Example #1
0
 def plot(self):
     for p in self.patch:
         geom.polyfill(p['x'],p['y'],color=next(color))
     for h in self.hole:
         geom.polyfill(h['x'],h['y'],color=np.ones(3))    
     pl.axis('equal')
     pl.plot(0,0,'s')
     pl.plot(self.C['x'],self.C['y'],'o')
Example #2
0
 def plot(self, plot_loops=False, color=colors[0]):
     geom.polyfill(self.patch['r'], self.patch['z'], color=color)
     if plot_loops:
         pl.plot(self.segment['r'],
                 self.segment['z'],
                 color=0.75 * np.ones(3))
         for loop in self.loops:
             r, z = self.get_segment(loop)
             pl.plot(r, z, '-')
Example #3
0
 def fill_loops(self):
     for part in self.parts:
         try:
             geom.polyfill(self.parts[part]['r'],
                           self.parts[part]['z'],
                           color=color(next(ic)))
         except:
             pass
     set_figure()
Example #4
0
 def fill_loops(self):
     color = cycle(sns.color_palette('Set2', 5))
     for part in self.parts:
         try:
             geom.polyfill(self.parts[part]['r'],
                           self.parts[part]['z'],
                           color=next(color))
         except:
             pass
Example #5
0
 def fill_part(self, part, alpha=1, **kwargs):
     if part == 'TF_Coil':
         cindex = len(self.parts.keys()) - 1
     else:
         cindex = list(self.parts.keys()).index(part) - 1
     c = kwargs.get('color', color[cindex])
     geom.polyfill(self.parts[part]['r'],
                   self.parts[part]['z'],
                   color=c,
                   alpha=alpha)
Example #6
0
 def plot(self):
     pl.figure()
     self.tf.fill()
     #self.pf.plot(coils=self.pf.coil,label=True,current=True)
     if hasattr(self, 'eq'):
         self.pf.plot(coils=self.pf.sub_coil, plasma=True)
     for name in self.PFsupport:
         nodes = np.array(self.PFsupport[name])
         geom.polyfill(nodes[:, 0], nodes[:, 1], color=0.4 * np.ones(3))
     nodes = np.array(self.Gsupport['base'])
     geom.polyfill(nodes[:, 0], nodes[:, 1], color=0.4 * np.ones(3))
     pl.plot(self.Gsupport['radius'] * np.ones(2),
             [self.Gsupport['zbase'], self.Gsupport['zfloor']],
             'o-',
             color=0.4 * np.ones(3),
             lw=4)
     for name in self.OISsupport:
         nodes = np.array(self.OISsupport[name])
         geom.polyfill(nodes[:, 0], nodes[:, 1], color=0.4 * np.ones(3))
     rnose = self.CSsupport['rnose']
     rwp = self.CSsupport['rwp']
     zo = self.CSsupport['zo']
     ztop = self.CSsupport['ztop']
     rCS = [rnose, rwp, rwp, rnose]
     zCS = [zo, zo, ztop, ztop]
     geom.polyfill(rCS, zCS, color=0.4 * np.ones(3))
Example #7
0
    def plot_ripple_contours(self, n=3e3, offset=-1):
        xlim, dx = np.zeros((3, 2)), np.zeros(3)
        xl = np.zeros((len(self.coil_loop), 3))
        xl[:, 0], xl[:, 2] = geom.offset(self.coil_loop[:, 0],
                                         self.coil_loop[:, 2], offset)
        for i in range(3):
            xlim[i] = [np.min(xl[:, i]), np.max(xl[:, i])]
            dx[i] = xlim[i][1] - xlim[i][0]
        xlim[0][0] = self.plasma_loop[np.argmax(self.plasma_loop[:, 2]),
                                      0]  # plasma top
        ar = dx[0] / dx[2]
        nz = int(np.sqrt(n / ar))
        nr = int(n / nz)
        r = np.linspace(xlim[0][0], xlim[0][1], nr)
        z = np.linspace(xlim[2][0], xlim[2][1], nz)
        R, Z = np.meshgrid(r, z, indexing='ij')
        rpl = np.zeros((nr, nz))
        for i, r_ in enumerate(r):
            for j, z_ in enumerate(z):
                if geom.inloop(xl[:, 0], xl[:, 2], r_, z_):
                    rpl[i, j] = self.point((r_, 0, z_), variable='ripple')
                else:
                    rpl[i, j] = np.NaN

        levels = 10**(np.linspace(np.log10(0.01), np.log10(5), 7))
        levels = np.round(levels, decimals=2)

        geom.polyfill(self.plasma_loop[:, 0],
                      self.plasma_loop[:, 2],
                      alpha=0.3,
                      color=sns.color_palette('Set2', 5)[3])
        self.get_ripple()  # get max ripple on plasma contour
        rpl_max = self.res['fun']
        iplasma = np.argmin(abs(np.log10(levels) - np.log10(rpl_max)))
        levels[iplasma] = rpl_max  # select edge contour
        CS = pl.contour(R, Z, rpl, levels=levels, colors=[0.6 * np.ones(3)])
        zc = CS.collections[iplasma]
        pl.setp(zc, color=[0.4 * np.ones(3)])
        pl.clabel(CS, inline=1, fontsize='xx-small', fmt='%1.2f')
Example #8
0
    def cross_section(self, plot=True):
        depth = self.tf.section['winding_pack']['depth']
        side = self.tf.section['case']['side']
        width = self.tf.section['winding_pack']['width']
        inboard = self.tf.section['case']['inboard']
        outboard = self.tf.section['case']['outboard']
        external = self.tf.section['case']['external']
        nose = self.tf.section['case']['nose']
        ro = self.profile.loop.p[0]['p0']['r']
        theta = np.pi / self.nTF
        rsep = (depth / 2 + side) / np.tan(theta)
        rnose = ro - (width + inboard + nose)
        if rsep <= rnose:
            ynose = depth / 2 + side
        else:
            ynose = rnose * np.tan(theta)
        dy = depth / 2 + side - ynose
        dr = rsep - rnose
        rpoint = rsep - (depth / 2 + side) / dy * dr - ro
        rwp = ro - (width + inboard)
        if rsep <= rwp:
            ywp = depth / 2 + side
        else:
            ywp = rwp * np.tan(theta)
        self.CSsupport = {
            'rnose': rnose,
            'ynose': ynose,
            'dt': side,
            'rwp': rwp,
            'ywp': ywp
        }
        self.cs = {}
        self.cs['wp'] = {
            'r': [-width / 2, width / 2],
            'y': depth / 2 * np.ones(2)
        }
        self.cs['ca'] = {
            'in': {
                'r': [
                    rpoint + width / 2 + inboard, -(nose + width / 2),
                    rsep - (ro - width / 2 - inboard), width / 2 + inboard
                ],
                'y': [0, ynose, depth / 2 + side, depth / 2 + side]
            },
            'out': {
                'r': [-width / 2 - external, width / 2 + outboard],
                'y': depth / 2 + side * np.ones(2)
            }
        }
        r, y = self.cs['wp']['r'], self.cs['wp']['y']
        self.cs['wp']['pnt'] = {
            'r': [r[0], r[1], r[1], r[0]],
            'y': [y[0], y[1], -y[1], -y[0]]
        }
        r, y = self.cs['ca']['in']['r'], self.cs['ca']['in']['y']
        self.cs['ca']['in']['pnt'] = {
            'r': [r[1], r[2], r[3], r[3], r[2], r[1]],
            'y': [y[1], y[2], y[3], -y[3], -y[2], -y[1]]
        }
        r, y = self.cs['ca']['out']['r'], self.cs['ca']['out']['y']
        self.cs['ca']['out']['pnt'] = {
            'r': [r[0], r[1], r[1], r[0]],
            'y': [y[0], y[1], -y[1], -y[0]]
        }

        if plot:
            fig, ax = pl.subplots(1, 2, sharex=True, figsize=(6, 4))
            pl.sca(ax[0])
            pl.axis('equal')
            pl.axis('off')
            pl.xlim([-1, 0.5])
            geom.polyfill(self.cs['ca']['in']['pnt']['r'],
                          self.cs['ca']['in']['pnt']['y'],
                          color=color[0])
            geom.polyfill(self.cs['wp']['pnt']['r'],
                          self.cs['wp']['pnt']['y'],
                          color=color[1])
            pl.sca(ax[1])
            pl.axis('equal')
            pl.axis('off')
            geom.polyfill(self.cs['ca']['out']['pnt']['r'],
                          self.cs['ca']['out']['pnt']['y'],
                          color=color[0])
            geom.polyfill(self.cs['wp']['pnt']['r'],
                          self.cs['wp']['pnt']['y'],
                          color=color[1])