pro jprecess, ra, dec, ra_2000, dec_2000, MU_RADEC = mu_radec, $ PARALLAX = parallax, RAD_VEL = rad_vel, EPOCH = epoch ;+ ; NAME: ; JPRECESS ; PURPOSE: ; Precess astronomical coordinates from B1950 to J2000 ; EXPLANATION: ; Calculate the mean place of a star at J2000.0 on the FK5 system from the ; mean place at B1950.0 on the FK4 system. ; ; Use BPRECESS for the reverse direction J2000 ==> B1950 ; CALLING SEQUENCE: ; jprecess, ra, dec, ra_2000, dec_2000, [ MU_RADEC = , PARALLAX = ; RAD_VEL =, EPOCH = ] ; ; INPUTS: ; RA,DEC - input B1950 right ascension and declination in *degrees*. ; Scalar or vector ; ; OUTPUTS: ; RA_2000, DEC_2000 - the corresponding J2000 right ascension and ; declination in *degrees*. Same number of elements as RA,DEC ; but always double precision. ; ; OPTIONAL INPUT-OUTPUT KEYWORDS ; MU_RADEC - 2xN element double precision vector containing the proper ; motion in seconds of arc per tropical *century* in right ; ascension and declination. ; PARALLAX - N_element vector giving stellar parallax (seconds of arc) ; RAD_VEL - N_element vector giving radial velocity in km/s ; ; The values of MU_RADEC, PARALLAX, and RADVEL will all be modified ; upon output to contain the values of these quantities in the ; J2000 system. Values will also be converted to double precision. ; The parallax and radial velocity will have a very minor influence on ; the J2000 position. ; ; EPOCH - scalar giving epoch of original observations, default 1950.0d ; This keyword value is only used if the MU_RADEC keyword is not set. ; NOTES: ; The algorithm is taken from the Explanatory Supplement to the ; Astronomical Almanac 1992, page 184. ; Also see Aoki et al (1983), A&A, 128,263 ; ; JPRECESS distinguishes between the following two cases: ; (1) The proper motion is known and non-zero ; (2) the proper motion is unknown or known to be exactly zero (i.e. ; extragalactic radio sources). In this case, the algorithm ; in Appendix 2 of Aoki et al. (1983) is used to ensure that ; the output proper motion is exactly zero. Better precision ; can be achieved in this case by inputting the EPOCH of the ; original observations. ; ; The error in using the IDL procedure PRECESS for converting between ; B1950 and J2000 can be up to 1.5", mainly in right ascension. If ; better accuracy than this is needed then JPRECESS should be used. ; ; EXAMPLE: ; The SAO catalogue gives the B1950 position and proper motion for the ; star HD 119288. Find the J2000 position. ; ; RA(1950) = 13h 39m 44.526s Dec(1950) = 8d 38' 28.63'' ; Mu(RA) = -.0259 s/yr Mu(Dec) = -.093 ''/yr ; ; IDL> mu_radec = 100D* [ -15D*.0259, -0.093 ] ; IDL> ra = ten(13,39,44.526)*15.D ; IDL> dec = ten(8,38,28.63) ; IDL> jprecess, ra, dec, ra2000, dec2000, mu_radec = mu_radec ; IDL> print, adstring(ra2000, dec2000,2) ; ===> 13h 42m 12.740s +08d 23' 17.69" ; ; RESTRICTIONS: ; "When transferring individual observations, as opposed to catalog mean ; place, the safest method is to tranform the observations back to the ; epoch of the observation, on the FK4 system (or in the system that was ; used to to produce the observed mean place), convert to the FK5 system, ; and transform to the the epoch and equinox of J2000.0" -- from the ; Explanatory Supplement (1992), p. 180 ; ; REVISION HISTORY: ; Written, W. Landsman September, 1992 ; Corrected a couple of typos in M matrix October, 1992 ; Vectorized, W. Landsman February, 1994 ; Implement Appendix 2 of Aoki et al. (1983) for case where proper ; motion unknown or exactly zero W. Landsman November, 1994 ; Converted to IDL V5.0 W. Landsman September 1997 ; Fixed typo in updating proper motion W. Landsman April 1999 ; Make sure proper motion is floating point W. Landsman December 2000 ;- On_error,2 if N_params() LT 4 then begin print,'Syntax - JPRECESS, ra,dec, ra_2000, dec_2000, [MU_RADEC =' print,' PARALLAX = , RAD_VEL = ]' print,'Input RA and Dec should be given in DEGREES for B1950' print,'Proper motion, MU_RADEC, (optional) in arc seconds per *century*' print,'Parallax (optional) in arc seconds' print,'Radial Velocity (optional) in km/s' return endif N = N_elements( ra ) if N EQ 0 then message,'ERROR - first parameter (RA vector) is undefined' if not keyword_set( RAD_VEL) then rad_vel = dblarr(N) else begin rad_vel = rad_vel*1. if N_elements( RAD_VEL ) NE N then message, $ 'ERROR - RAD_VEL keyword vector must contain ' + strtrim(N,2) + ' values' endelse if keyword_set( MU_RADEC) then begin if (N_elements( mu_radec) NE 2*N ) then message, $ 'ERROR - MU_RADEC keyword (proper motion) be dimensioned (2,' + $ strtrim(N,2) + ')' mu_radec = mu_radec*1. ;Make sure at least float endif if not keyword_set(epoch) then epoch = 1950.0d0 if not keyword_set( Parallax) then parallax = dblarr(N) else $ parallax = parallax*1. radeg = 180.D/!DPI sec_to_radian = 1./radeg/3600.0d0 M = [ [+0.9999256782D, +0.0111820610D, +0.0048579479D, $ -0.000551D, +0.238514D, -0.435623D ], $ [ -0.0111820611D, +0.9999374784D, -0.0000271474D, $ -0.238565D, -0.002667D, +0.012254D ], $ [ -0.0048579477D, -0.0000271765D, +0.9999881997D , $ +0.435739D, -0.008541D, +0.002117D ], $ [ +0.00000242395018D, +0.00000002710663D, +0.00000001177656D, $ +0.99994704D, +0.01118251D, +0.00485767D ], $ [ -0.00000002710663D, +0.00000242397878D, -0.00000000006582D, $ -0.01118251D, +0.99995883D, -0.00002714D ], $ [ -0.00000001177656D, -0.00000000006587D, 0.00000242410173D, $ -0.00485767D, -0.00002718D, 1.00000956D] ] A = 1D-6*[ -1.62557D, -0.31919D, -0.13843D] ;in radians A_dot = 1D-3*[1.244D, -1.579D, -0.660D ] ;in arc seconds per century if epoch NE 1950.0d then $ A = A + sec_to_radian * A_dot * (epoch - 1950.0D)/100.0d ra_rad = ra/radeg & dec_rad = dec/radeg cosra = cos( ra_rad ) & sinra = sin( ra_rad ) cosdec = cos( dec_rad ) & sindec = sin( dec_rad ) ra_2000 = ra*0. dec_2000 = dec*0. for i = 0l, N-1 do begin r0 = [ cosra[i]*cosdec[i], sinra[i]*cosdec[i], sindec[i] ] if not keyword_set( MU_RADEC) then begin mu_a = 0.0d0 mu_d = 0.0d0 endif else begin if (N_elements( mu_radec) NE 2*N ) then message, $ 'ERROR - MU_RADEC keyword (proper motion) must be dimensioned (2,' + $ strtrim(N,2) + ')' mu_a = mu_radec[ 0, i] mu_d = mu_radec[ 1, i ] endelse r0_dot = [ -mu_a*sinra[i]*cosdec[i] - mu_d*cosra[i]*sindec[i], $ ;Velocity vector mu_a*cosra[i]*cosdec[i] - mu_d*sinra[i]*sindec[i] , $ mu_d*cosdec[i] ] + 21.095 * rad_vel[i] * parallax[i] * r0 ; Remove the effects of the E-terms of aberration to form r1 and r1_dot. r1 = r0 - A + (total(r0 * A))*r0 r1_dot = r0_dot - A_dot + ( total( r0 * A_dot))*r0 R_1 = [r1, r1_dot] R = M # R_1 if not keyword_set(mu_RADEC) then begin rr = [ R[0], R[1], R[2]] v = [ R[3],R[4],R[5] ] t = ((epoch - 1950.0d0) - 50.00021d)/100.0d0 rr1 = rr + sec_to_radian*v*t x = rr1[0] & y = rr1[1] & Z = rr1[2] endif else begin x = R[0] & y = R[1] & Z = R[2] x_dot = R[3] & y_dot= R[4] & z_dot = R[5] endelse r2 = x^2 + y^2 + z^2 rmag = sqrt( r2 ) dec_2000[i] = asin( z / rmag) ra_2000[i] = atan( y, x) if keyword_set(mu_RADEC) then begin mu_radec[0, i] = ( x*y_dot - y*x_dot) / ( x^2 + y^2) mu_radec[1, i] = ( z_dot* (x^2 + y^2) - z*(x*x_dot + y*y_dot) ) / $ ( r2*sqrt( x^2 + y^2) ) endif if parallax[i] GT 0. then begin rad_vel[i] = ( x*x_dot + y*y_dot + z*z_dot )/ (21.095*Parallax[i]*rmag) parallax[i] = parallax[i] / rmag endif endfor neg = where( ra_2000 LT 0, NNeg ) if Nneg GT 0 then ra_2000[neg] = ra_2000[neg] + 2.D*!DPI ra_2000 = ra_2000*radeg & dec_2000 = dec_2000*radeg ; Make output scalar if input was scalar sz = size(ra) if sz[0] EQ 0 then begin ra_2000 = ra_2000[0] & dec_2000 = dec_2000[0] endif return end