C============================================================================ C CTEQ Parton Distribution Functions: Version 4.6 C June 21, 1996 C Modified: 10/17/96, 1/7/97, 1/15/97 C 2/17/97, 2/21/97 C Last Modified on April 2, 1997 C C Ref[1]: "IMPROVED PARTON DISTRIBUTIONS FROM GLOBAL ANALYSIS OF RECENT DEEP C INELASTIC SCATTERING AND INCLUSIVE JET DATA" C By: H.L. Lai, J. Huston, S. Kuhlmann, F. Olness, J. Owens, D. Soper C W.K. Tung, H. Weerts C Phys. Rev. D55, 1280 (1997) C C Ref[2]: "CHARM PRODUCTION AND PARTON DISTRIBUTIONS" C By: H.L. Lai and W.K. Tung C MSU-HEP-61222, CTEQ-622, e-Print Archive: hep-ph/9701256 C to appear in Z. Phys. C C This package contains 13 sets of CTEQ4 PDF's. Details are: C --------------------------------------------------------------------------- C Iset PDF Description Alpha_s(Mz) Lam4 Lam5 Table_File C --------------------------------------------------------------------------- C Ref[1] C 1 CTEQ4M Standard MSbar scheme 0.116 298 202 cteq4m.tbl C 2 CTEQ4D Standard DIS scheme 0.116 298 202 cteq4d.tbl C 3 CTEQ4L Leading Order 0.132 236 181 cteq4l.tbl C 4 CTEQ4A1 Alpha_s series 0.110 215 140 cteq4a1.tbl C 5 CTEQ4A2 Alpha_s series 0.113 254 169 cteq4a2.tbl C 6 CTEQ4A3 ( same as CTEQ4M ) C 7 CTEQ4A4 Alpha_s series 0.119 346 239 cteq4a4.tbl C 8 CTEQ4A5 Alpha_s series 0.122 401 282 cteq4a5.tbl C 9 CTEQ4HJ High Jet 0.116 303 206 cteq4hj.tbl C 10 CTEQ4LQ Low Q0 0.114 261 174 cteq4lq.tbl C --------------------------------------------------------------------------- C Ref[2] C 11 CTEQ4HQ Heavy Quark 0.116 298 202 cteq4hq.tbl C 12 CTEQ4HQ1 Heavy Quark:Q0=1,Mc=1.3 0.116 298 202 cteq4hq1.tbl C (Improved version of CTEQ4HQ, recommended) C 13 CTEQ4F3 Nf=3 FixedFlavorNumber 0.106 (Lam3=385) cteq4f3.tbl C 14 CTEQ4F4 Nf=4 FixedFlavorNumber 0.111 292 XXX cteq4f4.tbl C --------------------------------------------------------------------------- C C The available applied range is 10^-5 < x < 1 and 1.6 < Q < 10,000 (GeV) C except CTEQ4LQ(4HQ1) for which Q starts at a lower value of 0.7(1.0) GeV. C Lam5 (Lam4, Lam3) represents Lambda value (in MeV) for 5 (4,3) flavors. C The matching alpha_s between 4 and 5 flavors takes place at Q=5.0 GeV, C which is defined as the bottom quark mass, whenever it can be applied. C C The Table_Files are assumed to be in the working directory. C C Before using the PDF, it is necessary to do the initialization by C Call SetCtq4(Iset) C where Iset is the desired PDF specified in the above table. C C The function Ctq4Pdf (Iparton, X, Q) C returns the parton distribution inside the proton for parton [Iparton] C at [X] Bjorken_X and scale [Q] (GeV) in PDF set [Iset]. C Iparton is the parton label (5, 4, 3, 2, 1, 0, -1, ......, -5) C for (b, c, s, d, u, g, u_bar, ..., b_bar), C whereas CTEQ4F3 has, by definition, only 3 flavors and gluon; C CTEQ4F4 has only 4 flavors and gluon. C C For detailed information on the parameters used, e.q. quark masses, C QCD Lambda, ... etc., see info lines at the beginning of the C Table_Files. C C These programs, as provided, are in double precision. By removing the C "Implicit Double Precision" lines, they can also be run in single C precision. C C If you have detailed questions concerning these CTEQ4 distributions, C or if you find problems/bugs using this package, direct inquires to C Hung-Liang Lai(Lai_H@pa.msu.edu) or Wu-Ki Tung(Tung@pa.msu.edu). C C=========================================================================== Function Ctq4Pdf (Iparton, X, Q) Implicit Double Precision (A-H,O-Z) Logical Warn Common > / CtqPar2 / Nx, Nt, NfMx > / QCDtable / Alambda, Nfl, Iorder Data Warn /.true./ save Warn If (X .lt. 0D0 .or. X .gt. 1D0) Then Print *, 'X out of range in Ctq4Pdf: ', X Stop Endif If (Q .lt. Alambda) Then Print *, 'Q out of range in Ctq4Pdf: ', Q Stop Endif If ((Iparton .lt. -NfMx .or. Iparton .gt. NfMx)) Then If (Warn) Then C put a warning for calling extra flavor. Warn = .false. Print *, 'Warning: Iparton out of range in Ctq4Pdf: ' > , Iparton Endif Ctq4Pdf = 0D0 Return Endif Ctq4Pdf = PartonX (Iparton, X, Q) if(Ctq4Pdf.lt.0.D0) Ctq4Pdf = 0.D0 Return C ******************** End FUNCTION PartonX (IPRTN, X, Q) C C Given the parton distribution function in the array Upd in C COMMON / CtqPar1 / , this routine fetches u(fl, x, q) at any value of C x and q using Mth-order polynomial interpolation for x and Ln(Q/Lambda). C IMPLICIT DOUBLE PRECISION (A-H, O-Z) C PARAMETER (MXX = 105, MXQ = 25, MXF = 6) PARAMETER (MXPQX = (MXF *2 +2) * MXQ * MXX) PARAMETER (M= 2, M1 = M + 1) C Logical First Common > / CtqPar1 / Al, XV(0:MXX), QL(0:MXQ), UPD(MXPQX) > / CtqPar2 / Nx, Nt, NfMx > / XQrange / Qini, Qmax, Xmin C Dimension Fq(M1), Df(M1) Data First /.true./ save First C Work with Log (Q) QG = LOG (Q/AL) C Find lower end of interval containing X JL = -1 JU = Nx+1 11 If (JU-JL .GT. 1) Then JM = (JU+JL) / 2 If (X .GT. XV(JM)) Then JL = JM Else JU = JM Endif Goto 11 Endif Jx = JL - (M-1)/2 If (X .lt. Xmin .and. First ) Then First = .false. Print '(A, 2(1pE12.4))', > ' WARNING: X < Xmin, extrapolation used; X, Xmin =', X, Xmin If (Jx .LT. 0) Jx = 0 Elseif (Jx .GT. Nx-M) Then Jx = Nx - M Endif C Find the interval where Q lies JL = -1 JU = NT+1 12 If (JU-JL .GT. 1) Then JM = (JU+JL) / 2 If (QG .GT. QL(JM)) Then JL = JM Else JU = JM Endif Goto 12 Endif Jq = JL - (M-1)/2 If (Jq .LT. 0) Then Jq = 0 If (Q .lt. Qini) Print '(A, 2(1pE12.4))', > ' WARNING: Q < Qini, extrapolation used; Q, Qini =', Q, Qini Elseif (Jq .GT. Nt-M) Then Jq = Nt - M If (Q .gt. Qmax) Print '(A, 2(1pE12.4))', > ' WARNING: Q > Qmax, extrapolation used; Q, Qmax =', Q, Qmax Endif If (Iprtn .GE. 3) Then Ip = - Iprtn Else Ip = Iprtn EndIf C Find the off-set in the linear array Upd JFL = Ip + NfMx J0 = (JFL * (NT+1) + Jq) * (NX+1) + Jx C C Now interpolate in x for M1 Q's Do 21 Iq = 1, M1 J1 = J0 + (Nx+1)*(Iq-1) + 1 Call Polint (XV(Jx), Upd(J1), M1, X, Fq(Iq), Df(Iq)) 21 Continue C Finish off by interpolating in Q Call Polint (QL(Jq), Fq(1), M1, QG, Ftmp, Ddf) PartonX = Ftmp C RETURN C **************************** END Subroutine SetCtq4 (Iset) Implicit Double Precision (A-H,O-Z) Parameter (Isetmax=14) Character Flnm(Isetmax)*12, Tablefile*40 Data (Flnm(I), I=1,Isetmax) > / 'cteq4m.tbl', 'cteq4d.tbl', 'cteq4l.tbl' > , 'cteq4a1.tbl', 'cteq4a2.tbl', 'cteq4m.tbl', 'cteq4a4.tbl' > , 'cteq4a5.tbl', 'cteq4hj.tbl', 'cteq4lq.tbl' > , 'cteq4hq.tbl', 'cteq4hq1.tbl', 'cteq4f3.tbl', 'cteq4f4.tbl' / Data Tablefile / 'test.tbl' / Data Isetold, Isetmin, Isettest / -987, 1, 911 / save C If data file not initialized, do so. If(Iset.ne.Isetold) then IU= NextUn() If (Iset .eq. Isettest) then Print* ,'Opening ', Tablefile 21 Open(IU, File=Tablefile, Status='OLD', Err=101) ElseIf (Iset.lt.Isetmin .or. Iset.gt.Isetmax) Then Print *, 'Invalid Iset number in SetCtq4 :', Iset Stop Else Tablefile=Flnm(Iset) Open(IU, File=Tablefile, Status='OLD', Err=100) Endif Call ReadTbl (IU) Close (IU) Isetold=Iset Endif Return 100 Print *, ' Data file ', Tablefile, ' cannot be opened ' >//'in SetCtq4!!' Stop 101 Print*, Tablefile, ' cannot be opened ' Print*, 'Please input the .tbl file:' Read (*,'(A)') Tablefile Goto 21 C ******************** End Subroutine ReadTbl (Nu) Implicit Double Precision (A-H,O-Z) Character Line*80 PARAMETER (MXX = 105, MXQ = 25, MXF = 6) PARAMETER (MXPQX = (MXF *2 +2) * MXQ * MXX) Common > / CtqPar1 / Al, XV(0:MXX), QL(0:MXQ), UPD(MXPQX) > / CtqPar2 / Nx, Nt, NfMx > / XQrange / Qini, Qmax, Xmin > / QCDtable / Alambda, Nfl, Iorder > / Masstbl / Amass(6) Read (Nu, '(A)') Line Read (Nu, '(A)') Line Read (Nu, *) Dr, Fl, Al, (Amass(I),I=1,6) Iorder = Nint(Dr) Nfl = Nint(Fl) Alambda = Al Read (Nu, '(A)') Line Read (Nu, *) NX, NT, NfMx Read (Nu, '(A)') Line Read (Nu, *) QINI, QMAX, (QL(I), I =0, NT) Read (Nu, '(A)') Line Read (Nu, *) XMIN, (XV(I), I =0, NX) Do 11 Iq = 0, NT QL(Iq) = Log (QL(Iq) /Al) 11 Continue C C Since quark = anti-quark for nfl>2 at this stage, C we Read out only the non-redundent data points C No of flavors = NfMx (sea) + 1 (gluon) + 2 (valence) Nblk = (NX+1) * (NT+1) Npts = Nblk * (NfMx+3) Read (Nu, '(A)') Line Read (Nu, *, IOSTAT=IRET) (UPD(I), I=1,Npts) Return C **************************** End Function NextUn() C Returns an unallocated FORTRAN i/o unit. Logical EX C Do 10 N = 10, 300 INQUIRE (UNIT=N, OPENED=EX) If (.NOT. EX) then NextUn = N Return Endif 10 Continue Stop ' There is no available I/O unit. ' C ************************* End C SUBROUTINE POLINT (XA,YA,N,X,Y,DY) IMPLICIT DOUBLE PRECISION (A-H, O-Z) C Adapted from "Numerical Recipes" PARAMETER (NMAX=10) DIMENSION XA(N),YA(N),C(NMAX),D(NMAX) NS=1 DIF=ABS(X-XA(1)) DO 11 I=1,N DIFT=ABS(X-XA(I)) IF (DIFT.LT.DIF) THEN NS=I DIF=DIFT ENDIF C(I)=YA(I) D(I)=YA(I) 11 CONTINUE Y=YA(NS) NS=NS-1 DO 13 M=1,N-1 DO 12 I=1,N-M HO=XA(I)-X HP=XA(I+M)-X W=C(I+1)-D(I) DEN=HO-HP IF(DEN.EQ.0.)PAUSE DEN=W/DEN D(I)=HP*DEN C(I)=HO*DEN 12 CONTINUE IF (2*NS.LT.N-M)THEN DY=C(NS+1) ELSE DY=D(NS) NS=NS-1 ENDIF Y=Y+DY 13 CONTINUE RETURN END