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76 | ! *Separator: 2-1 RHIC dipoles lead end (MBRC: D2) : ON_MBRCLEND |
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77 | ! *Separator: 2-1 RHIC dipoles return end (MBRC: D2) : ON_MBRCREND |
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78 | ! *Separator: single channel (MBXW) and 2-1 warm Dipoles (MBW) : ON_MBW |
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79 | ! |
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80 | ! *Arc (MQ) and DS Quadrupoles (MQML, MQM, MQMC) : ON_MQ |
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81 | ! *Insertion 2-1 Quadrupoles (MQ, MQML, MQM, MQMC) : ON_MQIP |
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82 | ! *Arc Tune shift (MQT), DS (MQT) and DS trim Quads(MQTL) : ON_MQTL |
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83 | ! *Single apertureRF/Quadrupoles(MQR, MQRL) : ON_MQR |
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84 | ! *Low-Beta Quadupoles (MQX, MQXL) : ON_MQX |
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85 | ! *Wide Aperture Quadrupoles (MQY) : ON_MQY |
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86 | ! *Warm Quadrupoles (MQW) : ON_MQW |
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87 | ! |
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88 | !SELECTION OF IMPERFECTION ORDERS (i=1..11) |
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89 | ! *normal systematic : ON_BiS |
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90 | ! *normal random : ON_BiR |
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91 | ! *skew systematic : ON_AiS |
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92 | ! *skew random : ON_AiR |
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93 | ! |
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94 | !SELECTION OF RAMP INDUCED IMPERFECTIONS : ON_BDOT |
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95 | ! |
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96 | !SELECTION OF PERSISTENT CURRENT IMPERFECTIONS : ON_PERS |
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97 | ! |
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98 | !SUBROUTINES FOR FAST SELECTIONS |
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99 | ! *ALL multipole orders set to 1 : ON_MULT |
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100 | ! *ALL multipole orders for ALL elements set to 1 : ON_ALL |
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101 | ! |
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102 | !---------------------STRATEGY FOR SETTING ERRORS A LA V4.2---------------------- |
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103 | ! |
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104 | ! Random and systematic imperfections are defined for each production line |
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105 | ! of magnets. |
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106 | ! Production lines defined: |
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107 | ! - MB's : 8 lines, one per arc |
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108 | ! - MQ's : 8 lines, one per arc |
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109 | ! - all others: 1 line per kind of magnet |
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110 | ! |
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111 | ! Each line is defined by systematic (mean) and random (spread) imperfections: |
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112 | ! - RANDOM imperfections: The spread is assumed the same for all production |
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113 | ! lines of a given kind of magnets. For each magnet, an imperfection is |
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114 | ! drawn from a gaussian distribution with sigma= Bir(Air), |
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115 | ! cut a GCUTR sigma (3 by default). Bir(Air) is formed by quadratic addition of |
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116 | ! persistent current (pc), geometric (g) and ramp induced (t) contributions |
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117 | ! the latter depending on the switch ON_BDOT. |
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118 | ! - SYSTEMATIC imperfections: they are computed for each production line from |
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119 | ! the MEAN value for the OUTER channel and the UNCERTAINTY found in the table. |
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120 | ! The UNCERTAIN part is computed by adding quadratically the uncertainties for |
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121 | ! pc, g, t; the value obtained is considered to be 1.5 sigmas of a gaussian |
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122 | ! distribution cut at 1.5 sigmas; the uncertainty is drawn from this |
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123 | ! distribution for each line. |
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124 | ! The MEAN part is computed by adding linearly the pc, g, t components for |
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125 | ! the OUTER channel. For the INNER channel the GEOMETRIC MEAN component is |
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126 | ! deduced from that of the outer channel; it follows the following sign rules: |
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127 | ! * dipoles: - b2, b4 (2-1 design) |
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128 | ! - other b(2n) (assumption; no consequence) |
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129 | ! + b(2n+1) (design) |
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130 | ! + a(2n) (wild assumption; no consequence) |
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131 | ! - a(2n+1) (wild assumption; no consequence) |
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132 | ! * quads + b(2[2n+1]) (design) |
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133 | ! + b(4n), a(2n+1)(wild assumption; no consequence) |
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134 | ! - b(2n+1), a(2n)(wild assumption; no consequence) |
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135 | ! The other MEAN components (PERSISTENT CURRENT, RAMP) keep the sign of the |
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136 | ! tables for both channels. |
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137 | !---------------------STRATEGY FOR THE WORST CASE------------------------------ |
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138 | ! For each component (pc, g, t), the uncertainty and 3 rms (2 for MQX) of the |
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139 | ! bias due to randoms are |
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140 | ! added to the mean in such a way as to produce the largest number in |
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141 | ! absolute value with the sign of the dominant component. |
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142 | ! The contributions of the three components are then added linearly |
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143 | ! THE SIGN RULE IS APPLIED to the mean b2 in the dipoles which is the only one |
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144 | ! to change sign for sure. |
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145 | !------------------------------------------------------------------------------ |
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146 | ON_MULT: macro = { |
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147 | ON_A1s = 1 ; ON_A1r = 1 ; ON_B1s = 1 ; ON_B1r = 1 ; |
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148 | ON_A2s = 1 ; ON_A2r = 1 ; ON_B2s = 1 ; ON_B2r = 1 ; |
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149 | ON_A3s = 1 ; ON_A3r = 1 ; ON_B3s = 1 ; ON_B3r = 1 ; |
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150 | ON_A4s = 1 ; ON_A4r = 1 ; ON_B4s = 1 ; ON_B4r = 1 ; |
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151 | ON_A5s = 1 ; ON_A5r = 1 ; ON_B5s = 1 ; ON_B5r = 1 ; |
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152 | ON_A6s = 1 ; ON_A6r = 1 ; ON_B6s = 1 ; ON_B6r = 1 ; |
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153 | ON_A7s = 1 ; ON_A7r = 1 ; ON_B7s = 1 ; ON_B7r = 1 ; |
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154 | ON_A8s = 1 ; ON_A8r = 1 ; ON_B8s = 1 ; ON_B8r = 1 ; |
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155 | ON_A9s = 1 ; ON_A9r = 1 ; ON_B9s = 1 ; ON_B9r = 1 ; |
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156 | ON_A10s = 1 ; ON_A10r = 1 ; ON_B10s = 1 ; ON_B10r = 1 ; |
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157 | ON_A11s = 1 ; ON_A11r = 1 ; ON_B11s = 1 ; ON_B11r = 1 ; |
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158 | } |
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159 | |
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160 | ON_SYST: macro = { |
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161 | ON_A1s = 1 ; ON_A1r = 0 ; ON_B1s = 1 ; ON_B1r = 0 ; |
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162 | ON_A2s = 1 ; ON_A2r = 0 ; ON_B2s = 1 ; ON_B2r = 0 ; |
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163 | ON_A3s = 1 ; ON_A3r = 0 ; ON_B3s = 1 ; ON_B3r = 0 ; |
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164 | ON_A4s = 1 ; ON_A4r = 0 ; ON_B4s = 1 ; ON_B4r = 0 ; |
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165 | ON_A5s = 1 ; ON_A5r = 0 ; ON_B5s = 1 ; ON_B5r = 0 ; |
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166 | ON_A6s = 1 ; ON_A6r = 0 ; ON_B6s = 1 ; ON_B6r = 0 ; |
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167 | ON_A7s = 1 ; ON_A7r = 0 ; ON_B7s = 1 ; ON_B7r = 0 ; |
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168 | ON_A8s = 1 ; ON_A8r = 0 ; ON_B8s = 1 ; ON_B8r = 0 ; |
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169 | ON_A9s = 1 ; ON_A9r = 0 ; ON_B9s = 1 ; ON_B9r = 0 ; |
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170 | ON_A10s = 1 ; ON_A10r = 0 ; ON_B10s = 1 ; ON_B10r = 0 ; |
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171 | ON_A11s = 1 ; ON_A11r = 0 ; ON_B11s = 1 ; ON_B11r = 0 ; |
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172 | } |
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173 | |
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174 | ON_ALL : macro = { |
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175 | exec ON_MULT; |
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176 | ON_MB = 1 ; ON_MBW = 1 ; |
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177 | ON_MBX = 1 ; ON_MBRS = 1 ; ON_MBRB = 1 ; ON_MBRC = 1 ; |
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178 | ON_MBXLEND = 1 ; ON_MBRSLEND = 1 ; ON_MBRBLEND = 1 ; ON_MBRCLEND = 1 ; |
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179 | ON_MBXREND = 1 ; ON_MBRSREND = 1 ; ON_MBRBREND = 1 ; ON_MBRCREND = 1 ; |
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180 | |
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181 | ON_MQ = 1 ; ON_MQIP = 1 ; ON_MQTL = 1 ; ON_MQR = 1 ; |
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182 | ON_MQX = 1 ; ON_MQY = 1 ; ON_MQW = 1 ; |
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183 | } |
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184 | |
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185 | |
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186 | SetEfcomp_B: macro = { |
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187 | Efcomp, radius = Rr, order= 0, |
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188 | dknr:={1E-4*( B1s *ON_B1S + B1r *ON_B1R * TGAUSS(GCUTR)), |
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189 | 1E-4*(-B2s *ON_B2S + B2r *ON_B2R * TGAUSS(GCUTR)), |
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190 | 1E-4*( B3s *ON_B3S + B3r *ON_B3R * TGAUSS(GCUTR)), |
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191 | 1E-4*(-B4s *ON_B4S + B4r *ON_B4R * TGAUSS(GCUTR)), |
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192 | 1E-4*( B5s *ON_B5S + B5r *ON_B5R * TGAUSS(GCUTR)), |
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193 | 1E-4*(-B6s *ON_B6S + B6r *ON_B6R * TGAUSS(GCUTR)), |
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194 | 1E-4*( B7s *ON_B7S + B7r *ON_B7R * TGAUSS(GCUTR)), |
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195 | 1E-4*(-B8s *ON_B8S + B8r *ON_B8R * TGAUSS(GCUTR)), |
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196 | 1E-4*( B9s *ON_B9S + B9r *ON_B9R * TGAUSS(GCUTR)), |
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197 | 1E-4*(-B10s *ON_B10S + B10r *ON_B10R * TGAUSS(GCUTR)), |
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198 | 1E-4*( B11s *ON_B11S + B11r *ON_B11R * TGAUSS(GCUTR))}, |
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199 | dksr:={1E-4*(-A1s *ON_A1S + A1r *ON_A1R * TGAUSS(GCUTR)), |
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200 | 1E-4*( A2s *ON_A2S + A2r *ON_A2R * TGAUSS(GCUTR)), |
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201 | 1E-4*(-A3s *ON_A3S + A3r *ON_A3R * TGAUSS(GCUTR)), |
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202 | 1E-4*( A4s *ON_A4S + A4r *ON_A4R * TGAUSS(GCUTR)), |
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203 | 1E-4*(-A5s *ON_A5S + A5r *ON_A5R * TGAUSS(GCUTR)), |
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204 | 1E-4*( A6s *ON_A6S + A6r *ON_A6R * TGAUSS(GCUTR)), |
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205 | 1E-4*(-A7s *ON_A7S + A7r *ON_A7R * TGAUSS(GCUTR)), |
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206 | 1E-4*( A8s *ON_A8S + A8r *ON_A8R * TGAUSS(GCUTR)), |
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207 | 1E-4*(-A9s *ON_A9S + A9r *ON_A9R * TGAUSS(GCUTR)), |
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208 | 1E-4*( A10s *ON_A10S + A10r *ON_A10R * TGAUSS(GCUTR)), |
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209 | 1E-4*(-A11s *ON_A11S + A11r *ON_A11R * TGAUSS(GCUTR))}; |
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210 | } |
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211 | |
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212 | SetEfcomp_Binv: macro = { |
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213 | Efcomp, radius = Rr, order= 0, |
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214 | dknr:= {1E-4*( B1s *ON_B1S + B1r *ON_B1R * TGAUSS(GCUTR)), |
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215 | -1E-4*(-B2s *ON_B2S + B2r *ON_B2R * TGAUSS(GCUTR)), |
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216 | 1E-4*( B3s *ON_B3S + B3r *ON_B3R * TGAUSS(GCUTR)), |
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217 | -1E-4*(-B4s *ON_B4S + B4r *ON_B4R * TGAUSS(GCUTR)), |
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218 | 1E-4*( B5s *ON_B5S + B5r *ON_B5R * TGAUSS(GCUTR)), |
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219 | -1E-4*(-B6s *ON_B6S + B6r *ON_B6R * TGAUSS(GCUTR)), |
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220 | 1E-4*( B7s *ON_B7S + B7r *ON_B7R * TGAUSS(GCUTR)), |
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221 | -1E-4*(-B8s *ON_B8S + B8r *ON_B8R * TGAUSS(GCUTR)), |
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222 | 1E-4*( B9s *ON_B9S + B9r *ON_B9R * TGAUSS(GCUTR)), |
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223 | -1E-4*(-B10s *ON_B10S + B10r *ON_B10R * TGAUSS(GCUTR)), |
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224 | 1E-4*( B11s *ON_B11S + B11r *ON_B11R * TGAUSS(GCUTR))}, |
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225 | dksr:={-1E-4*(-A1s *ON_A1S + A1r *ON_A1R * TGAUSS(GCUTR)), |
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226 | 1E-4*( A2s *ON_A2S + A2r *ON_A2R * TGAUSS(GCUTR)), |
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227 | -1E-4*(-A3s *ON_A3S + A3r *ON_A3R * TGAUSS(GCUTR)), |
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228 | 1E-4*( A4s *ON_A4S + A4r *ON_A4R * TGAUSS(GCUTR)), |
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229 | -1E-4*(-A5s *ON_A5S + A5r *ON_A5R * TGAUSS(GCUTR)), |
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230 | 1E-4*( A6s *ON_A6S + A6r *ON_A6R * TGAUSS(GCUTR)), |
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231 | -1E-4*(-A7s *ON_A7S + A7r *ON_A7R * TGAUSS(GCUTR)), |
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232 | 1E-4*( A8s *ON_A8S + A8r *ON_A8R * TGAUSS(GCUTR)), |
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233 | -1E-4*(-A9s *ON_A9S + A9r *ON_A9R * TGAUSS(GCUTR)), |
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234 | 1E-4*( A10s *ON_A10S + A10r *ON_A10R * TGAUSS(GCUTR)), |
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235 | -1E-4*(-A11s *ON_A11S + A11r *ON_A11R * TGAUSS(GCUTR))}; |
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236 | } |
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237 | |
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238 | SetEfcomp_ABS: macro = { |
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239 | Efcomp, radius = Rr, order= 0, |
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240 | dkn:={1E-4*alpha* 1/Rr^0/ml *( B1s * ON_B1S + B1r * ON_B1R * TGAUSS(GCUTR)), |
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241 | 1E-4*alpha* 1/Rr^1/ml *(-B2s * ON_B2S + B2r * ON_B2R * TGAUSS(GCUTR)), |
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242 | 1E-4*alpha* 2/Rr^2/ml *( B3s * ON_B3S + B3r * ON_B3R * TGAUSS(GCUTR)), |
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243 | 1E-4*alpha* 6/Rr^3/ml *(-B4s * ON_B4S + B4r * ON_B4R * TGAUSS(GCUTR)), |
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244 | 1E-4*alpha* 24/Rr^4/ml *( B5s * ON_B5S + B5r * ON_B5R * TGAUSS(GCUTR)), |
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245 | 1E-4*alpha* 120/Rr^5/ml *(-B6s * ON_B6S + B6r * ON_B6R * TGAUSS(GCUTR)), |
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246 | 1E-4*alpha* 720/Rr^6/ml *( B7s * ON_B7S + B7r * ON_B7R * TGAUSS(GCUTR)), |
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247 | 1E-4*alpha* 5040/Rr^7/ml *(-B8s * ON_B8S + B8r * ON_B8R * TGAUSS(GCUTR)), |
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248 | 1E-4*alpha* 40320/Rr^8/ml *( B9s * ON_B9S + B9r * ON_B9R * TGAUSS(GCUTR)), |
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249 | 1E-4*alpha* 362880/Rr^9/ml *(-B10s *ON_B10S + B10r *ON_B10R * TGAUSS(GCUTR)), |
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250 | 1E-4*alpha*3628800/Rr^10/ml*( B11s *ON_B11S + B11r *ON_B11R * TGAUSS(GCUTR))}, |
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251 | dks:={1E-4*alpha* 1/Rr^0/ml *(-A1s * ON_A1S + A1r * ON_A1R * TGAUSS(GCUTR)), |
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252 | 1E-4*alpha* 1/Rr^1/ml *( A2s * ON_A2S + A2r * ON_A2R * TGAUSS(GCUTR)), |
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253 | 1E-4*alpha* 2/Rr^2/ml *(-A3s * ON_A3S + A3r * ON_A3R * TGAUSS(GCUTR)), |
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254 | 1E-4*alpha* 6/Rr^3/ml *( A4s * ON_A4S + A4r * ON_A4R * TGAUSS(GCUTR)), |
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255 | 1E-4*alpha* 24/Rr^4/ml *(-A5s * ON_A5S + A5r * ON_A5R * TGAUSS(GCUTR)), |
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256 | 1E-4*alpha* 120/Rr^5/ml *( A6s * ON_A6S + A6r * ON_A6R * TGAUSS(GCUTR)), |
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257 | 1E-4*alpha* 720/Rr^6/ml *(-A7s * ON_A7S + A7r * ON_A7R * TGAUSS(GCUTR)), |
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258 | 1E-4*alpha* 5040/Rr^7/ml *( A8s * ON_A8S + A8r * ON_A8R * TGAUSS(GCUTR)), |
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259 | 1E-4*alpha* 40320/Rr^8/ml *(-A9s * ON_A9S + A9r * ON_A9R * TGAUSS(GCUTR)), |
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260 | 1E-4*alpha* 362880/Rr^9/ml *( A10s *ON_A10S + A10r *ON_A10R * TGAUSS(GCUTR)), |
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261 | 1E-4*alpha*3628800/Rr^10/ml*(-A11s *ON_A11S + A11r *ON_A11R * TGAUSS(GCUTR))}; |
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262 | } |
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263 | |
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264 | |
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265 | SetEfcomp_Qinv: macro = { |
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266 | Efcomp, radius = Rr, order= 1, |
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267 | dknr:={0, |
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268 | 1E-4*( B2s *ON_B2S + B2r *ON_B2R * TGAUSS(GCUTR)), |
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269 | -1E-4*(-B3s *ON_B3S + B3r *ON_B3R * TGAUSS(GCUTR)), |
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270 | 1E-4*( B4s *ON_B4S + B4r *ON_B4R * TGAUSS(GCUTR)), |
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271 | -1E-4*(-B5s *ON_B5S + B5r *ON_B5R * TGAUSS(GCUTR)), |
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272 | 1E-4*( B6s *ON_B6S + B6r *ON_B6R * TGAUSS(GCUTR)), |
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273 | -1E-4*(-B7s *ON_B7S + B7r *ON_B7R * TGAUSS(GCUTR)), |
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274 | 1E-4*( B8s *ON_B8S + B8r *ON_B8R * TGAUSS(GCUTR)), |
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275 | -1E-4*(-B9s *ON_B9S + B9r *ON_B9R * TGAUSS(GCUTR)), |
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276 | 1E-4*( B10s *ON_B10S + B10r *ON_B10R * TGAUSS(GCUTR)), |
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277 | -1E-4*(-B11s *ON_B11S + B11r *ON_B11R * TGAUSS(GCUTR))}, |
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278 | dksr:={0, |
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279 | -1E-4*(-A2s *ON_A2S + A2r *ON_A2R * TGAUSS(GCUTR)), |
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280 | 1E-4*( A3s *ON_A3S + A3r *ON_A3R * TGAUSS(GCUTR)), |
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281 | -1E-4*(-A4s *ON_A4S + A4r *ON_A4R * TGAUSS(GCUTR)), |
---|
282 | 1E-4*( A5s *ON_A5S + A5r *ON_A5R * TGAUSS(GCUTR)), |
---|
283 | -1E-4*(-A6s *ON_A6S + A6r *ON_A6R * TGAUSS(GCUTR)), |
---|
284 | 1E-4*( A7s *ON_A7S + A7r *ON_A7R * TGAUSS(GCUTR)), |
---|
285 | -1E-4*(-A8s *ON_A8S + A8r *ON_A8R * TGAUSS(GCUTR)), |
---|
286 | 1E-4*( A9s *ON_A9S + A9r *ON_A9R * TGAUSS(GCUTR)), |
---|
287 | -1E-4*(-A10s *ON_A10S + A10r *ON_A10R * TGAUSS(GCUTR)), |
---|
288 | 1E-4*( A11s *ON_A11S + A11r *ON_A11R * TGAUSS(GCUTR))}; |
---|
289 | } |
---|
290 | |
---|
291 | SetEfcomp_Q: macro = { |
---|
292 | Efcomp, radius = Rr, order= 1, |
---|
293 | dknr:={0, |
---|
294 | 1E-4*( B2s *ON_B2S + B2r *ON_B2R * TGAUSS(GCUTR)), |
---|
295 | 1E-4*(-B3s *ON_B3S + B3r *ON_B3R * TGAUSS(GCUTR)), |
---|
296 | 1E-4*( B4s *ON_B4S + B4r *ON_B4R * TGAUSS(GCUTR)), |
---|
297 | 1E-4*(-B5s *ON_B5S + B5r *ON_B5R * TGAUSS(GCUTR)), |
---|
298 | 1E-4*( B6s *ON_B6S + B6r *ON_B6R * TGAUSS(GCUTR)), |
---|
299 | 1E-4*(-B7s *ON_B7S + B7r *ON_B7R * TGAUSS(GCUTR)), |
---|
300 | 1E-4*( B8s *ON_B8S + B8r *ON_B8R * TGAUSS(GCUTR)), |
---|
301 | 1E-4*(-B9s *ON_B9S + B9r *ON_B9R * TGAUSS(GCUTR)), |
---|
302 | 1E-4*( B10s *ON_B10S + B10r *ON_B10R * TGAUSS(GCUTR)), |
---|
303 | 1E-4*(-B11s *ON_B11S + B11r *ON_B11R * TGAUSS(GCUTR))}, |
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304 | dksr:={0, |
---|
305 | 1E-4*(-A2s *ON_A2S + A2r *ON_A2R * TGAUSS(GCUTR)), |
---|
306 | 1E-4*( A3s *ON_A3S + A3r *ON_A3R * TGAUSS(GCUTR)), |
---|
307 | 1E-4*(-A4s *ON_A4S + A4r *ON_A4R * TGAUSS(GCUTR)), |
---|
308 | 1E-4*( A5s *ON_A5S + A5r *ON_A5R * TGAUSS(GCUTR)), |
---|
309 | 1E-4*(-A6s *ON_A6S + A6r *ON_A6R * TGAUSS(GCUTR)), |
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310 | 1E-4*( A7s *ON_A7S + A7r *ON_A7R * TGAUSS(GCUTR)), |
---|
311 | 1E-4*(-A8s *ON_A8S + A8r *ON_A8R * TGAUSS(GCUTR)), |
---|
312 | 1E-4*( A9s *ON_A9S + A9r *ON_A9R * TGAUSS(GCUTR)), |
---|
313 | 1E-4*(-A10s *ON_A10S + A10r *ON_A10R * TGAUSS(GCUTR)), |
---|
314 | 1E-4*( A11s *ON_A11S + A11r *ON_A11R * TGAUSS(GCUTR))}; |
---|
315 | } |
---|
316 | |
---|
317 | |
---|
318 | New_Magnet: macro = { |
---|
319 | B1rr = B1r *TGAUSS(GCUTR); |
---|
320 | B2rr = B2r *TGAUSS(GCUTR); |
---|
321 | B3rr = B3r *TGAUSS(GCUTR); |
---|
322 | B4rr = B4r *TGAUSS(GCUTR); |
---|
323 | B5rr = B5r *TGAUSS(GCUTR); |
---|
324 | B6rr = B6r *TGAUSS(GCUTR); |
---|
325 | B7rr = B7r *TGAUSS(GCUTR); |
---|
326 | B8rr = B8r *TGAUSS(GCUTR); |
---|
327 | B9rr = B9r *TGAUSS(GCUTR); |
---|
328 | B10rr = B10r*TGAUSS(GCUTR); |
---|
329 | B11rr = B11r*TGAUSS(GCUTR); |
---|
330 | |
---|
331 | A1rr = A1r *TGAUSS(GCUTR); |
---|
332 | A2rr = A2r *TGAUSS(GCUTR); |
---|
333 | A3rr = A3r *TGAUSS(GCUTR); |
---|
334 | A4rr = A4r *TGAUSS(GCUTR); |
---|
335 | A5rr = A5r *TGAUSS(GCUTR); |
---|
336 | A6rr = A6r *TGAUSS(GCUTR); |
---|
337 | A7rr = A7r *TGAUSS(GCUTR); |
---|
338 | A8rr = A8r *TGAUSS(GCUTR); |
---|
339 | A9rr = A9r *TGAUSS(GCUTR); |
---|
340 | A10rr = A10r*TGAUSS(GCUTR); |
---|
341 | A11rr = A11r*TGAUSS(GCUTR); |
---|
342 | } |
---|
343 | |
---|
344 | New_Quad: macro = { |
---|
345 | B2rr = B2r *TGAUSS(GCUTR); |
---|
346 | B3rr = B3r *TGAUSS(GCUTR); |
---|
347 | B4rr = B4r *TGAUSS(GCUTR); |
---|
348 | B5rr = B5r *TGAUSS(GCUTR); |
---|
349 | B6rr = B6r *TGAUSS(GCUTR); |
---|
350 | B7rr = B7r *TGAUSS(GCUTR); |
---|
351 | B8rr = B8r *TGAUSS(GCUTR); |
---|
352 | B9rr = B9r *TGAUSS(GCUTR); |
---|
353 | B10rr = B10r*TGAUSS(GCUTR); |
---|
354 | B11rr = B11r*TGAUSS(GCUTR); |
---|
355 | |
---|
356 | A2rr = A2r *TGAUSS(GCUTR); |
---|
357 | A3rr = A3r *TGAUSS(GCUTR); |
---|
358 | A4rr = A4r *TGAUSS(GCUTR); |
---|
359 | A5rr = A5r *TGAUSS(GCUTR); |
---|
360 | A6rr = A6r *TGAUSS(GCUTR); |
---|
361 | A7rr = A7r *TGAUSS(GCUTR); |
---|
362 | A8rr = A8r *TGAUSS(GCUTR); |
---|
363 | A9rr = A9r *TGAUSS(GCUTR); |
---|
364 | A10rr = A10r*TGAUSS(GCUTR); |
---|
365 | A11rr = A11r*TGAUSS(GCUTR); |
---|
366 | } |
---|
367 | |
---|
368 | |
---|
369 | SetEfcomp_B_Slice: macro = { |
---|
370 | Efcomp, radius = Rr, order= 0, |
---|
371 | dknr:={1E-4*( B1s *ON_B1S + B1rr *ON_B1R ), |
---|
372 | 1E-4*(-B2s *ON_B2S + B2rr *ON_B2R ), |
---|
373 | 1E-4*( B3s *ON_B3S + B3rr *ON_B3R ), |
---|
374 | 1E-4*(-B4s *ON_B4S + B4rr *ON_B4R ), |
---|
375 | 1E-4*( B5s *ON_B5S + B5rr *ON_B5R ), |
---|
376 | 1E-4*(-B6s *ON_B6S + B6rr *ON_B6R ), |
---|
377 | 1E-4*( B7s *ON_B7S + B7rr *ON_B7R ), |
---|
378 | 1E-4*(-B8s *ON_B8S + B8rr *ON_B8R ), |
---|
379 | 1E-4*( B9s *ON_B9S + B9rr *ON_B9R ), |
---|
380 | 1E-4*(-B10s *ON_B10S + B10rr *ON_B10R ), |
---|
381 | 1E-4*( B11s *ON_B11S + B11rr *ON_B11R )}, |
---|
382 | dksr:={1E-4*(-A1s *ON_A1S + A1rr *ON_A1R ), |
---|
383 | 1E-4*( A2s *ON_A2S + A2rr *ON_A2R ), |
---|
384 | 1E-4*(-A3s *ON_A3S + A3rr *ON_A3R ), |
---|
385 | 1E-4*( A4s *ON_A4S + A4rr *ON_A4R ), |
---|
386 | 1E-4*(-A5s *ON_A5S + A5rr *ON_A5R ), |
---|
387 | 1E-4*( A6s *ON_A6S + A6rr *ON_A6R ), |
---|
388 | 1E-4*(-A7s *ON_A7S + A7rr *ON_A7R ), |
---|
389 | 1E-4*( A8s *ON_A8S + A8rr *ON_A8R ), |
---|
390 | 1E-4*(-A9s *ON_A9S + A9rr *ON_A9R ), |
---|
391 | 1E-4*( A10s *ON_A10S + A10rr *ON_A10R ), |
---|
392 | 1E-4*(-A11s *ON_A11S + A11rr *ON_A11R )}; |
---|
393 | } |
---|
394 | |
---|
395 | |
---|
396 | |
---|
397 | SetEfcomp_Binv_Slice: macro = { |
---|
398 | Efcomp, radius = Rr, order= 0, |
---|
399 | dknr:= {1E-4*( B1s *ON_B1S + B1rr *ON_B1R ), |
---|
400 | -1E-4*(-B2s *ON_B2S + B2rr *ON_B2R ), |
---|
401 | 1E-4*( B3s *ON_B3S + B3rr *ON_B3R ), |
---|
402 | -1E-4*(-B4s *ON_B4S + B4rr *ON_B4R ), |
---|
403 | 1E-4*( B5s *ON_B5S + B5rr *ON_B5R ), |
---|
404 | -1E-4*(-B6s *ON_B6S + B6rr *ON_B6R ), |
---|
405 | 1E-4*( B7s *ON_B7S + B7rr *ON_B7R ), |
---|
406 | -1E-4*(-B8s *ON_B8S + B8rr *ON_B8R ), |
---|
407 | 1E-4*( B9s *ON_B9S + B9rr *ON_B9R ), |
---|
408 | -1E-4*(-B10s *ON_B10S + B10rr *ON_B10R ), |
---|
409 | 1E-4*( B11s *ON_B11S + B11rr *ON_B11R )}, |
---|
410 | dksr:={-1E-4*(-A1s *ON_A1S + A1rr *ON_A1R ), |
---|
411 | 1E-4*( A2s *ON_A2S + A2rr *ON_A2R ), |
---|
412 | -1E-4*(-A3s *ON_A3S + A3rr *ON_A3R ), |
---|
413 | 1E-4*( A4s *ON_A4S + A4rr *ON_A4R ), |
---|
414 | -1E-4*(-A5s *ON_A5S + A5rr *ON_A5R ), |
---|
415 | 1E-4*( A6s *ON_A6S + A6rr *ON_A6R ), |
---|
416 | -1E-4*(-A7s *ON_A7S + A7rr *ON_A7R ), |
---|
417 | 1E-4*( A8s *ON_A8S + A8rr *ON_A8R ), |
---|
418 | -1E-4*(-A9s *ON_A9S + A9rr *ON_A9R ), |
---|
419 | 1E-4*( A10s *ON_A10S + A10rr *ON_A10R ), |
---|
420 | -1E-4*(-A11s *ON_A11S + A11rr *ON_A11R )}; |
---|
421 | } |
---|
422 | |
---|
423 | |
---|
424 | |
---|
425 | SetEfcomp_Q_Slice: macro = { |
---|
426 | Efcomp, radius = Rr, order= 1, |
---|
427 | dknr:={0, |
---|
428 | 1E-4*( B2s *ON_B2S + B2rr *ON_B2R ), |
---|
429 | 1E-4*(-B3s *ON_B3S + B3rr *ON_B3R ), |
---|
430 | 1E-4*( B4s *ON_B4S + B4rr *ON_B4R ), |
---|
431 | 1E-4*(-B5s *ON_B5S + B5rr *ON_B5R ), |
---|
432 | 1E-4*( B6s *ON_B6S + B6rr *ON_B6R ), |
---|
433 | 1E-4*(-B7s *ON_B7S + B7rr *ON_B7R ), |
---|
434 | 1E-4*( B8s *ON_B8S + B8rr *ON_B8R ), |
---|
435 | 1E-4*(-B9s *ON_B9S + B9rr *ON_B9R ), |
---|
436 | 1E-4*( B10s*ON_B10S + B10rr*ON_B10R), |
---|
437 | 1E-4*(-B11s*ON_B11S + B11rr*ON_B11R)}, |
---|
438 | dksr:={0, |
---|
439 | 1E-4*(-A2s *ON_A2S + A2rr *ON_A2R ), |
---|
440 | 1E-4*( A3s *ON_A3S + A3rr *ON_A3R ), |
---|
441 | 1E-4*(-A4s *ON_A4S + A4rr *ON_A4R ), |
---|
442 | 1E-4*( A5s *ON_A5S + A5rr *ON_A5R ), |
---|
443 | 1E-4*(-A6s *ON_A6S + A6rr *ON_A6R ), |
---|
444 | 1E-4*( A7s *ON_A7S + A7rr *ON_A7R ), |
---|
445 | 1E-4*(-A8s *ON_A8S + A8rr *ON_A8R ), |
---|
446 | 1E-4*( A9s *ON_A9S + A9rr *ON_A9R ), |
---|
447 | 1E-4*(-A10s*ON_A10S + A10rr*ON_A10R), |
---|
448 | 1E-4*( A11s*ON_A11S + A11rr*ON_A11R)}; |
---|
449 | } |
---|
450 | |
---|
451 | SetEfcomp_Qinv_Slice: macro = { |
---|
452 | Efcomp, radius = Rr, order= 1, |
---|
453 | dknr:={0, |
---|
454 | 1E-4*( B2s *ON_B2S + B2rr *ON_B2R ), |
---|
455 | -1E-4*(-B3s *ON_B3S + B3rr *ON_B3R ), |
---|
456 | 1E-4*( B4s *ON_B4S + B4rr *ON_B4R ), |
---|
457 | -1E-4*(-B5s *ON_B5S + B5rr *ON_B5R ), |
---|
458 | 1E-4*( B6s *ON_B6S + B6rr *ON_B6R ), |
---|
459 | -1E-4*(-B7s *ON_B7S + B7rr *ON_B7R ), |
---|
460 | 1E-4*( B8s *ON_B8S + B8rr *ON_B8R ), |
---|
461 | -1E-4*(-B9s *ON_B9S + B9rr *ON_B9R ), |
---|
462 | 1E-4*( B10s*ON_B10S + B10rr*ON_B10R), |
---|
463 | -1E-4*(-B11s*ON_B11S + B11rr*ON_B11R)}, |
---|
464 | dksr:={0, |
---|
465 | -1E-4*(-A2s *ON_A2S + A2rr *ON_A2R ), |
---|
466 | 1E-4*( A3s *ON_A3S + A3rr *ON_A3R ), |
---|
467 | -1E-4*(-A4s *ON_A4S + A4rr *ON_A4R ), |
---|
468 | 1E-4*( A5s *ON_A5S + A5rr *ON_A5R ), |
---|
469 | -1E-4*(-A6s *ON_A6S + A6rr *ON_A6R ), |
---|
470 | 1E-4*( A7s *ON_A7S + A7rr *ON_A7R ), |
---|
471 | -1E-4*(-A8s *ON_A8S + A8rr *ON_A8R ), |
---|
472 | 1E-4*( A9s *ON_A9S + A9rr *ON_A9R ), |
---|
473 | -1E-4*(-A10s*ON_A10S + A10rr*ON_A10R), |
---|
474 | 1E-4*( A11s*ON_A11S + A11rr*ON_A11R)}; |
---|
475 | } |
---|
476 | |
---|
477 | SetEfcomp_Q_Slice_Srot: macro = { |
---|
478 | Efcomp, radius = Rr, order= 1, |
---|
479 | dknr:={0, |
---|
480 | 1E-4*( B2s *ON_B2S + B2rr *ON_B2R ), |
---|
481 | -1E-4*(-B3s *ON_B3S + B3rr *ON_B3R ), |
---|
482 | 1E-4*( B4s *ON_B4S + B4rr *ON_B4R ), |
---|
483 | -1E-4*(-B5s *ON_B5S + B5rr *ON_B5R ), |
---|
484 | 1E-4*( B6s *ON_B6S + B6rr *ON_B6R ), |
---|
485 | -1E-4*(-B7s *ON_B7S + B7rr *ON_B7R ), |
---|
486 | 1E-4*( B8s *ON_B8S + B8rr *ON_B8R ), |
---|
487 | -1E-4*(-B9s *ON_B9S + B9rr *ON_B9R ), |
---|
488 | 1E-4*( B10s*ON_B10S + B10rr*ON_B10R), |
---|
489 | -1E-4*(-B11s*ON_B11S + B11rr*ON_B11R)}, |
---|
490 | dksr:={0, |
---|
491 | 1E-4*(-A2s *ON_A2S + A2rr *ON_A2R ), |
---|
492 | -1E-4*( A3s *ON_A3S + A3rr *ON_A3R ), |
---|
493 | 1E-4*(-A4s *ON_A4S + A4rr *ON_A4R ), |
---|
494 | -1E-4*( A5s *ON_A5S + A5rr *ON_A5R ), |
---|
495 | 1E-4*(-A6s *ON_A6S + A6rr *ON_A6R ), |
---|
496 | -1E-4*( A7s *ON_A7S + A7rr *ON_A7R ), |
---|
497 | 1E-4*(-A8s *ON_A8S + A8rr *ON_A8R ), |
---|
498 | -1E-4*( A9s *ON_A9S + A9rr *ON_A9R ), |
---|
499 | 1E-4*(-A10s*ON_A10S + A10rr*ON_A10R), |
---|
500 | -1E-4*( A11s*ON_A11S + A11rr*ON_A11R)}; |
---|
501 | } |
---|
502 | |
---|
503 | SetEfcomp_Qinv_Slice_Srot: macro = { |
---|
504 | Efcomp, radius = Rr, order= 1, |
---|
505 | dknr:={0, |
---|
506 | 1E-4*( B2s *ON_B2S + B2rr *ON_B2R ), |
---|
507 | 1E-4*(-B3s *ON_B3S + B3rr *ON_B3R ), |
---|
508 | 1E-4*( B4s *ON_B4S + B4rr *ON_B4R ), |
---|
509 | 1E-4*(-B5s *ON_B5S + B5rr *ON_B5R ), |
---|
510 | 1E-4*( B6s *ON_B6S + B6rr *ON_B6R ), |
---|
511 | 1E-4*(-B7s *ON_B7S + B7rr *ON_B7R ), |
---|
512 | 1E-4*( B8s *ON_B8S + B8rr *ON_B8R ), |
---|
513 | 1E-4*(-B9s *ON_B9S + B9rr *ON_B9R ), |
---|
514 | 1E-4*( B10s*ON_B10S + B10rr*ON_B10R), |
---|
515 | 1E-4*(-B11s*ON_B11S + B11rr*ON_B11R)}, |
---|
516 | dksr:={0, |
---|
517 | -1E-4*(-A2s *ON_A2S + A2rr *ON_A2R ), |
---|
518 | -1E-4*( A3s *ON_A3S + A3rr *ON_A3R ), |
---|
519 | -1E-4*(-A4s *ON_A4S + A4rr *ON_A4R ), |
---|
520 | -1E-4*( A5s *ON_A5S + A5rr *ON_A5R ), |
---|
521 | -1E-4*(-A6s *ON_A6S + A6rr *ON_A6R ), |
---|
522 | -1E-4*( A7s *ON_A7S + A7rr *ON_A7R ), |
---|
523 | -1E-4*(-A8s *ON_A8S + A8rr *ON_A8R ), |
---|
524 | -1E-4*( A9s *ON_A9S + A9rr *ON_A9R ), |
---|
525 | -1E-4*(-A10s*ON_A10S + A10rr*ON_A10R), |
---|
526 | -1E-4*( A11s*ON_A11S + A11rr*ON_A11R)}; |
---|
527 | } |
---|
528 | |
---|
529 | Return; |
---|