Пример #1
0
 def struct():
     if isinstance(structure, m.Structure):
         return structure
     elif isinstance(structure, tuple):
         return m.Structure(chip, structure)
     else:
         return chip.structure(structure)
Пример #2
0
 def struct():
     if isinstance(pos, m.Structure):
         return pos
     elif isinstance(pos, tuple):
         return m.Structure(chip, start=pos, direction=rotation)
     else:
         return chip.structure(pos)
Пример #3
0
def Spiral_Link_Rounded(dwg,
                        xy,
                        w,
                        s,
                        width,
                        height,
                        UD,
                        line_color,
                        r_ins=0,
                        LR=1,
                        curve_pts=30):
    #LR = 1 if coil goes clockwise and to the right, -1 if counterclockwise and to the left
    #UD = 1 if gap on top, -1 if gap on bottom
    q = m.transformedQuadrants(UD=UD, LR=LR)
    #draw
    pline = dxf.polyline(points=[(xy[0], xy[1] - UD * (w + s / 2))],
                         color=line_color,
                         flags=0)  #start offset by w/2
    pline.add_vertices(
        m.corner((xy[0], xy[1] + UD * height / 2), q[2], 1 * UD * LR, w / 3,
                 curve_pts))
    pline.add_vertices(
        m.corner((xy[0] + LR * width, xy[1] + UD * height / 2), q[1],
                 1 * UD * LR, w / 3, curve_pts))
    pline.add_vertices(
        m.corner((xy[0] + LR * width, xy[1] - UD * height / 2), q[4],
                 1 * UD * LR, w / 3, curve_pts))
    pline.add_vertices(
        m.corner((xy[0] + LR * 2 * (w + s), xy[1] - UD * height / 2), q[3],
                 1 * UD * LR, w / 3, curve_pts))
    pline.add_vertices([
        (xy[0] + LR * 2 * (w + s), xy[1] - UD * (w + s / 2)),
        (xy[0] + LR * (3 * w + 2 * s), xy[1] - UD * (w + s / 2)),
        (xy[0] + LR * (3 * w + 2 * s), xy[1] - UD * (height / 2 - w)),
        (xy[0] + LR * (-w + width), xy[1] - UD * (height / 2 - w)),
        (xy[0] + LR * (-w + width), xy[1] + UD * (height / 2 - w)),
        (xy[0] + LR * w, xy[1] + UD * (height / 2 - w)),
        (xy[0] + LR * w, xy[1] - UD * (w + s / 2))
    ])  #start offset by w/2

    pline.close()

    dwg.add(pline)
Пример #4
0
def Hamburgermon(chip,
                 pos,
                 rotation=0,
                 qwidth=1120,
                 qheight=795,
                 qr_out=200,
                 minQbunToGnd=100,
                 qbunwidth=960,
                 qbunthick=0,
                 qbunr=60,
                 qbunseparation=69.3751,
                 qccap_padw=40,
                 qccap_padl=170,
                 qccap_padr_out=10,
                 qccap_padr_ins=4.5,
                 qccap_gap=30,
                 qccapl=210,
                 qccapw=0,
                 qccapr_ins=30,
                 qccapr_out=15,
                 qccap_steml=70,
                 qccap_stemw=None,
                 XLAYER=None,
                 bgcolor=None,
                 **kwargs):
    '''
    Generates a hamburger shaped qubit. Needs XOR layers to define base metal layer. 
    Junction and contact tab parameters are monkey patched to Junction function through kwargs.
    '''
    thisStructure = None
    if isinstance(pos, tuple):
        thisStructure = m.Structure(chip, start=pos, direction=rotation)

    def struct():
        if isinstance(pos, m.Structure):
            return pos
        elif isinstance(pos, tuple):
            return thisStructure
        else:
            return chip.structure(pos)

    if bgcolor is None:  #color for junction, not undercut
        bgcolor = chip.wafer.bg()

    #get layers from wafer
    if XLAYER is None:
        try:
            XLAYER = chip.wafer.XLAYER
        except AttributeError:
            chip.wafer.setupXORlayer()
            XLAYER = chip.wafer.XLAYER

    if qccap_stemw is None:
        try:
            qccap_stemw = struct().defaults['w']
        except KeyError:
            print('\x1b[33mw not defined in ', chip.chipID, '!\x1b[0m')
            qccap_stemw = 6

    #increase thicknesses if radii are too large
    qccapw = max(qccapw, 2 * qccapr_out)
    qbunthick = max(qbunthick, 2 * qbunr)
    qccap_padw = max(qccap_padw, 2 * qccap_padr_out)
    qccap_padl = max(qccap_padl, 2 * qccap_padr_out)

    #increase qubit width and height if buns are too close to ground
    qwidth = max(qwidth, qbunwidth + 2 * minQbunToGnd)
    qheight = max(
        qheight,
        max(qccap_steml + qccap_padl, qccap_gap + qccapl) +
        2 * max(2 * qbunr, qbunthick) + qbunseparation + minQbunToGnd)

    #cache junction position and figure out if we're using structures or not
    jxpos = qccap_steml + qccap_padl + qccap_gap + qbunthick + qbunseparation / 2
    if thisStructure is not None:
        #not using structures
        struct().shiftPos(-jxpos)
    centerPos = struct().getPos((jxpos, 0))

    #hole in basemetal (negative)
    chip.add(
        RoundRect(struct().start,
                  qheight,
                  qwidth,
                  qr_out,
                  valign=const.MIDDLE,
                  rotation=struct().direction,
                  bgcolor=bgcolor,
                  **kwargs))

    #xor defined qubit (positive)
    if qccap_padr_ins > 0 and qccap_stemw + 2 * qccap_padr_ins < qccap_padw - 2 * qccap_padr_out:
        chip.add(
            InsideCurve(struct().getPos((qccap_steml, qccap_stemw / 2)),
                        qccap_padr_ins,
                        vflip=True,
                        rotation=struct().direction,
                        layer=XLAYER,
                        bgcolor=chip.bg(XLAYER),
                        **kwargs))
        chip.add(
            InsideCurve(struct().getPos((qccap_steml, -qccap_stemw / 2)),
                        qccap_padr_ins,
                        rotation=struct().direction,
                        layer=XLAYER,
                        bgcolor=chip.bg(XLAYER),
                        **kwargs))

    chip.add(
        dxf.rectangle(struct().start,
                      qccap_steml,
                      qccap_stemw,
                      valign=const.MIDDLE,
                      rotation=struct().direction,
                      layer=XLAYER,
                      bgcolor=chip.bg(XLAYER),
                      **kwargStrip(kwargs)))
    chip.add(
        RoundRect(struct().getPos((qccap_steml, 0)),
                  qccap_padl,
                  qccap_padw,
                  qccap_padr_out,
                  valign=const.MIDDLE,
                  rotation=struct().direction,
                  layer=XLAYER,
                  bgcolor=chip.bg(XLAYER),
                  **kwargs))

    if qccapr_ins > 0:
        chip.add(
            InsideCurve(struct().getPos(
                (jxpos - qbunseparation / 2 - qbunthick,
                 qccap_padw / 2 + qccap_gap)),
                        qccapr_ins,
                        rotation=struct().direction,
                        layer=XLAYER,
                        bgcolor=chip.bg(XLAYER),
                        **kwargs))
        chip.add(
            InsideCurve(struct().getPos(
                (jxpos - qbunseparation / 2 - qbunthick,
                 qccap_padw / 2 + qccap_gap + qccapw)),
                        qccapr_ins,
                        vflip=True,
                        rotation=struct().direction,
                        layer=XLAYER,
                        bgcolor=chip.bg(XLAYER),
                        **kwargs))

        chip.add(
            InsideCurve(struct().getPos(
                (jxpos - qbunseparation / 2 - qbunthick,
                 -qccap_padw / 2 - qccap_gap)),
                        qccapr_ins,
                        vflip=True,
                        rotation=struct().direction,
                        layer=XLAYER,
                        bgcolor=chip.bg(XLAYER),
                        **kwargs))
        chip.add(
            InsideCurve(struct().getPos(
                (jxpos - qbunseparation / 2 - qbunthick,
                 -qccap_padw / 2 - qccap_gap - qccapw)),
                        qccapr_ins,
                        rotation=struct().direction,
                        layer=XLAYER,
                        bgcolor=chip.bg(XLAYER),
                        **kwargs))

    chip.add(
        RoundRect(struct().getPos((jxpos - qbunseparation / 2 - qbunthick,
                                   qccap_padw / 2 + qccap_gap)),
                  qccapl,
                  qccapw,
                  qccapr_out,
                  roundCorners=[1, 0, 0, 1],
                  halign=const.RIGHT,
                  rotation=struct().direction,
                  layer=XLAYER,
                  bgcolor=chip.bg(XLAYER),
                  **kwargs))
    chip.add(
        RoundRect(struct().getPos((jxpos - qbunseparation / 2 - qbunthick,
                                   -qccap_padw / 2 - qccap_gap)),
                  qccapl,
                  qccapw,
                  qccapr_out,
                  roundCorners=[1, 0, 0, 1],
                  halign=const.RIGHT,
                  vflip=True,
                  rotation=struct().direction,
                  layer=XLAYER,
                  bgcolor=chip.bg(XLAYER),
                  **kwargs))

    JProbePads(chip,
               centerPos,
               rotation=struct().direction,
               padwidth=qbunthick,
               padheight=qbunwidth,
               padradius=qbunr,
               separation=qbunseparation,
               layer=XLAYER,
               bgcolor=chip.bg(XLAYER),
               **kwargs)

    ManhattanJunction(chip,
                      centerPos,
                      rotation=struct().direction,
                      separation=qbunseparation,
                      **kwargs)

    return centerPos, struct().direction
Пример #5
0
def Transmon3D(chip,
               pos,
               rotation=0,
               bgcolor=None,
               padh=200,
               padh2=200,
               padw=3000,
               padw2=3000,
               taperw=0,
               taperw2=0,
               leadw=85,
               leadw2=85,
               leadh=20,
               leadh2=20,
               separation=20,
               r_out=0.75,
               r_ins=0.75,
               taboffs=-0.05,
               steml=1.5,
               gapl=1.5,
               tabl=2,
               stemw=3,
               gapw=3,
               tabw=0.5,
               jpadTaper=10,
               jpadw=25,
               jpadh=16,
               jpadSeparation=28,
               jfingerl=4.5,
               jfingerex=1.5,
               jleadw=1,
               junctionClass=ManhattanJunction,
               **kwargs):
    '''
    Generates transmon paddles with a manhattan junction at the center. 
    Junction and contact tab parameters are monkey patched to Junction function through kwargs.
    
    padh, padh2: left,right transmon pad height
    padw, padw2: left,right  transmon pad width (or length)
    taperw, taperw2: left,right taper length from pad to lead
    leadw, leadw2: left,right lead width
    leadh, leadh2: left,right lead height
    separation: separation between leads (where junction goes)

    '''
    thisStructure = None
    if isinstance(pos, tuple):
        thisStructure = m.Structure(chip, start=pos, direction=rotation)

    def struct():
        if isinstance(pos, m.Structure):
            return pos
        elif isinstance(pos, tuple):
            return thisStructure
        else:
            return chip.structure(pos)

    if bgcolor is None:  #color for junction, not undercut
        bgcolor = chip.wafer.bg()

    j_struct = struct().start

    #start where the junction is, move left to where left pad starts
    struct().shiftPos(-separation / 2 - leadw - padw)
    JSingleProbePad(chip,
                    struct(),
                    padwidth=padw,
                    padheight=padh,
                    tabShoulder=True,
                    tabShoulderWidth=leadh,
                    tabShoulderLength=leadw,
                    flipped=False,
                    padradius=None,
                    r_out=r_out,
                    r_ins=r_ins,
                    taboffs=taboffs,
                    gapl=gapl,
                    tabl=tabl,
                    gapw=gapw,
                    tabw=tabw,
                    absoluteDimensions=True,
                    **kwargs)
    struct().shiftPos(separation)
    JSingleProbePad(chip,
                    struct(),
                    padwidth=padw2,
                    padheight=padh2,
                    tabShoulder=True,
                    tabShoulderWidth=leadh2,
                    tabShoulderLength=leadw2,
                    flipped=True,
                    padradius=None,
                    r_out=r_out,
                    r_ins=r_ins,
                    taboffs=taboffs,
                    gapl=gapl,
                    tabl=tabl,
                    gapw=gapw,
                    tabw=tabw,
                    absoluteDimensions=True,
                    **kwargs)
    #r_out=0,r_ins=0,taboffs=3,gapl=0,tabl=0,gapw=gapw,tabw=2,absoluteDimensions=True,**kwargs)

    #write the junction
    junctionClass(chip,
                  j_struct,
                  rotation=struct().direction,
                  jpadTaper=jpadTaper,
                  jpadw=jpadw,
                  jpadh=jpadh,
                  separation=jpadSeparation + jpadTaper,
                  jfingerl=jfingerl,
                  jfingerex=jfingerex,
                  leadw=jleadw,
                  **kwargs)
Пример #6
0
    def __init__(self,wafer,chipID,layer):
        m.Chip7mm.__init__(self,wafer,chipID,layer,defaults={'w':10, 's':5, 'radius':50,'r_out':5,'r_ins':5})
        
        for s in self.structures:
            self.add(dxf.rectangle(s.start,80,20,rotation=s.direction,layer='FRAME',halign = const.RIGHT,valign = const.MIDDLE))
            
        #test strip functions
        Strip_stub_open(self, 3,flipped=True)
        Strip_bend(self, 3,angle=20,CCW=False)
        Strip_straight(self, 3,20)
        Strip_taper(self, 3,w1=2)
        Strip_bend(self, 3,w=2)
        Strip_stub_short(self,3,w=2,extra_straight_section=True)
        Strip_stub_open(self, 3, w=40,flipped=True)
        Strip_straight(self,3,40,w=40)
        Strip_stub_open(self, 3, w=40)
        Strip_stub_short(self,3,w=2,extra_straight_section=True,flipped=True)
        Strip_wiggles(self,3,length=None,nTurns=5,maxWidth=200,w=2,radius=25)
        
        #test twopincpw functions
        TwoPinCPW_straight(self, 3, 40, s_ins=2,Width=250)
        s3 = self.structures[3].cloneAlong()
        Inductor_wiggles(self, 3, w=2+2*10,nTurns=2,maxWidth=200,radius=24,Width=250)
        Strip_wiggles(self, s3, w=2,nTurns=2,maxWidth=200-10,radius=24)
        #now do the same with TwoPinCPW_wiggles
        TwoPinCPW_wiggles(self,s3,s_ins=2,nTurns=2,maxWidth=200,radius=24,Width=250)
        
        #launcher subcomponents
        CPW_stub_open(self,1,r_out=100,r_ins=50,w=300,s=160,flipped=True)
        CPW_straight(self,1,300,w=300,s=160)
        CPW_taper(self,1,w0=300,s0=160)
        #        
        CPW_straight(self,1,600)
        
        JellyfishResonator(self,self.structures[1].cloneAlongLast((300,40),newDirection=90),520,480,5565,w_cap=40,s_cap=20,maxWidth=100)
        
        
        CPW_bend(self,1,angle=45)
        CPW_straight(self,1,600)
        
        DoubleJellyfishResonator(self,self.structures[1].cloneAlongLast((100,40),newDirection=90),520,480,2565,w_cap=40,s_cap=20,maxWidth=70,ialign=const.MIDDLE)
        DoubleJellyfishResonator(self,self.structures[1].cloneAlongLast((-200,640),newDirection=90),480,200,2565,w_ind=2,w_cap=40,s_cap=20,maxWidth=60,ialign=const.MIDDLE)
        
        #clone position for new structure
        s0 = m.Structure(self,start=self.structures[1].getLastPos((300,-40)),defaults={'w':20, 's':10, 'radius':100,'r_out':5,'r_ins':5})
        
        CPW_stub_short(self,1,s=10,r_out=2.5,curve_out=False)
        self.structure(1).shiftPos(40)
        CPW_stub_short(self,1,s=10,r_out=2.5,curve_ins=False,flipped=True)
        CPW_straight(self,1,200)
        
        DoubleJellyfishResonator(self,self.structures[1].cloneAlongLast((100,40),newDirection=90),520,80,2565,w_cap=40,s_cap=20,maxWidth=70,ialign=const.MIDDLE)
        
        CPW_bend(self,1,angle=20,radius=200)
        CPW_straight(self,1,200,10,5)
        CPW_wiggles(self,1,length=3750,maxWidth=270,CCW=False)
        CPW_straight(self,1,200)
        CPW_bend(self,1,angle=55,CCW=False,radius=200)
        CPW_wiggles(self,1,length=2350,maxWidth=370,CCW=False,stop_bend=False)
        CPW_wiggles(self,1,length=1205,maxWidth=170,CCW=False,stop_bend=False,start_bend=False)
        CPW_wiggles(self,1,length=2350,maxWidth=370,CCW=False,start_bend=False,stop_bend=False)
        CPW_straight(self,1,600)
        
        #s1 = m.Structure(self,start=self.structures[1].getLastPos((300,-50)),direction=self.structures[1].direction,defaults=self.defaults)
        s1 = self.structures[1].cloneAlongLast((300,-50))
        s2 = m.Structure(self,start=self.structures[1].getLastPos((300,-100)),direction=self.structures[1].direction,defaults=self.defaults)
        s3 = m.Structure(self,start=self.structures[1].getLastPos((300,-150)),direction=self.structures[1].direction,defaults=self.defaults)
        
        CPW_wiggles(self,1,length=1200,maxWidth=270,start_bend=False,stop_bend=False)
        CPW_wiggles(self,1,length=1200,maxWidth=270,radius=10,start_bend=False,stop_bend=True)
        CPW_straight(self,1,20,s=195)
        #CPW_straight(self,1,200)
        Inductor_wiggles(self,1,length=200,Width=200,nTurns=10,radius=20,start_bend=True,stop_bend=False,pad_to_width=True)
        #CPW_stub_open(self,1,r_out=0)
        
        CPW_launcher(self,2)
        
        
        #continue independent structure
        CPW_stub_open(self,s0,flipped=True,extra_straight_section=True,length=40)
        CPW_straight(self,s0,200)
        CPW_taper(self,s0,50,w1=self.structures[2].defaults['w'],s1=self.structures[2].defaults['s'])
        s0.defaults['w']=self.structures[2].defaults['w']
        s0.defaults['s']=self.structures[2].defaults['s']
        CPW_directTo(self,s0,self.structures[2],radius=200)
        
        #continue independent structure 2
        
        CPW_stub_open(self,s1,flipped=True,w=20,s=10)
        CPW_straight(self,s1,100,w=20,s=10)
        CPW_taper(self,s1,w0=20,s0=10)
        CPW_straight(self,s1,400)
        
        CPW_stub_open(self,s2,flipped=True,w=20,s=10)
        CPW_straight(self,s2,100,w=20,s=10)
        CPW_taper(self,s2,w0=20,s0=10)
        
        CPW_stub_open(self,s3,flipped=True,w=20,s=10)
        CPW_straight(self,s3,100,w=20,s=10)
        CPW_taper(self,s3,w0=20,s0=10)
        #CPW_bend(self,s3,30,radius=200)
        
        CPW_launcher(self,8,l_pad=360,l_gap=320,layer='MARKERS',r_ins=30,ptDensity=8)
        CPW_launcher(self,5)
        CPW_launcher(self,4)
        #>>>>>>>>>>> test directTo functions <<<<<<<<<<<<<<<
        
        CPW_directTo(self,s2,self.structures[5],radius=200)
        CPW_directTo(self,s3,self.structures[4],radius=200)
        
        #>>>>>>>>>>> test cpw_cap functions <<<<<<<<<<<<<<<
        
        CPW_cap(self, s1, 4)
        CPW_straight(self, s1, 6)
        CPW_taper_cap(self, s1, 2, 60, l_straight=25, l_taper=100)
        CPW_directTo(self,s1,self.structures[8],radius=200)
        
        #>>>>>>>>>>> test cpw_tee functions <<<<<<<<<<<<<<<
        
        s4=m.Structure(self,start=self.centered((-100,-2800)),direction=15,defaults={'w':10, 's':5, 'radius':50,'r_out':5})
        CPW_stub_open(self,s4,flipped=True,w=20,s=10)
        CPW_straight(self,s4,100,w=20,s=10)
        CPW_taper(self,s4,w0=20,s0=10)
        CPW_straight(self,s4,80)
        s4a,s4b = CPW_tee(self,s4,radius=3)#continue CPW off of each tee end
        CPW_straight(self,s4a,30)
        CPW_straight(self,s4b,50)
        
        s4.shiftPos(60)#flipped
        s4a,s4b =CPW_tee(self,s4,hflip=True)
        CPW_straight(self,s4,20)
        CPW_straight(self,s4a,30)
        CPW_straight(self,s4b,40)
        
        s4.shiftPos(40)#w different
        CPW_straight(self,s4,20)
        s4a,s4b = CPW_tee(self,s4,w1=20)
        CPW_straight(self,s4a,30) #branching structure defaults are automatically redefined
        CPW_taper(self,s4b,30,w1=10,s1=3)
        
        s4.shiftPos(60)#s1<s
        CPW_straight(self,s4,20)
        s4a,s4b = CPW_tee(self,s4,w1=4,s1=3)
        CPW_straight(self,s4a,30) #branching structure defaults are automatically redefined
        CPW_straight(self,s4b,20)
        
        s4.shiftPos(40)#s1>s
        CPW_straight(self,s4,20)
        s4a,s4b = CPW_tee(self,s4,w1=15,s1=15,r_ins=0)
        CPW_straight(self,s4a,30) #branching structure defaults are automatically redefined
        CPW_straight(self,s4b,20)
        
        s4.shiftPos(80)#flipped AND s1<s
        s4a,s4b = CPW_tee(self,s4,w1=4,s1=3,hflip=True,r_ins=20)
        CPW_straight(self,s4,20)
        CPW_straight(self,s4a,30) #branching structure defaults are automatically redefined
        CPW_straight(self,s4b,20)
        
        s4.shiftPos(60)#flipped AND s1>s
        s4a,s4b = CPW_tee(self,s4,w1=15,s1=15,hflip=True)
        CPW_straight(self,s4,20)
        CPW_straight(self,s4a,30) #branching structure defaults are automatically redefined
        CPW_straight(self,s4b,20)
        #test left oriented CPW tee
        s4a=CPW_tee(self,s4,branch_off=const.LEFT)
        CPW_straight(self,s4,30)
        CPW_straight(self,s4a,50) #continue off left branch
        CPW_straight(self,s4,30)
        
        s4b=CPW_tee(self,s4,branch_off=const.RIGHT)
        CPW_straight(self,s4b,50) #continue off right branch
        CPW_straight(self,s4,30)
        
        #>>>>>>>>>>> test junction pad functions <<<<<<<<<<<<<<<
        # slot functions
        s5=m.Structure(self,start=self.centered((100,2800)),direction=-15,defaults={'w':20, 's':10, 'radius':100,'r_out':1.5,'r_ins':1.5})
        self.add(dxf.rectangle(s5.getPos((0,0)),-100,13,valign=const.MIDDLE,rotation=s5.direction,bgcolor=w.bg()))
        self.add(dxf.rectangle(s5.getPos((8.5,6.5)),-100-8.5,50,rotation=s5.direction,bgcolor=w.bg()))
        self.add(dxf.rectangle(s5.getPos((8.5,-6.5)),-100-8.5,-50,rotation=s5.direction,bgcolor=w.bg()))
        JContact_slot(self,s5,gapl=1,tabl=2,tabw=2,taboffs=-0.5,hflip=True)
        s5.shiftPos(50)

        JContact_slot(self,s5,gapl=1,tabl=1,tabw=2,taboffs=1.5)
        self.add(dxf.rectangle(s5.getPos((0,0)),100,13,valign=const.MIDDLE,rotation=s5.direction,bgcolor=w.bg()))
        self.add(dxf.rectangle(s5.getPos((-9.5,6.5)),100+9.5,50,rotation=s5.direction,bgcolor=w.bg()))
        self.add(dxf.rectangle(s5.getPos((-9.5,-6.5)),100+9.5,-50,rotation=s5.direction,bgcolor=w.bg()))
        
        #works without structure as well
        JContact_slot(self,self.centered((100,2600)),gapl=1,tabl=1,tabw=2,taboffs=0,r_out=1.5,r_ins=1.5)
        self.add(dxf.rectangle(self.centered((109.5,2600)),20,13,valign=const.MIDDLE,bgcolor=w.bg()))
        
        # tab functons
        s6=m.Structure(self,start=self.centered((600,2800)),direction=-15,defaults={'w':20, 's':10, 'radius':100,'r_out':1.5,'r_ins':1.0})
        self.add(dxf.rectangle(s6.getPos((0,0)),-100,100,valign=const.MIDDLE,rotation=s5.direction,bgcolor=w.bg()))
        JContact_tab(self,s6,steml=1,tabw=2,taboffs=-0.5)
        s6.shiftPos(40)

        JContact_tab(self,s6,steml=1,tabl=1,tabw=2,taboffs=1.5,hflip=True)
        self.add(dxf.rectangle(s6.getPos((0,0)),100,100,valign=const.MIDDLE,rotation=s5.direction,bgcolor=w.bg()))
        
        #probe pad functions
        s7=m.Structure(self,start=self.centered((1200,2400)),direction=15,defaults={'w':20, 's':10, 'radius':100,'r_out':1.0,'r_ins':1.0})
        JSingleProbePad(self,s7,flipped=False)
        s7.shiftPos(40)
        JSingleProbePad(self,s7,flipped=True,padradius=0)
        
        #one function probe pads
        JProbePads(self, self.centered((1200,2000)), rotation=15)
        JProbePads(self, self.centered((1200,1600)),rotation=15,tab=True,tabShoulder=True)
        
        #>>>>>>>>>>> test manhattan junction functions <<<<<<<<<<<<<<<
        
        #setupManhattanJAngles(self.wafer,40,True)
        
        for i,ang in enumerate(range(0,140,20)):
            jpos =self.centered((2400,800+300*i))
            JProbePads(self, jpos,padwidth=100, padradius=15, rotation=ang)
            ManhattanJunction(self, jpos,rotation=ang,jpadTaper=6)
            self.add(dxf.text(str(ang)+'%%d',vadd(jpos,rotate_2d((-5,40),math.radians(ang))),height=8.0,layer=self.wafer.defaultLayer))
        for i,ang in enumerate(range(140,280,20)):
            jpos = self.centered((2800,800+300*i))
            JProbePads(self, jpos,padwidth=100,padradius=15, rotation=ang)
            ManhattanJunction(self, jpos,rotation=ang,jpadTaper=0)
            self.add(dxf.text(str(ang)+'%%d',vadd(jpos,rotate_2d((5,40),math.radians(ang))),height=8.0,layer=self.wafer.defaultLayer))
        for i,ang in enumerate(range(280,360,20)):
            jpos = self.centered((3200,800+300*i))
            JProbePads(self, jpos,padwidth=100,padradius=15, rotation=ang)
            ManhattanJunction(self, jpos,rotation=ang,jfingerex=-1,jfingerl=4,jpadTaper=6,ucdist=0)
            self.add(dxf.text(str(ang)+'%%d',vadd(jpos,rotate_2d((-5,40),math.radians(ang))),height=8.0,layer=self.wafer.defaultLayer))
        
        #>>>>>>>>>>> test qubit functions <<<<<<<<<<<<<<<
        CPW_launcher(self,0,l_taper=300,padw=280,pads=140)
        CPW_straight(self, 0, 20)
        CPW_bend(self, 0, CCW=False,radius=200)
        CPW_straight(self,0,1000)
        #CPW_bend(self,0,angle=20)
        Hamburgermon(self, 0,jfingerw=0.13)
        
        
        
        #>>>>>>>>>>> test solid pline functions <<<<<<<<<<<<<<<
        
        pline = SolidPline(self.centered((1000,500)),points = [(0,0)],color=2,bgcolor=2,rotation=30,flags=0)#1
        pline.add_vertices([(1000,0),(1000,500),(800,600),(0,600)])
        #don't need to close
        self.add(pline)
        
        pline = SolidPline(self.centered((300,-600)),points = [(300,-600)],bgcolor=w.bg(),rotation=-30,flags=0)#1
        pline.add_vertices([(300,0),(100,400),(0,-600)])
        #don't need to close
        self.add(pline)
        
        #>>>>>>>>>>> test roundRect functions <<<<<<<<<<<<<<<<<<
        self.add(dxf.line(self.centered((-10,2300)),self.centered((210,2300)),color=1))
        self.add(RoundRect(self.centered((0,2300)),200,130,radius=40,roundCorners=[1,1,0,1],rotation=15,valign=const.MIDDLE,bgcolor=w.bg()))
        self.add(RoundRect(self.centered((-10,2300)),200,130,radius=40,roundCorners=[1,1,0,1],rotation=15,hflip=True,valign=const.MIDDLE,bgcolor=w.bg()))
        self.add(RoundRect(self.centered((210,2300)),200,130,radius=40,roundCorners=[1,1,0,1],rotation=15,vflip=True,valign=const.MIDDLE,bgcolor=self.bg()))
        
        #demonstrate skewrect
        self.add(SkewRect(self.centered((-1600,-650)),100,80,(20,-30),10,bgcolor=w.bg(),valign=const.MIDDLE))
        self.add(dxf.rectangle(self.centered((-1600,-650)),100,80,color=1,valign=const.MIDDLE))
        self.add(dxf.line(self.centered((-1600 + 100,-650)),self.centered(( -1600 + 100 +20,-680)),color=2))
        
        #test alignment
        self.add(dxf.line(self.centered((-1600,-500)),self.centered((0,-500)),color=1))
        self.add(dxf.line(self.centered((-1200,-540)),self.centered((0,-540)),color=1))
        
        self.add(SkewRect(self.centered((-1200,-500)),100,80,(0,-40),20,valign=const.BOTTOM,edgeAlign=const.BOTTOM,bgcolor=w.bg()))
        self.add(SkewRect(self.centered((-1000,-500)),100,80,(0,-40),20,valign=const.TOP,edgeAlign=const.TOP,bgcolor=w.bg()))
        self.add(SkewRect(self.centered((-800,-500)),100,80,(0,-40),20,valign=const.MIDDLE,edgeAlign=const.MIDDLE,bgcolor=w.bg()))
        
        #test alignment and rotation
        self.add(dxf.line(self.centered((-1400,-800)),self.centered((0,-800)),color=1))
        self.add(dxf.line(self.centered((-1200,-840)),self.centered((0,-840)),color=1))
        
        self.add(SkewRect(self.centered((-1200,-800)),100,80,(0,-40),20,rotation=30,valign=const.BOTTOM,edgeAlign=const.BOTTOM,bgcolor=w.bg()))
        self.add(SkewRect(self.centered((-1000,-800)),100,80,(0,-40),20,rotation=30,valign=const.TOP,edgeAlign=const.TOP,bgcolor=w.bg()))
        self.add(SkewRect(self.centered((-800,-800)),100,80,(0,-40),20,rotation=30,valign=const.MIDDLE,edgeAlign=const.MIDDLE,bgcolor=w.bg()))
        
        #curverect testing
        self.add(dxf.line(self.centered((-2000,650)),self.centered((-100,650)),color=1))
        
        self.add(CurveRect(self.centered((-2400,650)),80,200,angle=140,rotation=30,bgcolor=2,valign=const.BOTTOM,hflip=True))
        
        self.add(CurveRect(self.centered((-1800,650)),30,60,angle=140,rotation=30,bgcolor=2,valign=const.BOTTOM))
        self.add(CurveRect(self.centered((-1800,650)),30,60,angle=140,rotation=30,bgcolor=3,hflip=True,valign=const.TOP))
        
        self.add(CurveRect(self.centered((-1600,650)),30,60,angle=140,rotation=30,valign=const.TOP,vflip=True))
        
        self.add(CurveRect(self.centered((-1400,650)),60,30,ralign=const.TOP,bgcolor=3))
        self.add(CurveRect(self.centered((-1400,650)),60,30,ralign=const.TOP,hflip=True,bgcolor=2))
        
        self.add(CurveRect(self.centered((-1200,650)),60,30,angle=200,valign=const.TOP,bgcolor=2))
        
        #cpw bend test
        self.add(CurveRect(self.centered((-1000,650)),30,90,angle=140,roffset=15,ralign=const.BOTTOM,rotation=30,vflip=True))
        self.add(CurveRect(self.centered((-1000,650)),30,90,angle=140,roffset=15,ralign=const.BOTTOM,rotation=30))
        self.add(CurveRect(self.centered((-1000,650)),30,90,angle=140,roffset=-15,ralign=const.TOP,valign=const.TOP,rotation=30,vflip=True))
        
        
        #inside corner test
        self.add(dxf.rectangle(self.centered((-500,0)),1000,100,valign=const.MIDDLE,halign=const.CENTER,bgcolor=w.bg()))
        self.add(dxf.rectangle(self.centered((-300,0)),800,100,valign=const.MIDDLE,halign=const.CENTER,rotation=50,bgcolor=w.bg()))
        self.add(dxf.rectangle(self.centered((-700,0)),800,100,valign=const.MIDDLE,halign=const.CENTER,rotation=90,bgcolor=w.bg()))
        
        self.add(InsideCurve(self.centered((-750,-50)),50,bgcolor=2))
        self.add(InsideCurve(self.centered((-650,-50)),50,bgcolor=2,hflip=True))
        self.add(InsideCurve(self.centered((-750,50)),50,bgcolor=2,vflip=True))
        self.add(InsideCurve(self.centered((-650,50)),50,bgcolor=2,hflip=True,vflip=True))
        
        x1 = 50/np.tan(np.radians(50))
        x2 = 50/np.sin(np.radians(50))
        self.add(InsideCurve(self.centered((-300 - x1 - x2,-50)),50,angle=50,bgcolor=2))
        self.add(InsideCurve(self.centered((-300 - x1 + x2,-50)),50,angle=130,bgcolor=2,hflip=True))
        self.add(InsideCurve(self.centered((-300 + x1 - x2,50)),50,angle=130,bgcolor=2,vflip=True))
        self.add(InsideCurve(self.centered((-300 + x1 + x2,50)),50,angle=50,bgcolor=2,hflip=True,vflip=True))
Пример #7
0
from maskLib.junctionLib import ManhattanJunction
from maskLib.resonatorLib import JellyfishResonator, DoubleJellyfishResonator

from maskLib.qubitLib import Hamburgermon

import numpy as np
from dxfwrite import DXFEngine as dxf
from dxfwrite import const
from dxfwrite.entities import *
from dxfwrite.vector2d import vadd

# ===============================================================================
# wafer setup
# ===============================================================================

w = m.Wafer('StructureTest01','DXF/',7000,7000,waferDiameter=m.waferDiameters['2in'],sawWidth=m.sawWidths['8A'],
                frame=1,solid=1,multiLayer=1)
# w.frame: draw frame layer?
# w.solid: draw things solid?
# w.multiLayer: draw in multiple layers?

w.SetupLayers([
    ['BASEMETAL',4],
    ])

setupJunctionLayers(w)

#initialize the wafer
w.init()

#do dicing border
w.DicingBorder()
Пример #8
0
    def __init__(self,
                 wafer,
                 chipID,
                 layer,
                 jfingerw=0.0,
                 padwidth=150,
                 padradius=5,
                 **kwargs):
        m.Chip7mm.__init__(self,
                           wafer,
                           chipID,
                           layer,
                           defaults={
                               'w': 11,
                               's': 5,
                               'radius': 180,
                               'r_out': 5,
                               'r_ins': 5
                           })
        #do local p80 ebeam markers
        doMirrored(MarkerSquare,
                   self, (3250, 3250),
                   80,
                   layer='EMARKER',
                   chipCentered=True)

        for s in self.structures:
            s.shiftPos(340)
        '''
        #by default the corner structures are angled to match the pads
        self.structures[4].shiftPos(0,angle=-45)
        #make a reference to structure #4 so we don't confuse it for a variable
        s4 = self.structures[4]
        '''

        #this code is copied closely from Jeronimo's file
        s4 = m.Structure(self, self.chipSpace((5883, 1000)), direction=90)

        CPW_launcher(self,
                     s4,
                     l_taper=400,
                     padw=234,
                     pads=100,
                     l_pad=400,
                     l_gap=434)
        CPW_straight(self, s4, 429)
        CPW_taper(self, s4, 10, w0=11, s0=5, w1=11, s1=10.625)
        CPW_taper(self, s4, 30, 11, 10.625, 44.75, 10.625)
        CPW_taper(self, s4, 10, 44.75, 10.625, 60, 3)
        CPW_straight(self, s4, 2790, w=60, s=3)
        CPW_bend(self, s4, CCW=False, w=60, s=3)
        CPW_straight(self, s4, 200, w=60, s=3)
        CPW_bend(self, s4, CCW=False, w=60, s=3)
        CPW_straight(self, s4, 1934.5, 60, 3)
        CPW_taper(self, s4, 40, w0=60, s0=3, w1=3, s1=47)
        CPW_straight(self, s4, 2300, 3, 47)
        CPW_bend(self, s4, w=3, s=47)
        CPW_straight(self, s4, 200, 3, 47)
        CPW_bend(self, s4, w=3, s=47)
        CPW_straight(self, s4, 4000, 3, 47)
        CPW_bend(self, s4, CCW=False, w=3, s=47)
        CPW_straight(self, s4, 200, 3, 47)
        CPW_bend(self, s4, CCW=False, w=3, s=47)
        CPW_straight(self, s4, 169, 3, 47)
        CPW_taper(self, s4, 39.884, 3, 47, 60, 3)
        CPW_straight(self, s4, 3800, 60, 3)
        CPW_bend(self, s4, w=60, s=3)
        CPW_straight(self, s4, 200, w=60, s=3)
        CPW_bend(self, s4, w=60, s=3)
        CPW_straight(self, s4, 934.5, 60, 3)
        CPW_taper(self, s4, 40, 60, 3, 3, 47)
        CPW_straight(self, s4, 3300, 3, 47)
        CPW_bend(self, s4, CCW=False, w=3, s=47)
        CPW_straight(self, s4, 200, 3, 47)
        CPW_bend(self, s4, CCW=False, w=3, s=47)
        CPW_straight(self, s4, 3934.5, 3, 47)
        CPW_taper(self, s4, 50.15, 3, 47, 11, 5)
        CPW_bend(self, s4, angle=180, w=11, s=5, radius=210.5)
        CPW_straight(self, s4, 361.77, 11, 5)
        CPW_taper(self, s4, 100, 11, 5, 59, 26.818)  #capacitor
        CPW_straight(self, s4, 25, 59, 26.818)  #capacitor
        Strip_straight(self, s4, 5, 2 * 56.318)  #capacitor
        CPW_straight(self, s4, 25, 59, 26.818)  #capacitor
        CPW_taper(self, s4, 100, 59, 26.818, 11, 5)
        CPW_straight(self, s4, 1514 + 114.2, 11, 5)
        CPW_bend(self, s4, angle=180, CCW=False, w=11, s=5, radius=210.5)
        CPW_straight(self, s4, 2175.01, 11, 5)
        CPW_bend(self, s4, angle=180, w=11, s=5, radius=210.5)
        CPW_straight(self, s4, 3098, 11, 5)

        Hamburgermon(self,
                     s4,
                     qbunthick=120,
                     qbunr=59.9,
                     qccap_padl=170,
                     qccapl=120,
                     jfingerw=jfingerw,
                     **kwargs)

        #this is for the test junctions on the left

        #cutout
        self.add(
            RoundRect(self.chipSpace((650, 2375)),
                      670,
                      2275 + 300,
                      1,
                      valign=const.MIDDLE)
        )  #note we are purposefully not setting the bgcolor
        #contact pads
        for y in range(5):
            for x in range(2):
                JProbePads(self,
                           self.chipSpace(
                               (830 + 300 * x, 3180 + 170 - 500 * y)),
                           rotation=90,
                           padwidth=padwidth,
                           padradius=padradius,
                           layer=self.wafer.XLAYER,
                           **kwargs)
                ManhattanJunction(self,
                                  self.chipSpace(
                                      (830 + 300 * x, 3180 + 170 - 500 * y)),
                                  rotation=90,
                                  jfingerw=jfingerw,
                                  **kwargs)
Пример #9
0
from maskLib.utilities import doMirrored
from maskLib.markerLib import MarkerSquare
from maskLib.Entities import RoundRect

from maskLib.junctionLib import setupJunctionLayers, JProbePads, ManhattanJunction
from maskLib.qubitLib import Hamburgermon

# ===============================================================================
# wafer setup
# ===============================================================================

w = m.Wafer('ReflectionQubitExample',
            'DXF/',
            7000,
            7000,
            waferDiameter=m.waferDiameters['2in'],
            sawWidth=m.sawWidths['8A'],
            frame=1,
            solid=0,
            multiLayer=1)
# w.frame: draw frame layer?
# w.solid: draw things solid?
# w.multiLayer: draw in multiple layers?

#[string layername,int color]
w.SetupLayers([['BASEMETAL', 4], ['EMARKER', 3]])

setupJunctionLayers(w)

#initialize the wafer
w.init()
Пример #10
0
from maskLib.junctionLib import ManhattanJunction
from maskLib.qubitLib import Transmon3D, qubit_defaults

from maskLib.markerLib import MarkerSquare, MarkerCross
from maskLib.utilities import doMirrored

# ===============================================================================
# wafer setup
# ===============================================================================

w = m.Wafer(
    '3DMultimodeExample',
    'DXF/',
    23000,
    2000,
    padding=2500,
    waferDiameter=m.waferDiameters['2in'],
    sawWidth=200,  #sawWidth=m.sawWidths['8A'],
    frame=1,
    solid=0,
    multiLayer=1,
    singleChipColumn=True)
#set wafer properties
# w.frame: draw frame layer?
# w.solid: draw things solid?
# w.multiLayer: draw in multiple layers?
# w.singleChipColumn: only make one column of chips?

w.SetupLayers([['BASEMETAL', 4], ['DICEBORDER', 5], ['MARKERS', 3]])

#setup junction layers
setupJunctionLayers(w)
Пример #11
0
def DoubleSpiral(dwg,
                 xy,
                 w,
                 s,
                 width,
                 turns,
                 UD,
                 line_color,
                 r_ins=0,
                 LR=1,
                 curve_pts=30):
    #set up close packed width + height
    height = GetDoubleSpiralHeight(w, s, turns)
    width = max(width, height + w + s)
    #do number of selected loops
    for n in range(turns):
        Spiral_Link_Rounded(dwg, (xy[0] + LR * (n * 2 * (w + s)), xy[1]),
                            w,
                            s,
                            width - 4 * n * (w + s),
                            height - 4 * n * (w + s),
                            UD,
                            line_color,
                            r_ins=r_ins,
                            LR=LR,
                            curve_pts=curve_pts)  #outer spiral
    for n in range(turns - 1):
        Spiral_Link_Rounded(dwg,
                            (xy[0] + LR * (w + s + n * 2 * (w + s)), xy[1]),
                            w,
                            s,
                            width - 4 * n * (w + s) - 2 * w - 2 * s,
                            height - 4 * n * (w + s) - 2 * w - 2 * s,
                            UD,
                            line_color,
                            r_ins=r_ins,
                            LR=LR)  #inner spiral

    #UD = 1 if gap on top, -1 if gap on bottom
    q = m.transformedQuadrants(UD=UD, LR=LR)
    #recenter
    xy = (xy[0] + LR * (w + s + (turns - 1) * 2 * (w + s)),
          xy[1] - UD * (w + s / 2))
    #draw
    pline = dxf.polyline(points=[(xy[0], xy[1])], color=line_color,
                         flags=0)  #start offset by w/2
    pline.add_vertices(
        m.corner((xy[0], xy[1] + UD * (2 * w + s)), q[2], 1 * UD * LR, w / 3,
                 curve_pts))
    pline.add_vertices(
        m.corner((xy[0] + LR * (width - 2 * (2 * turns - 1) *
                                (w + s)), xy[1] + UD * (2 * w + s)), q[1],
                 1 * UD * LR, w / 3, curve_pts))
    pline.add_vertices(
        m.corner((xy[0] + LR * (width - 2 * (2 * turns - 1) * (w + s)), xy[1]),
                 q[4], 1 * UD * LR, w / 3, curve_pts))
    pline.add_vertices([(xy[0] + LR * (w + s), xy[1])])
    pline.add_vertices(
        m.corner((xy[0] + LR * (w + s), xy[1] + UD * w), q[2], 1 * UD * LR,
                 w / 3, curve_pts))
    pline.add_vertices([
        (xy[0] + LR * (width - 2 * (2 * turns - 1) * (w + s) - w),
         xy[1] + UD * w),
        (xy[0] + LR * (width - 2 * (2 * turns - 1) * (w + s) - w),
         xy[1] + UD * (w + s)), (xy[0] + LR * w, xy[1] + UD * (w + s)),
        (xy[0] + LR * w, xy[1])
    ])
    pline.close()

    dwg.add(pline)
Пример #12
0
def Paperclip_Rounded(dwg,
                      xy,
                      w,
                      s,
                      L_res,
                      gap,
                      r_ins,
                      UD,
                      line_color,
                      curve_pts=30):
    #UD = 1 if gap on top, -1 if gap on bottom
    RL = 1
    q = m.transformedQuadrants(UD=UD)
    #draw
    pline = dxf.polyline(points=[(xy[0], xy[1])], color=line_color)
    pline.add_vertices(r_ins > 0 and m.corner(
        (xy[0] - RL * s / 2, xy[1]), q[2], -1 * UD, r_ins, curve_pts // 2)
                       or [(xy[0] - RL * s / 2, xy[1])])
    pline.add_vertices(r_ins > 0 and m.corner(
        (xy[0] - RL * s / 2, xy[1] - UD * L_res), q[3], -1 * UD, r_ins,
        curve_pts // 2) or [(xy[0] - RL * s / 2, xy[1] - UD * L_res)])
    pline.add_vertices(r_ins > 0 and m.corner(
        (xy[0] + RL * s / 2, xy[1] - UD * L_res), q[4], -1 * UD, r_ins,
        curve_pts // 2) or [(xy[0] + RL * s / 2, xy[1] - UD * L_res)])
    pline.add_vertices(
        m.corner((xy[0] + RL * s / 2, xy[1] - UD * gap), q[2], 1 * UD, w / 3,
                 curve_pts))
    pline.add_vertices(
        m.corner((xy[0] + RL * (s / 2 + w), xy[1] - UD * gap), q[1], 1 * UD,
                 w / 3, curve_pts))
    pline.add_vertices(
        m.corner((xy[0] + RL * (s / 2 + w), xy[1] - UD * (L_res + w)), q[4],
                 1 * UD, w, curve_pts))
    pline.add_vertices(
        m.corner((xy[0] - RL * (s / 2 + w), xy[1] - UD * (L_res + w)), q[3],
                 1 * UD, w, curve_pts))
    pline.add_vertices(
        m.corner((xy[0] - RL * (s / 2 + w), xy[1] + UD * w), q[2], 1 * UD, w,
                 curve_pts))
    pline.add_vertices(
        m.corner((xy[0] + RL * (s / 2 + w), xy[1] + UD * w), q[1], 1 * UD,
                 w / 3, curve_pts))
    pline.add_vertices(
        m.corner((xy[0] + RL * (s / 2 + w), xy[1]), q[4], 1 * UD, w / 3,
                 curve_pts))

    pline.close()

    dwg.add(pline)
Пример #13
0
def CPS_Rounded(dwg,
                xy,
                w,
                s,
                L_res,
                L_rabbit,
                r_ins,
                RL,
                line_color,
                half=False,
                curve_pts=30,
                w_rabbit=None):

    if w_rabbit is None:
        w_rabbit = w
    #print(half)
    #RL = 1 if right, -1 if left

    q = m.transformedQuadrants(LR=RL)
    #draw a cps resonator, dipole origin centered on (x,y) facing right
    pline = dxf.polyline(points=[(xy[0] + L_res * RL, xy[1])],
                         color=line_color,
                         flags=0)  #1
    pline.add_vertices(r_ins > 0 and m.corner(
        (xy[0] + L_res * RL, xy[1] + s / 2), q[1], -1 * RL, r_ins,
        curve_pts // 2) or [(xy[0] + L_res * RL, xy[1] + s / 2)])  #2
    if L_rabbit >= w / 3:  #draw top antenna
        pline.add_vertices(
            half and [(xy[0] + RL * w_rabbit / 2, xy[1] + s / 2)] or m.corner(
                (xy[0], xy[1] + s / 2), q[3], 1 * RL, w_rabbit, curve_pts))  #3
        pline.add_vertices(half and [
            (xy[0] + RL * w_rabbit / 2, xy[1] + s / 2 + w_rabbit + L_rabbit)
        ] or m.corner((xy[0], xy[1] + s / 2 + w_rabbit + L_rabbit), q[2],
                      1 * RL, w_rabbit / 3, curve_pts))  #4
        pline.add_vertices(
            m.corner(
                (xy[0] + w_rabbit * RL, xy[1] + s / 2 + w_rabbit + L_rabbit),
                q[1], 1 * RL, w_rabbit / 3, curve_pts))  #5
        pline.add_vertices(r_ins > 0 and m.corner(
            (xy[0] + w_rabbit, xy[1] + s / 2 + w), q[3], -1 * RL, r_ins,
            curve_pts // 2)
                           or [(xy[0] + w_rabbit * RL, xy[1] + s / 2 + w)])  #6
    else:  #top stub only
        pline.add_vertices(
            half and [(xy[0] + RL * w / 2, xy[1] + s / 2)] or m.corner(
                (xy[0], xy[1] + s / 2), q[3], 1 * RL, w / 3, curve_pts))  #3
        pline.add_vertices(half and [(xy[0] + RL * w / 2, xy[1] + s / 2 + w)]
                           or m.corner((xy[0], xy[1] + s / 2 + w), q[2],
                                       1 * RL, w / 3, curve_pts))  #4
    pline.add_vertices(
        m.corner((xy[0] + (L_res + w) * RL, xy[1] + s / 2 + w), q[1], 1 * RL,
                 w, curve_pts))  #7
    pline.add_vertices(
        m.corner((xy[0] + (L_res + w) * RL, xy[1] - s / 2 - w), q[4], 1 * RL,
                 w, curve_pts))  #8
    if L_rabbit >= w / 3:  #draw bottom antenna
        pline.add_vertices(r_ins > 0 and m.corner(
            (xy[0] + w_rabbit * RL, xy[1] - s / 2 - w), q[2], -1 * RL, r_ins,
            curve_pts // 2)
                           or [(xy[0] + w_rabbit * RL, xy[1] - s / 2 - w)])  #9
        pline.add_vertices(
            m.corner(
                (xy[0] + w_rabbit * RL, xy[1] - s / 2 - w_rabbit - L_rabbit),
                q[4], 1 * RL, w_rabbit / 3, curve_pts))  #10
        pline.add_vertices(half and [
            (xy[0] + RL * w_rabbit / 2, xy[1] - s / 2 - w_rabbit - L_rabbit)
        ] or m.corner((xy[0], xy[1] - s / 2 - w_rabbit - L_rabbit), q[3],
                      1 * RL, w_rabbit / 3, curve_pts))  #11
        pline.add_vertices(
            half and [(xy[0] + RL * w_rabbit / 2, xy[1] - s / 2)] or m.corner(
                (xy[0], xy[1] - s / 2), q[2], 1 * RL, w_rabbit,
                curve_pts))  #12
    else:  #bottom stub only
        pline.add_vertices(half and [(xy[0] + RL * w / 2, xy[1] - s / 2 - w)]
                           or m.corner((xy[0], xy[1] - s / 2 - w), q[3],
                                       1 * RL, w / 3, curve_pts))  #11
        pline.add_vertices(
            half and [(xy[0] + RL * w / 2, xy[1] - s / 2)] or m.corner(
                (xy[0], xy[1] - s / 2), q[2], 1 * RL, w / 3, curve_pts))  #12
    pline.add_vertices(r_ins > 0 and m.corner(
        (xy[0] + L_res * RL, xy[1] - s / 2), q[4], -1 * RL, r_ins,
        curve_pts // 2) or [(xy[0] + L_res * RL, xy[1] - s / 2)])  #13
    pline.close()
    dwg.add(pline)
Пример #14
0
    def __init__(self,
                 wafer,
                 chipID,
                 layer,
                 left=False,
                 right=False,
                 defaults=None,
                 structures=None,
                 l_waveguide=870,
                 h_waveguide=1270,
                 r_waveguide=400,
                 slot_width=2270,
                 slot_height=2110,
                 r_slot=400,
                 **kwargs):
        m.Chip.__init__(self, wafer, chipID, layer)
        self.defaults = {'s': 80, 'radius': 25, 'r_out': 0, 'r_ins': 0}
        if defaults is not None:
            #self.defaults = defaults.copy()
            for d in defaults:
                self.defaults[d] = defaults[d]
        if structures is not None:
            #override default structures
            self.structures = structures
        else:
            self.structures = [  #hardwired structures
                m.Structure(self,
                            start=(0, self.height / 2),
                            direction=0,
                            defaults=self.defaults),
                m.Structure(self,
                            start=(self.width, self.height / 2),
                            direction=180,
                            defaults=self.defaults)
            ]
        if wafer.frame:
            self.add(
                RoundRect(self.centered((-self.width / 2, 0)),
                          l_waveguide,
                          h_waveguide,
                          r_waveguide,
                          roundCorners=[0, 1, 1, 0],
                          valign=const.MIDDLE,
                          layer=wafer.lyr('FRAME')))
            self.add(
                RoundRect(self.centered((self.width / 2, 0)),
                          l_waveguide,
                          h_waveguide,
                          r_waveguide,
                          roundCorners=[1, 0, 0, 1],
                          halign=const.RIGHT,
                          valign=const.MIDDLE,
                          layer=wafer.lyr('FRAME')))
            self.add(
                RoundRect(self.center,
                          slot_width,
                          slot_height,
                          r_slot,
                          halign=const.CENTER,
                          valign=const.MIDDLE,
                          layer=wafer.lyr('FRAME')))

        if left:
            Slot_vivaldi_taper(self, 0, **kwargs)
        if right:
            Slot_vivaldi_taper(self, 1, **kwargs)