13
by plane1
Changed directory names for HPRF cavities to the acronyms now used in the dissertation (i.e., HC and DLHC) |
1 |
Los Alamos National Laboratory Poisson Superfish
|
2 |
Program SFO written by James H. Billen and Lloyd M. Young
|
|
3 |
||
4 |
The original Poisson Superfish codes were developed |
|
5 |
by Ron F. Holsinger in collaboration with Klaus Halbach. |
|
6 |
These programs are provided as a service to the accelerator |
|
7 |
community by the Los Alamos Accelerator Code Group (LAACG). |
|
8 |
||
9 |
(c) Copyright 1985-2005, by the Regents of the University of California. |
|
10 |
This software was produced under U. S. Government contract W-7405-ENG-36 |
|
11 |
by Los Alamos National Laboratory, which is operated by the University |
|
12 |
of California for the U. S. Department of Energy. Neither the Government |
|
13 |
nor the University makes any warranty, express or implied, or assumes |
|
14 |
any liability or responsibility for its use, or represents that use of |
|
15 |
this software would not infringe privately owned rights. |
|
16 |
Unpublished - rights reserved under Copyright Laws of the United States. |
|
17 |
||
18 |
||
19 |
Program SFO 7.17 released 1-13-2006 |
|
20 |
||
21 |
Solution file C:\Users\plane\Documents\Superfish\HPRF_ELECTRODE_ATMOSPHERIC.T35. |
|
22 |
More input from file C:\Users\plane\Documents\Superfish\HPRF_ELECTRODE_ATMOSPHERIC.SEG. |
|
23 |
Program file: C:\LANL\AUTOFISH.EXE |
|
24 |
SF.INI file: C:\LANL\SF.INI 12-29-2014 9:59:06 |
|
25 |
Memory used for HPRF_ELECTRODE_ATMOSPHERIC.T35 arrays: 109.296 K |
|
26 |
||
27 |
Problem description: |
|
28 |
HPRF Cavity with electrodes at atmospheric pressure |
|
29 |
Problem file: C:\USERS\PLANE\DOCUMENTS\SUPERFISH\HPRF_ELECTRODE_ATMOSPHERIC.AM 6-05-2015 15:23:36 |
|
30 |
Problem file length: 604 bytes |
|
31 |
Originating program: Autofish Problem type: Unknown RF Cavity |
|
32 |
||
33 |
Coordinates and lengths have dimensions of centimeters. |
|
34 |
||
35 |
Problem constants and variables. |
|
36 |
Letter A in the code column indicates a value supplied in the |
|
37 |
Automesh input file. |
|
38 |
Letter S in the code column indicates a value supplied in the |
|
39 |
SFO input file. |
|
40 |
||
41 |
Variable Code Value Description |
|
42 |
ALPHAT 3.930000000E-03 Temperature coefficient of resistance |
|
43 |
ASCALE 3767.30313 Scaling factor for H at drive point |
|
44 |
BETA 0.0 Particle velocity |
|
45 |
BETA1 0.100000000 Starting BETA in transit-time table |
|
46 |
BETA2 0.950000000 Ending BETA in transit-time table |
|
47 |
CCLDELK 1.00000000 Increment for coupling for table in SFO |
|
48 |
CCLMAXK 6.00000000 Highest coupling for table in SFO |
|
49 |
CCLMINK 1.00000000 Lowest coupling for table in SFO |
|
50 |
CLENGTH 0.0 Cavity length for normalization in SFO |
|
51 |
CLIGHT 2.997924580E+10 Exact speed of light in cm/sec |
|
52 |
CONV 1.00000000 Length conversion (number of units per cm) |
|
53 |
DBETA 5.000000000E-02 BETA increment in transit-time table |
|
54 |
DELFR 0.0 Frequency step size for a resonance search |
|
55 |
DIAGDLL 0 If 1, DLL writes diagnostics to DiagDLL.txt |
|
56 |
DKSQ -1.419710145E-08 Change in k^2 after an iteration in Fish |
|
57 |
DPHI S 100.000000 Phase length of the problem geometry |
|
58 |
DSLOPE -1.04400404 Slope of D(k^2) function |
|
59 |
DSTOLER 2.000000000E-02 Tolerance required on D(k^2) |
|
60 |
DX1 0.198243902 First X mesh interval (at XMIN) |
|
61 |
DXMIN 0.198243902 Minimum X mesh interval (found by Automesh) |
|
62 |
DYMIN 0.173181818 Minimum Y mesh interval (found by Automesh) |
|
63 |
ENORM 1000000.00 Field normalization for NORM=4 option |
|
64 |
EPS0 8.854187818E-12 Permittivity of free space |
|
65 |
EPSIK 1.000000000E-04 Frequency convergence parameter |
|
66 |
EPSO 1.000000000E-05 Convergence parameter in mesh optimization |
|
67 |
ERG 443.123594 Integral (H^2 r dr dz) |
|
68 |
EZERO 1000000.00 E0 for normalization in SFO when NORM=0 |
|
69 |
EZEROT S 20000000.0 E0*T for normalization in SFO when NORM=1 |
|
70 |
FMU0 1.256637061E-06 Permeability of free space |
|
71 |
FREQ 809.395083 RF cavity resonant frequency |
|
72 |
FREQD 0.0 Design frequency for a cavity (MHz) |
|
73 |
HPHI 5000.00000 Normalization magnetic field for NORM=2 |
|
74 |
IBETA 0 If >0, SFO writes transit-time vs BETA |
|
75 |
ICCC 1 1 for real arrays, 2 for complex arrays |
|
76 |
ICCP 1 If 1, compute material power loss |
|
77 |
ICORNER1 0 First corner segment for computing average H |
|
78 |
ICORNER2 0 Last corner segment for computing average H |
|
79 |
ICYCLE 3 Present iteration number |
|
80 |
ICYLIN A 1 0 for X,Y problems, 1 for Z,R problems |
|
81 |
IMAX 44 KMAX+2 |
|
82 |
INFODATA 0 Number of tuning-code parameters |
|
83 |
IOBSEG -1 First segment of the CCL outer boundary |
|
84 |
IPIVOT 1 Pivoting in matrix inversion routines |
|
85 |
IRESID 0 If 1, calculate potential residuals |
|
86 |
IRMAX 25 Used in optimization of RHOXY |
|
87 |
IRTYPE 0 Surface resistance option indicator |
|
88 |
ISLOT 0 If 1, SFO computes coupling-slot power loss |
|
89 |
ITFILE 0 If 1, SFO writes transit-time plot file |
|
90 |
ITOT 3036 (KMAX+2)*(LMAX+2) |
|
91 |
KDRI 1 K coordinate of the drive point |
|
92 |
KMAX 42 Number of horizontal logical mesh points |
|
93 |
KMETHOD 0 Wavenumber computation method (1= use beta) |
|
94 |
KPROB A 1 Problem type indicator (Superfish) |
|
95 |
LAST35 1 Code for last program to update T35 file |
|
96 |
LCYCLE 73 Iteration number in mesh optimization |
|
97 |
LDRI 36 L coordinate of the drive point |
|
98 |
LINT 1 Logical-mesh coordinate for Ez integration |
|
99 |
LMAX 67 Number of vertical logical mesh points |
|
100 |
MAXCY 19 Maximum number of cycles (-1: use default) |
|
101 |
MAXPPR 204 Maximum points per region |
|
102 |
METHOD 2 Method used to get frequency in root finder |
|
103 |
NAIR 2410 Number of air points |
|
104 |
NBND 10 Number of Dirichlet boundary points |
|
105 |
NBSLF 1 Left-side boundary condition |
|
106 |
NBSLO 0 Lower boundary condition |
|
107 |
NBSRT 1 Right-side boundary condition |
|
108 |
NBSUP 1 Upper boundary condition |
|
109 |
NDRI 1586 Drive point index = IRLAX(NPINP) |
|
110 |
NEGAT 0 Zero-area triangle indicator |
|
111 |
NFE 0 Number of iron points |
|
112 |
NHSTEM 1 Number of half stems |
|
113 |
NINTER 0 Number of interface points |
|
114 |
NMATR 0 Number of material records in T35 file |
|
115 |
NORM S 1 Normalization method in SFO |
|
116 |
NPBOUND 203 Total number of boundary points in the mesh |
|
117 |
NPINP 2421 Total points in problem |
|
118 |
NPONTS 2219 Number of unknown relaxation points |
|
119 |
NREG 2 Number of regions |
|
120 |
NRMSEG 1 Normalization segment number for NORM=2 |
|
121 |
NSEG 8 Number of boundary segments |
|
122 |
NSPL 1 Number of special-potential points |
|
123 |
NSTEP 0 Number of steps for a resonance search |
|
124 |
OMEGAM 1.000000000E-03 Used in optimization of RHOXY |
|
125 |
PI 3.14159265 The number pi to machine precision |
|
126 |
PLCELL 360.000000 Phase length per cell for multicell problems |
|
127 |
Q2I 0.0 1/2Q passed from CFish to SFO |
|
128 |
RESIDR 1.000000000E-08 Residual resistance of a superconductor |
|
129 |
RESIK 4.933851847E-07 Residual = DKSQ/XKSQ |
|
130 |
RFMU 1.00000000 Permeability for rf surface resistance |
|
131 |
RHO 1.724100000E-06 Material resistivity (Ohm-m) |
|
132 |
RHOR 1.724100000E-06 Reference resistivity (Ohm-cm) at TEMPR |
|
133 |
RHOXY 1.60000000 Over-relaxation factor in mesh optimization |
|
134 |
RMASS -2.00000000 Rest mass energy of particle in SFO |
|
135 |
RSTEM 1.00000000 Stem radius in cm |
|
136 |
SLOSS 3.000000000E-02 Coupling-slot power factor per % coupling |
|
137 |
TC 9.20000000 Critical temperature of a superconductor |
|
138 |
TEMPC 20.0000000 Normal conductor operating temperature |
|
139 |
TEMPK 2.00000000 Operating temperature of a superconductor |
|
140 |
TEMPR 20.0000000 Reference temperature for IRTYPE=3 |
|
141 |
TRIAVG 1.715216854E-02 Average area of all triangles |
|
142 |
TRIMAX 2.405174620E-02 Area of the largest positive-area triangle |
|
143 |
TRIMIN 7.532059290E-03 Area of the smallest positive-area triangle |
|
144 |
VOLUME 3241.70913 Cavity volume (cylindrical symmetry only) |
|
145 |
XDRI A 0.0 X coordinate of the drive point |
|
146 |
XK0 0.169636665 The wave number k = 2pif/c |
|
147 |
XKSQ 2.877659827E-02 Square of the wave number |
|
148 |
XMAXG 8.12800000 Upper X bound of the problem geometry |
|
149 |
XMING 0.0 Lower X bound of the problem geometry |
|
150 |
XNORM1 0.0 Starting X for NORM=4 integration path |
|
151 |
XNORM2 0.0 Ending X for NORM=4 integration path |
|
152 |
XYAREA 79.5517577 Total cross sectional area |
|
153 |
YDRI A 5.97000000 Y coordinate of the drive point |
|
154 |
YMAXG 11.4300000 Upper Y bound of the problem geometry |
|
155 |
YMING 0.0 Lower Y bound of the problem geometry |
|
156 |
YNORM1 0.0 Starting Y for NORM=4 integration path |
|
157 |
YNORM2 0.0 Ending Y for NORM=4 integration path |
|
158 |
ZCTR 0.0 Reference Z in transit-time integrals |
|
159 |
------------------------------------------------------------------------------- |
|
160 |
Segment numbers for field calculations |
|
161 |
[Note: negative values indicate stem segments.] |
|
162 |
1 2 3 |
|
163 |
------------------------------------------------------------------------------- |
|
164 |
No materials other than air or empty space. |
|
165 |
------------------------------------------------------------------------------- |
|
166 |
The field normalization factor ASCALE for this problem is based |
|
167 |
upon the calculated cavity length ZLONG = 1.77800000. |
|
168 |
||
169 |
Transit-time factor integrals and partial derivatives with repect to k |
|
170 |
TT = (1/V0)Int{Ez(z) cos k(z-Zc) dz} - tan(phi)(1/V0)Int{Ez(z) sin k(z-Zc) dz} |
|
171 |
TT = T - tan(phi) S |
|
172 |
T' and S' are partial derivative with respect to k. |
|
173 |
T" and S" are second partial derivatives. |
|
174 |
||
175 |
For symmetric half cells (Zs = Zc), the computations are done using |
|
176 |
integration limits Zs to Ze, but reported results correspond to a lower |
|
177 |
limit of integration equal to -Ze. |
|
178 |
||
179 |
Integrals along logical row L = 1 [R = 0.0 cm] |
|
180 |
between logical coordinates K = 17 and 25 |
|
181 |
||
182 |
Integration lower limit: Zs = 3.1750000 cm |
|
183 |
Integration upper limit: Ze = 4.9530000 cm |
|
184 |
Center of gap: Zc = 0.0000000 cm |
|
185 |
Electrical center: Zec = 0.8644785 cm |
|
186 |
Frequency for T integrals = 809.3950826 MHz |
|
187 |
Wave number: k = 2pif/c = 0.1696367 radians/cm |
|
188 |
Particle velocity: beta = 0.1728121 |
|
189 |
Structure wave number: k/beta = 0.9816250 radians/cm |
|
190 |
V0 = Int{Ez(z) dz} = 4.11078E+05 V |
|
191 |
E0 = (1/L)*Int{Ez(z) dz} = 2.31202E+07 V/m |
|
192 |
Treating the problem geometry as a single full cell: |
|
193 |
The single-cell results may not be useful for a multigap geometry. |
|
194 |
Consider supplying a CellData table in file HPRF_ELECTRODE_ATMOSPHERIC.SEG. |
|
195 |
Transit-time factor = 0.865044 (when Zc = Zec) |
|
196 |
T = -0.571828 |
|
197 |
S = -0.649087 |
|
198 |
T' = -0.439397 |
|
199 |
S' = -0.332201 |
|
200 |
T" = -0.194905 |
|
201 |
S" = -0.300416 |
|
202 |
------------------------------------------------------------------------------- |
|
203 |
Electric field along R = 0.000000 |
|
204 |
for normalization ASCALE = 31794.391004: |
|
205 |
||
206 |
Z(cm) Ez(V/m) |
|
207 |
3.17500 2.850324E+07 |
|
208 |
3.31573 2.620488E+07 |
|
209 |
3.37256 2.502003E+07 |
|
210 |
3.49739 2.359273E+07 |
|
211 |
3.57011 2.266410E+07 |
|
212 |
3.68903 2.180124E+07 |
|
213 |
3.76767 2.125620E+07 |
|
214 |
3.88424 2.081818E+07 |
|
215 |
3.96522 2.061454E+07 |
|
216 |
4.08164 2.053641E+07 |
|
217 |
4.16278 2.066172E+07 |
|
218 |
4.28152 2.094040E+07 |
|
219 |
4.36033 2.143657E+07 |
|
220 |
4.48571 2.214748E+07 |
|
221 |
4.55789 2.302097E+07 |
|
222 |
4.70042 2.445249E+07 |
|
223 |
4.75544 2.513297E+07 |
|
224 |
4.95300 2.855683E+07 |
|
225 |
Total cavity stored energy (from program Fish): 1.2460185E-01 Joules |
|
226 |
------------------------------------------------------------------------------- |
|
227 |
Power and fields on wall segment 1. K,L = 1,67 to 1,16 |
|
228 |
This segment uses surface resistance option IRTYPE = 0 |
|
229 |
Surface resistance, Rs = 7.422349E-03 Ohm calculated from: |
|
230 |
Operating temperature, TEMPC = 20.000 C |
|
231 |
Reference resistivity, RHOR = 1.724100E-06 Ohm-cm |
|
232 |
Reference temperature, TEMPR = 20.000 C |
|
233 |
Temperature coefficient, ALPHAT = 3.930000E-03 /C |
|
234 |
Relative permeability, RFMU = 1.000 |
|
235 |
||
236 |
m K L Z R H |E| |
|
237 |
(cm) (cm) (A/m) (V/m) |
|
238 |
1 1 67 0.00000 11.4300 6.4333E+03 0.0000E+00 |
|
239 |
0.00000 11.3428 6.4821E+03 3.5192E+04 |
|
240 |
2 1 66 0.00000 11.2557 6.5302E+03 7.0929E+04 |
|
241 |
0.00000 11.1685 6.5776E+03 1.0722E+05 |
|
242 |
3 1 65 0.00000 11.0814 6.6245E+03 1.4308E+05 |
|
243 |
0.00000 10.9942 6.6705E+03 1.8064E+05 |
|
244 |
4 1 64 0.00000 10.9071 6.7160E+03 2.1753E+05 |
|
245 |
0.00000 10.8199 6.7608E+03 2.5460E+05 |
|
246 |
5 1 63 0.00000 10.7327 6.8049E+03 2.9187E+05 |
|
247 |
0.00000 10.6456 6.8484E+03 3.2934E+05 |
|
248 |
6 1 62 0.00000 10.5584 6.8912E+03 3.6713E+05 |
|
249 |
0.00000 10.4713 6.9333E+03 4.0512E+05 |
|
250 |
7 1 61 0.00000 10.3841 6.9748E+03 4.4324E+05 |
|
251 |
0.00000 10.2970 7.0156E+03 4.8156E+05 |
|
252 |
8 1 60 0.00000 10.2098 7.0558E+03 5.2015E+05 |
|
253 |
0.00000 10.1226 7.0953E+03 5.5896E+05 |
|
254 |
9 1 59 0.00000 10.0355 7.1341E+03 5.9782E+05 |
|
255 |
0.00000 9.94833 7.1722E+03 6.3687E+05 |
|
256 |
10 1 58 0.00000 9.86118 7.2098E+03 6.7615E+05 |
|
257 |
0.00000 9.77402 7.2466E+03 7.1567E+05 |
|
258 |
11 1 57 0.00000 9.68686 7.2828E+03 7.5515E+05 |
|
259 |
0.00000 9.59971 7.3184E+03 7.9483E+05 |
|
260 |
12 1 56 0.00000 9.51255 7.3533E+03 8.3467E+05 |
|
261 |
0.00000 9.42539 7.3876E+03 8.7479E+05 |
|
262 |
13 1 55 0.00000 9.33824 7.4212E+03 9.1476E+05 |
|
263 |
0.00000 9.25108 7.4542E+03 9.5493E+05 |
|
264 |
14 1 54 0.00000 9.16392 7.4867E+03 9.9519E+05 |
|
265 |
0.00000 9.07676 7.5185E+03 1.0358E+06 |
|
266 |
15 1 53 0.00000 8.98961 7.5498E+03 1.0761E+06 |
|
267 |
0.00000 8.90245 7.5804E+03 1.1166E+06 |
|
268 |
16 1 52 0.00000 8.81529 7.6105E+03 1.1571E+06 |
|
269 |
0.00000 8.72814 7.6400E+03 1.1980E+06 |
|
270 |
17 1 51 0.00000 8.64098 7.6690E+03 1.2385E+06 |
|
271 |
0.00000 8.55382 7.6974E+03 1.2791E+06 |
|
272 |
18 1 50 0.00000 8.46667 7.7254E+03 1.3197E+06 |
|
273 |
0.00000 8.37951 7.7529E+03 1.3607E+06 |
|
274 |
19 1 49 0.00000 8.29235 7.7798E+03 1.4011E+06 |
|
275 |
0.00000 8.20520 7.8063E+03 1.4417E+06 |
|
276 |
20 1 48 0.00000 8.11804 7.8324E+03 1.4821E+06 |
|
277 |
0.00000 8.03088 7.8581E+03 1.5231E+06 |
|
278 |
21 1 47 0.00000 7.94373 7.8833E+03 1.5631E+06 |
|
279 |
0.00000 7.85657 7.9082E+03 1.6033E+06 |
|
280 |
22 1 46 0.00000 7.76941 7.9328E+03 1.6433E+06 |
|
281 |
0.00000 7.68225 7.9572E+03 1.6838E+06 |
|
282 |
23 1 45 0.00000 7.59510 7.9811E+03 1.7231E+06 |
|
283 |
0.00000 7.50794 8.0048E+03 1.7627E+06 |
|
284 |
24 1 44 0.00000 7.42078 8.0284E+03 1.8018E+06 |
|
285 |
0.00000 7.33363 8.0519E+03 1.8417E+06 |
|
286 |
25 1 43 0.00000 7.24647 8.0751E+03 1.8798E+06 |
|
287 |
0.00000 7.15931 8.0982E+03 1.9183E+06 |
|
288 |
26 1 42 0.00000 7.07216 8.1216E+03 1.9560E+06 |
|
289 |
0.00000 6.98500 8.1449E+03 1.9947E+06 |
|
290 |
27 1 41 0.00000 6.89784 8.1681E+03 2.0311E+06 |
|
291 |
0.00000 6.81069 8.1914E+03 2.0679E+06 |
|
292 |
28 1 40 0.00000 6.72353 8.2152E+03 2.1036E+06 |
|
293 |
0.00000 6.63637 8.2392E+03 2.1406E+06 |
|
294 |
29 1 39 0.00000 6.54922 8.2633E+03 2.1744E+06 |
|
295 |
0.00000 6.46206 8.2878E+03 2.2083E+06 |
|
296 |
30 1 38 0.00000 6.37490 8.3132E+03 2.2407E+06 |
|
297 |
0.00000 6.28775 8.3392E+03 2.2747E+06 |
|
298 |
31 1 37 0.00000 6.20059 8.3655E+03 2.3062E+06 |
|
299 |
0.00000 6.08529 8.4015E+03 2.3461E+06 |
|
300 |
32 1 36 0.00000 5.97000 8.4397E+03 2.3855E+06 |
|
301 |
0.00000 5.91098 8.4600E+03 2.4070E+06 |
|
302 |
33 1 35 0.00000 5.85196 8.4803E+03 2.4217E+06 |
|
303 |
0.00000 5.76480 8.5116E+03 2.4488E+06 |
|
304 |
34 1 34 0.00000 5.67765 8.5450E+03 2.4718E+06 |
|
305 |
0.00000 5.59049 8.5800E+03 2.4974E+06 |
|
306 |
35 1 33 0.00000 5.50333 8.6160E+03 2.5150E+06 |
|
307 |
0.00000 5.41618 8.6538E+03 2.5340E+06 |
|
308 |
36 1 32 0.00000 5.32902 8.6948E+03 2.5496E+06 |
|
309 |
0.00000 5.24186 8.7381E+03 2.5687E+06 |
|
310 |
37 1 31 0.00000 5.15471 8.7830E+03 2.5771E+06 |
|
311 |
0.00000 5.06755 8.8306E+03 2.5864E+06 |
|
312 |
38 1 30 0.00000 4.98039 8.8827E+03 2.5913E+06 |
|
313 |
0.00000 4.89324 8.9381E+03 2.6010E+06 |
|
314 |
39 1 29 0.00000 4.80608 8.9959E+03 2.5956E+06 |
|
315 |
0.00000 4.71892 9.0576E+03 2.5915E+06 |
|
316 |
40 1 28 0.00000 4.63176 9.1256E+03 2.5816E+06 |
|
317 |
0.00000 4.54461 9.1984E+03 2.5783E+06 |
|
318 |
41 1 27 0.00000 4.45745 9.2746E+03 2.5537E+06 |
|
319 |
0.00000 4.37029 9.3563E+03 2.5309E+06 |
|
320 |
42 1 26 0.00000 4.28314 9.4470E+03 2.5002E+06 |
|
321 |
0.00000 4.19598 9.5445E+03 2.4791E+06 |
|
322 |
43 1 25 0.00000 4.10882 9.6469E+03 2.4275E+06 |
|
323 |
0.00000 4.02167 9.7570E+03 2.3786E+06 |
|
324 |
44 1 24 0.00000 3.93451 9.8800E+03 2.3188E+06 |
|
325 |
0.00000 3.84735 1.0013E+04 2.2732E+06 |
|
326 |
45 1 23 0.00000 3.76020 1.0152E+04 2.1838E+06 |
|
327 |
0.00000 3.67304 1.0303E+04 2.0990E+06 |
|
328 |
46 1 22 0.00000 3.58588 1.0472E+04 1.9986E+06 |
|
329 |
0.00000 3.49873 1.0655E+04 1.9198E+06 |
|
330 |
47 1 21 0.00000 3.41157 1.0848E+04 1.7779E+06 |
|
331 |
0.00000 3.32441 1.1056E+04 1.6461E+06 |
|
332 |
48 1 20 0.00000 3.23725 1.1292E+04 1.4894E+06 |
|
333 |
0.00000 3.15010 1.1547E+04 1.3669E+06 |
|
334 |
49 1 19 0.00000 3.06294 1.1817E+04 1.1534E+06 |
|
335 |
0.00000 2.97578 1.2115E+04 1.0881E+06 |
|
336 |
50 1 18 0.00000 2.88863 1.2441E+04 8.9671E+05 |
|
337 |
0.00000 2.80147 1.2796E+04 6.9346E+05 |
|
338 |
51 1 17 0.00000 2.71431 1.3185E+04 4.7129E+05 |
|
339 |
0.00000 2.62716 1.3607E+04 2.4527E+05 |
|
340 |
52 1 16 0.00000 2.54000 1.4069E+04 0.0000E+00 |
|
341 |
||
342 |
Summary for the above wall segment: |
|
343 |
Emax = 2.6010E+06 V/m |
|
344 |
Hmax = 1.4069E+04 A/m |
|
345 |
Surface Area = 3.9016E+02 cm^2 |
|
346 |
Power = 9.4728E+03 W |
|
347 |
Maximum P/A = 7.3461E+01 W/cm^2 |
|
348 |
Average P/A = 2.4279E+01 W/cm^2 |
|
349 |
df/dz = -3.7969E+00 MHz/mm (for volume added to the cavity) |
|
350 |
df/f = -4.6910E-03 |
|
351 |
------------------------------------------------------------------------------- |
|
352 |
Power and fields on wall segment 2. K,L = 1,16 to 4,16 |
|
353 |
This segment uses surface resistance option IRTYPE = 0 |
|
354 |
Surface resistance, Rs = 7.422349E-03 Ohm calculated from: |
|
355 |
Operating temperature, TEMPC = 20.000 C |
|
356 |
Reference resistivity, RHOR = 1.724100E-06 Ohm-cm |
|
357 |
Reference temperature, TEMPR = 20.000 C |
|
358 |
Temperature coefficient, ALPHAT = 3.930000E-03 /C |
|
359 |
Relative permeability, RFMU = 1.000 |
|
360 |
||
361 |
m K L Z R H |E| |
|
362 |
(cm) (cm) (A/m) (V/m) |
|
363 |
1 1 16 0.00000 2.54000 1.4069E+04 0.0000E+00 |
|
364 |
0.105833 2.54000 1.4059E+04 4.1990E+05 |
|
365 |
2 2 16 0.211667 2.54000 1.4029E+04 8.4512E+05 |
|
366 |
0.317500 2.54000 1.3979E+04 1.2677E+06 |
|
367 |
3 3 16 0.423333 2.54000 1.3904E+04 1.7918E+06 |
|
368 |
0.529167 2.54000 1.3809E+04 2.2364E+06 |
|
369 |
4 4 16 0.635000 2.54000 1.3684E+04 2.8740E+06 |
|
370 |
||
371 |
Summary for the above wall segment: |
|
372 |
Emax = 2.8740E+06 V/m |
|
373 |
Hmax = 1.4059E+04 A/m |
|
374 |
Surface Area = 1.0134E+01 cm^2 |
|
375 |
Power = 7.3120E+02 W |
|
376 |
Maximum P/A = 7.3356E+01 W/cm^2 |
|
377 |
Average P/A = 7.2152E+01 W/cm^2 |
|
378 |
df/dr = -3.7097E-01 MHz/mm (for volume added to the cavity) |
|
379 |
df/f = -4.5833E-04 |
|
380 |
------------------------------------------------------------------------------- |
|
381 |
Power and fields on wall segment 3. K,L = 4,16 to 17,1 |
|
382 |
This segment uses surface resistance option IRTYPE = 0 |
|
383 |
Surface resistance, Rs = 7.422349E-03 Ohm calculated from: |
|
384 |
Operating temperature, TEMPC = 20.000 C |
|
385 |
Reference resistivity, RHOR = 1.724100E-06 Ohm-cm |
|
386 |
Reference temperature, TEMPR = 20.000 C |
|
387 |
Temperature coefficient, ALPHAT = 3.930000E-03 /C |
|
388 |
Relative permeability, RFMU = 1.000 |
|
389 |
||
390 |
m K L Z R H |E| |
|
391 |
(cm) (cm) (A/m) (V/m) |
|
392 |
1 4 16 0.635000 2.54000 1.3684E+04 2.8740E+06 |
|
393 |
0.732225 2.53627 1.3573E+04 3.2517E+06 |
|
394 |
2 5 16 0.829450 2.53255 1.3439E+04 3.8892E+06 |
|
395 |
0.925931 2.52141 1.3322E+04 4.2773E+06 |
|
396 |
3 6 16 1.02241 2.51028 1.3193E+04 5.0394E+06 |
|
397 |
1.11743 2.49189 1.3061E+04 5.5326E+06 |
|
398 |
4 6 15 1.21244 2.47349 1.2908E+04 6.0175E+06 |
|
399 |
1.30531 2.44806 1.2771E+04 6.5194E+06 |
|
400 |
5 7 15 1.39817 2.42264 1.2599E+04 7.1685E+06 |
|
401 |
1.48826 2.39048 1.2448E+04 7.6645E+06 |
|
402 |
6 8 15 1.57835 2.35832 1.2272E+04 8.5191E+06 |
|
403 |
1.66511 2.31980 1.2098E+04 9.0383E+06 |
|
404 |
7 9 14 1.75187 2.28127 1.1904E+04 9.5556E+06 |
|
405 |
1.83481 2.23679 1.1721E+04 1.0110E+07 |
|
406 |
8 10 14 1.91774 2.19230 1.1500E+04 1.0747E+07 |
|
407 |
1.99645 2.14228 1.1301E+04 1.1285E+07 |
|
408 |
9 11 14 2.07515 2.09226 1.1063E+04 1.2222E+07 |
|
409 |
2.14927 2.03717 1.0837E+04 1.2732E+07 |
|
410 |
10 11 13 2.22340 1.98207 1.0597E+04 1.3465E+07 |
|
411 |
2.29267 1.92234 1.0352E+04 1.4023E+07 |
|
412 |
11 12 12 2.36193 1.86261 1.0087E+04 1.4597E+07 |
|
413 |
2.42612 1.79869 9.8260E+03 1.5240E+07 |
|
414 |
12 13 12 2.49030 1.73478 9.5137E+03 1.6048E+07 |
|
415 |
2.54924 1.66711 9.2281E+03 1.6568E+07 |
|
416 |
13 13 11 2.60817 1.59944 8.9128E+03 1.7439E+07 |
|
417 |
2.66171 1.52844 8.6014E+03 1.7989E+07 |
|
418 |
14 14 10 2.71526 1.45743 8.2552E+03 1.8843E+07 |
|
419 |
2.76332 1.38350 7.9171E+03 1.9405E+07 |
|
420 |
15 14 9 2.81139 1.30956 7.5425E+03 2.0262E+07 |
|
421 |
2.85389 1.23307 7.1762E+03 2.0824E+07 |
|
422 |
16 15 8 2.89640 1.15657 6.7729E+03 2.1670E+07 |
|
423 |
2.93330 1.07789 6.3775E+03 2.2218E+07 |
|
424 |
17 15 7 2.97020 0.999211 5.9452E+03 2.3033E+07 |
|
425 |
3.00146 0.918686 5.5210E+03 2.3549E+07 |
|
426 |
18 16 6 3.03272 0.838162 5.0602E+03 2.4303E+07 |
|
427 |
3.05832 0.756125 4.6085E+03 2.4764E+07 |
|
428 |
19 16 5 3.08392 0.674088 4.1225E+03 2.5429E+07 |
|
429 |
3.10384 0.590857 3.6463E+03 2.5820E+07 |
|
430 |
20 17 4 3.12376 0.507627 3.1406E+03 2.6347E+07 |
|
431 |
3.13799 0.423510 2.6201E+03 2.6791E+07 |
|
432 |
21 16 3 3.15222 0.339394 2.1095E+03 2.7008E+07 |
|
433 |
3.16076 0.254691 1.5963E+03 2.7357E+07 |
|
434 |
22 17 2 3.16931 0.169988 1.0711E+03 2.7720E+07 |
|
435 |
3.17215 8.499425E-02 5.4049E+02 2.8101E+07 |
|
436 |
23 17 1 3.17500 0.00000 0.0000E+00 2.8503E+07 |
|
437 |
||
438 |
Summary for the above wall segment: |
|
439 |
Emax = 2.8503E+07 V/m |
|
440 |
Hmax = 1.3573E+04 A/m |
|
441 |
Surface Area = 4.0509E+01 cm^2 |
|
442 |
Power = 1.8263E+03 W |
|
443 |
Maximum P/A = 6.8370E+01 W/cm^2 |
|
444 |
Average P/A = 4.5084E+01 W/cm^2 |
|
445 |
df/dz = 7.9949E+00 MHz/mm (for volume added to the cavity) |
|
446 |
df/f = 9.8776E-03 |
|
447 |
df/dr = 5.2488E+00 MHz/mm (for volume added to the cavity) |
|
448 |
df/f = 6.4849E-03 |
|
449 |
------------------------------------------------------------------------------- |
|
450 |
Transit-time factor summary |
|
451 |
||
452 |
Input data for Parmila; originating program = Autofish. |
|
453 |
Cavity type: Unknown RF Cavity |
|
454 |
Design frequency = 809.395 MHz |
|
455 |
Resonant frequency = 809.395 MHz |
|
456 |
Design beta = 0.172812 |
|
457 |
Particle beta = 0.172812 |
|
458 |
Cavity E0 = 23.1202 MV/m |
|
459 |
Transit-time factor = 0.865044 |
|
460 |
Normalization length = 1.77800 cm |
|
461 |
||
462 |
Cell Zstart(cm) Zcenter(cm) Zend(cm) Lnorm(cm) E0(MV/m) g/bl |
|
463 |
1 3.17500 0.00000 4.95300 1.77800 23.1202 0.277778 |
|
464 |
||
465 |
Cell 1 Beta = 0.172812 dZctr = 0.864479 |
|
466 |
X X1 X2 X1+X2 |X1|+|X2| |
|
467 |
T 0.000000 -0.5718275 -0.5718275 0.5718275 |
|
468 |
T' 0.000000 -0.4393971 -0.4393971 0.4393971 |
|
469 |
T" 0.000000 -0.1949050 -0.1949050 0.1949050 |
|
470 |
S 0.000000 -0.6490868 -0.6490868 0.6490868 |
|
471 |
S' 0.000000 -0.3322010 -0.3322010 0.3322010 |
|
472 |
S" 0.000000 -0.3004156 -0.3004156 0.3004156 |
|
473 |
||
474 |
SFDATA line expected in old versions of Parmila: |
|
475 |
0.172812 -0.571828 -0.439397 0.324543 0.166100 0.277778 790.019 |
|
476 |
------------------------------------------------------------------------------- |
|
477 |
||
478 |
Problem variables computed by this code. |
|
479 |
||
480 |
Variable Code Value Description |
|
481 |
ASCALE 31794.3910 Scaling factor for H at drive point |
|
482 |
BETA 0.172812087 Particle velocity |
|
483 |
CAPK 0.981625001 2pi/beta*lambda, phase change/length |
|
484 |
EMAX 28503237.5 Peak electric field on boundary segments |
|
485 |
ENERGY 0.124601852 Total stored energy in RF fields |
|
486 |
EZERO 23120223.8 E0 for normalization in SFO when NORM=0 |
|
487 |
EZEROT S 20000000.0 E0*T for normalization in SFO when NORM=1 |
|
488 |
FREQC 809.395083 Frequency corrected for stems and posts |
|
489 |
HCORNER 0.0 Average H at corner arc with coupling slot |
|
490 |
HMAX 14069.2793 Peak H on specified boundary segments |
|
491 |
HPHI 14076.2241 Normalization magnetic field for NORM=2 |
|
492 |
NCELL 0 Number of cells for multicell problems |
|
493 |
NPEG 3 Number of FieldSegments entries |
|
494 |
NRESIST 0 Number of segments with unique resistivity |
|
495 |
NSTEM 0 Number of stems for multicell problems |
|
496 |
POWER 12030.3527 Power on conducting boundaries |
|
497 |
RHOC 1.724100000E-06 Computed resistivity for IRTYPE=3 |
|
498 |
RS 7.422349068E-03 RF surface resistance (Ohms) |
|
499 |
SAREA 440.808349 Total surface area in power calculations |
|
500 |
T 0.865043529 Transit-time factor |
|
501 |
ZLONG 1.77800000 Length in SFO used to define E0 |
|
502 |
||
503 |
Superfish output summary for problem description: |
|
504 |
HPRF Cavity with electrodes at atmospheric pressure |
|
505 |
Problem file: C:\USERS\PLANE\DOCUMENTS\SUPERFISH\HPRF_ELECTRODE_ATMOSPHERIC.AM 6-05-2015 15:23:36 |
|
506 |
------------------------------------------------------------------------------- |
|
507 |
All calculated values below refer to the mesh geometry only. |
|
508 |
Field normalization (NORM = 1): EZEROT = 20.00000 MV/m |
|
509 |
Frequency = 809.39508 MHz |
|
510 |
Particle rest mass energy = 938.272029 MeV |
|
511 |
Beta = 0.1728121 Kinetic energy = 14.332 MeV |
|
512 |
Normalization factor for E0 = 23.120 MV/m = 31794.391 |
|
513 |
Transit-time factor = 0.8650435 |
|
514 |
Stored energy = 0.1246019 Joules |
|
515 |
Using standard room-temperature copper. |
|
516 |
Surface resistance = 7.42235 milliOhm |
|
517 |
Normal-conductor resistivity = 1.72410 microOhm-cm |
|
518 |
Operating temperature = 20.0000 C |
|
519 |
Power dissipation = 12.0304 kW |
|
520 |
Q = 52672.8 Shunt impedance = 790.019 MOhm/m |
|
521 |
Rs*Q = 390.956 Ohm Z*T*T = 591.171 MOhm/m |
|
522 |
r/Q = 199.553 Ohm Wake loss parameter = 0.25371 V/pC |
|
523 |
Average magnetic field on the outer wall = 6430.11 A/m, 15.3443 W/cm^2 |
|
524 |
Maximum H (at Z,R = 0.0,2.54) = 14069.3 A/m, 73.4607 W/cm^2 |
|
525 |
Maximum E (at Z,R = 3.175,0.0) = 28.5032 MV/m, 1.09134 Kilp. |
|
526 |
Ratio of peak fields Bmax/Emax = 0.6203 mT/(MV/m) |
|
527 |
Peak-to-average ratio Emax/E0 = 1.2328 |
|
528 |
||
529 |
Wall segments: |
|
530 |
Segment Zend Rend Emax Power P/A dF/dZ dF/dR |
|
531 |
(cm) (cm) (MV/m) (kW) (W/cm^2) (MHz/mm) (MHz/mm) |
|
532 |
---------------------------------------------------------------------------------------------- |
|
533 |
0.0000 11.430 |
|
534 |
1 0.0000 2.5400 2.601 9.473 24.28 -3.797 0.000 |
|
535 |
2 0.63500 2.5400 2.874 0.7312 72.15 0.000 -0.3710 |
|
536 |
3 3.1750 0.0000 28.50 1.826 45.08 7.995 5.249 |
|
537 |
---------------------------------------------------------------------------------------------- |
|
538 |
Total 12.03 |