Пример #1
0
def pdiff_xy ( nr, nz, r, z, f ):
    # Get field components
    dfdR = numpy.zeros((nr, nz))
    dfdZ = numpy.zeros((nr, nz))
  
    for i in range (nz) :
        dfdR[:,i] = deriv(r, f[:,i])
     
  
    for i in range (nr) :
        dfdZ[i,:] = deriv(z, f[i,:])
     
  
    return Bunch(r=dfdR, z=dfdZ, phi=0.0)
Пример #2
0
def pdiff ( nr, nz, r, z, f):
    print "Calculating DCT..."
    dctf= dct2dslow( f )
    print "Finished DCT"

    drdi = deriv(r)
    dzdi = deriv(z)

    # Get field components
    dfdR = numpy.zeros((nr, nz))
    dfdZ = numpy.zeros((nr, nz))
    for i in range (nr) :
        for j in range (nz) :
            g = local_gradient(dctf, i, j, status=None)
            status=g.status
            dfdr=g.dfdr[0][0]
            dfdz=g.dfdz[0][0]

            # dfd* are derivatives wrt the indices. Need to divide by dr/di etc
            dfdR[i,j] = dfdr/drdi[i]
            dfdZ[i,j] = dfdz/dzdi[j]
    
    
    return Bunch(r=dfdR, z=dfdZ, phi=0.0)
Пример #3
0
def new_hfunc ( h, psi, a, b, h0, fixpos ):
   # global psi, fixpos, h0, a, b


    if fixpos == 0 : 
        h2 = numpy.append(h0, h)
    elif fixpos == numpy.size(psi)-1 :
        h2 = numpy.append(h, h0)
    else:
        h2 = numpy.append(numpy.append(h[0:(fixpos)], h0), h[fixpos::])
    
    f = a*h2 + b*deriv( h2, psi)
  
    if fixpos == 0 :
        f = f[1::]
    elif fixpos == numpy.size(psi)-1 :
        f = f[0:(numpy.size(f)-1)]
    else:
        f = numpy.append(f[0:(fixpos)], f[(fixpos+1)::])
     

    return f
Пример #4
0
def curvature( nx, ny, Rxy, Zxy, BRxy, BZxy, BPHIxy, PSIxy, THETAxy, hthexy, 
               CURLB=None, JXB=None, CURVEC=None, BXCURVEC=None, BXCV=None, 
               DEBUG=None, mesh=None):
#;
#; Calculate the magnetic field curvature and other related quantities
#;--------------------------------------------------------------------

    print 'Calculating curvature-related quantities...'
   
#;;-vector quantities are stored as 2D arrays of structures {r,phi,z}
    vec=Bunch( r=0.,phi=0.,z=0.)
    curlb=numpy.tile(vec,(nx,ny)) 
    jxb=numpy.tile(vec,(nx,ny)) 
    curvec=numpy.tile(vec,(nx,ny)) 
    bxcurvec=numpy.tile(vec,(nx,ny))

    bxcv=Bunch()
    bxcv.psi=numpy.zeros((nx,ny))
    bxcv.theta=numpy.zeros((nx,ny))
    bxcv.phi=numpy.zeros((nx,ny))


    status = gen_surface(mesh=mesh) # Start generator
      
   
    while True:
        period, yi, xi, last = gen_surface(period=None, last=None, xi=None)
        nys = numpy.size(yi)
        x=xi
        
        
     # Get vector along the surface
        if period ==1 :
            dr = fft_deriv(Rxy[x,yi])
            dz = fft_deriv(Zxy[x,yi])
        else:
            dr = deriv(Rxy[x,yi])
            dz = deriv(Zxy[x,yi])
        
        dl = numpy.sqrt(dr**2 + dz**2)
                
        dr = dr / dl
        dz = dz / dl
        
    
    
        for j in range (nys) :
            y = yi[j]
       
            if period :
                yp = yi[ (j+1)     % nys ]
                ym = yi[ (j-1+nys) % nys ]
            else:
                yp = yi[ numpy.min([j+1 , nys-1]) ]
                ym = yi[ numpy.max([j-1 , 0]) ]
         
            
            grad_Br   = pdiff_rz(Rxy, Zxy, BRxy, x, y, yp, ym)
            grad_Bz   = pdiff_rz(Rxy, Zxy, BZxy, x, y, yp, ym)
            grad_Bphi = pdiff_rz(Rxy, Zxy, BPHIxy, x, y, yp, ym)
            
            
       
            grad_Psi  = pdiff_rz(Rxy, Zxy, PSIxy, x, y, yp, ym)
                   

            #grad_Theta = pdiff_rz(Rxy, Zxy, THETAxy, x, y, yp, ym)
            grad_Theta = Bunch( r=dr[j]/hthexy[x,y], z=dz[j]/hthexy[x,y], phi=0.0 )

            grad_Phi=Bunch( r=0.0,z=0.0,phi=1./Rxy[x,y] ) #-gradient of the toroidal angle

            vecR=Bunch(  r=Rxy[x,y],z=Zxy[x,y] )
            vecB=Bunch( r=BRxy[x,y],z=BZxy[x,y],phi=BPHIxy[x,y] )
       
              
            curlb[x,y]=curlcyl(vecR, vecB, grad_Br, grad_Bphi, grad_Bz)
            
            
            jxb[x,y]=xprod(curlb[x,y], vecB)
       
       
            #-magnitude of B at 5 locations in cell
            bstrength = numpy.sqrt(BRxy**2 + BZxy**2 + BPHIxy**2)
       
            #-unit B vector at cell center
            vecB_unit=Bunch( r=BRxy[x,y]/bstrength[x,y],  
                  z=BZxy[x,y]/bstrength[x,y],  
                  phi=BPHIxy[x,y]/bstrength[x,y] )
       
            #-components of gradient of unit B vector at 5 locations in cell
            grad_Br_unit = pdiff_rz(Rxy, Zxy, BRxy/bstrength, x, y, yp, ym)
       
            grad_Bz_unit = pdiff_rz(Rxy, Zxy, BZxy/bstrength, x, y, yp, ym)
       
            grad_Bphi_unit = pdiff_rz(Rxy, Zxy, BPHIxy/bstrength, x, y, yp, ym)

            #-curl of unit B vector at cell center
            curlb_unit=curlcyl(vecR, vecB_unit, grad_Br_unit, grad_Bphi_unit, grad_Bz_unit)

            #-curvature vector at cell center
            curvec[x,y]=xprod(vecB_unit,curlb_unit,minus='MINUS')

            #-unit b cross curvature vector at cell center
            bxcurvec[x,y]=xprod(vecB_unit,curvec[x,y])
       
            #-calculate bxcurvec dotted with grad_psi, grad_theta, and grad_phi
            bxcv.psi[x,y]=dotprod(bxcurvec[x,y],grad_Psi)
            bxcv.theta[x,y]=numpy.real(dotprod(bxcurvec[x,y],grad_Theta))
            bxcv.phi[x,y]=dotprod(bxcurvec[x,y],grad_Phi)    
            
            
        if last==1 : break
   
#   if DEBUG : sys.exit()
           
    print '...done'

    return bxcv
Пример #5
0
def follow_gradient( interp_data, R, Z, ri0, zi0, ftarget, ri, zi, status=0, 
                     boundary=None, fbndry=None, ibndry=None ):
  
    global rd_com, idata, lastgoodf, lastgoodpos, Rpos, Zpos, ood, tol, Ri, Zi, dR, dZ
      
    tol = 0.1

    Rpos = R
    Zpos = Z
    
    Ri=numpy.arange(Rpos.size).astype(float)
    Zi=numpy.arange(Zpos.size).astype(float)
    dR=deriv(Rpos)
    dZ=deriv(Zpos)
  
    ibndry = -1
  
    idata = interp_data

    if boundary != None :
        bndry = boundary
        ri0c = ri0
        zi0c = zi0
    else:
        bndry = 0
  
    ood = 0

    if ftarget==None : print ftarget

  # Get starting f
    out=local_gradient( interp_data, ri0, zi0, status=status, f=0., dfdr=None, dfdz=None)
    status=out.status
    f0=out.f
    if status == 1 :
        ri = ri0
        zi = zi0
        status = 1
        return Bunch(status=status, ri=ri, zi=zi)
    

    fmax = ftarget # Target (with maybe boundary in the way)


#   CATCH, theError
#    try :
    # Call LSODE to follow gradient
    rzold = [ri0, zi0]
    rcount = 0
  #      while True:

#@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@
# toggle this for lsode            

    solver = lsode(radial_differential, f0, rzold) 
    rznew=solver.integrate(ftarget)
    nsteps = solver.steps

#@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@
# toggle this for odeint            
                                    
 # get the value out of a list
#    x0 = chain.from_iterable(f0)
#    x0 = list(x0)[0]
#                       
#   # print x0, ftarget                  
#    solode=odeint(radial_differential,rzold,[x0,ftarget],full_output=True)
#
#    rznew=solode[0][1,:]
#    nsteps=solode[1]['nst'][0]

#@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@
  
    lstat=0
#    print 'nsteps=',nsteps    
    #print rzold, rznew
    #
    #sys.exit()
#
#   #         if nsteps > 100 : lstat = -1
#            if lstat == -1 :
#                print "  -> Excessive work "+str(f0)+" to "+str(ftarget)+" Trying to continue..."
#                lstat = 2 # continue
#                rcount = rcount + 1
#                if rcount > 3 :
#                    print "   -> Too many repeats. Giving Up."
#          
#                    ri = lastgoodpos[0]
#                    zi = lastgoodpos[1]
#                    fmax = lastgoodf
#          
#                    return Bunch(status=status,ri=ri,zi=zi)
#         
#            # Get f at this new location
#                out=local_gradient( interp_data, rznew[0], rznew[1], status=status, f=f0, dfdr=None, dfdz=None)
#                status=out.status
#                f0=out.f
#
#                if status == 1 :
#                    ri = ri0
#                    zi = zi0
#                    status = 1
#                    return Bunch(status=status, rinext=ri, zinext=zi)
#            
#                rzold = rznew
#        
#                 
#            else :
#                print "I break"        
#                break
#        
#        print 'am I here?'
#        
#        if status==0:
#            print 'I break from try?'
#            break
#    
#        if lstat < 0 :
#            print "Error in LSODE routine when following psi gradient."
#            print "LSODE status: ", lstat
#           #STOP
#
#
#    except Exception as theError:
#        print theError
        
    
    ri = rznew[0]
    zi = rznew[1]
    
 #   else:
 #   # An error occurred in LSODE.
 #   # lastgoodf contains the last known good f value
 #   #PRINT, "CAUGHT ERROR "+!ERROR_STATE.MSG
 #   #CATCH, /cancel
 #       ri = lastgoodpos[0]
 #       zi = lastgoodpos[1]
 #       fmax = lastgoodf
 #       if ood :
 #       # Gone Out Of Domain
 #           status = 2
 #           fbndry = lastgoodf
 #       #PRINT, "Out of domain at f = ", fbndry
 #       # Repeat to verify that this does work
 #           rzold = [ri0, zi0]
 #           try :
 #               fbndry = lastgoodf - 0.1*(ftarget - f0)
 #               if theError != 0 :
 #                   print "   Error again at ", fbndry
 #      
 #               
 #               solver=lsode(radial_differential, f0, rzold)
 #               rznew=solver.integrate(fbndry - f0) 
 #           except Exception as theError:
 #               print theError
 #     
 #           return Bunch(status=status, rinext=ri, zinext=zi)
 #    
 #   # Otherwise just crossed a boundary
 #
 #   #CATCH, /cancel
    

  
    #if boundary != None:
    ## Check if the line crossed a boundary
    ##PRINT, "Checking boundary ", boundary[*,1:2], [ri0, ri], [zi0, zi]
    #    cpos, ncross, inds2 = line_crossings([ri0, ri], [zi0, zi], 0, 
    #                      boundary[0,:], boundary[1,:], 1, ncross=0, inds2=0)
    #    if (ncross % 2) == 1 : # Odd number of boundary crossings
    #        if numpy.sqrt( (ri - cpos[0,0])**2 + (zi - cpos[1,0])**2 ) > 0.1 :
    #    #PRINT, "FINDING BOUNDARY", SQRT( (ri - cpos[0,0])^2 + (zi - cpos[1,0])^2 )
    #    # Use divide-and-conquer to find crossing point
    #    
    #            tol = 1e-4 # Make the boundary crossing stricter
    #    
    #            ibndry = inds2[0] # Index in boundary where hit
    #    
    #            fcur = f0 # Current known good position
    #            rzold = [ri0,zi0]
    #            rzcur = rzold
    #            while True:
    #                fbndry = (fcur + fmax) / 2
    #     # Try to go half-way to fmax
    #                #CATCH, theError
    #                if theError != 0 :
    #        # Crossed boundary. Change fmax
    #                    #CATCH, /cancel
    #                    fmax = fbndry
    #                    ibndry = inds2[0] # refined boundary index
    #                else:
    #                    solver=lsode(radial_differential, f0, rzold)
    #                    rznew=solver.integrate(fbndry - f0) 
    #        
    #       # Didn't cross. Make this the new current location
    #                    fcur = fbndry
    #                    rzcur = rznew
    #        
    #                    #CATCH, /cancel
    #       
    #                if numpy.abs(fmax - fcur) < 0.01*numpy.abs(ftarget - f0):
    #                    break
    #            ri = rzcur[0]
    #            zi = rzcur[1]
    #            fbndry = fcur
    #    
    #    #PRINT, "Hit boundary", ri, zi, " f =", fbndry
    #            status = 2
    #            return Bunch(status=status, rinext=ri, zinext=zi, fbndry=fbndry, ibndry=ibndry)
 
    #print "follow_gradient"
    #print ri, zi
    return Bunch(status = 0, rinext=ri, zinext=zi, fbndry=fbndry, ibndry=ibndry)
Пример #6
0
def process_grid( rz_grid, mesh, output=None, poorquality=None, 
                  gui=None, parent=None, reverse_bt=None,  
                  curv=None, smoothpressure=None,  
                  smoothhthe=None, smoothcurv=None,  
                  settings=None):
  
    if settings==None :
        # Create an empty structure
        settings = Bunch(dummy=0)
     
    # Check settings
        settings.calcp= -1
        settings.calcbt= -1
        settings.calchthe= -1
        settings.calcjpar= -1
  
   # ;CATCH, err
   # ;IF err NE 0 THEN BEGIN
   # ;  PRINT, "PROCESS_GRID failed"
  	#;  PRINT, "   Error message: "+!ERROR_STATE.MSG
   # ;  CATCH, /cancel
   # ;  RETURN
   # ;ENDIF

    MU = 4.e-7*numpy.pi

    poorquality = 0

    if output==None : output="bout.grd.nc"
  
    # Size of the mesh
    nx = numpy.int(numpy.sum(mesh.nrad))
    ny = numpy.int(numpy.sum(mesh.npol))

    # Find the midplane
    ymid = 0
    status = gen_surface(mesh=mesh) # Start generator
     
    while True:
        period, yi, xi, last = gen_surface(period=None, last=None, xi=None)
        if period :
            rm = numpy.max(mesh.Rxy[xi,yi])
            ymidindx = numpy.argmax(mesh.Rxy[xi,yi])
            ymid = yi[ymidindx]
            break
         
        if last==1: break
  

    Rxy = numpy.asarray(mesh.Rxy)
    Zxy = numpy.asarray(mesh.Zxy)
    psixy = mesh.psixy*mesh.fnorm + mesh.faxis # Non-normalised psi

    pressure = numpy.zeros((nx, ny))
    
    
 
    # Use splines to interpolate pressure profile
    status = gen_surface(mesh=mesh) # Start generator
    while True:
        # Get the next domain
        period, yi, xi, last = gen_surface(period=period, last=last, xi=xi)
        if period :
            # Pressure only given on core surfaces
           # pressure[xi,yi] = SPLINE(rz_grid.npsigrid, rz_grid.pres, mesh.psixy[xi,yi[0]], /double)
            sol=interpolate.UnivariateSpline(rz_grid.npsigrid, rz_grid.pres,s=1)
            pressure[xi,yi] =sol(mesh.psixy[xi,yi[0]])

        else:

            pressure[xi,yi] = rz_grid.pres[numpy.size(rz_grid.pres)-1]

        if last==1 : break
        
  
    # Add a minimum amount
    if numpy.min(pressure) < 1.0e-2*numpy.max(pressure) :
        print "****Minimum pressure is very small:", numpy.min(pressure)
        print  "****Setting minimum pressure to 1% of maximum"
        pressure = pressure + 1e-2*numpy.max(pressure)
         
  
    if smoothpressure != None :
        p0 = pressure[:,ymid] # Keep initial pressure for comparison
        while True :
            #!P.multi=[0,0,2,0,0]
            fig=figure()
            plot( p0, xtitle="X index", ytitle="pressure at y="+numpy.strip(numpy.str(ymid),2)+" dashed=original", color=1, lines=1)
            plot( pressure[:,ymid], color=1)
            plot( deriv(p0), xtitle="X index", ytitle="DERIV(pressure)", color=1, lines=1)
            plot( deriv(pressure[:,ymid]), color=1 )
            sm = query_yes_no("Smooth pressure profile?")#, gui=gui, dialog_parent=parent)
            if sm :
                # Smooth the pressure profile
        
                p2 = pressure
                for i in range (6) :
                    status = gen_surface(mesh=mesh) # Start generator
                    while True :
                        # Get the next domain
                        period, yi, xi, last = gen_surface(period=period, last=last, xi=xi)
            
                        if (xi > 0) and (xi < (nx-1)) :
                            for j in range (numpy.size(yi)) :
                                p2[xi,yi[j]] = ( 0.5*pressure[xi,yi[j]] +  
                                                0.25*(pressure[xi-1,yi[j]] + pressure[xi+1,yi[j]]) 
                                                )
                             
                         
            
                        # Make sure it's still constant on flux surfaces
                        p2[xi,yi] = numpy.mean(p2[xi,yi])
                        if last != None : break
                    pressure = p2
                 
             
            if sm == 0 : break
     

    if numpy.min(pressure) < 0.0 :
        print ""
        print "============= WARNING =============="
        print "Poor quality equilibrium: Pressure is negative"
        print ""
        poorquality = 1
     
  
    dpdpsi = DDX(psixy, pressure)
    
    
    #;IF MAX(dpdpsi)*mesh.fnorm GT 0.0 THEN BEGIN
    #;  PRINT, ""
    #;  PRINT, "============= WARNING =============="
    #;  PRINT, "Poor quality equilibrium: Pressure is increasing radially"
    #;  PRINT, ""
    #;  poorquality = 1
    #;ENDIF

    # Grid spacing
    dx = numpy.zeros((nx, ny))
    for y in range (ny) : 
        dx[0:(nx-1),y] = psixy[1::,y] - psixy[0:(nx-1),y]
        dx[nx-1,y] = dx[nx-2,y]
     
  
    # Sign
    bpsign = 1.
    xcoord = psixy
    if numpy.min(dx) < 0. :
        bpsign = -1.
        dx = -dx # dx always positive
        xcoord = -xcoord
     

    dtheta = 2.*numpy.pi / numpy.float(ny)
    dy = numpy.zeros((nx, ny)) + dtheta
     
    
    # B field components
    # Following signs mean that psi increasing outwards from
    # core to edge results in Bp clockwise in the poloidal plane
    # i.e. in the positive Grad Theta direction.
  
    Brxy = mesh.dpsidZ / Rxy
    Bzxy = -mesh.dpsidR / Rxy
    Bpxy = numpy.sqrt(Brxy**2 + Bzxy**2)
    

    # Determine direction (dot B with grad y vector)
  
    dot = ( Brxy[0,ymid]*(Rxy[0,ymid+1] - Rxy[0,ymid-1]) + 
            Bzxy[0,ymid]*(Zxy[0,ymid+1] - Zxy[0,ymid-1])
            ) 
  
    if dot < 0. :
        print "**** Poloidal field is in opposite direction to Grad Theta -> Bp negative"
        Bpxy = -Bpxy
        if bpsign > 0 : sys.exit() # Should be negative
        bpsign = -1.0
    else:
        if bpsign < 0 : sys.exit() # Should be positive
        bpsign = 1.
     

  # Get toroidal field from poloidal current function fpol
    Btxy = numpy.zeros((nx, ny))
    fprime = numpy.zeros((nx, ny))
    fp = deriv(rz_grid.fpol, rz_grid.npsigrid*(rz_grid.sibdry - rz_grid.simagx))
    
    
    status = gen_surface(mesh=mesh) # Start generator
    while True:
        # Get the next domain
        period, yi, xi, last = gen_surface(period=period, last=period, xi=xi)

        if period :
            # In the core
            #fpol = numpy.interp(rz_grid.fpol, rz_grid.npsigrid, mesh.psixy[xi,yi], /spline)
                        
            sol=interpolate.UnivariateSpline(rz_grid.npsigrid, rz_grid.fpol,s=1)
         #  fpol = SPLINE(rz_grid.npsigrid, rz_grid.fpol, mesh.psixy[xi,yi[0]], 'double')
            fpol = sol(mesh.psixy[xi,yi[0]])
            
            sol=interpolate.UnivariateSpline(rz_grid.npsigrid, fp ,s=1)
           # fprime[xi,yi] = SPLINE(rz_grid.npsigrid, fp, mesh.psixy[xi,yi[0]], 'double')
            fprime[xi,yi] = sol(mesh.psixy[xi,yi[0]])
            
        else:
            # Outside core. Could be PF or SOL
            fpol = rz_grid.fpol[numpy.size(rz_grid.fpol)-1]
            fprime[xi,yi] = 0.
         
        Btxy[xi,yi] = fpol / Rxy[xi,yi]
        
        if last ==1 : break
  
    # Total B field
    Bxy = numpy.sqrt(Btxy**2 + Bpxy**2)
    

  #;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
  # Go through the domains to get a starting estimate
  # of hthe
    hthe = numpy.zeros((nx, ny))

  #   Pick a midplane index
    status = gen_surface(mesh=mesh) # Start generator
    while True:
    # Get the next domain
        period, yi, xi, last = gen_surface(period=period, last=last, xi=xi)
    
        if period :
      # In the core
            rmax = numpy.argmax(Rxy[xi,yi])
            ymidplane = yi[rmax]
            break
     
        if last == 1: break

    status = gen_surface(mesh=mesh) # Start generator
    while True:
    # Get the next domain
        period, yi, xi, last = gen_surface(period=period, last=last, xi=xi)
    
        n = numpy.size(yi)
    
        # Get distance along this line
    
        if period :
             
            # Periodic, so can use FFT
            #drdi = REAL_PART(fft_deriv(Rxy[xi, yi]))
            #dzdi = REAL_PART(fft_deriv(Zxy[xi, yi]))
            line=numpy.append(Rxy[xi,yi[n-1::]], Rxy[xi,yi])  
            line=numpy.append(line,Rxy[xi,yi[0:1]])
           
            drdi = deriv(line)[1:n+1]
            
            line=numpy.append(Zxy[xi,yi[n-1::]], Zxy[xi,yi])  
            line=numpy.append(line,Zxy[xi,yi[0:1]])
                              
            dzdi = deriv(line)[1:n+1]
        else:
        # Non-periodic
            drdi = numpy.gradient(Rxy[xi, yi])
            dzdi = numpy.gradient(Zxy[xi, yi])
     
    
        dldi = numpy.sqrt(drdi**2 + dzdi**2)
    
            
        if 0 :

        # Need to smooth to get sensible results
            if period :
                n = numpy.size(dldi)
                line=numpy.append(dldi[(n-2)::], dldi) # once
                line=numpy.append(line,dldi[0:2])
                dldi = SMOOTH(line, 5)[4:(n+4)]
                
                line=numpy.append(dldi[(n-2)::], dldi) #twice
                line=numpy.append(line,dldi[0:2])
                dldi = SMOOTH(line, 5)[4:(n+4)]
                
                line=numpy.append(dldi[(n-2)::], dldi) # three
                line=numpy.append(line,dldi[0:2])
                dldi = SMOOTH(line, 5)[4:(n+4)]
                
            else:
                line = dldi
                dldi = SMOOTH(line, 5)[2:n+2]
                line = dldi
                dldi = SMOOTH(line, 5)[2:n+2]
                line = dldi
                dldi = SMOOTH(dldi, 5)[2:n+2]
        
    
        hthe[xi, yi] = dldi / dtheta # First estimate of hthe
    
        # Get outboard midplane
        if period and xi == 0 :
            m = numpy.argmax(Rxy[0,yi])
            ymidplane = yi[m]
         
        if last == 1 : break

    print "Midplane index ", ymidplane

    fb0 = force_balance(psixy, Rxy, Bpxy, Btxy, hthe, pressure)
    print "Force imbalance: ", numpy.mean(numpy.abs(fb0)), numpy.max(numpy.abs(fb0))

    

    
  #;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
  # Correct pressure using hthe
  
    print "Calculating pressure profile from force balance"

    try:

    # Calculate force balance
        dpdx = ( -Bpxy*DDX(xcoord, Bpxy * hthe) - Btxy*hthe*DDX(xcoord, Btxy) - (Btxy*Btxy*hthe/Rxy)*DDX(xcoord, Rxy) ) / (MU*hthe)
    
        # Surface average
        dpdx2 = surface_average(dpdx, mesh)
        
        pres = numpy.zeros((nx, ny))
        # Integrate to get pressure
        for i in range (ny) :
            pres[:,i] = int_func(psixy[:,i], dpdx2[:,i])
            pres[:,i] = pres[:,i] - pres[nx-1,i]
         
        
       
        status = gen_surface(mesh=mesh) # Start generator
        while True:
      # Get the next domain
            period, yi, xi, last = gen_surface(period=None, last=None, xi=None)
      
            ma = numpy.max(pres[xi,yi])
           
            for i in range (numpy.size(yi)) :
                pres[:,yi[i]] = pres[:,yi[i]] - pres[xi,yi[i]] + ma
             
            if last == 1 : break
        
    
        pres = pres - numpy.min(pres)
  
    # Some sort of smoothing here?
  
  
        fb0 = force_balance(psixy, Rxy, Bpxy, Btxy, hthe, pres)
        print "Force imbalance: ", numpy.mean(numpy.abs(fb0)), numpy.max(numpy.abs(fb0))
  
  
       #!P.MULTI=[0,0,2,0,0]
        fig=figure(figsize=(7, 11))
        subplots_adjust(left=.07, bottom=.07, right=0.95, top=0.95,
                wspace=.3, hspace=.25)
        
        SURFACE( pressure, fig, xtitle="X", ytitle="Y", var='Pa', sub=[2,1,1])
        title("Input pressure")
        SURFACE( pres, fig, xtitle="X", ytitle="Y", var='Pa', sub=[2,1,2])
        title("New pressure")
  #  arrange the plot on the screen      
  #      mngr = get_current_fig_manager()
  #      geom = mngr.window.geometry()
  #      x,y,dx,dy = geom.getRect()
  #      mngr.window.setGeometry(0, 0, dx, dy)
  #
        show(block=False)
        
  
        calcp = settings.calcp
    
        if calcp == -1 :
            calcp = query_yes_no("Keep new pressure?")#, gui=gui, dialog_parent=parent)
        else: time.sleep( 2 )
        if calcp == 1 :
            pressure = pres
            dpdpsi = dpdx2
            
         
    except Exception:
        print "WARNING: Pressure profile calculation failed: "#, !ERROR_STATE.MSG 
        pass

    #CATCH, /cancel
  
  #;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
  # Correct f = RBt using force balance

    calcbt = settings.calcbt
    if calcbt == -1 : calcbt = query_yes_no("Correct f=RBt using force balance?")#, gui=gui, dialog_parent=parent)
    if calcbt == 1 :

        new_Btxy = newton_Bt(psixy, Rxy, Btxy, Bpxy, pres, hthe, mesh)
    
        fb0 = force_balance(psixy, Rxy, Bpxy, new_Btxy, hthe, pressure)
        print "force imbalance: ", numpy.mean(numpy.abs(fb0)), numpy.max(numpy.abs(fb0))
    
    
        fig=figure(figsize=(7, 11))
        subplots_adjust(left=.07, bottom=.07, right=0.95, top=0.95,
                wspace=.3, hspace=.25)
        
        subplot(211)
        SURFACE( Btxy, fig, xtitle="X", ytitle="Y", var='T', sub=[2,1,1])
        title("Input Bt")
        subplot(212)
        SURFACE( new_Btxy, fig, xtitle="X", ytitle="Y", var='T', sub=[2,1,2])
        title("New Bt")
          #  arrange the plot on the screen      
        #mngr = get_current_fig_manager()
        #geom = mngr.window.geometry()
        #x,y,dx,dy = geom.getRect()
        #mngr.window.setGeometry(600, 0, dx, dy)


        show(block=False)

        calcbt = settings.calcbt
        if calcbt == -1 : calcbt = query_yes_no("Keep new Bt?")#, gui=gui, dialog_parent=parent)
        if calcbt == 1 :
            Btxy = new_Btxy
            Bxy = numpy.sqrt(Btxy**2 + Bpxy**2)
    
  #;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
  # CALCULATE HTHE
  # Modify hthe to fit force balance using initial guess
  # Does not depend on signs
  #;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
  
    calchthe = settings.calchthe
    if calchthe == -1 : calchthe = query_yes_no("Adjust hthe using force balance?")#, gui=gui, dialog_parent=parent) 
    if calchthe == 1 :
        # This doesn't behave well close to the x-points
        fixhthe = numpy.int(nx / 2)
        nh = correct_hthe(Rxy, psixy, Btxy, Bpxy, hthe, pressure, fixhthe=fixhthe)
    
        fb0 = force_balance(psixy, Rxy, Bpxy, Btxy, nh, pressure)
        print "Force imbalance: ", numpy.mean(numpy.abs(fb0)), numpy.max(numpy.abs(fb0))
    
        print "numpy.maximum difference in hthe: ", numpy.max(numpy.abs(hthe - nh))
        print "numpy.maximum percentage difference: ", 100.*numpy.max(numpy.abs((hthe - nh)/hthe))

       #!P.multi=[0,0,1,0,0]
        fig=figure(figsize=(7, 4))
        title("Poloidal arc length at midplane. line is initial estimate")
        plot( hthe[:,0], '-' )
        plot( nh[:,0], 'r-+' )
                  #  arrange the plot on the screen      
        #mngr = get_current_fig_manager()
        #geom = mngr.window.geometry()
        #x,y,dx,dy = geom.getRect()
        #mngr.window.setGeometry(0, 1150, dx, dy)

        show(block=False)

        if query_yes_no("Keep new hthe?") == 1:#, gui=gui, dialog_parent=parent) :
            hthe = nh
             
   
  
    if smoothhthe != None :
    # Smooth hthe to prevent large jumps in X or Y. This
    # should be done by creating a better mesh in the first place
    
    # Need to smooth in Y and X otherwise smoothing in X
    # produces discontinuities in Y
        hold = hthe
    
        if 1 :
      # Nonlinear smoothing. Tries to smooth only regions with large
      # changes in gradient
      
            hthe =0.# smooth_nl(hthe, mesh)
      
        else:
      # Just use smooth in both directions
      
            for i in range (ny) :
                hthe[:,i] = SMOOTH(SMOOTH(hthe[:,i],10),10)
         
      
        status = gen_surface(mesh=mesh) # Start generator
        while True:
        # Get the next domain
            period, yi, xi, last = gen_surface(period=None, last=None, xi=None)
        
            n = numpy.size(yi)
        
            if period :
                hthe[xi,yi] = (SMOOTH([hthe[xi,yi[(n-4):(n-1)]], hthe[xi,yi], hthe[xi,yi[0:3]]], 4))[4:(n+3)]
            else:
                hthe[xi,yi] = SMOOTH(hthe[xi,yi], 4)
           
            if last == 1: break
            
    

    # Calculate field-line pitch
    pitch = hthe * Btxy / (Bpxy * Rxy)
  
   
    # derivative with psi
    dqdpsi = DDX(psixy, pitch)
      

    qinty, qloop = int_y(pitch, mesh, loop=0, nosmooth='nosmooth', simple='simple') 
    qinty = qinty * dtheta
    qloop = qloop * dtheta
    
    
    sinty = int_y(dqdpsi, mesh, nosmooth='nosmooth', simple='simple') * dtheta
  

  
    # NOTE: This is only valid in the core
    pol_angle = numpy.zeros((nx,ny))
    for i in range (nx) :  pol_angle[i, :] = 2.0*numpy.pi * qinty[i,:] / qloop[i]
    
    
  #;;;;;;;;;;;;;;;;;;; THETA_ZERO ;;;;;;;;;;;;;;;;;;;;;;
  # re-set zshift to be zero at the outboard midplane
  
    print "MIDPLANE INDEX = ", ymidplane
  
    status = gen_surface(mesh=mesh) # Start generator
    while True:
    # Get the next domain
        period, yi, xi, last = gen_surface(period=None, last=None, xi=None)
    
        w = numpy.size(numpy.where(yi == ymidplane))
        if w > 0 :
      # Crosses the midplane
            qinty[xi, yi] = qinty[xi, yi] - qinty[xi, ymidplane]
            sinty[xi, yi] = sinty[xi, yi] - sinty[xi, ymidplane]
        else:
      # Doesn't include a point at the midplane
            qinty[xi, yi] = qinty[xi, yi] - qinty[xi,yi[0]]
            sinty[xi, yi] = sinty[xi, yi] - sinty[xi,yi[0]]
     
        if last ==1 : break
  
    print ""
    print "==== Calculating curvature ===="
  
  #;;;;;;;;;;;;;;;;;;; CURVATURE ;;;;;;;;;;;;;;;;;;;;;;;
  # Calculating b x kappa
  
    if curv == None :
    
        print "*** Calculating curvature in toroidal coordinates"
    
        thetaxy = numpy.zeros((nx, ny))
        status = gen_surface(mesh=mesh) # Start generator
        while True:
            # Get the next domain
            period, yi, xi, last = gen_surface(period=None, last=None, xi=None)
            thetaxy[xi,yi] = numpy.arange(numpy.size(yi)).astype(float)*dtheta
            if last ==1 : break
    
        
        bxcv = curvature( nx, ny, Rxy,Zxy, Brxy, Bzxy, Btxy,  
                    psixy, thetaxy, hthe,  
                     mesh=mesh)
                             
        bxcvx = bpsign*bxcv.psi 
        bxcvy= bxcv.theta
        bxcvz = bpsign*(bxcv.phi - sinty*bxcv.psi - pitch*bxcv.theta)
        
       
        # x borders
        bxcvx[0,:] = bxcvx[1,:]
        bxcvx[nx-1,:] = bxcvx[nx-2,:]
    
        bxcvy[0,:] = bxcvy[1,:]
        bxcvy[nx-1,:] = bxcvy[nx-2,:]
    
        bxcvz[0,:] = bxcvz[1,:]
        bxcvz[nx-1,:] = bxcvz[nx-2,:]

    elif curv == 1 :
        # Calculate on R-Z mesh and then interpolate onto grid
        # ( cylindrical coordinates)

        print "*** Calculating curvature in cylindrical coordinates"
    
        bxcv = rz_curvature(rz_grid)
    
        # DCT methods cause spurious oscillations
        # Linear interpolation seems to be more robust
        bxcv_psi = numpy.interp(bxcv.psi, mesh.Rixy, mesh.Zixy)
        bxcv_theta = numpy.interp(bxcv.theta, mesh.Rixy, mesh.Zixy) / hthe
        bxcv_phi = numpy.interp(bxcv.phi, mesh.Rixy, mesh.Zixy)
    
        # If Bp is reversed, then Grad x = - Grad psi
        bxcvx = bpsign*bxcv_psi
        bxcvy = bxcv_theta
        bxcvz = bpsign*(bxcv_phi - sinty*bxcv_psi - pitch*bxcv_theta)
    elif curv == 2 :
        # Curvature from Curl(b/B)
    
        bxcvx = bpsign*(Bpxy * Btxy*Rxy * DDY(1. / Bxy, mesh) / hthe)
        bxcvy = -bpsign*Bxy*Bpxy * DDX(xcoord, Btxy*Rxy/Bxy^2) / (2.*hthe)
        bxcvz = Bpxy^3 * DDX(xcoord, hthe/Bpxy) / (2.*hthe*Bxy) - Btxy*Rxy*DDX(xcoord, Btxy/Rxy) / (2.*Bxy) - sinty*bxcvx
    
    else:
        # calculate in flux coordinates.
    
        print "*** Calculating curvature in flux coordinates"
    
        dpb = numpy.zeros((nx, ny))      # quantity used for y and z components
    
        for i in range (ny) :
            dpb[:,i] = MU*dpdpsi/Bxy[:,i]
         
        dpb = dpb + DDX(xcoord, Bxy)

        bxcvx = bpsign*(Bpxy * Btxy*Rxy * DDY(1. / Bxy, mesh) / hthe)
        bxcvy = bpsign*(Bpxy*Btxy*Rxy*dpb / (hthe*Bxy^2))
        bxcvz = -dpb - sinty*bxcvx
     
  

    if smoothcurv:
        # Smooth curvature to prevent large jumps
    
        # Nonlinear smoothing. Tries to smooth only regions with large
        # changes in gradient
    
        bz = bxcvz + sinty * bxcvx
    
        print "Smoothing bxcvx..."
        bxcvx = 0.#smooth_nl(bxcvx, mesh)
        print "Smoothing bxcvy..."
        bxcvy = 0.#smooth_nl(bxcvy, mesh)
        print "Smoothing bxcvz..."
        bz = 0.#smooth_nl(bz, mesh)
    
        bxcvz = bz - sinty * bxcvx
   

  #;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
  # CALCULATE PARALLEL CURRENT
  # 
  # Three ways to calculate Jpar0:
  # 1. From fprime and pprime
  # 2. From Curl(B) in field-aligned coords
  # 3. From the curvature
  # 
  # Provides a way to check if Btor should be reversed
  #
  #;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
  
    print ""
    print "==== Calculating parallel current ===="
    
    jpar0 = - Bxy * fprime / MU - Rxy*Btxy * dpdpsi / Bxy
     
  
    # Set to zero in PF and SOL
    status = gen_surface(mesh=mesh) # Start generator
    while True:
    # Get the next domain
        period, yi, xi, last = gen_surface(period=None, last=None, xi=None)
    
        if period == None : jpar0[xi,yi] = 0.0
        if last == 1 : break
  
  # Curl(B) expression for Jpar0 (very noisy usually)
    j0 = ( bpsign*((Bpxy*Btxy*Rxy/(Bxy*hthe))*( DDX(xcoord, Bxy**2*hthe/Bpxy) - bpsign*Btxy*Rxy*DDX(xcoord,Btxy*hthe/(Rxy*Bpxy)) ) 
        - Bxy*DDX(xcoord, Btxy*Rxy)) / MU )
  

  
  # Create a temporary mesh structure to send to adjust_jpar
    tmp_mesh = Bunch(mesh,  
                           bxcvx=bxcvx, bxcvy=bxcvy,  bxcvz=bxcvz,  
                            Bpxy=Bpxy,  Btxy=Btxy,  Bxy=Bxy,  
                            dx=dx,  dy=dy,  
                            hthe=hthe,  jpar0=jpar0,  pressure=pressure)
    tmp_mesh.psixy = psixy
  
    jpar = adjust_jpar( tmp_mesh, noplot='noplot')
    

   #!P.multi=[0,2,2,0,0]
   
    fig=figure(figsize=(15, 11))
    subplots_adjust(left=.07, bottom=.07, right=0.95, top=0.95,
                wspace=.3, hspace=.25)

    subplot(221)
    SURFACE( jpar0, fig, xtitle="X", ytitle="Y", var='A', sub=[2,2,1])
    title("Jpar from F' and P'")
    
    subplot(222)
    SURFACE( jpar, fig, xtitle="X", ytitle="Y", var='A', sub=[2,2,2])
    title("Jpar from curvature")
 
    subplot(223)
    plot( jpar0[0,:],'-', jpar[0,:] ,'+' )
    ylim([numpy.min([jpar0[0,:],jpar[0,:]]), numpy.max([jpar0[0,:],jpar[0,:]])])
    title("jpar at x=0. Solid from f' and p'")
    
    subplot(224)
    plot(jpar0[:,ymidplane],'-' , jpar[:,ymidplane] , '+' )
    ylim([numpy.min([jpar0[:,ymidplane],jpar[:,ymidplane]]),numpy.max([jpar0[:,ymidplane],jpar[:,ymidplane]])])
        
    title("Jpar at y="+numpy.str(ymidplane)+" Solid from f' and p'")
    
        #  arrange the plot on the screen      
    #mngr = get_current_fig_manager()
    #geom = mngr.window.geometry()
    #x,y,dx,dy = geom.getRect()
    #mngr.window.setGeometry(1350, 0, dx, dy)

    
    show(block=False)
  
 # !P.multi=0
  
    calcjpar = settings.calcjpar
    if calcjpar == -1 : calcjpar = query_yes_no("Use Jpar from curvature?")#, gui=gui, dialog_parent=parent)
    if calcjpar == True :
        jpar0 = jpar
   
  
    if 0 :
    
    # Try smoothing jpar0 in psi, preserving zero points and maxima
        jps = jpar0
        for y in range ( ny ):
            j = jpar0[:,y]
            js = j
            ma = numpy.max(numpy.abs(j))
            ip = numpy.argmax(numpy.abs(j))
            if (ma < 1.e-4) or (ip == 0) :
                jps[:,y] = j
         
            level = 1.
            #i0 = MAX(WHERE(ABS(j[0:ip]) LT level))
            i1 = numpy.min(numpy.where(numpy.abs(j[ip::]) < level))
      
            #IF i0 LE 0 THEN i0 = 1
            i0 = 1
      
            if i1 == -1 :
                i1 = nx-2 
            else: 
                i1 = i1 + ip
      
            if (ip <= i0) or (ip >= i1) :
      
      # Now preserve starting and end points, and peak value
                div = numpy.int((i1-i0)/10)+1 # reduce number of points by this factor
      
                inds = [i0] # first point
                for i in [i0+div, ip-div, div] : inds = [inds, i]
                inds = [inds, ip] # Put in the peak point
      
        # Calculate spline interpolation of inner part
        
                js[0:ip] = spline_mono(inds, j[inds], numpy.arange(ip+1),
                             yp0=(j[i0] - j[i0-1]), ypn_1=0.0)
      
                inds = [ip] # peak point
                for i in [ip+div, i1-div, div] :
                    inds = [inds, i]
                 
      
                inds = [inds, i1]  # Last point
                js[ip:i1] = spline_mono(inds, j[inds], ip+numpy.arange(i1-ip+1),  
                              yp0=0.0, ypn_1=(j[i1+1]-j[i1]))
      
                jps[:,y] = js
     
   
  
  #;;;;;;;;;;;;;;;;;;; TOPOLOGY ;;;;;;;;;;;;;;;;;;;;;;;
  # Calculate indices for backwards-compatibility
  
    nr = numpy.size(mesh.nrad)
    np = numpy.size(mesh.npol)
    if (nr == 2) and (np == 3) :
        print "Single null equilibrium"
    
        ixseps1 = mesh.nrad[0]
        ixseps2 = nx
    
        jyseps1_1 = mesh.npol[0]-1
        jyseps1_2 = mesh.npol[0] + numpy.int(mesh.npol[1]/2)
        ny_inner = jyseps1_2
        jyseps2_1 = jyseps1_2
        jyseps2_2 = ny - mesh.npol[2]-1

    elif (nr == 3) and (np == 6) :
        print "Double null equilibrium"
    
        ixseps1 = mesh.nrad[0]
        ixseps2 = ixseps1 + mesh.nrad[1]
    
        jyseps1_1 = mesh.npol[0]-1
        jyseps2_1 = jyseps1_1 + mesh.npol[1]
    
        ny_inner = jyseps2_1 + mesh.npol[2] + 1
    
        jyseps1_2 = ny_inner + mesh.npol[3] - 1
        jyseps2_2 = jyseps1_2 + mesh.npol[4]
    
    elif (nr == 1) and (np == 1) :
    
        print "Single domain"
    
        ixseps1 = nx
        ixseps2 = nx
    
        jyseps1_1 = -1
        jyseps1_2 = numpy.int(ny/2)
        jyseps2_1 = numpy.int(ny/2)
        ny_inner = numpy.int(ny/2)
        jyseps2_2 = ny - 1
    
    else:
        print  "***************************************" 
        print  "* WARNING: Equilibrium not recognised *"
        print  "*                                     *"
        print  "*  Check mesh carefully!              *"
        print  "*                                     *"
        print  "*  Contact Ben Dudson                 *"
        print  "*      [email protected]     *"
        print  "***************************************" 
        ixseps1 = -1
        ixseps2 = -1
    
        jyseps1_1 = -1
        jyseps1_2 = numpy.int(ny/2)
        jyseps2_1 = numpy.int(ny/2)
        ny_inner = numpy.int(ny/2)
        jyseps2_2 = ny - 1
   

    print "Generating plasma profiles:"
          
    print "  1. Flat temperature profile"
    print "  2. Flat density profile"
    print "  3. Te proportional to density"
    while True:
        opt = raw_input("Profile option:")
        if eval(opt) >= 1 and eval(opt) <= 3 : break

  
    if opt == 1 :
        # flat temperature profile
    
        print "Setting flat temperature profile"
        while True:
            Te_x = eval(raw_input("Temperature (eV):"))
                
      
        # get density
            Ni = pressure / (2.* Te_x* 1.602e-19*1.0e20)
      
            print "numpy.maximum density (10^20 m^-3):", numpy.max(Ni)
      
            done = query_yes_no("Is this ok?")
            if done == 1 : break
    
        Te = numpy.zeros((nx, ny))+Te_x
        Ti = Te
        Ni_x = numpy.max(Ni)
        Ti_x = Te_x
    elif opt == 2 :
        print "Setting flat density profile"
    
        while True:
            Ni_x = eval(raw_input("Density [10^20 m^-3]:"))
      
            # get temperature
            Te = pressure / (2.* Ni_x * 1.602e-19*1.0e20)
      
            print "numpy.maximum temperature (eV):", numpy.max(Te)
            if query_yes_no("Is this ok?") == 1 : break
    
        Ti = Te
        Ni = numpy.zeros((nx, ny)) + Ni_x
        Te_x = numpy.max(Te)
        Ti_x = Te_x
    else:
        print "Setting te proportional to density"
    
        while True:
            Te_x = eval(raw_input("Maximum temperature [eV]:"))
            
            
            Ni_x = numpy.max(pressure) / (2.*Te_x * 1.602e-19*1.0e20)
      
            print "Maximum density [10^20 m^-3]:", Ni_x
      
            Te = Te_x * pressure / numpy.max(pressure)
            Ni = Ni_x * pressure / numpy.max(pressure)
            if query_yes_no("Is this ok?") == 1 : break
        Ti = Te
        Ti_x =  Te_x
   
  
    rmag = numpy.max(numpy.abs(Rxy))
    print "Setting rmag = ", rmag
  
    bmag = numpy.max(numpy.abs(Bxy))
    print "Setting bmag = ", bmag

    #;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
    # save to file
    # open a new netCDF file for writing.
    handle = file_open(output) 

    print "Writing grid to file "+output

    # Size of the grid

    s = file_write(handle, "nx", nx)
    s = file_write(handle, "ny", ny)


    # Topology for original scheme
    s = file_write(handle, "ixseps1", ixseps1)
    s = file_write(handle, "ixseps2", ixseps2)
    s = file_write(handle, "jyseps1_1", jyseps1_1)
    s = file_write(handle, "jyseps1_2", jyseps1_2)
    s = file_write(handle, "jyseps2_1", jyseps2_1)
    s = file_write(handle, "jyseps2_2", jyseps2_2)
    s = file_write(handle, "ny_inner", ny_inner);
  
    # Grid spacing
    
    s = file_write(handle, "dx", dx)
    s = file_write(handle, "dy", dy)
    
    s = file_write(handle, "ShiftAngle", qloop)
    s = file_write(handle, "zShift", qinty)
    s = file_write(handle, "pol_angle", pol_angle)
    s = file_write(handle, "ShiftTorsion", dqdpsi)

    s = file_write(handle, "Rxy",  Rxy)
    s = file_write(handle, "Zxy",  Zxy)
    s = file_write(handle, "Bpxy", Bpxy)
    s = file_write(handle, "Btxy", Btxy)
    s = file_write(handle, "Bxy",  Bxy)
    s = file_write(handle, "hthe", hthe)
    s = file_write(handle, "sinty", sinty)
    s = file_write(handle, "psixy", psixy)
    
    # Topology for general configurations
    s = file_write(handle, "yup_xsplit", mesh.yup_xsplit)
    s = file_write(handle, "ydown_xsplit", mesh.ydown_xsplit)
    s = file_write(handle, "yup_xin", mesh.yup_xin)
    s = file_write(handle, "yup_xout", mesh.yup_xout)
    s = file_write(handle, "ydown_xin", mesh.ydown_xin)
    s = file_write(handle, "ydown_xout", mesh.ydown_xout)
    s = file_write(handle, "nrad", mesh.nrad)
    s = file_write(handle, "npol", mesh.npol)

    # plasma profiles

    s = file_write(handle, "pressure", pressure)
    s = file_write(handle, "Jpar0", jpar0)
    s = file_write(handle, "Ni0", Ni)
    s = file_write(handle, "Te0", Te)
    s = file_write(handle, "Ti0", Ti)
    

    s = file_write(handle, "Ni_x", Ni_x)
    s = file_write(handle, "Te_x", Te_x)
    s = file_write(handle, "Ti_x", Ti_x)
    s = file_write(handle, "bmag", bmag)
    s = file_write(handle, "rmag", rmag)

    # Curvature
    s = file_write(handle, "bxcvx", bxcvx)
    s = file_write(handle, "bxcvy", bxcvy)
    s = file_write(handle, "bxcvz", bxcvz)

    # Psi range
    s = file_write(handle, "psi_axis", mesh.faxis)
    psi_bndry = mesh.faxis + mesh.fnorm
    s = file_write(handle, "psi_bndry", psi_bndry)

    file_close, handle
    print "DONE"
Пример #7
0
def Bt_func ( Bt , psi, a, b):
    #global  psi, a, b
    
    return deriv( Bt, psi ) + a*Bt + b / Bt