zbknu.f

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      SUBROUTINE zbknu(ZR, ZI, FNU, KODE, N, YR, YI, NZ, TOL, ELIM,
     * alim)
C***BEGIN PROLOGUE  ZBKNU
C***REFER TO  ZBESI,ZBESK,ZAIRY,ZBESH
C
C     ZBKNU COMPUTES THE K BESSEL FUNCTION IN THE RIGHT HALF Z PLANE.
C
C***ROUTINES CALLED  DGAMLN,I1MACH,D1MACH,ZKSCL,ZSHCH,ZUCHK,XZABS,ZDIV,
C                    XZEXP,XZLOG,ZMLT,XZSQRT
C***END PROLOGUE  ZBKNU
C
      DOUBLE PRECISION AA, AK, ALIM, ASCLE, A1, A2, BB, BK, BRY, CAZ,
     * cbi, cbr, cc, cchi, cchr, cki, ckr, coefi, coefr, conei, coner,
     * crscr, csclr, cshi, cshr, csi, csr, csrr, cssr, ctwor,
     * czeroi, czeror, czi, czr, dnu, dnu2, dpi, elim, etest, fc, fhs,
     * fi, fk, fks, fmui, fmur, fnu, fpi, fr, g1, g2, hpi, pi, pr, pti,
     * ptr, p1i, p1r, p2i, p2m, p2r, qi, qr, rak, rcaz, rthpi, rzi,
     * rzr, r1, s, smui, smur, spi, sti, str, s1i, s1r, s2i, s2r, tm,
     * tol, tth, t1, t2, yi, yr, zi, zr, dgamln, d1mach, xzabs, elm,
     * celmr, zdr, zdi, as, alas, helim, cyr, cyi
      INTEGER I, IFLAG, INU, K, KFLAG, KK, KMAX, KODE, KODED, N, NZ,
     * idum, i1mach, j, ic, inub, nw
      dimension yr(n), yi(n), cc(8), cssr(3), csrr(3), bry(3), cyr(2),
     * cyi(2)
C     COMPLEX Z,Y,A,B,RZ,SMU,FU,FMU,F,FLRZ,CZ,S1,S2,CSH,CCH
C     COMPLEX CK,P,Q,COEF,P1,P2,CBK,PT,CZERO,CONE,CTWO,ST,EZ,CS,DK
C
      DATA kmax / 30 /
      DATA czeror,czeroi,coner,conei,ctwor,r1/
     1  0.0d0 , 0.0d0 , 1.0d0 , 0.0d0 , 2.0d0 , 2.0d0 /
      DATA dpi, rthpi, spi ,hpi, fpi, tth /
     1     3.14159265358979324d0,       1.25331413731550025d0,
     2     1.90985931710274403d0,       1.57079632679489662d0,
     3     1.89769999331517738d0,       6.66666666666666666d-01/
      DATA cc(1), cc(2), cc(3), cc(4), cc(5), cc(6), cc(7), cc(8)/
     1     5.77215664901532861d-01,    -4.20026350340952355d-02,
     2    -4.21977345555443367d-02,     7.21894324666309954d-03,
     3    -2.15241674114950973d-04,    -2.01348547807882387d-05,
     4     1.13302723198169588d-06,     6.11609510448141582d-09/
C
      caz = xzabs(zr,zi)
      csclr = 1.0d0/tol
      crscr = tol
      cssr(1) = csclr
      cssr(2) = 1.0d0
      cssr(3) = crscr
      csrr(1) = crscr
      csrr(2) = 1.0d0
      csrr(3) = csclr
      bry(1) = 1.0d+3*d1mach(1)/tol
      bry(2) = 1.0d0/bry(1)
      bry(3) = d1mach(2)
      nz = 0
      iflag = 0
      koded = kode
      rcaz = 1.0d0/caz
      str = zr*rcaz
      sti = -zi*rcaz
      rzr = (str+str)*rcaz
      rzi = (sti+sti)*rcaz
      inu = int(sngl(fnu+0.5d0))
      dnu = fnu - dble(float(inu))
      IF (dabs(dnu).EQ.0.5d0) go to 110
      dnu2 = 0.0d0
      IF (dabs(dnu).GT.tol) dnu2 = dnu*dnu
      IF (caz.GT.r1) go to 110
C-----------------------------------------------------------------------
C     SERIES FOR CABS(Z).LE.R1
C-----------------------------------------------------------------------
      fc = 1.0d0
      CALL xzlog(rzr, rzi, smur, smui, idum)
      fmur = smur*dnu
      fmui = smui*dnu
      CALL zshch(fmur, fmui, cshr, cshi, cchr, cchi)
      IF (dnu.EQ.0.0d0) go to 10
      fc = dnu*dpi
      fc = fc/dsin(fc)
      smur = cshr/dnu
      smui = cshi/dnu
   10 CONTINUE
      a2 = 1.0d0 + dnu
C-----------------------------------------------------------------------
C     GAM(1-Z)*GAM(1+Z)=PI*Z/SIN(PI*Z), T1=1/GAM(1-DNU), T2=1/GAM(1+DNU)
C-----------------------------------------------------------------------
      t2 = dexp(-dgamln(a2,idum))
      t1 = 1.0d0/(t2*fc)
      IF (dabs(dnu).GT.0.1d0) go to 40
C-----------------------------------------------------------------------
C     SERIES FOR F0 TO RESOLVE INDETERMINACY FOR SMALL ABS(DNU)
C-----------------------------------------------------------------------
      ak = 1.0d0
      s = cc(1)
      DO 20 k=2,8
        ak = ak*dnu2
        tm = cc(k)*ak
        s = s + tm
        IF (dabs(tm).LT.tol) go to 30
   20 CONTINUE
   30 g1 = -s
      go to 50
   40 CONTINUE
      g1 = (t1-t2)/(dnu+dnu)
   50 CONTINUE
      g2 = (t1+t2)*0.5d0
      fr = fc*(cchr*g1+smur*g2)
      fi = fc*(cchi*g1+smui*g2)
      CALL xzexp(fmur, fmui, str, sti)
      pr = 0.5d0*str/t2
      pi = 0.5d0*sti/t2
      CALL zdiv(0.5d0, 0.0d0, str, sti, ptr, pti)
      qr = ptr/t1
      qi = pti/t1
      s1r = fr
      s1i = fi
      s2r = pr
      s2i = pi
      ak = 1.0d0
      a1 = 1.0d0
      ckr = coner
      cki = conei
      bk = 1.0d0 - dnu2
      IF (inu.GT.0 .OR. n.GT.1) go to 80
C-----------------------------------------------------------------------
C     GENERATE K(FNU,Z), 0.0D0 .LE. FNU .LT. 0.5D0 AND N=1
C-----------------------------------------------------------------------
      IF (caz.LT.tol) go to 70
      CALL zmlt(zr, zi, zr, zi, czr, czi)
      czr = 0.25d0*czr
      czi = 0.25d0*czi
      t1 = 0.25d0*caz*caz
   60 CONTINUE
      fr = (fr*ak+pr+qr)/bk
      fi = (fi*ak+pi+qi)/bk
      str = 1.0d0/(ak-dnu)
      pr = pr*str
      pi = pi*str
      str = 1.0d0/(ak+dnu)
      qr = qr*str
      qi = qi*str
      str = ckr*czr - cki*czi
      rak = 1.0d0/ak
      cki = (ckr*czi+cki*czr)*rak
      ckr = str*rak
      s1r = ckr*fr - cki*fi + s1r
      s1i = ckr*fi + cki*fr + s1i
      a1 = a1*t1*rak
      bk = bk + ak + ak + 1.0d0
      ak = ak + 1.0d0
      IF (a1.GT.tol) go to 60
   70 CONTINUE
      yr(1) = s1r
      yi(1) = s1i
      IF (koded.EQ.1) RETURN
      CALL xzexp(zr, zi, str, sti)
      CALL zmlt(s1r, s1i, str, sti, yr(1), yi(1))
      RETURN
C-----------------------------------------------------------------------
C     GENERATE K(DNU,Z) AND K(DNU+1,Z) FOR FORWARD RECURRENCE
C-----------------------------------------------------------------------
   80 CONTINUE
      IF (caz.LT.tol) go to 100
      CALL zmlt(zr, zi, zr, zi, czr, czi)
      czr = 0.25d0*czr
      czi = 0.25d0*czi
      t1 = 0.25d0*caz*caz
   90 CONTINUE
      fr = (fr*ak+pr+qr)/bk
      fi = (fi*ak+pi+qi)/bk
      str = 1.0d0/(ak-dnu)
      pr = pr*str
      pi = pi*str
      str = 1.0d0/(ak+dnu)
      qr = qr*str
      qi = qi*str
      str = ckr*czr - cki*czi
      rak = 1.0d0/ak
      cki = (ckr*czi+cki*czr)*rak
      ckr = str*rak
      s1r = ckr*fr - cki*fi + s1r
      s1i = ckr*fi + cki*fr + s1i
      str = pr - fr*ak
      sti = pi - fi*ak
      s2r = ckr*str - cki*sti + s2r
      s2i = ckr*sti + cki*str + s2i
      a1 = a1*t1*rak
      bk = bk + ak + ak + 1.0d0
      ak = ak + 1.0d0
      IF (a1.GT.tol) go to 90
  100 CONTINUE
      kflag = 2
      a1 = fnu + 1.0d0
      ak = a1*dabs(smur)
      IF (ak.GT.alim) kflag = 3
      str = cssr(kflag)
      p2r = s2r*str
      p2i = s2i*str
      CALL zmlt(p2r, p2i, rzr, rzi, s2r, s2i)
      s1r = s1r*str
      s1i = s1i*str
      IF (koded.EQ.1) go to 210
      CALL xzexp(zr, zi, fr, fi)
      CALL zmlt(s1r, s1i, fr, fi, s1r, s1i)
      CALL zmlt(s2r, s2i, fr, fi, s2r, s2i)
      go to 210
C-----------------------------------------------------------------------
C     IFLAG=0 MEANS NO UNDERFLOW OCCURRED
C     IFLAG=1 MEANS AN UNDERFLOW OCCURRED- COMPUTATION PROCEEDS WITH
C     KODED=2 AND A TEST FOR ON SCALE VALUES IS MADE DURING FORWARD
C     RECURSION
C-----------------------------------------------------------------------
  110 CONTINUE
      CALL xzsqrt(zr, zi, str, sti)
      CALL zdiv(rthpi, czeroi, str, sti, coefr, coefi)
      kflag = 2
      IF (koded.EQ.2) go to 120
      IF (zr.GT.alim) go to 290
C     BLANK LINE
      str = dexp(-zr)*cssr(kflag)
      sti = -str*dsin(zi)
      str = str*dcos(zi)
      CALL zmlt(coefr, coefi, str, sti, coefr, coefi)
  120 CONTINUE
      IF (dabs(dnu).EQ.0.5d0) go to 300
C-----------------------------------------------------------------------
C     MILLER ALGORITHM FOR CABS(Z).GT.R1
C-----------------------------------------------------------------------
      ak = dcos(dpi*dnu)
      ak = dabs(ak)
      IF (ak.EQ.czeror) go to 300
      fhs = dabs(0.25d0-dnu2)
      IF (fhs.EQ.czeror) go to 300
C-----------------------------------------------------------------------
C     COMPUTE R2=F(E). IF CABS(Z).GE.R2, USE FORWARD RECURRENCE TO
C     DETERMINE THE BACKWARD INDEX K. R2=F(E) IS A STRAIGHT LINE ON
C     12.LE.E.LE.60. E IS COMPUTED FROM 2**(-E)=B**(1-I1MACH(14))=
C     TOL WHERE B IS THE BASE OF THE ARITHMETIC.
C-----------------------------------------------------------------------
      t1 = dble(float(i1mach(14)-1))
      t1 = t1*d1mach(5)*3.321928094d0
      t1 = dmax1(t1,12.0d0)
      t1 = dmin1(t1,60.0d0)
      t2 = tth*t1 - 6.0d0
      IF (zr.NE.0.0d0) go to 130
      t1 = hpi
      go to 140
  130 CONTINUE
      t1 = datan(zi/zr)
      t1 = dabs(t1)
  140 CONTINUE
      IF (t2.GT.caz) go to 170
C-----------------------------------------------------------------------
C     FORWARD RECURRENCE LOOP WHEN CABS(Z).GE.R2
C-----------------------------------------------------------------------
      etest = ak/(dpi*caz*tol)
      fk = coner
      IF (etest.LT.coner) go to 180
      fks = ctwor
      ckr = caz + caz + ctwor
      p1r = czeror
      p2r = coner
      DO 150 i=1,kmax
        ak = fhs/fks
        cbr = ckr/(fk+coner)
        ptr = p2r
        p2r = cbr*p2r - p1r*ak
        p1r = ptr
        ckr = ckr + ctwor
        fks = fks + fk + fk + ctwor
        fhs = fhs + fk + fk
        fk = fk + coner
        str = dabs(p2r)*fk
        IF (etest.LT.str) go to 160
  150 CONTINUE
      go to 310
  160 CONTINUE
      fk = fk + spi*t1*dsqrt(t2/caz)
      fhs = dabs(0.25d0-dnu2)
      go to 180
  170 CONTINUE
C-----------------------------------------------------------------------
C     COMPUTE BACKWARD INDEX K FOR CABS(Z).LT.R2
C-----------------------------------------------------------------------
      a2 = dsqrt(caz)
      ak = fpi*ak/(tol*dsqrt(a2))
      aa = 3.0d0*t1/(1.0d0+caz)
      bb = 14.7d0*t1/(28.0d0+caz)
      ak = (dlog(ak)+caz*dcos(aa)/(1.0d0+0.008d0*caz))/dcos(bb)
      fk = 0.12125d0*ak*ak/caz + 1.5d0
  180 CONTINUE
C-----------------------------------------------------------------------
C     BACKWARD RECURRENCE LOOP FOR MILLER ALGORITHM
C-----------------------------------------------------------------------
      k = int(sngl(fk))
      fk = dble(float(k))
      fks = fk*fk
      p1r = czeror
      p1i = czeroi
      p2r = tol
      p2i = czeroi
      csr = p2r
      csi = p2i
      DO 190 i=1,k
        a1 = fks - fk
        ak = (fks+fk)/(a1+fhs)
        rak = 2.0d0/(fk+coner)
        cbr = (fk+zr)*rak
        cbi = zi*rak
        ptr = p2r
        pti = p2i
        p2r = (ptr*cbr-pti*cbi-p1r)*ak
        p2i = (pti*cbr+ptr*cbi-p1i)*ak
        p1r = ptr
        p1i = pti
        csr = csr + p2r
        csi = csi + p2i
        fks = a1 - fk + coner
        fk = fk - coner
  190 CONTINUE
C-----------------------------------------------------------------------
C     COMPUTE (P2/CS)=(P2/CABS(CS))*(CONJG(CS)/CABS(CS)) FOR BETTER
C     SCALING
C-----------------------------------------------------------------------
      tm = xzabs(csr,csi)
      ptr = 1.0d0/tm
      s1r = p2r*ptr
      s1i = p2i*ptr
      csr = csr*ptr
      csi = -csi*ptr
      CALL zmlt(coefr, coefi, s1r, s1i, str, sti)
      CALL zmlt(str, sti, csr, csi, s1r, s1i)
      IF (inu.GT.0 .OR. n.GT.1) go to 200
      zdr = zr
      zdi = zi
      IF(iflag.EQ.1) go to 270
      go to 240
  200 CONTINUE
C-----------------------------------------------------------------------
C     COMPUTE P1/P2=(P1/CABS(P2)*CONJG(P2)/CABS(P2) FOR SCALING
C-----------------------------------------------------------------------
      tm = xzabs(p2r,p2i)
      ptr = 1.0d0/tm
      p1r = p1r*ptr
      p1i = p1i*ptr
      p2r = p2r*ptr
      p2i = -p2i*ptr
      CALL zmlt(p1r, p1i, p2r, p2i, ptr, pti)
      str = dnu + 0.5d0 - ptr
      sti = -pti
      CALL zdiv(str, sti, zr, zi, str, sti)
      str = str + 1.0d0
      CALL zmlt(str, sti, s1r, s1i, s2r, s2i)
C-----------------------------------------------------------------------
C     FORWARD RECURSION ON THE THREE TERM RECURSION WITH RELATION WITH
C     SCALING NEAR EXPONENT EXTREMES ON KFLAG=1 OR KFLAG=3
C-----------------------------------------------------------------------
  210 CONTINUE
      str = dnu + 1.0d0
      ckr = str*rzr
      cki = str*rzi
      IF (n.EQ.1) inu = inu - 1
      IF (inu.GT.0) go to 220
      IF (n.GT.1) go to 215
      s1r = s2r
      s1i = s2i
  215 CONTINUE
      zdr = zr
      zdi = zi
      IF(iflag.EQ.1) go to 270
      go to 240
  220 CONTINUE
      inub = 1
      IF(iflag.EQ.1) go to 261
  225 CONTINUE
      p1r = csrr(kflag)
      ascle = bry(kflag)
      DO 230 i=inub,inu
        str = s2r
        sti = s2i
        s2r = ckr*str - cki*sti + s1r
        s2i = ckr*sti + cki*str + s1i
        s1r = str
        s1i = sti
        ckr = ckr + rzr
        cki = cki + rzi
        IF (kflag.GE.3) go to 230
        p2r = s2r*p1r
        p2i = s2i*p1r
        str = dabs(p2r)
        sti = dabs(p2i)
        p2m = dmax1(str,sti)
        IF (p2m.LE.ascle) go to 230
        kflag = kflag + 1
        ascle = bry(kflag)
        s1r = s1r*p1r
        s1i = s1i*p1r
        s2r = p2r
        s2i = p2i
        str = cssr(kflag)
        s1r = s1r*str
        s1i = s1i*str
        s2r = s2r*str
        s2i = s2i*str
        p1r = csrr(kflag)
  230 CONTINUE
      IF (n.NE.1) go to 240
      s1r = s2r
      s1i = s2i
  240 CONTINUE
      str = csrr(kflag)
      yr(1) = s1r*str
      yi(1) = s1i*str
      IF (n.EQ.1) RETURN
      yr(2) = s2r*str
      yi(2) = s2i*str
      IF (n.EQ.2) RETURN
      kk = 2
  250 CONTINUE
      kk = kk + 1
      IF (kk.GT.n) RETURN
      p1r = csrr(kflag)
      ascle = bry(kflag)
      DO 260 i=kk,n
        p2r = s2r
        p2i = s2i
        s2r = ckr*p2r - cki*p2i + s1r
        s2i = cki*p2r + ckr*p2i + s1i
        s1r = p2r
        s1i = p2i
        ckr = ckr + rzr
        cki = cki + rzi
        p2r = s2r*p1r
        p2i = s2i*p1r
        yr(i) = p2r
        yi(i) = p2i
        IF (kflag.GE.3) go to 260
        str = dabs(p2r)
        sti = dabs(p2i)
        p2m = dmax1(str,sti)
        IF (p2m.LE.ascle) go to 260
        kflag = kflag + 1
        ascle = bry(kflag)
        s1r = s1r*p1r
        s1i = s1i*p1r
        s2r = p2r
        s2i = p2i
        str = cssr(kflag)
        s1r = s1r*str
        s1i = s1i*str
        s2r = s2r*str
        s2i = s2i*str
        p1r = csrr(kflag)
  260 CONTINUE
      RETURN
C-----------------------------------------------------------------------
C     IFLAG=1 CASES, FORWARD RECURRENCE ON SCALED VALUES ON UNDERFLOW
C-----------------------------------------------------------------------
  261 CONTINUE
      helim = 0.5d0*elim
      elm = dexp(-elim)
      celmr = elm
      ascle = bry(1)
      zdr = zr
      zdi = zi
      ic = -1
      j = 2
      DO 262 i=1,inu
        str = s2r
        sti = s2i
        s2r = str*ckr-sti*cki+s1r
        s2i = sti*ckr+str*cki+s1i
        s1r = str
        s1i = sti
        ckr = ckr+rzr
        cki = cki+rzi
        as = xzabs(s2r,s2i)
        alas = dlog(as)
        p2r = -zdr+alas
        IF(p2r.LT.(-elim)) go to 263
        CALL xzlog(s2r,s2i,str,sti,idum)
        p2r = -zdr+str
        p2i = -zdi+sti
        p2m = dexp(p2r)/tol
        p1r = p2m*dcos(p2i)
        p1i = p2m*dsin(p2i)
        CALL zuchk(p1r,p1i,nw,ascle,tol)
        IF(nw.NE.0) go to 263
        j = 3 - j
        cyr(j) = p1r
        cyi(j) = p1i
        IF(ic.EQ.(i-1)) go to 264
        ic = i
        go to 262
  263   CONTINUE
        IF(alas.LT.helim) go to 262
        zdr = zdr-elim
        s1r = s1r*celmr
        s1i = s1i*celmr
        s2r = s2r*celmr
        s2i = s2i*celmr
  262 CONTINUE
      IF(n.NE.1) go to 270
      s1r = s2r
      s1i = s2i
      go to 270
  264 CONTINUE
      kflag = 1
      inub = i+1
      s2r = cyr(j)
      s2i = cyi(j)
      j = 3 - j
      s1r = cyr(j)
      s1i = cyi(j)
      IF(inub.LE.inu) go to 225
      IF(n.NE.1) go to 240
      s1r = s2r
      s1i = s2i
      go to 240
  270 CONTINUE
      yr(1) = s1r
      yi(1) = s1i
      IF(n.EQ.1) go to 280
      yr(2) = s2r
      yi(2) = s2i
  280 CONTINUE
      ascle = bry(1)
      CALL zkscl(zdr,zdi,fnu,n,yr,yi,nz,rzr,rzi,ascle,tol,elim)
      inu = n - nz
      IF (inu.LE.0) RETURN
      kk = nz + 1
      s1r = yr(kk)
      s1i = yi(kk)
      yr(kk) = s1r*csrr(1)
      yi(kk) = s1i*csrr(1)
      IF (inu.EQ.1) RETURN
      kk = nz + 2
      s2r = yr(kk)
      s2i = yi(kk)
      yr(kk) = s2r*csrr(1)
      yi(kk) = s2i*csrr(1)
      IF (inu.EQ.2) RETURN
      t2 = fnu + dble(float(kk-1))
      ckr = t2*rzr
      cki = t2*rzi
      kflag = 1
      go to 250
  290 CONTINUE
C-----------------------------------------------------------------------
C     SCALE BY DEXP(Z), IFLAG = 1 CASES
C-----------------------------------------------------------------------
      koded = 2
      iflag = 1
      kflag = 2
      go to 120
C-----------------------------------------------------------------------
C     FNU=HALF ODD INTEGER CASE, DNU=-0.5
C-----------------------------------------------------------------------
  300 CONTINUE
      s1r = coefr
      s1i = coefi
      s2r = coefr
      s2i = coefi
      go to 210
C
C
  310 CONTINUE
      nz=-2
      RETURN
      END