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1# This file was automatically generated by SWIG (http://www.swig.org). 

2# Version 3.0.12 

3# 

4# Do not make changes to this file unless you know what you are doing--modify 

5# the SWIG interface file instead. 

6 

7from sys import version_info as _swig_python_version_info 

8if _swig_python_version_info >= (2, 7, 0): 

9 def swig_import_helper(): 

10 import importlib 

11 pkg = __name__.rpartition('.')[0] 

12 mname = '.'.join((pkg, '_measures')).lstrip('.') 

13 try: 

14 return importlib.import_module(mname) 

15 except ImportError: 

16 return importlib.import_module('_measures') 

17 _measures = swig_import_helper() 

18 del swig_import_helper 

19elif _swig_python_version_info >= (2, 6, 0): 

20 def swig_import_helper(): 

21 from os.path import dirname 

22 import imp 

23 fp = None 

24 try: 

25 fp, pathname, description = imp.find_module('_measures', [dirname(__file__)]) 

26 except ImportError: 

27 import _measures 

28 return _measures 

29 try: 

30 _mod = imp.load_module('_measures', fp, pathname, description) 

31 finally: 

32 if fp is not None: 

33 fp.close() 

34 return _mod 

35 _measures = swig_import_helper() 

36 del swig_import_helper 

37else: 

38 import _measures 

39del _swig_python_version_info 

40 

41try: 

42 _swig_property = property 

43except NameError: 

44 pass # Python < 2.2 doesn't have 'property'. 

45 

46try: 

47 import builtins as __builtin__ 

48except ImportError: 

49 import __builtin__ 

50 

51def _swig_setattr_nondynamic(self, class_type, name, value, static=1): 

52 if (name == "thisown"): 

53 return self.this.own(value) 

54 if (name == "this"): 

55 if type(value).__name__ == 'SwigPyObject': 

56 self.__dict__[name] = value 

57 return 

58 method = class_type.__swig_setmethods__.get(name, None) 

59 if method: 

60 return method(self, value) 

61 if (not static): 

62 if _newclass: 

63 object.__setattr__(self, name, value) 

64 else: 

65 self.__dict__[name] = value 

66 else: 

67 raise AttributeError("You cannot add attributes to %s" % self) 

68 

69 

70def _swig_setattr(self, class_type, name, value): 

71 return _swig_setattr_nondynamic(self, class_type, name, value, 0) 

72 

73 

74def _swig_getattr(self, class_type, name): 

75 if (name == "thisown"): 

76 return self.this.own() 

77 method = class_type.__swig_getmethods__.get(name, None) 

78 if method: 

79 return method(self) 

80 raise AttributeError("'%s' object has no attribute '%s'" % (class_type.__name__, name)) 

81 

82 

83def _swig_repr(self): 

84 try: 

85 strthis = "proxy of " + self.this.__repr__() 

86 except __builtin__.Exception: 

87 strthis = "" 

88 return "<%s.%s; %s >" % (self.__class__.__module__, self.__class__.__name__, strthis,) 

89 

90try: 

91 _object = object 

92 _newclass = 1 

93except __builtin__.Exception: 

94 class _object: 

95 pass 

96 _newclass = 0 

97 

98class measures(_object): 

99 """Proxy of C++ casac::measures class.""" 

100 

101 __swig_setmethods__ = {} 

102 __setattr__ = lambda self, name, value: _swig_setattr(self, measures, name, value) 

103 __swig_getmethods__ = {} 

104 __getattr__ = lambda self, name: _swig_getattr(self, measures, name) 

105 __repr__ = _swig_repr 

106 

107 def __init__(self): 

108 """__init__(self) -> measures""" 

109 this = _measures.new_measures() 

110 try: 

111 self.this.append(this) 

112 except __builtin__.Exception: 

113 self.this = this 

114 

115 def dirshow(self, *args, **kwargs): 

116 """ 

117 dirshow(self, _v) -> string 

118 

119 

120 

121 Summary: 

122 Show direction measure as a string.  

123 

124 Description: 

125 

126 

127 dirshow will convert a direction measure to a string 

128 

129 Input Parameters: 

130 v a direction measure value to be converted to string  

131 

132 Example: 

133 

134 print 't----t dirshow Ex 1 t----' 

135 print me.dirshow(me.direction('venus')) 

136 #[0, 90] deg VENUS 

137 

138 -------------------------------------------------------------------------------- 

139 

140 """ 

141 return _measures.measures_dirshow(self, *args, **kwargs) 

142 

143 

144 def show(self, *args, **kwargs): 

145 """ 

146 show(self, _v, _refcode) -> string 

147 

148 

149 

150 Summary: 

151 Show a measure as a string  

152 

153 Description: 

154 

155 

156 show will convert a measure to a string. 

157 

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

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

160 

161 Input Parameters: 

162 v measure value to be converted to string 

163 refcode add the reference code to output 

164 

165 Example: 

166 

167 print 't----t show Ex 1 t----' 

168 print me.show(me.frequency('lsrk', qa.constants('HI'))) 

169 #1.42041e+09 Hz LSRK 

170 print me.show(me.frequency('lsrk', qa.constants('HI')), refcode=false) 

171 #1.42041e+09 Hz 

172 

173 -------------------------------------------------------------------------------- 

174 

175 """ 

176 return _measures.measures_show(self, *args, **kwargs) 

177 

178 

179 def epoch(self, *args, **kwargs): 

180 """ 

181 epoch(self, _rf, _v0, _off) -> record * 

182 

183 

184 

185 Summary: 

186 define an epoch measure 

187 

188 Description: 

189 

190 

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

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

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

194 

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

196 epoch. Allowable reference codes are: 

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

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

199 

200 begin{verbatim} 

201 print 't----t epoch Ex 1 t----' 

202 print me.listcodes(me.epoch()) 

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

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

205 # 

206 end{verbatim} 

207 

208 See quantity for possible time formats. 

209 

210 Input Parameters: 

211 rf reference code 

212 v0 epoch value 

213 off optional offset epoch measure 

214 

215 Example: 

216 

217 print 't----t epoch Ex 2 t----' 

218 print me.epoch('utc','today') 

219 #{'m0': {'value': 54048.861237743055, 'unit': 'd'}, 

220 # 'refer': 'UTC', 

221 # 'type': 'epoch'} 

222 

223 -------------------------------------------------------------------------------- 

224 

225 """ 

226 return _measures.measures_epoch(self, *args, **kwargs) 

227 

228 

229 def direction(self, *args, **kwargs): 

230 """ 

231 direction(self, _rf, _v0, _v1, _off) -> record * 

232 

233 

234 

235 Summary: 

236 define a direction measure 

237 

238 Description: 

239 

240 

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

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

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

244 

245 and optionally it can specify an 

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

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

248 SUPERGAL ECLIPTIC MECLIPTIC TECLIPTIC MERCURY 

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

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

251 

252 begin{verbatim} 

253 print 't----t direction Ex 1 t----' 

254 print me.listcodes(me.direction()) 

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

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

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

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

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

260 #'SUN', 'MOON', 'COMET']} 

261 end{verbatim} 

262 

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

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

265 See quantity for possible angle formats. 

266 

267 Input Parameters: 

268 rf reference code 

269 v0 longitude 

270 v1 latitude 

271 off optional offset direction measure 

272 

273 Example: 

274 

275 print 't----t direction Ex 2 t----' 

276 print me.direction('j2000','30deg','40deg') 

277 #{'m0': {'value': 0.52359877559829882, 'unit': 'rad'}, 

278 # 'm1': {'value': 0.69813170079773168, 'unit': 'rad'}, 

279 # 'refer': 'J2000', 

280 # 'type': 'direction'} 

281 # 

282 print me.direction('mars') 

283 #{'m0': {'value': 0.0, 'unit': 'rad'}, 

284 # 'm1': {'value': 1.5707963267948966, 'unit': 'rad'}, 

285 # 'refer': 'MARS', 

286 # 'type': 'direction'} 

287 

288 -------------------------------------------------------------------------------- 

289 

290 """ 

291 return _measures.measures_direction(self, *args, **kwargs) 

292 

293 

294 def getvalue(self, *args, **kwargs): 

295 """ 

296 getvalue(self, _v) -> record * 

297 

298 

299 

300 Summary: 

301 get the value of a measure 

302 

303 Description: 

304 

305 

306 getvalue gets the actual implementation value of the measure. 

307 

308 Input Parameters: 

309 v measure (array of measures) 

310 

311 Example: 

312 

313 print 't----t getvalue Ex 1 t----' 

314 b=me.direction('j2000','0deg','80deg') 

315 print me.getvalue(b) 

316 #{'m0': {'value': 0.0, 'unit': 'rad'}, 

317 # 'm1': {'value': 1.3962634015954634, 'unit': 'rad'}} 

318 

319 -------------------------------------------------------------------------------- 

320 

321 """ 

322 return _measures.measures_getvalue(self, *args, **kwargs) 

323 

324 

325 def gettype(self, *args, **kwargs): 

326 """ 

327 gettype(self, _v) -> string 

328 

329 

330 

331 Summary: 

332 get the type of a measure 

333 

334 Description: 

335 

336 

337 gettype gets the actual type of the measure. 

338 

339 Input Parameters: 

340 v measure (array of measures) 

341 

342 Example: 

343 

344 print 't----t gettype Ex 1 t----' 

345 b=me.direction('j2000','0deg','80deg') 

346 print me.getvalue(b) 

347 #{'m0': {'value': 0.0, 'unit': 'rad'}, 

348 # 'm1': {'value': 1.3962634015954634, 'unit': 'rad'}} 

349 print me.gettype(b) 

350 #'Direction' 

351 

352 -------------------------------------------------------------------------------- 

353 

354 """ 

355 return _measures.measures_gettype(self, *args, **kwargs) 

356 

357 

358 def getref(self, *args, **kwargs): 

359 """ 

360 getref(self, _v) -> string 

361 

362 

363 

364 Summary: 

365 get the reference code of a measure 

366 

367 Description: 

368 

369 

370 gettype gets the actual reference code of the measure. 

371 

372 Input Parameters: 

373 v measure (array of measures) 

374 

375 Example: 

376 

377 print 't----t getref Ex 1 t----' 

378 b=me.direction('j2000','0deg','80deg') 

379 print me.getvalue(b) 

380 #{'m0': {'value': 0.0, 'unit': 'rad'}, 

381 # 'm1': {'value': 1.3962634015954634, 'unit': 'rad'}} 

382 print me.gettype(b) 

383 #'Direction' 

384 print me.getref(b) 

385 #'J2000' 

386 

387 -------------------------------------------------------------------------------- 

388 

389 """ 

390 return _measures.measures_getref(self, *args, **kwargs) 

391 

392 

393 def getoffset(self, *args, **kwargs): 

394 """ 

395 getoffset(self, _v) -> record * 

396 

397 

398 

399 Summary: 

400 get the offset of a measure 

401 

402 Description: 

403 

404 

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

406 given. 

407 

408 Input Parameters: 

409 v measure (array of measures) 

410 

411 Example: 

412 

413 print 't----t getoffset Ex 1 t----' 

414 b=me.direction('j2000','0deg','80deg') 

415 print me.getvalue(b) 

416 #{'m0': {'value': 0.0, 'unit': 'rad'}, 

417 # 'm1': {'value': 1.3962634015954634, 'unit': 'rad'}} 

418 print me.gettype(b) 

419 #'Direction' 

420 print me.getref(b) 

421 #'J2000' 

422 print me.getoffset(b) 

423 #{} 

424 

425 -------------------------------------------------------------------------------- 

426 

427 """ 

428 return _measures.measures_getoffset(self, *args, **kwargs) 

429 

430 

431 def cometname(self): 

432 """ 

433 cometname(self) -> string 

434 

435 

436 

437 Summary: 

438 get the current comet name 

439 

440 Description: 

441 

442 

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

444 

445 Example: 

446 

447 print 't----t cometname Ex 1 t----' 

448 print me.cometname() 

449 #Thu Nov 9 21:27:25 2006 WARN : 

450 #Method cometname fails! No Comet table present 

451 #'' 

452 

453 -------------------------------------------------------------------------------- 

454 

455 """ 

456 return _measures.measures_cometname(self) 

457 

458 

459 def comettype(self): 

460 """ 

461 comettype(self) -> string 

462 

463 

464 

465 Summary: 

466 get the current comet table type 

467 

468 Description: 

469 

470 

471 comettype gets the comet table type (apparent or topocentric) 

472 

473 Example: 

474 

475 print 't----t comettype Ex 1 t----' 

476 print me.comettype() 

477 # 'none' 

478 

479 -------------------------------------------------------------------------------- 

480 

481 """ 

482 return _measures.measures_comettype(self) 

483 

484 

485 def cometdist(self): 

486 """ 

487 cometdist(self) -> record * 

488 

489 

490 

491 Summary: 

492 get the distance of the current comet in the current frame 

493 

494 Description: 

495 

496 

497 cometdist returns the distance in AU of the current comet in the current frame, 

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

499 

500 

501 Example: 

502 

503 print 't----t cometdist Ex 1 t----' 

504 # Directory with several Solar System ephemerides for setjy. 

505 cometdir = os.getenv('CASAPATH').split()[0] + '/data/ephemerides/JPL-Horizons/' 

506 me.framecomet(cometdir + 'Ganymede_55438-56292dUTC.tab') 

507 # Out[5]: True 

508 me.doframe(me.epoch('utc', '2011/01/03/17:00:00')) 

509 me.doframe(me.observatory('ALMA')) 

510 gandist = me.cometdist() 

511 print gandist 

512 # {'value': 5.1241088343892631, 'unit': 'AU'} 

513 

514 -------------------------------------------------------------------------------- 

515 

516 """ 

517 return _measures.measures_cometdist(self) 

518 

519 

520 def cometangdiam(self): 

521 """ 

522 cometangdiam(self) -> record * 

523 

524 

525 

526 Summary: 

527 get the angular diameter of the current comet in the current frame 

528 

529 Description: 

530 

531 

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

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

534 

535 

536 Example: 

537 

538 print 't----t cometangdiam Ex 1 t----' 

539 # Directory with several Solar System ephemerides for setjy. 

540 cometdir = os.getenv('CASAPATH').split()[0] + '/data/ephemerides/JPL-Horizons/' 

541 me.framecomet(cometdir + 'Ganymede_55438-56292dUTC.tab') 

542 # Out[5]: True 

543 me.doframe(me.epoch('utc', '2011/01/03/17:00:00')) 

544 me.doframe(me.observatory('ALMA')) 

545 gad = me.cometangdiam() 

546 print gad 

547 # {'unit': 'rad', 'value': 6.8679673431729014e-06} 

548 

549 -------------------------------------------------------------------------------- 

550 

551 """ 

552 return _measures.measures_cometangdiam(self) 

553 

554 

555 def comettopo(self): 

556 """ 

557 comettopo(self) -> record * 

558 

559 

560 

561 Summary: 

562 get the current comet table coordinates 

563 

564 Description: 

565 

566 

567 comettopo gets the comet table's topographic coordinates used. 

568 

569 Example: 

570 

571 print 't----t comettopo Ex 1 t----' 

572 print me.comettopo() 

573 #Thu Nov 9 21:45:40 2006 WARN : 

574 #Method comettopo fails! No Topocentric Comet table present 

575 #{'value': [0.0], 'unit': ''} 

576 

577 -------------------------------------------------------------------------------- 

578 

579 """ 

580 return _measures.measures_comettopo(self) 

581 

582 

583 def framecomet(self, *args, **kwargs): 

584 """ 

585 framecomet(self, _v) -> bool 

586 

587 

588 

589 Summary: 

590 set the current comet table 

591 

592 Description: 

593 

594 

595 framecomet will put the specified comet table in the frame. 

596 

597 Input Parameters: 

598 v name of a table 

599 

600 Example: 

601 

602 print 't----t framecomet Ex 1 t----' 

603 print me.framecomet('VGEO') 

604 #True 

605 print me.showframe() 

606 #'Frame: VENUS comet between MJD 50802.7 and 50803.1' 

607 print me.cometname() 

608 #'VENUS' 

609 print me.comettype() 

610 #'APP' 

611 print me.doframe(me.epoch('et',qa.quantity('1997/12/20/17:30:0'))) 

612 #True 

613 print me.measure(me.direction('comet'),'app') 

614 #{'m0': {'value': -0.94936485919663083, 'unit': 'rad'}, 

615 # 'm1': {'value': -0.34710256485894436, 'unit': 'rad'}, 

616 # 'refer': 'APP', 

617 # 'type': 'direction'} 

618 

619 -------------------------------------------------------------------------------- 

620 

621 """ 

622 return _measures.measures_framecomet(self, *args, **kwargs) 

623 

624 

625 def position(self, *args, **kwargs): 

626 """ 

627 position(self, _rf, _v0, _v1, _v2, _off) -> record * 

628 

629 

630 

631 Summary: 

632 define a position measure 

633 

634 Description: 

635 

636 

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

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

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

640 

641 and optionally it can specify an 

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

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

644 Reference Frame). 

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

646 

647 begin{verbatim} 

648 print 't----t position Ex 1 t----' 

649 print me.listcodes(me.position()) 

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

651 end{verbatim} 

652 

653 The position quantity values should be either longitude 

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

655 See quantity for possible angle formats. 

656 

657 Input Parameters: 

658 rf reference code 

659 v0 longitude or x 

660 v1 latitude or y 

661 v2 height or z 

662 off optional offset position measure 

663 

664 Example: 

665 

666 print 't----t position Ex 2 t----' 

667 print me.position('wgs84','30deg','40deg','10m') 

668 #{'m0': {'value': 0.52359877559829882, 'unit': 'rad'}, 

669 # 'm1': {'value': 0.6981317007977319, 'unit': 'rad'}, 

670 # 'm2': {'value': 9.9999999999999982, 'unit': 'm'}, 

671 # 'refer': 'WGS84', 

672 # 'type': 'position'} 

673 print me.observatory('ATCA') 

674 #{'m0': {'value': 2.6101423190348916, 'unit': 'rad'}, 

675 # 'm1': {'value': -0.5261379196128062, 'unit': 'rad'}, 

676 # 'm2': {'value': 6372960.2577234386, 'unit': 'm'}, 

677 # 'refer': 'ITRF', 

678 # 'type': 'position'} 

679 

680 ###One can use a quantity-vectors especially when dealing with multiple antenna positions for e.g for 3 positions 

681 

682 ants=me.position('itrf',qa.quantity([3828763.11,3828746.55, 3828727.43],'m'), qa.quantity([442449.106,442592.14, 442580.12],'m'), 

683 qa.quantity([5064923.01, 5064923.01, 5064923.51],'m')) 

684 

685 print ants 

686 

687 #{'m0': {'unit': 'rad', 

688 # 'value': array([ 0.11504897, 0.11508633, 0.1150838 ])}, 

689 # 'm1': {'unit': 'rad', 

690 # 'value': array([ 0.92031276, 0.92031276, 0.92031535])}, 

691 # 'm2': {'unit': 'm', 

692 # 'value': array([ 6364639.28758924, 6364639.27051283, 6364627.33064587])}, 

693 # 'refer': 'ITRF', 

694 # 'type': 'position'} 

695 

696 -------------------------------------------------------------------------------- 

697 

698 """ 

699 return _measures.measures_position(self, *args, **kwargs) 

700 

701 

702 def observatory(self, *args, **kwargs): 

703 """ 

704 observatory(self, _name) -> record * 

705 

706 

707 

708 Summary: 

709 get position of an observatory 

710 

711 Description: 

712 

713 

714 observatory will give you the position of an observatory as given in the 

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

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

717 me.obslist() tool function):: 

718 

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

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

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

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

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

724 'Effelsberg' 'MWA32T' }. 

725 

726 Input Parameters: 

727 name observatory name - case insensitive 

728 

729 Example: 

730 

731 print 't----t observatory Ex 1 t----' 

732 print me.observatory('ATCA') 

733 #{'m0': {'value': 2.6101423190348916, 'unit': 'rad'}, 

734 # 'm1': {'value': -0.5261379196128062, 'unit': 'rad'}, 

735 # 'm2': {'value': 6372960.2577234386, 'unit': 'm'}, 

736 # 'refer': 'ITRF', 

737 # 'type': 'position'} 

738 

739 -------------------------------------------------------------------------------- 

740 

741 """ 

742 return _measures.measures_observatory(self, *args, **kwargs) 

743 

744 

745 def obslist(self): 

746 """ 

747 obslist(self) -> std::vector< std::string > 

748 

749 

750 

751 Summary: 

752 get a list of known observatories 

753 

754 Description: 

755 

756 

757 obslist will give you an array of strings of the 

758 observatories known in the Observatories table. 

759 

760 Example: 

761 

762 print 't----t obslist Ex 1 t----' 

763 print me.obslist() 

764 

765 #['ALMA' 'ARECIBO' 'ATCA' 'BIMA' 'CLRO' 'DRAO' 'DWL' 'GB' 'GBT' 'GMRT' 

766 #'IRAM PDB' 'IRAM_PDB' 'JCMT' 'MOPRA' 'MOST' 'NRAO12M' 'NRAO_GBT' 'PKS' 

767 #'SAO SMA' 'SMA' 'VLA' 'VLBA' 'WSRT' 'ATF' 'ATA' 'CARMA' 'ACA' 'OSF' 

768 #'OVRO_MMA' 'EVLA' 'ASKAP' 'APEX' 'SMT' 'NRO' 'ASTE' 'LOFAR' 'MeerKAT' 

769 #'KAT-7' 'EVN' 'LWA1' 'PAPER_SA' 'PAPER_GB' 'e-MERLIN' 'MERLIN2' 

770 #'Effelsberg' 'MWA32T'] 

771 

772 -------------------------------------------------------------------------------- 

773 

774 """ 

775 return _measures.measures_obslist(self) 

776 

777 

778 def linelist(self): 

779 """ 

780 linelist(self) -> string 

781 

782 

783 

784 Summary: 

785 get a list of known spectral lines 

786 

787 Description: 

788 

789 

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

791 known in the Lines table. 

792 

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

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

795 the tens of thousands of lines. 

796 

797 Example: 

798 

799 print 't----t linelist Ex 1 t----' 

800 print me.linelist() 

801 #'C109A CI CII166A DI H107A H110A H138B H166A H240A H272A 

802 # H2CO HE110A HE138B HI OH1612 OH1665 OH1667 OH1720' 

803 

804 -------------------------------------------------------------------------------- 

805 

806 """ 

807 return _measures.measures_linelist(self) 

808 

809 

810 def spectralline(self, *args, **kwargs): 

811 """ 

812 spectralline(self, _name) -> record * 

813 

814 

815 

816 Summary: 

817 get frequency of a spectral line 

818 

819 Description: 

820 

821 

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

823 can be obtained by me.linelist(). 

824 

825 Input Parameters: 

826 name name 

827 

828 Example: 

829 

830 print 't----t spectralline Ex 1 t----' 

831 print me.spectralline('HI') 

832 #{'m0': {'value': 1420405751.786, 'unit': 'Hz'}, 

833 # 'refer': 'REST', 

834 # 'type': 'frequency'} 

835 

836 -------------------------------------------------------------------------------- 

837 

838 """ 

839 return _measures.measures_spectralline(self, *args, **kwargs) 

840 

841 

842 def sourcelist(self): 

843 """ 

844 sourcelist(self) -> string 

845 

846 

847 

848 Summary: 

849 get a list of known sources 

850 

851 Description: 

852 

853 

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

855 known in the Sources table. 

856 

857 Example: 

858 

859 print 't----t sourcelist Ex 1 t----' 

860 print me.sourcelist()[0:62] 

861 #'0002-478 0003+380 0003-066 0007+106 0007+171 0008-264 0008-421' 

862 #...... 

863 

864 -------------------------------------------------------------------------------- 

865 

866 """ 

867 return _measures.measures_sourcelist(self) 

868 

869 

870 def source(self, *args, **kwargs): 

871 """ 

872 source(self, _name) -> record * 

873 

874 

875 

876 Summary: 

877 get direction of a source 

878 

879 Description: 

880 

881 

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

883 can be obtained by me.sourcelist(). 

884 

885 Input Parameters: 

886 name name 

887 

888 Example: 

889 

890 print 't----t source Ex 1 t----' 

891 print me.source() 

892 print me.source('1934-638') 

893 # Out[19]: 

894 #{'m0': {'value': -1.1370073467795063, 'unit': 'rad'}, 

895 # 'm1': {'value': -1.1119959323803881, 'unit': 'rad'}, 

896 # 'refer': 'ICRS', 

897 # 'type': 'direction'} 

898 

899 -------------------------------------------------------------------------------- 

900 

901 """ 

902 return _measures.measures_source(self, *args, **kwargs) 

903 

904 

905 def frequency(self, *args, **kwargs): 

906 """ 

907 frequency(self, _rf, _v0, _off) -> record * 

908 

909 

910 

911 Summary: 

912 define a frequency measure 

913 

914 Description: 

915 

916 

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

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

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

920 

921 and optionally it can specify an 

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

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

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

925 begin{verbatim} 

926 print 't----t frequency Ex 1 t----' 

927 print me.listcodes(me.frequency()) 

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

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

930 end{verbatim} 

931 

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

933 (examples all give same frequency): 

934 begin{itemize} 

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

936 item value as frequency: 2Hz 

937 item value in angular frequency: 720deg/s 

938 item value as length: 149896km 

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

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

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

942 end{itemize} 

943 

944 Input Parameters: 

945 rf reference code 

946 v0 frequency/wavelength/ldots 

947 off optional offset frequency measure 

948 

949 Example: 

950 

951 print 't----t frequency Ex 2 t----' 

952 print me.frequency('lsrk','5GHz') 

953 #{'m0': {'value': 5000000000.0, 'unit': 'Hz'}, 

954 # 'refer': 'LSRK', 

955 # 'type': 'frequency'} 

956 print me.frequency('lsrk','21cm') 

957 #{'m0': {'value': 1427583133.3333333, 'unit': 'Hz'}, 

958 # 'refer': 'LSRK', 

959 # 'type': 'frequency'} 

960 

961 -------------------------------------------------------------------------------- 

962 

963 """ 

964 return _measures.measures_frequency(self, *args, **kwargs) 

965 

966 

967 def doppler(self, *args, **kwargs): 

968 """ 

969 doppler(self, _rf, _v0, _off) -> record * 

970 

971 

972 

973 Summary: 

974 define a doppler measure 

975 

976 Description: 

977 

978 

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

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

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

982 

983 and optionally it can specify an offset, 

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

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

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

987 

988 begin{verbatim} 

989 print 't----t doppler Ex 1 t----' 

990 print me.listcodes(me.doppler()) 

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

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

993 end{verbatim} 

994 

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

996 ratio of the light velocity, or in velocity. 

997 

998 Input Parameters: 

999 rf reference code 

1000 v0 doppler ratio/velocity 

1001 off optional offset doppler measure 

1002 

1003 Example: 

1004 

1005 Examples both give same doppler: 

1006 

1007 print 't----t doppler Ex 2 t----' 

1008 print me.doppler('radio','0.4') 

1009 #{'m0': {'value': 119916983.2, 'unit': 'm/s'}, 

1010 # 'refer': 'RADIO', 

1011 # 'type': 'doppler'} 

1012 print me.doppler('radio',qa.mul(qa.quantity('0.4'),qa.constants('c'))) 

1013 #{'m0': {'value': 119916983.2, 'unit': 'm/s'}, 

1014 # 'refer': 'RADIO', 

1015 # 'type': 'doppler'} 

1016 

1017 -------------------------------------------------------------------------------- 

1018 

1019 """ 

1020 return _measures.measures_doppler(self, *args, **kwargs) 

1021 

1022 

1023 def radialvelocity(self, *args, **kwargs): 

1024 """ 

1025 radialvelocity(self, _rf, _v0, _off) -> record * 

1026 

1027 

1028 

1029 Summary: 

1030 define a radialvelocity measure 

1031 

1032 Description: 

1033 

1034 

1035 radialvelocity defines a radialvelocity measure from the CLI. It has to 

1036 specify a reference code, radialvelocity quantity value (see introduction for 

1037 the action on a 

1038 scalar quantity with either a vector or scalar value), 

1039 

1040 and optionally it 

1041 can specify an offset, which in itself has to be a radialvelocity. 

1042 Allowable reference codes are: 

1043 {em LSRK LSRD BARY GEO TOPO GALACTO LGROUP CMB}. 

1044 Note that additional ones may become available. Check in casa with: 

1045 

1046 begin{verbatim} 

1047 print 't----t radialvelocity Ex 1 t----' 

1048 print me.listcodes(me.radialvelocity()) 

1049 # Out[17]: 

1050 #{'extra': [], 

1051 # 'normal': ['LSRK', 'LSRD', 'BARY', 'GEO', 'TOPO', 'GALACTO', 

1052 # 'LGROUP', 'CMB']} 

1053 end{verbatim} 

1054 The radialvelocity quantity values should be given as velocity. 

1055 

1056 Input Parameters: 

1057 rf reference code 

1058 v0 radial velocity 

1059 off optional offset radialvelocity measure 

1060 

1061 Example: 

1062 

1063 print 't----t radialvelocity Ex 2 t----' 

1064 print me.radialvelocity('lsrk','20km/s') 

1065 # Out[18]: 

1066 #{'m0': {'value': 20000.0, 'unit': 'm/s'}, 

1067 # 'refer': 'LSRK', 

1068 # 'type': 'radialvelocity'} 

1069 

1070 -------------------------------------------------------------------------------- 

1071 

1072 """ 

1073 return _measures.measures_radialvelocity(self, *args, **kwargs) 

1074 

1075 

1076 def shift(self, *args, **kwargs): 

1077 """ 

1078 shift(self, _v, _offset, _pa) -> record * 

1079 

1080 

1081 

1082 Summary: 

1083 Shift a direction measure by an offset angle at a position angle. 

1084 

1085 Description: 

1086 

1087 

1088 This method calculates the direction measure located at the specified offset angular amount along the specified 

1089 position angle from the specified direction measure. 

1090 

1091 

1092 Input Parameters: 

1093 v The direction measure to shift, represented as a record. 

1094 offset The angular offset, represented as a quantity record or string. 

1095 pa Position angle of the offset, measured from the positive latitude axis through the positive longitude axis. 

1096 

1097 Example: 

1098 

1099 v = me.direction('J2000', '13:22:44', '-50.20.20') 

1100 # shift along 4 arcminues at a pa of 30 degrees. 

1101 offset = me.shift(v, offset='4arcmin', pa='30deg') 

1102 

1103 -------------------------------------------------------------------------------- 

1104 

1105 """ 

1106 return _measures.measures_shift(self, *args, **kwargs) 

1107 

1108 

1109 def uvw(self, *args, **kwargs): 

1110 """ 

1111 uvw(self, _rf, _v0, _v1, _v2, _off) -> record * 

1112 

1113 

1114 

1115 Summary: 

1116 define a uvw measure 

1117 

1118 Description: 

1119 

1120 

1121 uvw defines a uvw measure from the CLI. It has to specify a 

1122 reference code, uvw quantity values (see introduction for the action on a 

1123 scalar quantity with either a vector or scalar value), and optionally it can specify an 

1124 offset, which in itself has to be a uvw. Allowable reference codes are 

1125 ITRF and the direction ones. 

1126 

1127 Note that additional ones may become available. Check in casa with:: 

1128 

1129 print 't----t uvw Ex 1 t----' 

1130 print me.listcodes(me.uvw()) 

1131 

1132 { 

1133 'normal': array(['J2000', 'JMEAN', 'JTRUE', 'APP', 'B1950', 'B1950_VLA', 'BMEAN', 

1134 'BTRUE', 'GALACTIC', 'HADEC', 'AZEL', 'AZELSW', 'AZELNE', 'AZELGEO', 

1135 'AZELSWGEO', 'AZELNEGEO', 'JNAT', 'ECLIPTIC', 'MECLIPTIC', 

1136 'TECLIPTIC', 'SUPERGAL', 'ITRF', 'TOPO', 'ICRS'], dtype='|S10'), 

1137 'extra': array([], dtype='|S1') 

1138 } 

1139 

1140 The uvw quantity values should be either longitude 

1141 (angle), latitude(angle) and height(length); or x,y,z (length). 

1142 See quantity for possible angle formats. 

1143 

1144 Input Parameters: 

1145 rf reference code 

1146 v0 longitude or x 

1147 v1 latitude or y 

1148 v2 height or z 

1149 off optional offset uvw measure 

1150 

1151 Example: 

1152 

1153 print 't----t uvw Ex 2 t----' 

1154 print me.uvw('itrf','30deg','40deg','10m') 

1155 #{'m0': {'value': 0.52359877559829882, 'unit': 'rad'}, 

1156 # 'm1': {'value': 0.6981317007977319, 'unit': 'rad'}, 

1157 # 'm2': {'value': 9.9999999999999982, 'unit': 'm'}, 

1158 # 'refer': 'ITRF', 

1159 # 'type': 'uvw'} 

1160 print me.doframe(me.epoch('utc','today')) 

1161 #True 

1162 print me.doframe(me.observatory('ALMA')) 

1163 #True 

1164 print me.doframe(me.direction('mars')) 

1165 #True 

1166 print me.measure(me.uvw('itrf','30deg','40deg','10m'), 'j2000') 

1167 #{'m0': {'value': 0.52321924738347259, 'unit': 'rad'}, 

1168 # 'm1': {'value': 0.69813169995801672, 'unit': 'rad'}, 

1169 # 'm2': {'value': 10.0, 'unit': 'm'}, 

1170 # 'refer': 'J2000', 

1171 # 'type': 'uvw'} 

1172 

1173 -------------------------------------------------------------------------------- 

1174 

1175 """ 

1176 return _measures.measures_uvw(self, *args, **kwargs) 

1177 

1178 

1179 def touvw(self, *args, **kwargs): 

1180 """ 

1181 touvw(self, _v, _dot, _xyz) -> record * 

1182 

1183 

1184 

1185 Summary: 

1186 calculate a uvw measure from a baseline 

1187 

1188 Description: 

1189 

1190 

1191 touvw calculates a uvw measure from a baseline. Note that the 

1192 baseline does not have to be a proper {em baseline}, but can be a 

1193 series of positions (to call positions baselines see 

1194 asbaseline ) for speed reasons: 

1195 operations are linear and can be done on positions, which are 

1196 converted to baseline values at the end (with 

1197 expand ). 

1198 

1199 Whatever the reference code of the baseline, the returned {em uvw} will be 

1200 given in J2000. If the {em dot} argument is given, that variable 

1201 will be filled with a quantity array consisting of the time 

1202 derivative of the uvw (note that only the sidereal rate is taken 

1203 into account; not precession, earth tides and similar variations, 

1204 which are much smaller). If the {em xyz} variable is given, it will 

1205 be filled with the quantity values of the uvw measure. 

1206 

1207 The values of the input baselines can be given as a quantity 

1208 vector per x, y or z value. 

1209 

1210 uvw coordinates are calculated for a certain direction in the sky; 

1211 hence the frame has to contain the direction for the calculation to 

1212 work. Since the baseline and the sky rotate with respect of each 

1213 other, the time should be specified as well. 

1214 

1215 Input Parameters: 

1216 v baseline measure 

1217 

1218 Output Parameters: 

1219 dot uvw-dot (quantity array) 

1220 xyz uvw (quantity array) 

1221 

1222 Example: 

1223 

1224 print 't----t touvw Ex 1 t----' 

1225 print me.doframe(me.observatory('atca')) 

1226 #True 

1227 print me.doframe(me.source('1934-638')) 

1228 #True 

1229 print me.doframe(me.epoch('utc',qa.unit('today'))) 

1230 #True 

1231 b=me.baseline('itrf','10m','20m','30m') 

1232 print me.touvw(b) 

1233 #{'dot': {'unit': 'm/s', 

1234 # 'value': [-0.0011912452908351659, 

1235 # -0.00098731747136827593, 

1236 # -0.00048769097314181744]}, 

1237 # 'return': {'m0': {'value': -0.094777304811312649, 'unit': 'rad'}, 

1238 # 'm1': {'value': -1.1509286139398101, 'unit': 'rad'}, 

1239 # 'm2': {'value': 37.416573867739416, 'unit': 'm'}, 

1240 # 'refer': 'J2000', 

1241 # 'type': 'uvw'}, 

1242 # 'xyz': {'unit': 'm', 

1243 # 'value': [15.184026188402472, 

1244 # -1.4434256399579168, 

1245 # -34.166677788919138]}} 

1246 print me.getvalue(me.touvw(b)) 

1247 #{'m0': {'value': -0.094777304811312649, 'unit': 'rad'}, 

1248 # 'm1': {'value': -1.1509286139398101, 'unit': 'rad'}, 

1249 # 'm2': {'value': 37.416573867739416, 'unit': 'm'}} 

1250 print me.getvalue(me.touvw(b))['m0'] 

1251 #{'value': -0.094777304811312649, 'unit': 'rad'} 

1252 

1253 ###Or when you are dealing with multiple antennas 

1254 ####set the frame..i,e where, direction and when. 

1255 me.doframe(me.observatory('VLA')) 

1256 me.doframe(me.direction('J2000', '19h20m00', '20d10m00')) 

1257 me.doframe(me.epoch('utc', '2007/07/08/20:30:00')) 

1258 ####antenna positions 

1259 ants=me.position('itrf',qa.quantity([3828763.11,3828746.55, 3828727.43],'m'), qa.quantity([442449.106,442592.14, 442580.12],'m'), qa.quantity([5064923.01, 5064923.01, 5064923.51],'m')) 

1260 ###convert to baseline measures 

1261 bl=me.asbaseline(ants) 

1262 ###convert to uvw 

1263 me.touvw(bl) 

1264 

1265 #{'dot': {'unit': 'm/s', 

1266 # 'value': array([ 181.25190155, -73.29924893, 199.57974846, 181.25985238, 

1267 # -73.29691498, 199.57339353, 181.2583565 , -73.29668498, 

1268 # 199.57276731])}, 

1269 # 'return': {'m0': {'unit': 'rad', 

1270 # 'value': array([ 2.21611194, 2.21610131, 2.21609887])}, 

1271 # 'm1': {'unit': 'rad', 

1272 # 'value': array([ 0.6984441 , 0.69846521, 0.69846285])}, 

1273 # 'm2': {'unit': 'm', 

1274 # 'value': array([ 6364639.28758924, 6364639.27051283, 6364627.33064587])}, 

1275 # 'refer': 'J2000', 

1276 # 'type': 'uvw'}, 

1277 # 'xyz': {'unit': 'm', 

1278 # 'value': array([-2931661.69632123, 3894141.52172208, 4092634.20894752, 

1279 # -2931568.34776551, 3894103.64373003, 4092737.08879791, 

1280 # -2931559.14911939, 3894111.22249941, 4092717.89890567])}} 

1281 

1282 

1283 ####print the (n-1)n/2 baselines(u,v,w) 

1284 me.expand(me.touvw(bl)['return'])['xyz'] 

1285 #{'unit': 'm', 

1286 # 'value': array([ 93.34855573, -37.87799205, 102.8798504 , 102.54720184, 

1287 # -30.29922267, 83.68995815, 9.19864612, 7.57876938, 

1288 # -19.18989224])} 

1289 

1290 -------------------------------------------------------------------------------- 

1291 

1292 """ 

1293 return _measures.measures_touvw(self, *args, **kwargs) 

1294 

1295 

1296 def expand(self, *args, **kwargs): 

1297 """ 

1298 expand(self, _v, _xyz) -> record * 

1299 

1300 

1301 

1302 Summary: 

1303 expand n positions to n*(n-1)/2 baselines 

1304 

1305 Description: 

1306 

1307 

1308 expand calculates the differences between a series of given measure 

1309 values: it calculates baseline values from position values. The 

1310 returned value is a measure, but the value of the optional output 

1311 variable {em xyz} will be set to an array of values. 

1312 

1313 Input Parameters: 

1314 v measure (baseline, position or uvw measure) 

1315 

1316 Output Parameters: 

1317 xyz uvw (quantity array) 

1318 

1319 Example: 

1320 

1321 print 't----t expand Ex 1 t----' 

1322 b=me.baseline('itrf', qa.quantity([10, 20, 30], 'm'), qa.quantity([10, 20, 30], 'm'), qa.quantity([0, 0, 0], 'm')) 

1323 print me.expand(b) 

1324 me.expand(b) 

1325 

1326 #{'return': {'m0': {'unit': 'rad', 

1327 # 'value': array([ 0.78539816, 0.78539816, 0.78539816])}, 

1328 # 'm1': {'unit': 'rad', 'value': array([ 0., 0., 0.])}, 

1329 # 'm2': {'unit': 'm', 

1330 # 'value': array([ 14.14213562, 28.28427125, 14.14213562])}, 

1331 # 'refer': 'ITRF', 

1332 # 'type': 'baseline'}, 

1333 # 'xyz': {'unit': 'm', 

1334 # 'value': array([ 10., 10., 0., 20., 20., 0., 10., 10., 0.])}} 

1335 

1336 print me.expand(b)['xyz']['value'] 

1337 

1338 #[ 10. 10. 0. 20. 20. 0. 10. 10. 0.] 

1339 

1340 -------------------------------------------------------------------------------- 

1341 

1342 """ 

1343 return _measures.measures_expand(self, *args, **kwargs) 

1344 

1345 

1346 def earthmagnetic(self, *args, **kwargs): 

1347 """ 

1348 earthmagnetic(self, _rf, _v0, _v1, _v2, _off) -> record * 

1349 

1350 

1351 

1352 Summary: 

1353 define an earthmagnetic measure 

1354 

1355 Description: 

1356 

1357 

1358 earthmagnetic defines an earthmagnetic measure from the CLI. It needs 

1359 a reference code, earthmagnetic quantity values 

1360 (see introduction for the action on a 

1361 scalar quantity with either a vector or scalar value) if the reference code is not 

1362 for a model, and optionally it 

1363 can specify an offset, which in itself has to be a earthmagnetic. In general 

1364 you specify a model (IGRF is the default and the only one known) and convert 

1365 it to an explicit field. (See 

1366 

1367 http://fdd.gsfc.nasa.gov/IGRF.html 

1368 

1369 for information on the International Geomagnetic Reference Field). The 

1370 earthmagnetic quantity values should be either longitude (angle), 

1371 latitude(angle) and length(field strength); or x,y,z (field). 

1372 See quantity for possible angle formats. 

1373 

1374 Input Parameters: 

1375 rf reference code 

1376 v0 Field strength 

1377 v1 longitude 

1378 v2 latitude 

1379 off optional offset earthmagnetic measure 

1380 

1381 Example: 

1382 

1383 print 't----t earthmagnetic Ex 1 t----' 

1384 print me.earthmagnetic('igrf') 

1385 #{'type': 'earthmagnetic', 'refer': 'IGRF', 'm1': {'value': 0.0, 'unit': 'nT'}, 

1386 # 'm0': {'value': 6.1230317691118855e-23, 'unit': 'nT'}, 

1387 # 'm2': {'value': 9.9999999999999995e-07, 'unit': 'nT'}} 

1388 print me.doframe(me.observatory('atca')) 

1389 print me.doframe(me.source('1934-638')) 

1390 print me.doframe(me.epoch('utc',qa.unit('today'))) 

1391 print me.measure(me.earthmagnetic('igrf'), 'j2000') 

1392 #{'type': 'earthmagnetic', 'refer': 'J2000', 

1393 # 'm1': {'value': -8664.8767628222304, 'unit': 'nT'}, 

1394 # 'm0': {'value': 50544.054410564473, 'unit': 'nT'}, 

1395 # 'm2': {'value': 1799.5131920958615, 'unit': 'nT'}} 

1396 

1397 -------------------------------------------------------------------------------- 

1398 

1399 """ 

1400 return _measures.measures_earthmagnetic(self, *args, **kwargs) 

1401 

1402 

1403 def baseline(self, *args, **kwargs): 

1404 """ 

1405 baseline(self, _rf, _v0, _v1, _v2, _off) -> record * 

1406 

1407 

1408 

1409 Summary: 

1410 define a baseline measure 

1411 

1412 Description: 

1413 

1414 

1415 baseline defines a baseline measure from the CLI. It has to specify a 

1416 reference code, baseline quantity values (see introduction for the action on a 

1417 scalar quantity with either a vector or scalar value, and when a vector of 

1418 quantities is given), and optionally it can specify an 

1419 offset, which in itself has to be a baseline. Allowable reference codes are 

1420 ITRF and the direction ones. 

1421 

1422 Note that additional ones may become available. Check in casa with:: 

1423 

1424 print 't----t baseline Ex 1 t----' 

1425 print me.listcodes(me.baseline()) 

1426 # {'normal': array(['J2000', 'JMEAN', 'JTRUE', 'APP', 'B1950', 'B1950_VLA', 'BMEAN', 

1427 # 'BTRUE', 'GALACTIC', 'HADEC', 'AZEL', 'AZELSW', 'AZELNE', 'AZELGEO', 

1428 # 'AZELSWGEO', 'AZELNEGEO', 'JNAT', 'ECLIPTIC', 'MECLIPTIC', 

1429 # 'TECLIPTIC', 'SUPERGAL', 'ITRF', 'TOPO', 'ICRS'], 

1430 # dtype='|S10'), 'extra': array([], 

1431 # dtype='|S1')} 

1432 

1433 The baseline quantity values should be either longitude 

1434 (angle), latitude(angle) and height(length); or x,y,z (length). 

1435 See quantity for possible angle formats. 

1436 

1437 Input Parameters: 

1438 rf reference code 

1439 v0 longitude or x 

1440 v1 latitude or y 

1441 v2 height or z 

1442 off optional offset baseline measure 

1443 

1444 Example: 

1445 

1446 print 't----t Ex 2 t----' 

1447 print me.baseline('itrf','30deg','40deg','10m') 

1448 #{'m0': {'value': 0.52359877559829882, 'unit': 'rad'}, 

1449 # 'm1': {'value': 0.6981317007977319, 'unit': 'rad'}, 

1450 # 'm2': {'value': 9.9999999999999982, 'unit': 'm'}, 

1451 # 'refer': 'ITRF', 

1452 # 'type': 'baseline'} 

1453 print me.doframe(me.observatory('atca')) 

1454 print me.doframe(me.source('1934-638')) 

1455 print me.doframe(me.epoch('utc',qa.unit('today'))) 

1456 print me.measure(me.baseline('itrf','30deg','40deg','10m'), 'J2000') 

1457 #{'m0': {'value': 0.58375325605991979, 'unit': 'rad'}, 

1458 # 'm1': {'value': 0.69758519780286155, 'unit': 'rad'}, 

1459 # 'm2': {'value': 9.9999999999999964, 'unit': 'm'}, 

1460 # 'refer': 'J2000', 

1461 # 'type': 'baseline'} 

1462 

1463 -------------------------------------------------------------------------------- 

1464 

1465 """ 

1466 return _measures.measures_baseline(self, *args, **kwargs) 

1467 

1468 

1469 def asbaseline(self, *args, **kwargs): 

1470 """ 

1471 asbaseline(self, _pos) -> record * 

1472 

1473 

1474 

1475 Summary: 

1476 define a baseline from a position measure 

1477 

1478 Description: 

1479 

1480 

1481 asbaseline converts a position measure into a baseline measure. No 

1482 actual baseline is calculated, since operations can be done on 

1483 positions, with subtractions to obtain baselines at a later stage. 

1484 

1485 Input Parameters: 

1486 pos position measure 

1487 

1488 Example: 

1489 

1490 print 't----t asbaseline Ex 1 t----' 

1491 

1492 ####An example of getting baselines with 3 antenna positions 

1493 #### Define the frame ; where, which-direction and when 

1494 me.doframe(me.observatory('VLA')) 

1495 me.doframe(me.direction('J2000', '19h20m00', '20d10m00')) 

1496 me.doframe(me.epoch('utc', '2007/07/08/20:30:00')) 

1497 

1498 ##antenna position 

1499 ants=me.position('itrf',qa.quantity([3828763.11,3828746.55, 3828727.43],'m'), qa.quantity([442449.106,442592.14, 442580.12],'m'), qa.quantity([5064923.01, 5064923.01, 5064923.51],'m')) 

1500 print ants 

1501 #{'type': 'position', 'refer': 'ITRF', 'm1': {'value': array([ 0.92031276, 0.92031276, 0.92031535]), 'unit': 'rad'}, 

1502 #'m0': {'value': array([ 0.11504897, 0.11508633, 0.1150838 ]), 'unit': 'rad'}, 

1503 #'m2': {'value': array([ 6364639.28758924, 6364639.27051283, 6364627.33064587]), 'unit': 'm'}} 

1504 

1505 bl=me.asbaseline(ants) 

1506 print bl 

1507 #{'type': 'baseline', 'refer': 'J2000', 'm1': {'value': array([ 0.92068328, 0.92068326, 0.92068585]), 'unit': 'rad'}, 

1508 #'m0': {'value': array([-2.08658811, -2.08655073, -2.08655326]), 'unit': 'rad'}, 

1509 #'m2': {'value': array([ 6364639.28758924, 6364639.27051283, 6364627.33064587]), 'unit': 'm'}} 

1510 

1511 me.expand(bl) 

1512 

1513 #{'return': {'m0': {'unit': 'rad', 

1514 # 'value': array([-0.51637894, -0.36575235, 1.50036599])}, 

1515 # 'm1': {'unit': 'rad', 

1516 # 'value': array([-0.00060966, 0.00302388, 0.02206414])}, 

1517 # 'm2': {'unit': 'm', 

1518 # 'value': array([ 143.98943974, 135.78652583, 22.58992696])}, 

1519 # 'refer': 'J2000', 

1520 # 'type': 'baseline'}, 

1521 # 'xyz': {'unit': 'm', 

1522 # 'value': array([ 1.25215025e+02, -7.10925354e+01, -8.77850493e-02, 

1523 # 1.26804339e+02, -4.85640980e+01, 4.10601842e-01, 

1524 # 1.58931410e+00, 2.25284374e+01, 4.98386892e-01])}} 

1525 

1526 -------------------------------------------------------------------------------- 

1527 

1528 """ 

1529 return _measures.measures_asbaseline(self, *args, **kwargs) 

1530 

1531 

1532 def listcodes(self, *args, **kwargs): 

1533 """ 

1534 listcodes(self, _ms) -> record * 

1535 

1536 

1537 

1538 Summary: 

1539 get known reference code names (list indices do not necessarily correspond to enumeration indices) 

1540 

1541 Description: 

1542 

1543 

1544 listcodes will produce the known reference codes for a specified measure 

1545 type. It will return a record with two entries. The first is a string vector 

1546 of all normal codes; the second a string vector (maybe empty) with all extra 

1547 codes (like planets). 

1548 NOTE: Synonyms and different code groups may be present in the code name lists. 

1549 The indices in these lists therefore do not necessarily correspond to 

1550 the internal CASA enumeration indices. 

1551 

1552 Input Parameters: 

1553 ms the measure type for which to list 

1554 

1555 Example: 

1556 

1557 print 't----t listcodes Ex 1 t----' 

1558 # Generate some direction 

1559 # Note that an empty or non-specified reference code will produce the 

1560 # measure with the default code for that measure type 

1561 a=me.direction() 

1562 print me.getref(a) 

1563 #'J2000' 

1564 print me.ismeasure(a) 

1565 #True 

1566 # Get the known reference codes for direction 

1567 print me.listcodes(a) 

1568 # {'normal': array(['J2000', 'JMEAN', 'JTRUE', 'APP', 'B1950', 'B1950_VLA', 'BMEAN', 

1569 # 'BTRUE', 'GALACTIC', 'HADEC', 'AZEL', 'AZELSW', 'AZELNE', 'AZELGEO', 

1570 # 'AZELSWGEO', 'AZELNEGEO', 'JNAT', 'ECLIPTIC', 'MECLIPTIC', 

1571 # 'TECLIPTIC', 'SUPERGAL', 'ITRF', 'TOPO', 'ICRS'], 

1572 # dtype='|S10'), 'extra': array(['MERCURY', 'VENUS', 'MARS', 'JUPITER', 'SATURN', 'URANUS', 

1573 # 'NEPTUNE', 'PLUTO', 'SUN', 'MOON', 'COMET'], 

1574 # dtype='|S8')} 

1575 

1576 -------------------------------------------------------------------------------- 

1577 

1578 """ 

1579 return _measures.measures_listcodes(self, *args, **kwargs) 

1580 

1581 

1582 def measure(self, *args, **kwargs): 

1583 """ 

1584 measure(self, _v, _rf, _off) -> record * 

1585 

1586 

1587 

1588 Summary: 

1589 convert a measure to another reference 

1590 

1591 Description: 

1592 

1593 

1594 measure converts measures (epoch, direction etc.) from one reference to 

1595 another. It will, for instance, convert a direction from J2000 to AZEL 

1596 representation.  

1597 Its arguments are a measure, an output reference code (see the individual 

1598 measures for the allowable codes (direction, 

1599 position, 

1600 epoch, 

1601 frequency, 

1602 doppler, 

1603 radialvelocity, 

1604 baseline, 

1605 uvw, 

1606 earthmagnetic)), and an optional offset of 

1607 the same type as the main measure. The offset will be subtracted from the 

1608 result before it is returned. 

1609 In some cases (see the individual measures for when), more information than 

1610 just a reference code is necessary. E.g. the above example of a conversion to 

1611 AZEL, needs to know for when, and where on Earth we want it. This information 

1612 is stored in a reference frame. Measures are set in the reference frame with 

1613 the doframe function. The frame is tool 

1614 wide. 

1615 

1616 {bf IMPORTANT NOTE:} 

1617 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 

1618 i.e (after setting the appropriate frames)  

1619 

1620 moonazel=me.measure(me.direction('moon'), 'AZELGEO') 

1621 moonJ2000=me.measure(moonazel, 'J2000') 

1622 

1623 Input Parameters: 

1624 v measure to be converted 

1625 rf output reference code 

1626 off optional output offset measure 

1627 

1628 Example: 

1629 

1630 print 't----t measure Ex 1 t----' 

1631 a = me.epoch('utc','today') # a time 

1632 print a 

1633 #{'m0': {'value': 54054.872957673608, 'unit': 'd'}, 

1634 # 'refer': 'UTC', 

1635 # 'type': 'epoch'} 

1636 print me.doframe(me.source('1934-638')) 

1637 print me.measure(a, 'tai')# convert to IAT 

1638 #{'m0': {'value': 54054.873339618054, 'unit': 'd'}, 

1639 # 'refer': 'TAI', 

1640 # 'type': 'epoch'} 

1641 print me.doframe(a)# set time in frame 

1642 #True 

1643 print me.doframe(me.observatory('ALMA'))# set position in frame 

1644 #True 

1645 b=me.direction('j2000', qa.toangle('0h'), '-30deg') # a direction 

1646 print b 

1647 #{'m0': {'value': 0.0, 'unit': 'rad'}, 

1648 # 'm1': {'value': -0.52359877559829882, 'unit': 'rad'}, 

1649 # 'refer': 'J2000', 

1650 # 'type': 'direction'} 

1651 print me.measure(b, 'azel')# convert to AZEL 

1652 #{'m0': {'value': 1.9244096810822324, 'unit': 'rad'}, 

1653 # 'm1': {'value': 0.76465385681363052, 'unit': 'rad'}, 

1654 # 'refer': 'AZEL', 

1655 # 'type': 'direction'} 

1656 print qa.angle(me.getvalue(me.measure(b,'azel'))['m0']) # show as angles 

1657 #['+110.15.38'] 

1658 print qa.angle(me.getvalue(me.measure(b,'azel'))['m1']) 

1659 #['+043.48.41'] 

1660 

1661 

1662 Another example: 

1663 

1664 print 't----t measure Ex 2 t----' 

1665 # Fill the frame with necessary information 

1666 print me.doframe(me.epoch('utc','today')) 

1667 #True 

1668 print me.doframe(me.observatory('ALMA')) 

1669 #True 

1670 print me.doframe(me.direction('mars')) 

1671 #True 

1672 a=qa.unit('1GHz') 

1673 print a 

1674 #{'value': 1.0, 'unit': 'GHz'} 

1675 m=me.frequency('lsrk',qa.quantity(qa.getvalue(a),qa.getunit(a))) 

1676 print m 

1677 #{'m0': {'value': 1000000000.0, 'unit': 'Hz'}, 

1678 # 'refer': 'LSRK', 

1679 # 'type': 'frequency'} 

1680 print me.measure(m,'lsrd') 

1681 #{'m0': {'value': 1000001766.3928765, 'unit': 'Hz'}, 

1682 # 'refer': 'LSRD', 

1683 # 'type': 'frequency'} 

1684 

1685 -------------------------------------------------------------------------------- 

1686 

1687 """ 

1688 return _measures.measures_measure(self, *args, **kwargs) 

1689 

1690 

1691 def doframe(self, *args, **kwargs): 

1692 """ 

1693 doframe(self, _v) -> bool 

1694 

1695 

1696 

1697 Summary: 

1698 save a measure as frame reference 

1699 

1700 Description: 

1701 

1702 

1703 doframe will set the measure specified as part of a frame. 

1704 

1705 If conversion from one type to another is necessary, with the 

1706 measure function, 

1707 the following frames 

1708 should be set if one of the reference types involved in the conversion is as 

1709 in the following lists. 

1710 {em Epoch} 

1711 

1712 UTC 

1713 TAI 

1714 LASTposition 

1715 LMST position 

1716 GMST1 

1717 GAST 

1718 UT1 

1719 UT2 

1720 TDT 

1721 TCG 

1722 TDB 

1723 TCD 

1724 

1725 {em Direction} 

1726 

1727 J2000 

1728 JMEANepoch 

1729 JTRUE epoch 

1730 APP epoch 

1731 B1950 

1732 BMEAN epoch 

1733 BTRUE epoch 

1734 GALACTIC 

1735 HADEC epochposition 

1736 AZELepoch position 

1737 SUPERGALACTIC 

1738 ECLIPTIC 

1739 MECLIPTIC epoch 

1740 TECLIPTICepoch 

1741 PLANETepoch [position] 

1742 

1743 {em Position} 

1744 

1745 WGS84 

1746 ITRF 

1747 

1748 {em Radial Velocity} 

1749 

1750 LSRK direction 

1751 LSRD direction 

1752 BARY direction 

1753 GEO directionepoch 

1754 TOPO directionepochposition 

1755 GALACTOdirection 

1756 

1757 {em Doppler} 

1758 

1759 RADIO 

1760 OPTICAL 

1761 Z 

1762 RATIO 

1763 RELATIVISTIC 

1764 BETA 

1765 GAMMA 

1766 

1767 {em Frequency} 

1768 

1769 REST directionradialvelocity 

1770 LSRK direction 

1771 LSRD direction 

1772 BARY direction 

1773 GEO directionepoch 

1774 TOPO directionepochposition 

1775 GALACTO 

1776 

1777 Input Parameters: 

1778 v measure to be set in frame 

1779 

1780 Example: 

1781 

1782 print 't----t doframe Ex 1 t----' 

1783 a = me.epoch('utc', 'today') # a time 

1784 print a 

1785 #{'m0': {'value': 54054.91671484954, 'unit': 'd'}, 

1786 # 'refer': 'UTC', 

1787 # 'type': 'epoch'} 

1788 print me.doframe(a)# set time in frame 

1789 #True 

1790 

1791 -------------------------------------------------------------------------------- 

1792 

1793 """ 

1794 return _measures.measures_doframe(self, *args, **kwargs) 

1795 

1796 

1797 def framenow(self): 

1798 """ 

1799 framenow(self) -> bool 

1800 

1801 

1802 

1803 Summary: 

1804 set the active frame time at now 

1805 

1806 Description: 

1807 

1808 

1809 framenow will fill the active frame time with the current date and time. 

1810 The different frame values necessary are described in the 

1811 doframe function 

1812 

1813 Example: 

1814 

1815 print 't----t framenow Ex 1 t----' 

1816 print me.framenow()# specify now as frame reference 

1817 #True 

1818 print me.showframe() # and show the current frame 

1819 #'Frame: Epoch: 54054::22:01:42.2880' 

1820 

1821 -------------------------------------------------------------------------------- 

1822 

1823 """ 

1824 return _measures.measures_framenow(self) 

1825 

1826 

1827 def showframe(self): 

1828 """ 

1829 showframe(self) -> string 

1830 

1831 

1832 

1833 Summary: 

1834 show the currently active frame reference 

1835 

1836 Description: 

1837 

1838 

1839 showframe will display the currently active reference frame values on the 

1840 terminal. The 

1841 different frame values necessary are described in the 

1842 doframe function. 

1843 The frame is 

1844 displayed on the terminal using the formatting as done for the 

1845 show function. 

1846 

1847 Example: 

1848 

1849 print 't----t showframe Ex 1 t----' 

1850 print me.doframe(me.epoch('utc','today'))# specify now as frame reference 

1851 #T 

1852 print me.showframe()# and show the current frame 

1853 #'Frame: Epoch: 54054::22:01:42.2880' 

1854 

1855 -------------------------------------------------------------------------------- 

1856 

1857 """ 

1858 return _measures.measures_showframe(self) 

1859 

1860 

1861 def toradialvelocity(self, *args, **kwargs): 

1862 """ 

1863 toradialvelocity(self, _rf, _v0) -> record * 

1864 

1865 

1866 

1867 Summary: 

1868 convert a doppler type value to a real radial velocity 

1869 

1870 Description: 

1871 

1872 

1873 toradialvelocity will convert a Doppler type value (e.g. in radio mode) to a 

1874 real radialvelocity. The type of velocity (e.g. LSRK) should be specified 

1875 

1876 Input Parameters: 

1877 rf radial velocity reference type 

1878 v0 doppler value measure 

1879 

1880 Example: 

1881 

1882 print 't----t toradialvelocity Ex 1 t----' 

1883 a = me.doppler('radio','0.4') 

1884 print a 

1885 # Out[4]: 

1886 #{'m0': {'value': 119916983.2, 'unit': 'm/s'}, 

1887 # 'refer': 'RADIO', 

1888 # 'type': 'doppler'} 

1889 print me.toradialvelocity('topo',a) 

1890 #{'m0': {'value': 141078803.7647059, 'unit': 'm/s'}, 

1891 # 'refer': 'TOPO', 

1892 # 'type': 'radialvelocity'} 

1893 

1894 -------------------------------------------------------------------------------- 

1895 

1896 """ 

1897 return _measures.measures_toradialvelocity(self, *args, **kwargs) 

1898 

1899 

1900 def tofrequency(self, *args, **kwargs): 

1901 """ 

1902 tofrequency(self, _rf, _v0, _rfq) -> record * 

1903 

1904 

1905 

1906 Summary: 

1907 convert a doppler type value to a frequency 

1908 

1909 Description: 

1910 

1911 

1912 tofrequency will convert a Doppler type value (e.g. in radio mode) to a 

1913 frequency. The type of frequency (e.g. LSRK) and a rest frequency (either as a 

1914 frequency quantity (e.g. qa.constants('HI')) or a frequency measure (e.g. 

1915 me.frequency('rest','5100MHz')) should be specified 

1916 

1917 Input Parameters: 

1918 rf frequency reference type 

1919 v0 doppler measure value 

1920 rfq rest frequency (frequency measure or freuency quantity) 

1921 

1922 Example: 

1923 

1924 print 't----t tofrequency Ex 1 t----' 

1925 a=me.doppler('radio','0.4') 

1926 print a 

1927 #{'m0': {'value': 119916983.2, 'unit': 'm/s'}, 

1928 # 'refer': 'RADIO', 

1929 # 'type': 'doppler'} 

1930 print me.tofrequency('lsrk',a,qa.constants('HI')) 

1931 #{'m0': {'value': 852243451.07159996, 'unit': 'Hz'}, 

1932 # 'refer': 'LSRK', 

1933 # 'type': 'frequency'} 

1934 

1935 -------------------------------------------------------------------------------- 

1936 

1937 """ 

1938 return _measures.measures_tofrequency(self, *args, **kwargs) 

1939 

1940 

1941 def todoppler(self, *args, **kwargs): 

1942 """ 

1943 todoppler(self, _rf, _v0, _rfq) -> record * 

1944 

1945 

1946 

1947 Summary: 

1948 convert a frequency or radialvelocity measure to a doppler measure 

1949 

1950 Description: 

1951 

1952 

1953 todoppler will convert a radialvelocity measure or a frequency measure to a 

1954 doppler measure. In the case of a frequency, a rest frequency has to be 

1955 specified. The type of doppler wanted (e.g. RADIO) has to be specified. 

1956 

1957 Input Parameters: 

1958 rf doppler reference type 

1959 v0 radial velocity or frequency measure 

1960 rfq rest frequency (frequency measure or frequency quantity) 

1961 

1962 Example: 

1963 

1964 print 't----t todoppler Ex 1 t----' 

1965 f = me.frequency('lsrk','1410MHz') # specify a frequency 

1966 print f 

1967 #{'m0': {'value': 1410000000.0, 'unit': 'Hz'}, 

1968 # 'refer': 'LSRK', 

1969 # 'type': 'frequency'} 

1970 print me.todoppler('radio', f, qa.constants('HI')) # give doppler, using HI rest 

1971 #{'m0': {'value': 2196249.8401180855, 'unit': 'm/s'}, 

1972 # 'refer': 'RADIO', 

1973 # 'type': 'doppler'} 

1974 

1975 -------------------------------------------------------------------------------- 

1976 

1977 """ 

1978 return _measures.measures_todoppler(self, *args, **kwargs) 

1979 

1980 

1981 def torestfrequency(self, *args, **kwargs): 

1982 """ 

1983 torestfrequency(self, _v0, _d0) -> record * 

1984 

1985 

1986 

1987 Summary: 

1988 convert a frequency and doppler measure to a rest frequency 

1989 

1990 Description: 

1991 

1992 

1993 torestfrequency will convert a frequency measure and a doppler measure 

1994 (e.g. obtained from another spectral line with a known rest frequency) to a 

1995 rest frequency. 

1996 

1997 Input Parameters: 

1998 v0 frequency reference type 

1999 d0 doppler measure value 

2000 

2001 Example: 

2002 

2003 print 't----t torestfrequency Ex 1 t----' 

2004 dp = me.doppler('radio', '2196.24984km/s') # a measured doppler speed 

2005 print dp 

2006 #{'m0': {'value': 2196249.8399999999, 'unit': 'm/s'}, 

2007 # 'refer': 'RADIO', 

2008 # 'type': 'doppler'} 

2009 f = me.frequency('lsrk','1410MHz') # a measured frequency 

2010 print f 

2011 #{'m0': {'value': 1410000000.0, 'unit': 'Hz'}, 

2012 # 'refer': 'LSRK', 

2013 # 'type': 'frequency'} 

2014 print me.torestfrequency(f, dp) # the corresponding rest frequency 

2015 #{'m0': {'value': 1420405751.7854364, 'unit': 'Hz'}, 

2016 # 'refer': 'REST', 

2017 # 'type': 'frequency'} 

2018 

2019 -------------------------------------------------------------------------------- 

2020 

2021 """ 

2022 return _measures.measures_torestfrequency(self, *args, **kwargs) 

2023 

2024 

2025 def rise(self, *args, **kwargs): 

2026 """ 

2027 rise(self, _crd, _ev) -> record * 

2028 

2029 

2030 

2031 Summary: 

2032 get rise and set sidereal time 

2033 

2034 Description: 

2035 

2036 

2037 rise will give the rise/set hour-angles of a source. It needs the position 

2038 in the frame, and a time. If the latter is not set, the current time will be 

2039 used. 

2040 

2041 Input Parameters: 

2042 crd direction of source (direction measure) 

2043 ev elevation angle limit 

2044 

2045 Example: 

2046 

2047 # NOT IMPLEMENTED 

2048 print 't----t rise Ex 1 t----' 

2049 print me.rise(me.direction('sun')) 

2050 #[rise=[value=267.12445, unit=deg], set=[value=439.029964, unit=deg]] 

2051 print qa.form.long(me.rise(me.direction('sun')).rise) 

2052 #17:48:29.868 

2053 # 

2054 

2055 -------------------------------------------------------------------------------- 

2056 

2057 """ 

2058 return _measures.measures_rise(self, *args, **kwargs) 

2059 

2060 

2061 def riseset(self, *args, **kwargs): 

2062 """ 

2063 riseset(self, _crd, _ev) -> record * 

2064 

2065 

2066 

2067 Summary: 

2068 get rise and set times 

2069 

2070 Description: 

2071 

2072 

2073 rise will give the rise/set times of a source. It needs the position 

2074 in the frame, and a time. If the latter is not set, the current time will be 

2075 used. The returned value is a record with a 'solved' field, which is F if the 

2076 source is always below or above the horizon. In that case the rise and set 

2077 fields will all have a string value. The record also returns a rise and set 

2078 record, with 'last' and 'utc' fields showing the rise and set times as epochs. 

2079 

2080 Input Parameters: 

2081 crd direction of source (direction measure) 

2082 ev elevation limit 

2083 

2084 Example: 

2085 

2086 # NOT IMPLEMENTED 

2087 print 't----t riseset Ex 1 t----' 

2088 print me.riseset(me.direction('sun')) 

2089 #[solved=T, 

2090 # rise=[last=[type=epoch, refer=LAST, m0=[value=0.0731388605, unit=d]], 

2091 # utc=[type=epoch, refer=UTC, m0=[value=52085.8964, unit=d]]], 

2092 # set=[last=[type=epoch, refer=LAST, m0=[value=0.455732593, unit=d]], 

2093 # utc=[type=epoch, refer=UTC, m0=[value=52086.2779, unit=d]]]] 

2094 print me.riseset(me.direction('sun'), qa.unit('80deg')) 

2095 #[solved=F, 

2096 # rise=[last=below, utc=below], 

2097 # set=[last=below, utc=below]] 

2098 print qa.form.long(me.riseset(me.direction('sun')).rise.utc.m0) 

2099 #21:30:47.439 

2100 # 

2101 

2102 -------------------------------------------------------------------------------- 

2103 

2104 """ 

2105 return _measures.measures_riseset(self, *args, **kwargs) 

2106 

2107 

2108 def posangle(self, *args, **kwargs): 

2109 """ 

2110 posangle(self, _m1, _m2) -> record * 

2111 

2112 

2113 

2114 Summary: 

2115 get position angle of two directions 

2116 

2117 Description: 

2118 

2119 

2120 posangle will give the position angle from a direction to another. I.e. the 

2121 angle in a direction between the direction to the North pole and the other 

2122 direction. 

2123 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. 

2124 

2125 Input Parameters: 

2126 m1 direction of source (direction measure) 

2127 m2 direction of other source (direction measure) 

2128 

2129 Example: 

2130 

2131 print 't----t posangle Ex 1 t----' 

2132 a=me.direction('j2000','0deg','70deg') 

2133 b=me.direction('j2000','0deg','80deg') 

2134 print me.posangle(a,b) 

2135 #{'value': -0.0, 'unit': 'deg'} 

2136 print me.separation(a,b) 

2137 #{'value': 9.9999999999999893, 'unit': 'deg'} 

2138 tim=me.epoch('utc','today') 

2139 print me.doframe(tim) 

2140 #True 

2141 pos=me.observatory('ATCA') 

2142 print me.doframe(pos) 

2143 #True 

2144 print me.posangle(a,b) 

2145 #{'value': -0.0, 'unit': 'deg'} 

2146 

2147 ###Example of how to calculate the parallactic angle of a given direction on thesky. 

2148 

2149 ###set the frames and epoch 

2150 

2151 -------------------------------------------------------------------------------- 

2152 

2153 """ 

2154 return _measures.measures_posangle(self, *args, **kwargs) 

2155 

2156 

2157 def separation(self, *args, **kwargs): 

2158 """ 

2159 separation(self, _m1, _m2) -> record * 

2160 

2161 

2162 

2163 Summary: 

2164 get separation angle between two directions 

2165 

2166 Description: 

2167 

2168 

2169 separation will give the separation of a direction from another as an angle. 

2170 

2171 Input Parameters: 

2172 m1 direction of source (direction measure) 

2173 m2 direction of other source (direction measure) 

2174 

2175 Example: 

2176 

2177 print 't----t separation Ex 1 t----' 

2178 a=me.direction('j2000','0deg','70deg') 

2179 b=me.direction('j2000','0deg','80deg') 

2180 print me.separation(a,b) 

2181 #{'value': 9.9999999999999893, 'unit': 'deg'} 

2182 tim = me.epoch('utc','today') # set the time 

2183 print me.doframe(tim) 

2184 #True 

2185 pos = me.observatory('ATCA') # set where 

2186 print me.doframe(pos) 

2187 #True 

2188 c=me.measure(b,'azel') # try with different type 

2189 print me.separation(a,c) 

2190 #{'value': 10.000000000062277, 'unit': 'deg'} 

2191 

2192 ### the example below is how to calculate 

2193 ### the parallactic angle 

2194 me.doframe(me.epoch('utc','2015/06/30/19:30:40'))) 

2195 me.doframe(me.observatory('ALMA')) 

2196 mydir = me.direction('J2000','17h28m00','-28d00m00' ) 

2197 #convert direction to AZEL 

2198 mydirazel=me.measure(mydir, 'AZEL') 

2199 hadecpol=me.direction('HADEC', '00h00m00', '90d00m00') 

2200 ### no need to convert north pole direction to AZEL 

2201 ### as it will coverted to the frame of mydirazel 

2202 parAngle=me.posangle(mydirazel, hadecpol) 

2203 

2204 -------------------------------------------------------------------------------- 

2205 

2206 """ 

2207 return _measures.measures_separation(self, *args, **kwargs) 

2208 

2209 

2210 def addxvalue(self, *args, **kwargs): 

2211 """ 

2212 addxvalue(self, _a) -> record * 

2213 

2214 

2215 

2216 Summary: 

2217 get some additional measure information 

2218 

2219 Description: 

2220 

2221 

2222 addxvalue will give some additional information about some measures as a vector 

2223 of quantities. It is used internally to get the rectangular coordinates of 

2224 measures that are normally given in angles. The casual user will probably in 

2225 general not interested in this function. 

2226 

2227 Input Parameters: 

2228 a measures for which extra information is to be gotten 

2229 

2230 Example: 

2231 

2232 print 't----t addxvalue Ex 1 t----' 

2233 a=me.observatory('atca') 

2234 print a 

2235 #{'m0': {'value': 2.6101423190348916, 'unit': 'rad'}, 

2236 # 'm1': {'value': -0.5261379196128062, 'unit': 'rad'}, 

2237 # 'm2': {'value': 6372960.2577234386, 'unit': 'm'}, 

2238 # 'refer': 'ITRF', 

2239 # 'type': 'position'} 

2240 print me.addxvalue(a) 

2241 #{'value': [-4750915.8370000012, 2792906.1819999996, -3200483.747], 'unit': 'm'} 

2242 print me.addxvalue(me.epoch('utc','today')) 

2243 #{} 

2244 

2245 -------------------------------------------------------------------------------- 

2246 

2247 """ 

2248 return _measures.measures_addxvalue(self, *args, **kwargs) 

2249 

2250 

2251 def type(self): 

2252 """ 

2253 type(self) -> string 

2254 

2255 

2256 

2257 Summary: 

2258 type of tool 

2259 

2260 Description: 

2261 

2262 

2263 type will return the tool name. 

2264 

2265 Example: 

2266 

2267 print 't----t type Ex 1 t----' 

2268 print me.type() 

2269 #'measures' 

2270 

2271 -------------------------------------------------------------------------------- 

2272 

2273 """ 

2274 return _measures.measures_type(self) 

2275 

2276 

2277 def done(self): 

2278 """ 

2279 done(self) -> bool 

2280 

2281 

2282 

2283 Summary: 

2284 free resources used by tool. 

2285 

2286 Description: 

2287 

2288 

2289 In general you will not want to call this method. It removes and then 

2290 recreates the default measures tool. 

2291 

2292 Example: 

2293 

2294 print 't----t done Ex 1 t----' 

2295 print me.done() 

2296 #True 

2297 

2298 -------------------------------------------------------------------------------- 

2299 

2300 """ 

2301 return _measures.measures_done(self) 

2302 

2303 

2304 def ismeasure(self, *args, **kwargs): 

2305 """ 

2306 ismeasure(self, _v) -> bool 

2307 

2308 

2309 

2310 Summary: 

2311 Check if measure 

2312 

2313 Description: 

2314 

2315 

2316 Checks if the operand is a correct measure 

2317 

2318 Input Parameters: 

2319 v value to be tested 

2320 

2321 Example: 

2322 

2323 print 't----t ismeasure Ex 1 t----' 

2324 x=me.epoch('utc','today') 

2325 print x 

2326 #{'m0': {'value': 54056.043754386577, 'unit': 'd'}, 

2327 # 'refer': 'UTC', 

2328 # 'type': 'epoch'} 

2329 print me.ismeasure(x) 

2330 #True 

2331 y=me.getvalue(x) 

2332 print y 

2333 #{'m0': {'value': 54056.043754386577, 'unit': 'd'}} 

2334 print me.ismeasure(y) 

2335 #False 

2336 print 'Last example, exiting!' 

2337 exit() 

2338 

2339 -------------------------------------------------------------------------------- 

2340 

2341 """ 

2342 return _measures.measures_ismeasure(self, *args, **kwargs) 

2343 

2344 __swig_destroy__ = _measures.delete_measures 

2345 __del__ = lambda self: None 

2346 __swig_setmethods__["_dot_touvw"] = _measures.measures__dot_touvw_set 

2347 __swig_getmethods__["_dot_touvw"] = _measures.measures__dot_touvw_get 

2348 if _newclass: 

2349 _dot_touvw = _swig_property(_measures.measures__dot_touvw_get, _measures.measures__dot_touvw_set) 

2350 __swig_setmethods__["_xyz_touvw"] = _measures.measures__xyz_touvw_set 

2351 __swig_getmethods__["_xyz_touvw"] = _measures.measures__xyz_touvw_get 

2352 if _newclass: 

2353 _xyz_touvw = _swig_property(_measures.measures__xyz_touvw_get, _measures.measures__xyz_touvw_set) 

2354 __swig_setmethods__["_xyz_expand"] = _measures.measures__xyz_expand_set 

2355 __swig_getmethods__["_xyz_expand"] = _measures.measures__xyz_expand_get 

2356 if _newclass: 

2357 _xyz_expand = _swig_property(_measures.measures__xyz_expand_get, _measures.measures__xyz_expand_set) 

2358measures_swigregister = _measures.measures_swigregister 

2359measures_swigregister(measures) 

2360cvar = _measures.cvar 

2361 

2362# This file is compatible with both classic and new-style classes. 

2363 

2364