Coverage for /wheeldirectory/casa-6.7.0-12-py3.10.el8/lib/py/lib/python3.10/site-packages/casatools/measures.py: 57%

109 statements  

« prev     ^ index     » next       coverage.py v7.6.4, created at 2024-10-31 17:39 +0000

1##################### generated by xml-casa (v2) from measures.xml ################## 

2##################### 10d0ffd28eb07533e776e745f7d49a27 ############################## 

3from __future__ import absolute_import 

4from .__casac__.measures import measures as _measures 

5 

6from .errors import create_error_string 

7from .typecheck import CasaValidator as _validator 

8_pc = _validator( ) 

9from .coercetype import coerce as _coerce 

10 

11 

12class measures: 

13 _info_group_ = """measures""" 

14 _info_desc_ = """measures tool""" 

15 ### self 

16 def __init__(self, *args, **kwargs): 

17 """Create a measures tool on the specified host (or by default the 

18 host you are running on). 

19 """ 

20 self._swigobj = kwargs.get('swig_object',None) 

21 if self._swigobj is None: 

22 self._swigobj = _measures() 

23 

24 def dirshow(self, v): 

25 """dirshow will convert a direction measure to a string 

26 """ 

27 return self._swigobj.dirshow(v) 

28 

29 def show(self, v, refcode=True): 

30 """show will convert a measure to a string. 

31  

32 All measures are catered for (at this moment {em direction, position, epoch, 

33 radialvelocity, frequency, doppler, baseline, uvw, earthmagnetic} ). 

34 """ 

35 return self._swigobj.show(v, refcode) 

36 

37 def epoch(self, rf='UTC', v0=[ ], off={ }): 

38 """epoch defines an epoch measure from the CLI. It has to specify a 

39 reference code, an epoch quantity value (see introduction for the 

40 action on a scalar quantity with either a vector or scalar value), 

41  

42 and optionally it can specify an offset, which in itself has to be an 

43 epoch. Allowable reference codes are: 

44 {em UTC TAI LAST LMST GMST1 GAST UT1 UT2 TDT TCG TDB TCB}. 

45 Note that additional ones may become available. Check in casa with: 

46  

47 begin{verbatim} 

48 print "t----t epoch Ex 1 t----" 

49 print me.listcodes(me.epoch()) 

50 #{'normal': ['LAST', 'LMST', 'GMST1', 'GAST', 'UT1', 'UT2', 'UTC', 'TAI', 

51 # 'TDT', 'TCG', 'TDB', 'TCB', 'IAT', 'GMST', 'TT', 'ET', 'UT'], 'extra': []} 

52 # 

53 end{verbatim} 

54  

55 See quantity for possible time formats. 

56 """ 

57 return self._swigobj.epoch(rf, v0, off) 

58 

59 def direction(self, rf='J2000', v0=[ ], v1=[ ], off={ }): 

60 """direction defines a direction measure from the CLI. It has to specify a 

61 reference code, direction quantity values (see introduction for the action on a 

62 scalar quantity with either a vector or scalar value), 

63  

64 and optionally it can specify an 

65 offset, which in itself has to be a direction. Allowable reference codes are: 

66 {em J2000 JMEAN JTRUE APP B1950 BMEAN BTRUE GALACTIC HADEC AZEL 

67 SUPERGAL ECLIPTIC MECLIPTIC TECLIPTIC MERCURY 

68 VENUS MARS JUPITER SATURN URANUS NEPTUNE PLUTO MOON SUN COMET}. 

69 Note that additional ones may become available. Check in casa with: 

70  

71 begin{verbatim} 

72 print "t----t direction Ex 1 t----" 

73 print me.listcodes(me.direction()) 

74 #{'normal': ['J2000', 'JMEAN', 'JTRUE', 'APP', 'B1950', 'BMEAN', 

75 #'BTRUE', 'GALACTIC', 'HADEC', 'AZEL', 'AZELSW', 'AZELNE', 'AZELGEO', 

76 #'AZELSWGEO', 'AZELNEGEO', 'JNAT', 'ECLIPTIC', 'MECLIPTIC', 

77 #'TECLIPTIC', 'SUPERGAL', 'ITRF', 'TOPO', 'ICRS'], 'extra': ['MERCURY', 

78 #'VENUS', 'MARS', 'JUPITER', 'SATURN', 'URANUS', 'NEPTUNE', 'PLUTO', 

79 #'SUN', 'MOON', 'COMET']} 

80 end{verbatim} 

81  

82 The direction quantity values should be longitude(angle) and 

83 latitude(angle) (none needed for planets: the frame epoch defines coordinates). 

84 See quantity for possible angle formats. 

85 """ 

86 return self._swigobj.direction(rf, v0, v1, off) 

87 

88 def getvalue(self, v): 

89 """getvalue gets the actual implementation value of the measure. 

90 """ 

91 return self._swigobj.getvalue(v) 

92 

93 def gettype(self, v): 

94 """gettype gets the actual type of the measure. 

95 """ 

96 return self._swigobj.gettype(v) 

97 

98 def getref(self, v): 

99 """gettype gets the actual reference code of the measure. 

100 """ 

101 return self._swigobj.getref(v) 

102 

103 def getoffset(self, v): 

104 """getoff gets the actual offset of the measure (as a measure) or F if no offset 

105 given. 

106 """ 

107 return self._swigobj.getoffset(v) 

108 

109 def cometname(self): 

110 """cometname gets the name of the current comet (if any). 

111 """ 

112 return self._swigobj.cometname() 

113 

114 def comettype(self): 

115 """comettype gets the comet table type (apparent or topocentric) 

116 """ 

117 return self._swigobj.comettype() 

118 

119 def cometdist(self): 

120 """cometdist returns the distance in AU of the current comet in the current frame, 

121 as a quantity. It will return -1 AU on failure! 

122  

123 """ 

124 return self._swigobj.cometdist() 

125 

126 def cometangdiam(self): 

127 """cometdist returns the angular diameter (as seen from Earth) in AU of the current 

128 comet in the current frame, as a quantity. It will return -1 radians on failure! 

129  

130 """ 

131 return self._swigobj.cometangdiam() 

132 

133 def comettopo(self): 

134 """comettopo gets the comet table's topographic coordinates used. 

135 """ 

136 return self._swigobj.comettopo() 

137 

138 def framecomet(self, v=''): 

139 """framecomet will put the specified comet table in the frame. 

140 """ 

141 return self._swigobj.framecomet(v) 

142 

143 def position(self, rf='WGS84', v0=[ ], v1=[ ], v2=[ ], off={ }): 

144 """position defines a position measure from the CLI. It has to specify a 

145 reference code, position quantity values (see introduction for the action on a 

146 scalar quantity with either a vector or scalar value), 

147  

148 and optionally it can specify an 

149 offset, which in itself has to be a position. Allowable reference codes are: 

150 {em WGS84 ITRF} (World Geodetic System and International Terrestrial 

151 Reference Frame). 

152 Note that additional ones may become available. Check in casa with: 

153  

154 begin{verbatim} 

155 print "t----t position Ex 1 t----" 

156 print me.listcodes(me.position()) 

157 #{'normal': ['ITRF', 'WGS84'], 'extra': []} 

158 end{verbatim} 

159  

160 The position quantity values should be either longitude 

161 (angle), latitude(angle) and height(length); or x,y,z (length). 

162 See quantity for possible angle formats. 

163 """ 

164 return self._swigobj.position(rf, v0, v1, v2, off) 

165 

166 def observatory(self, name='ALMA'): 

167 """observatory will give you the position of an observatory as given in the 

168 system. At the time of writing the following observatories are recognised 

169 (but check e.g. the position GUI for currently known ones, or the 

170 me.obslist() tool function):: 

171  

172 {'ALMA' 'ARECIBO' 'ATCA' 'BIMA' 'CLRO' 'DRAO' 'DWL' 'GB' 'GBT' 'GMRT' 

173 'IRAM PDB' 'IRAM_PDB' 'JCMT' 'MOPRA' 'MOST' 'NRAO12M' 'NRAO_GBT' 'PKS' 

174 'SAO SMA' 'SMA' 'VLA' 'VLBA' 'WSRT' 'ATF' 'ATA' 'CARMA' 'ACA' 'OSF' 

175 'OVRO_MMA' 'EVLA' 'ASKAP' 'APEX' 'SMT' 'NRO' 'ASTE' 'LOFAR' 'MeerKAT' 

176 'KAT-7' 'EVN' 'LWA1' 'PAPER_SA' 'PAPER_GB' 'e-MERLIN' 'MERLIN2' 

177 'Effelsberg' 'MWA32T' }. 

178 """ 

179 return self._swigobj.observatory(name) 

180 

181 def obslist(self): 

182 """obslist will give you an array of strings of the 

183 observatories known in the Observatories table. 

184 """ 

185 return self._swigobj.obslist() 

186 

187 def linelist(self): 

188 """linelist will give you a string with a space separated list of spectral lines 

189 known in the Lines table. 

190  

191 A number of lines are available now, but tables with many lines are 

192 already online, and will be interfaced once a nomenclature can be defined for 

193 the tens of thousands of lines. 

194 """ 

195 return self._swigobj.linelist() 

196 

197 def spectralline(self, name='HI'): 

198 """spectralline will give you the frequency of a spectral line. The known list 

199 can be obtained by me.linelist(). 

200 """ 

201 return self._swigobj.spectralline(name) 

202 

203 def sourcelist(self): 

204 """sourcelist will give you a string with the space separated list of sources 

205 known in the Sources table. 

206 """ 

207 return self._swigobj.sourcelist() 

208 

209 def source(self, name=[ ]): 

210 """source will give you the direction of a source. The known list 

211 can be obtained by me.sourcelist(). 

212 """ 

213 return self._swigobj.source(name) 

214 

215 def frequency(self, rf='LSRK', v0=[ ], off={ }): 

216 """frequency defines a frequency measure from the CLI. It has to specify a 

217 reference code, frequency quantity value (see introduction for the action on a 

218 scalar quantity with either a vector or scalar value), 

219  

220 and optionally it can specify an 

221 offset, which in itself has to be a frequency. Allowable reference codes are: 

222 {em REST LSRK LSRD BARY GEO TOPO GALACTO LGROUP CMB}. 

223 Note that additional ones may become available. Check in casa with: 

224 begin{verbatim} 

225 print "t----t frequency Ex 1 t----" 

226 print me.listcodes(me.frequency()) 

227 #{'normal': ['REST', 'LSRK', 'LSRD', 'BARY', 'GEO', 'TOPO', 

228 # 'GALACTO', 'LGROUP', 'CMB'], 'extra': []} 

229 end{verbatim} 

230  

231 The frequency quantity values should be in one of the recognised units 

232 (examples all give same frequency): 

233 begin{itemize} 

234 item value with time units: a period (0.5s) 

235 item value as frequency: 2Hz 

236 item value in angular frequency: 720deg/s 

237 item value as length: 149896km 

238 item value as wave number: 4.19169e-8m-1 

239 item value as energy (h.nu): 8.27134e-9ueV 

240 item value as momentum: 4.42044e-42kg.m 

241 end{itemize} 

242 """ 

243 return self._swigobj.frequency(rf, v0, off) 

244 

245 def doppler(self, rf='RADIO', v0=[ ], off={ }): 

246 """doppler defines a doppler measure from the CLI. It has to specify a 

247 reference code, doppler quantity value (see introduction for the action on a 

248 scalar quantity with either a vector or scalar value), 

249  

250 and optionally it can specify an offset, 

251 which in itself has to be a doppler. Allowable reference codes are: 

252 {em RADIO Z RATIO BETA GAMMA OPTICAL TRUE RELATIVISTIC}. 

253 Note that additional ones may become available. Check in casa with: 

254  

255 begin{verbatim} 

256 print "t----t doppler Ex 1 t----" 

257 print me.listcodes(me.doppler()) 

258 #{'normal': ['RADIO', 'Z', 'RATIO', 'BETA', 'GAMMA', 'OPTICAL', 

259 # 'TRUE', 'RELATIVISTIC'], 'extra': []} 

260 end{verbatim} 

261  

262 The doppler quantity values should be either non-dimensioned to specify a 

263 ratio of the light velocity, or in velocity. 

264 """ 

265 return self._swigobj.doppler(rf, v0, off) 

266 

267 def radialvelocity(self, rf='LSRK', v0=[ ], off={ }): 

268 """radialvelocity defines a radialvelocity measure from the CLI. It has to 

269 specify a reference code, radialvelocity quantity value (see introduction for 

270 the action on a 

271 scalar quantity with either a vector or scalar value), 

272  

273 and optionally it 

274 can specify an offset, which in itself has to be a radialvelocity. 

275 Allowable reference codes are: 

276 {em LSRK LSRD BARY GEO TOPO GALACTO LGROUP CMB}. 

277 Note that additional ones may become available. Check in casa with: 

278  

279 begin{verbatim} 

280 print "t----t radialvelocity Ex 1 t----" 

281 print me.listcodes(me.radialvelocity()) 

282 # Out[17]: 

283 #{'extra': [], 

284 # 'normal': ['LSRK', 'LSRD', 'BARY', 'GEO', 'TOPO', 'GALACTO', 

285 # 'LGROUP', 'CMB']} 

286 end{verbatim} 

287 The radialvelocity quantity values should be given as velocity. 

288 """ 

289 return self._swigobj.radialvelocity(rf, v0, off) 

290 

291 def shift(self, v={ }, offset=[ ], pa=[ ]): 

292 """This method calculates the direction measure located at the specified offset angular amount along the specified 

293 position angle from the specified direction measure. 

294  

295 """ 

296 return self._swigobj.shift(v, offset, pa) 

297 

298 def uvw(self, rf='ITRF', v0=[ ], v1=[ ], v2=[ ], off={ }): 

299 """uvw defines a uvw measure from the CLI. It has to specify a 

300 reference code, uvw quantity values (see introduction for the action on a 

301 scalar quantity with either a vector or scalar value), and optionally it can specify an 

302 offset, which in itself has to be a uvw. Allowable reference codes are 

303 ITRF and the direction ones. 

304  

305 Note that additional ones may become available. Check in casa with:: 

306  

307 print "t----t uvw Ex 1 t----" 

308 print me.listcodes(me.uvw()) 

309  

310 { 

311 'normal': array(['J2000', 'JMEAN', 'JTRUE', 'APP', 'B1950', 'B1950_VLA', 'BMEAN', 

312 'BTRUE', 'GALACTIC', 'HADEC', 'AZEL', 'AZELSW', 'AZELNE', 'AZELGEO', 

313 'AZELSWGEO', 'AZELNEGEO', 'JNAT', 'ECLIPTIC', 'MECLIPTIC', 

314 'TECLIPTIC', 'SUPERGAL', 'ITRF', 'TOPO', 'ICRS'], dtype='|S10'), 

315 'extra': array([], dtype='|S1') 

316 } 

317  

318 The uvw quantity values should be either longitude 

319 (angle), latitude(angle) and height(length); or x,y,z (length). 

320 See quantity for possible angle formats. 

321 """ 

322 return self._swigobj.uvw(rf, v0, v1, v2, off) 

323 

324 def touvw(self, v={ }): 

325 """touvw calculates a uvw measure from a baseline. Note that the 

326 baseline does not have to be a proper {em baseline}, but can be a 

327 series of positions (to call positions baselines see 

328 asbaseline ) for speed reasons: 

329 operations are linear and can be done on positions, which are 

330 converted to baseline values at the end (with 

331 expand ). 

332  

333 Whatever the reference code of the baseline, the returned {em uvw} will be 

334 given in J2000. If the {em dot} argument is given, that variable 

335 will be filled with a quantity array consisting of the time 

336 derivative of the uvw (note that only the sidereal rate is taken 

337 into account; not precession, earth tides and similar variations, 

338 which are much smaller). If the {em xyz} variable is given, it will 

339 be filled with the quantity values of the uvw measure. 

340  

341 The values of the input baselines can be given as a quantity 

342 vector per x, y or z value. 

343  

344 uvw coordinates are calculated for a certain direction in the sky; 

345 hence the frame has to contain the direction for the calculation to 

346 work. Since the baseline and the sky rotate with respect of each 

347 other, the time should be specified as well. 

348 """ 

349 return self._swigobj.touvw(v) 

350 

351 def expand(self, v={ }): 

352 """expand calculates the differences between a series of given measure 

353 values: it calculates baseline values from position values. The 

354 returned value is a measure, but the value of the optional output 

355 variable {em xyz} will be set to an array of values. 

356 """ 

357 return self._swigobj.expand(v) 

358 

359 def earthmagnetic(self, rf='IGRF', v0=[ ], v1=[ ], v2=[ ], off={ }): 

360 """earthmagnetic defines an earthmagnetic measure from the CLI. It needs 

361 a reference code, earthmagnetic quantity values 

362 (see introduction for the action on a 

363 scalar quantity with either a vector or scalar value) if the reference code is not 

364 for a model, and optionally it 

365 can specify an offset, which in itself has to be a earthmagnetic. In general 

366 you specify a model (IGRF is the default and the only one known) and convert 

367 it to an explicit field. (See 

368  

369 http://fdd.gsfc.nasa.gov/IGRF.html 

370  

371 for information on the International Geomagnetic Reference Field). The 

372 earthmagnetic quantity values should be either longitude (angle), 

373 latitude(angle) and length(field strength); or x,y,z (field). 

374 See quantity for possible angle formats. 

375 """ 

376 return self._swigobj.earthmagnetic(rf, v0, v1, v2, off) 

377 

378 def baseline(self, rf='ITRF', v0=[ ], v1=[ ], v2=[ ], off={ }): 

379 """baseline defines a baseline measure from the CLI. It has to specify a 

380 reference code, baseline quantity values (see introduction for the action on a 

381 scalar quantity with either a vector or scalar value, and when a vector of 

382 quantities is given), and optionally it can specify an 

383 offset, which in itself has to be a baseline. Allowable reference codes are 

384 ITRF and the direction ones. 

385  

386 Note that additional ones may become available. Check in casa with:: 

387  

388 print "t----t baseline Ex 1 t----" 

389 print me.listcodes(me.baseline()) 

390 # {'normal': array(['J2000', 'JMEAN', 'JTRUE', 'APP', 'B1950', 'B1950_VLA', 'BMEAN', 

391 # 'BTRUE', 'GALACTIC', 'HADEC', 'AZEL', 'AZELSW', 'AZELNE', 'AZELGEO', 

392 # 'AZELSWGEO', 'AZELNEGEO', 'JNAT', 'ECLIPTIC', 'MECLIPTIC', 

393 # 'TECLIPTIC', 'SUPERGAL', 'ITRF', 'TOPO', 'ICRS'], 

394 # dtype='|S10'), 'extra': array([], 

395 # dtype='|S1')} 

396  

397 The baseline quantity values should be either longitude 

398 (angle), latitude(angle) and height(length); or x,y,z (length). 

399 See quantity for possible angle formats. 

400 """ 

401 return self._swigobj.baseline(rf, v0, v1, v2, off) 

402 

403 def asbaseline(self, pos): 

404 """asbaseline converts a position measure into a baseline measure. No 

405 actual baseline is calculated, since operations can be done on 

406 positions, with subtractions to obtain baselines at a later stage. 

407 """ 

408 return self._swigobj.asbaseline(pos) 

409 

410 def listcodes(self, ms): 

411 """listcodes will produce the known reference codes for a specified measure 

412 type. It will return a record with two entries. The first is a string vector 

413 of all normal codes; the second a string vector (maybe empty) with all extra 

414 codes (like planets). 

415 NOTE: Synonyms and different code groups may be present in the code name lists. 

416 The indices in these lists therefore do not necessarily correspond to 

417 the internal CASA enumeration indices. 

418 """ 

419 return self._swigobj.listcodes(ms) 

420 

421 def measure(self, v, rf, off={ }): 

422 """measure converts measures (epoch, direction etc.) from one reference to 

423 another. It will, for instance, convert a direction from J2000 to AZEL 

424 representation.  

425 Its arguments are a measure, an output reference code (see the individual 

426 measures for the allowable codes (direction, 

427 position, 

428 epoch, 

429 frequency, 

430 doppler, 

431 radialvelocity, 

432 baseline, 

433 uvw, 

434 earthmagnetic)), and an optional offset of 

435 the same type as the main measure. The offset will be subtracted from the 

436 result before it is returned. 

437 In some cases (see the individual measures for when), more information than 

438 just a reference code is necessary. E.g. the above example of a conversion to 

439 AZEL, needs to know for when, and where on Earth we want it. This information 

440 is stored in a reference frame. Measures are set in the reference frame with 

441 the doframe function. The frame is tool 

442 wide. 

443  

444 {bf IMPORTANT NOTE:} 

445 To get an accurate conversion of solar system objects direction to a celestial frame, one should convert to AZEL or HADEC before to get parallax accounted for. Thus if you want to get the moon's position in J2000..one would do it in 2 stages 

446 i.e (after setting the appropriate frames)  

447  

448 moonazel=me.measure(me.direction('moon'), 'AZELGEO') 

449 moonJ2000=me.measure(moonazel, 'J2000') 

450 """ 

451 return self._swigobj.measure(v, rf, off) 

452 

453 def doframe(self, v): 

454 """doframe will set the measure specified as part of a frame. 

455  

456 If conversion from one type to another is necessary, with the 

457 measure function, 

458 the following frames 

459 should be set if one of the reference types involved in the conversion is as 

460 in the following lists. 

461 {em Epoch} 

462  

463 UTC 

464 TAI 

465 LASTposition 

466 LMST position 

467 GMST1 

468 GAST 

469 UT1 

470 UT2 

471 TDT 

472 TCG 

473 TDB 

474 TCD 

475  

476 {em Direction} 

477  

478 J2000 

479 JMEANepoch 

480 JTRUE epoch 

481 APP epoch 

482 B1950 

483 BMEAN epoch 

484 BTRUE epoch 

485 GALACTIC 

486 HADEC epochposition 

487 AZELepoch position 

488 SUPERGALACTIC 

489 ECLIPTIC 

490 MECLIPTIC epoch 

491 TECLIPTICepoch 

492 PLANETepoch [position] 

493  

494 {em Position} 

495  

496 WGS84 

497 ITRF 

498  

499 {em Radial Velocity} 

500  

501 LSRK direction 

502 LSRD direction 

503 BARY direction 

504 GEO directionepoch 

505 TOPO directionepochposition 

506 GALACTOdirection 

507  

508 {em Doppler} 

509  

510 RADIO 

511 OPTICAL 

512 Z 

513 RATIO 

514 RELATIVISTIC 

515 BETA 

516 GAMMA 

517  

518 {em Frequency} 

519  

520 REST directionradialvelocity 

521 LSRK direction 

522 LSRD direction 

523 BARY direction 

524 GEO directionepoch 

525 TOPO directionepochposition 

526 GALACTO 

527 """ 

528 return self._swigobj.doframe(v) 

529 

530 def framenow(self): 

531 """framenow will fill the active frame time with the current date and time. 

532 The different frame values necessary are described in the 

533 doframe function 

534 """ 

535 return self._swigobj.framenow() 

536 

537 def showframe(self): 

538 """showframe will display the currently active reference frame values on the 

539 terminal. The 

540 different frame values necessary are described in the 

541 doframe function. 

542 The frame is 

543 displayed on the terminal using the formatting as done for the 

544 show function. 

545 """ 

546 return self._swigobj.showframe() 

547 

548 def toradialvelocity(self, rf, v0): 

549 """toradialvelocity will convert a Doppler type value (e.g. in radio mode) to a 

550 real radialvelocity. The type of velocity (e.g. LSRK) should be specified 

551 """ 

552 return self._swigobj.toradialvelocity(rf, v0) 

553 

554 def tofrequency(self, rf, v0, rfq): 

555 """tofrequency will convert a Doppler type value (e.g. in radio mode) to a 

556 frequency. The type of frequency (e.g. LSRK) and a rest frequency (either as a 

557 frequency quantity (e.g. qa.constants('HI')) or a frequency measure (e.g. 

558 me.frequency('rest','5100MHz')) should be specified 

559 """ 

560 return self._swigobj.tofrequency(rf, v0, rfq) 

561 

562 def todoppler(self, rf, v0, rfq=[ ]): 

563 """todoppler will convert a radialvelocity measure or a frequency measure to a 

564 doppler measure. In the case of a frequency, a rest frequency has to be 

565 specified. The type of doppler wanted (e.g. RADIO) has to be specified. 

566 """ 

567 return self._swigobj.todoppler(rf, v0, rfq) 

568 

569 def torestfrequency(self, v0, d0): 

570 """torestfrequency will convert a frequency measure and a doppler measure 

571 (e.g. obtained from another spectral line with a known rest frequency) to a 

572 rest frequency. 

573 """ 

574 return self._swigobj.torestfrequency(v0, d0) 

575 

576 def rise(self, crd=[ ], ev=[ ]): 

577 """rise will give the rise/set hour-angles of a source. It needs the position 

578 in the frame, and a time. If the latter is not set, the current time will be 

579 used. 

580 """ 

581 return self._swigobj.rise(crd, ev) 

582 

583 def riseset(self, crd=[ ], ev=[ ]): 

584 """rise will give the rise/set times of a source. It needs the position 

585 in the frame, and a time. If the latter is not set, the current time will be 

586 used. The returned value is a record with a 'solved' field, which is F if the 

587 source is always below or above the horizon. In that case the rise and set 

588 fields will all have a string value. The record also returns a rise and set 

589 record, with 'last' and 'utc' fields showing the rise and set times as epochs. 

590 """ 

591 return self._swigobj.riseset(crd, ev) 

592 

593 def posangle(self, m1, m2): 

594 """posangle will give the position angle from a direction to another. I.e. the 

595 angle in a direction between the direction to the North pole and the other 

596 direction. 

597 The posiation angle is calculated in the frame of the first argument. m2 is thus converted to the frame of m1 before calculating the position angle. 

598 """ 

599 return self._swigobj.posangle(m1, m2) 

600 

601 def separation(self, m1, m2): 

602 """separation will give the separation of a direction from another as an angle. 

603 """ 

604 return self._swigobj.separation(m1, m2) 

605 

606 def addxvalue(self, a): 

607 """addxvalue will give some additional information about some measures as a vector 

608 of quantities. It is used internally to get the rectangular coordinates of 

609 measures that are normally given in angles. The casual user will probably in 

610 general not interested in this function. 

611 """ 

612 return self._swigobj.addxvalue(a) 

613 

614 def type(self): 

615 """type will return the tool name. 

616 """ 

617 return self._swigobj.type() 

618 

619 def done(self): 

620 """In general you will not want to call this method. It removes and then 

621 recreates the default measures tool. 

622 """ 

623 return self._swigobj.done() 

624 

625 def ismeasure(self, v): 

626 """Checks if the operand is a correct measure 

627 """ 

628 return self._swigobj.ismeasure(v) 

629