Esempio n. 1
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 def offset_curve(self, amount, quality=None):
     """ +ve dilation
         -ve erosion """
     if amount == 0.0:
         return self.copy()
     elif amount > 0.0:
         return self.minkowski_sum(shape.circle(amount*2.0, quality).shape_2())
     else:
         return self.erosion(shape.circle(amount*-2.0, quality).shape_2())    
Esempio n. 2
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 def offset_curve(self, amount, quality=None):
     """ +ve dilation
         -ve erosion """
     if amount == 0.0:
         return self.copy()
     elif amount > 0.0:
         return self.minkowski_sum(
             shape.circle(amount * 2.0, quality).shape_2())
     else:
         return self.erosion(shape.circle(amount * -2.0, quality).shape_2())
Esempio n. 3
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def draw_house():
    arena.clear("blue", show=False) #sky
    # Note the order of drawing! (Some shapes overlap)
    shape.plot(shape.rectangle(24,15,72,15,72,7,24,7), colour="orange") #main house
    shape.plot(shape.rectangle(20,7,24,3,72,3,76,7), colour="red") #roof
    shape.plot(shape.rectangle(58,15,58,10,64,10,64,15), colour="magenta") #door
    arena.set_pixel(63,12,"red") #doorknob
    shape.plot(shape.rectangle(32,9,44,9,44,12,32,12), colour="cyan") #window
    shape.plot(shape.rectangle(98,11,100,11,100,15,98,15), colour="magenta") #tree trunk
    shape.plot(shape.circle(99,6,5), colour="green") #tree foliage
    shape.plot(shape.circle(122,3,2), colour="yellow") #sun
    shape.plot(shape.line(0,15,127,15), colour="green") #grass
    arena.render()
Esempio n. 4
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    def render(self, bit_diameter, bit_pad):
        xsize = self.xsize
        ysize = self.ysize
        
        a = bit_pad
        b = bit_pad + self.zsize/10.0
        pad_cone = shape.extrude_profile(profile.Profile([0,self.zsize],[a*2,b*2],[a*2,b*2]), cross_section=lambda d: shape.circle(d,16))
        pad_cylinder = shape.extrude_profile(profile.Profile([0,self.zsize+bit_diameter],[a*2,a*2],[a*2,a*2]), cross_section=lambda d: shape.circle(d,16))
        
        pad = 0.5 + self.zsize/10.0
        
        upper = shape.block(-pad,xsize+pad,-pad,ysize+pad,0,self.zsize)
        
        print 'Cut holes'

        for i,(x,y,packable) in enumerate(self.items):
            if packable.use_upper:
                flat = packable.mask.to_3()
                flat.move(x,y,0)
                minsum = flat.minkowski_sum(pad_cone)
                upper.remove( minsum )

        print 'Put things in them'

        for x,y,packable in self.items:
            if packable.use_upper:
                temp = packable.shapes[0].copy()
                temp.move(x,y,0)
                upper.add(temp)
            
        bol = int(self.xsize / 10.0)
        bol_width = 1.0
            # 0.5 seemed to allow shifting on a sop flute
        bol_height = 1.0 
            # 0.5 was too low, middle piece tore loose in final pass of
            # contour finishing (x-scan of horizontal-like surfaces)
        xmins = [ x for x,y,packable in self.items ]
        xmaxs = [ x+packable.extent.xmax for x,y,packable in self.items ]
        margin = bol_width+bit_diameter+0.25
        
        potential_bols = [ ((i+0.5)*xsize/bol, 0,ysize) for i in xrange(bol) ]
        bols = [ ]
        while potential_bols:
            pos, y_low, y_high = potential_bols.pop()
            for i, (x,y,packable) in enumerate(self.items):
                if pos-margin <= xmins[i] <= pos+margin or \
                   pos-margin <= xmaxs[i] <= pos+margin:
                   low = y-bit_diameter
                   high = y+packable.extent.ymax+bit_diameter
                   if low <= y_low and y_high <= high:
                       break
                   elif y_low < low and high < y_high:
                       potential_bols.append((pos, y_low, low))
                       potential_bols.append((pos, high, y_high))
                       break
                   elif y_low < low < y_high <= high:
                       potential_bols.append((pos, y_low, low))
                       break
                   elif low < y_low < high <= y_high:
                       potential_bols.append((pos, high, y_high))
                       break
            else:
                bols.append((pos,y_low,y_high))
                
        for pos, y_low, y_high in bols:    
            upper.add(shape.block(
                pos-bol_width*0.5, pos+bol_width*0.5,
                y_low, y_high,
                #0,ysize,
                #-bit_diameter*0.6, bol_height,
                0,bol_height,
            ))     
        
        
        print 'Underside'
        
        # Cut the bottom of upper with lower, to depth    bit_diameter
        lower = shape.block(-pad,xsize+pad,-pad,ysize+pad,bit_diameter,self.zsize)
        lower.add(upper)
        
        print 'Remove bores'

        for x,y,packable in self.items:
            temp = packable.shapes[1].copy()
            temp.move(x,y,0)

            flat = packable.mask.to_3()
            flat.move(x,y,0)
            minsum = flat.minkowski_sum(pad_cylinder)
            temp.clip(minsum)

            lower.remove(temp)
        
        lower.rotate(0,1,0, 180)
        
        return lower, upper
Esempio n. 5
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    def run(self):
        zsize = self.thickness
        
        pad = self.wall
        diameter = zsize - pad*2
        
        self.log.log('Thickness: %.1fmm\n' % zsize)
        self.log.log('Min wall thickness: %.1fmm\n' % pad)
        self.log.log('Hole diameter: %.1fmm\n' % diameter)
        
        negatives = [ ]
        lengths = [ ]
        xs = [ ]
        for i, note in enumerate(SCALE):
            print 'Make hole %d / %d' % (i+1,len(SCALE))
            length = design.wavelength(note,self.transpose)*0.25 + LENGTH_CORRECTION*diameter
            x = i*(diameter+pad)
            lengths.append(length)
            xs.append(x)
            hole = make_hole(diameter, length)
            hole.move(x,0,0)
            negatives.append(hole)
        
        string_hole_diameter = diameter*1.5
        string_hole_loop = shape.circle(string_hole_diameter)
        string_hole = shape.extrusion([-zsize,zsize],[string_hole_loop,string_hole_loop])
        string_hole.rotate(1,0,0, 90)
        
        xlow = xs[0]-zsize
        #xmid = xs[-1]*0.5
        xhigh = xs[-1]+zsize
        
        zhigh = lengths[0]+zsize*0.5
        #zmid  = max(lengths[-1]+zsize*0.5, zhigh-(xhigh-xmid))
        
        trim = min(xhigh-xlow,zhigh) * 0.5
        
        #string_x = (xmid+xhigh)*0.5 - diameter
        #string_z = (zmid+zhigh)*0.5 - diameter
        #string_z = lengths[3] + diameter*2
        #string_x = xhigh-trim*0.5-diameter
        #string_z = zhigh-trim*0.5-diameter
        
        a = math.pi*-5/8
        d = diameter * 1.5
        string_x = xhigh-trim + math.cos(a)*d
        string_z = zhigh      + math.sin(a)*d
        
        string_hole.move(string_x,0,string_z)
        
        #p = pad*0.5
        #loop = shape.Loop([(0,p),(p*2,-p),(-p*2,p)])
        #r = diameter-pad
        #stick = shape.extrusion([-r,r],[loop,loop])
        #
        #for i in xrange(-1,len(SCALE)+2):
        #    for j in xrange(int(zhigh / (diameter+pad))+1):
        #        x = (i-0.5)*(diameter+pad)
        #        z = r + j*(diameter+pad)
        #        c = stick.copy()
        #        if (i^j)&1:
        #            c.rotate(0,1,0,90)
        #        c.move(x,-diameter*0.5-pad,z)
        #        negatives.append(c)
        
        loop = shape.Loop([
            (xlow,0),
            (xhigh,0),
            (xhigh,zhigh-trim),
            (xhigh-trim,zhigh),
            (xlow,zhigh)
        ])

        bev = zsize / 4.0
        loop_bevel = shape.Loop([
            (xlow,bev),
            (xhigh,bev),
            (xhigh,zhigh-trim),
            (xhigh-trim,zhigh),
            (xlow,zhigh)
        ])
        
        #mask = loop.mask(RES)
        
        #amount = diameter * 0.5
        #op = shape.circle(amount).mask(RES)
        #mask = mask.open(op)
        
        #loop = mask.trace(RES)[0]
        
        #sloop = mask.erode(op).trace(RES)[0]
        
        #z1 = zsize*0.5-amount
        z2 = zsize*0.5
        
        #positive = shape.extrusion([-z2,z2],[loop,loop])
        positive = shape.extrusion([-z2,-z2+bev,z2-bev,z2],[loop_bevel,loop,loop,loop_bevel])
        positive.rotate(1,0,0,90)
        
        negative = string_hole.copy()
        for i, item in enumerate(negatives):
            print 'Merge %d / %d' % (i+1,len(negatives))
            negative.add(item)
        
        del negatives
        
        instrument = positive.copy()
        
        print 'Remove holes from instrument'
        instrument.remove(negative)
        
        del positive
        del negative
        
        instrument.rotate(1,0,0,90)
        extent = instrument.extent()

        copy = instrument.copy()
        copy.rotate(0,0,1,-45)
        cextent = copy.extent()
        copy.move(-(cextent.xmin+cextent.xmax)*0.5,
                  -(cextent.ymin+cextent.ymax)*0.5,
                  -cextent.zmin)
        self.save(copy,'instrument')
        del copy
        
        top = shape.block(
            extent.xmin-1,extent.xmax+1,
            extent.ymin-1,extent.ymax+1,
            0,extent.zmax+1
        )
        bottom = shape.block(
            extent.xmin-1,extent.xmax+1,
            extent.ymin-1,extent.ymax+1,
            extent.zmin-1,0
        )
        
        top.clip(instrument)
        bottom.clip(instrument)
        top.rotate(1,0,0,180)
        top.move(0,4,0)
        bottom.add(top)
        pattern = bottom
        
        del top
        del bottom
        
        pattern.move(0,0,z2)
        pattern.rotate(0,0,1, -90)

        bit_pad = 4.0
        extra_depth = 3.0
        a = bit_pad
        b = bit_pad + z2/10.0
        pad_cone = shape.extrude_profile(profile.Profile(
                [-extra_depth,0,z2],[a*2,a*2,b*2]
            ), 
            cross_section=lambda d: shape.circle(d,16))
        
        extra = b + 0.5
        
        extent = pattern.extent()
        mill = shape.block(
            extent.xmin-extra, extent.xmax+extra,
            extent.ymin-extra, extent.ymax+extra,
            -extra_depth, z2,
        )
        
        mill.remove( pattern.polygon_mask().to_3().minkowski_sum(pad_cone) )
        mill.add( pattern )
        
        del pad_cone
        del pattern
        
        self.save(mill, 'mill')
Esempio n. 6
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def nanowire_binary(number,
                    width,
                    pitch,
                    length,
                    n,
                    m,
                    is_interrupt,
                    device_shape,
                    pals_length,
                    itr,
                    elec_width,
                    pin_length=60):
    """
    用于绘制任意大小,并联根数的纳米线版图,python版本:2.7.14,3.3,只画方形器件
    长度单位:μm
    width 单根纳米线宽度
    length 纳米线长度,同时是纳米线区域的半径  
    pitch 纳米线周期宽度
    itr 计数纳米线根数
    n:并联纳米线根数
    m:二级并联根数
    pals_length:二级并联长度
    elec_width MA6光刻电极宽度
    """
    length = float(length)
    width = float(width)
    pitch = float(pitch)
    n = int(n)
    is_interrupt = int(is_interrupt)
    device_shape = int(device_shape)
    pals_length = float(pals_length)
    elec_width = int(elec_width)
    pin_length = float(pin_length)

    minedge = 10
    maxdiameter = length + 2 * minedge  #外围结构为5um,设置纳米线电子束曝光尺寸大小
    Cellname = "nanowire" + str(itr)
    single_cell = gdspy.Cell(Cellname, exclude_from_current=True)
    mark = itr
    #gdspy.GdsLibrary.add(single_cell,overwrite_duplication = True)

    if is_interrupt == 1 and pals_length < pitch - width:
        print("并联长度过小")
        return single_cell
    if length + minedge > maxdiameter:
        print("纳米线长度设置应小于等于50μm")
        return single_cell  #返回空的cell
    if is_interrupt == 1 and pals_length > length:
        print("纳米线并联长度应小于直径")
        return single_cell  #返回空的cell

    total = int(length / pitch)
    """
    #根据并联纳米线根数和纳米线间距来微调纳米线直径
    """
    if n < 1 or m < 1:
        print("纳米线小于1,n应该>=1")
        return single_cell
    elif type(n) == float:
        print('纳米线并联数应为>=1的整数')
        return single_cell
    unnece = total % (n * m)  #多余的纳米线根数
    itr = int(total / n / m)  #纳米线周期
    if unnece > int(n / 2):
        total = (itr + 1) * n * m
    else:
        total = itr * n * m

    a = (elec_width - length) / pin_length / 2
    if a - int(a) > 0.8:
        a = int(a) + 2
    else:
        a = int(a) + 1

    oldl = length
    length = total * pitch
    print("对纳米线" + Cellname +
          "长度进行了微调:原始值{},微调后值{},".format(oldl, total * pitch))
    #   length = total*pitch
    #    total1 = total
    half = total / 2
    """
    绘制纳米线核心区域
    两步绘制:
    计算调整圆的直径,确定圆的刻蚀线终点
    1 绘制中心圆区域
    2,绘制隔离线
    """
    #步骤一1
    if device_shape == 0:
        edge = shape.circle(pitch * total, width, pitch, total, half)
#        iso = shape.circleiso(length,width,n)
#        equ_area = shape.circle_equ(length,maxdiameter,width,pitch,total,half)
    elif device_shape == 1:
        edge = shape.squire(pitch * total, width, pitch, total, half)


#        iso = shape.squireiso(length,width,n)
#        equ_area = shape.squire_equ(length,maxdiameter,width,pitch,total,half)
#    single_cell.add(iso[0])
#    single_cell.add(iso[1])
#
#    #绘制外围等效曝光区
#    for i in equ_area:
#        for j in i:
#            single_cell.add(gdspy.Rectangle(*j,layer = 1,datatype = 1))
#

#纳米线核心区域点阵
    startpoint = edge[0]
    finalpoint = edge[1]

    i = 0
    location = numpy.linspace(0, total, int(total / n) + 1)  #二级并联线位置
    location1 = numpy.linspace(0, total, int(total / n / m) + 1)  #隔离线位置
    j = 1.0  #direction
    max_length = 0
    m1 = m
    while i < len(startpoint) - n * 2:  #调整并联单元长度相等
        m = 0
        while m < n and i < len(startpoint):
            if i == 0:  #保证0点的线存在
                startpoint[i] = (startpoint[i - m + 1][0], startpoint[i][1])
                finalpoint[i] = (finalpoint[i - m + 1][0], finalpoint[i][1])
            startpoint[i] = (startpoint[i - m][0], startpoint[i][1])
            finalpoint[i] = (finalpoint[i - m][0], finalpoint[i][1])
            m = m + 1
            i = i + 1
    i = 0
    while i < len(startpoint):  #计算最大圆直径
        if is_interrupt == 1 and n > 1:
            step = pals_length  #
            single_length = abs(finalpoint[i][0] - startpoint[i][0])
            if (int(single_length / step) + 1) * step - length < n * pitch:
                single_length = int(single_length / step + 1) * step
            else:
                single_length = int(single_length / step) * step
            if numpy.sqrt(single_length**2 / 4 + startpoint[i][1]**2
                          ) > max_length and device_shape == 0:  #圆形的隔离圆大小需要修改
                max_length = numpy.sqrt(
                    (single_length**2 / 4 + startpoint[i][1]**2))
            startpoint[i] = (-single_length / 2, startpoint[i][1])
            finalpoint[i] = (single_length / 2, finalpoint[i][1])
        i = i + 1
    max_length = 2 * max_length
    if max_length < pitch * total:
        max_length = pitch * total  #保证外切圆直径为离散值后的最大直径
    maxdiameter = max_length + 2 * minedge  #调整最大曝光区域
    if maxdiameter <= pin_length:
        maxdiameter = pin_length

    i = 0
    while i < len(startpoint):  #i=0,和total对应在x=0位置
        if 0 == 1:
            j = -j
        else:  #每隔30um绘制一个断点
            if is_interrupt == 1 and n > 1:
                step = pals_length  #
                k = 0
                if i not in location:
                    while (k + 1) * step < finalpoint[i][0] - startpoint[i][0]:
                        steppoint1 = (startpoint[i][0] + k * step,
                                      startpoint[i][1])
                        steppoint2 = (startpoint[i][0] + (k + 1) * step -
                                      width * (n - 1), finalpoint[i][1])
                        polym = gdspy.Rectangle(steppoint1,
                                                steppoint2,
                                                layer=1,
                                                datatype=1)
                        polym.fillet(pitch - width, points_per_2pi=20)
                        single_cell.add(polym)
                        k = k + 1
                    else:
                        steppoint1 = (startpoint[i][0] + k * step,
                                      startpoint[i][1])
                        steppoint2 = finalpoint[i]
                        polym = gdspy.Rectangle(steppoint1,
                                                steppoint2,
                                                layer=1,
                                                datatype=1)
                        polym.fillet(pitch - width, points_per_2pi=20)
                        single_cell.add(polym)
            else:
                if i not in location:
                    polym = gdspy.Rectangle(startpoint[i],
                                            finalpoint[i],
                                            layer=1,
                                            datatype=1)
                    polym.fillet((pitch - width) / 2, points_per_2pi=20)
                    single_cell.add(polym)
        if i in location:
            if i in location1:
                startpoint[i] = (j * startpoint[i][0], startpoint[i][1])
                if device_shape == 0:
                    finalpoint[i] = (j * numpy.sqrt((max_length / 2 + 3)**2 -
                                                    ((half - i) * pitch)**2),
                                     finalpoint[i][1])
                elif device_shape == 1:
                    finalpoint[i] = (j * (max_length / 2 + 3),
                                     finalpoint[i][1])
                    j = -j
            polym = gdspy.Rectangle(startpoint[i],
                                    finalpoint[i],
                                    layer=1,
                                    datatype=1)
            polym.fillet((pitch - width) / 2, points_per_2pi=20)
            single_cell.add(polym)
        i = i + 1

    if device_shape == 0:
        iso = shape.circleiso(max_length, width, n)
        equ_area = shape.circle_equ(max_length, maxdiameter, width, pitch,
                                    total, half)
    elif device_shape == 1:
        iso = shape.squireiso(max_length, width, n)
        equ_area = shape.squire_equ(max_length, maxdiameter, width, pitch,
                                    total, half)
    single_cell.add(iso[0])
    single_cell.add(iso[1])

    #绘制外围等效曝光区

    layer = {'layer': 1, 'datatype': 1}  #定义图层
    for i in equ_area:
        for j in i:
            single_cell.add(gdspy.Rectangle(*j, **layer))

    #纳米线核心区域点阵
    startpoint = edge[0]
    finalpoint = edge[1]
    """
    电极线结构
    pitch 纳米线间距,即周期
    width:纳米线宽度
    length 纳米线长度,电极宽度设置为2um,在并联纳米线总宽宽度>1μm后,
    电极宽度调整为(n+4)*width
    预曝光区域,宽度设置为5μm
    曝光长度设置为length/2+5,pitch与纳米线一致
    """
    length = max_length  #将length改为划出纳米线调整后的最大直径
    total = int((maxdiameter / 2 - length / 2 - 1) / pitch)
    i = 0
    m = m1
    if n * m * width >= 1:
        half_elecwidth = (n * m + 4) * width
    else:
        half_elecwidth = 1
    old = half_elecwidth

    while i <= total - 1:
        if i <= int(n * m * width / pitch) + 1:
            half_elecwidth = max_length / 2 + 3
        else:
            half_elecwidth = old
        elec1 = gdspy.Rectangle(
            (half_elecwidth, i * pitch + length / 2),
            (maxdiameter / 2, i * pitch + length / 2 + pitch - width), **layer)
        single_cell.add(elec1)
        elec2 = gdspy.Rectangle(
            (-half_elecwidth, i * pitch + length / 2),
            (-maxdiameter / 2, i * pitch + length / 2 + pitch - width),
            **layer)
        single_cell.add(elec2)
        elec3 = gdspy.Rectangle(
            (-half_elecwidth, (-i - 1) * pitch - length / 2),
            (-maxdiameter / 2, -i * pitch - length / 2 - (pitch - width)),
            **layer)
        single_cell.add(elec3)
        elec4 = gdspy.Rectangle(
            (half_elecwidth, (-i - 1) * pitch - length / 2),
            (maxdiameter / 2, -i * pitch - length / 2 - (pitch - width)),
            **layer)
        single_cell.add(elec4)
        i = i + 1
    """
    隔离线,宽度1um,伸出纳米线区域elec_width/2+pin_ength
    """
    #    length = oldl   #需要原始直径值

    if elec_width / 2 > length / 2 + pin_length - 10:
        a = (elec_width / 2 - length / 2 - pin_length) / pin_length
        if a - int(a) > 0.9:
            a = int(a) + 2
        else:
            a = int(a) + 1
        halflen = pin_length * (a + 1) + length / 2
    else:
        halflen = length / 2 + pin_length
    edgelen = maxdiameter / 2  #纳米线区域边界
    insulate1 = gdspy.Rectangle((half_elecwidth, edgelen - 1),
                                (halflen, edgelen), **layer)
    single_cell.add(insulate1)
    insulate2 = gdspy.Rectangle((-half_elecwidth, edgelen - 1),
                                (-halflen, edgelen), **layer)
    single_cell.add(insulate2)
    insulate3 = gdspy.Rectangle((-half_elecwidth, -edgelen + 1),
                                (-halflen, -edgelen), **layer)
    single_cell.add(insulate3)
    insulate4 = gdspy.Rectangle((half_elecwidth, -edgelen + 1),
                                (halflen, -edgelen), **layer)
    single_cell.add(insulate4)

    insulate5 = gdspy.Rectangle((edgelen - 1, halflen), (edgelen, -halflen),
                                **layer)
    single_cell.add(insulate5)
    insulate6 = gdspy.Rectangle((-edgelen + 1, halflen), (-edgelen, -halflen),
                                **layer)
    single_cell.add(insulate6)
    """
    绘制拼接场外围尺寸,固定等效曝光区域宽10μm
    位置在边界处:pin_length-minedge
    """
    """
    length = oldl  # oldl=原始length,保证被整场分割而不滑移。允许出现边界处拼接场存在。
    layer_useless = {'layer': 3, 'datatype': 3}
    out = gdspy.Rectangle((-length / 2 - pin_length, -maxdiameter / 2),  # 左边
                          (-length / 2 - pin_length + 1, maxdiameter / 2),
                          **layer_useless
                          )
    single_cell.add(out)
    out = gdspy.Rectangle((length / 2 + pin_length, -maxdiameter / 2),  # 右边
                          (length / 2 + pin_length - 1, maxdiameter / 2),
                          **layer_useless
                          )
    single_cell.add(out)
    out = gdspy.Rectangle((-maxdiameter / 2, length / 2 + pin_length),  # 上左
                          (-half_elecwidth, length / 2 + pin_length - 1),
                          **layer_useless
                          )
    single_cell.add(out)
    out = gdspy.Rectangle((maxdiameter / 2, length / 2 + pin_length),  # 上右
                          (half_elecwidth, length / 2 + pin_length - 1),
                          **layer_useless
                          )
    single_cell.add(out)
    out = gdspy.Rectangle((-maxdiameter / 2, -length / 2 - pin_length),  # 下左
                          (-half_elecwidth, -length / 2 - pin_length + 1),
                          **layer_useless
                          )
    single_cell.add(out)
    out = gdspy.Rectangle((maxdiameter / 2, -length / 2 - pin_length),  # 下右
                          (half_elecwidth, -length / 2 - pin_length + 1),
                          **layer_useless
                          )
    single_cell.add(out)
    """
    """
    对准标记
    4umX100μm大小十字
    位置,-500um,500um
    """
    markers = [1, 9, 41, 73, 81]
    if mark in markers:
        cross = gdspy.Rectangle((-450, 498), (-550, 502), **layer)
        single_cell.add(cross)
        cross = gdspy.Rectangle((-498, 450), (-502, 550), **layer)
        single_cell.add(cross)
    """
    编号
    """
    text = gdspy.Text(str(number), 20, (1000, 300), **layer)
    single_cell.add(text)

    merged = gdspy.fast_boolean(gdspy.Rectangle(
        (-maxdiameter / 2, -maxdiameter / 2),
        (maxdiameter / 2, maxdiameter / 2)),
                                gdspy.CellReference(single_cell),
                                'not',
                                max_points=190)

    # Offset the path shape by 0.5 and add it to the cell.
    single_cell.add(merged)

    return single_cell
Esempio n. 7
0
    #loops = [ loop ]
    #for line in process.stdout:
    #     parts = line.rstrip().split()
    #     if parts[0] != 'TYPE:': continue
    #     assert parts[2] == 'X:' and parts[4] == 'Y:'
    #     if parts[1] == '2': continue
    #     if parts[1] == '3':
    #          loop = [ ]
    #          loops.append(loop)
    #     loop.append( (0.5+mask.x+int(parts[3])*0.01,0.5+mask.y+int(parts[5])*0.01) )
    #return [ shape.Loop(item[::-1]) for item in loops ]


if __name__ == '__main__':
    import shape
    loop = shape.Loop(shape.circle(50.0)[:50])
    with open('/tmp/test.pbm', 'wt') as f:
        write_pbm(f, loop.mask(1.0).data)
    print(max(x for x, y in loop) - min(x for x, y in loop))
    for i in range(10):
        mask = loop.mask(1.0)
        with open('/tmp/test2.pbm', 'wt') as f:
            write_pbm(f, mask.data)
        [loop] = trace(mask)
        print(max(x for x, y in loop), min(x for x, y in loop))
        print(max(y for x, y in loop), min(y for x, y in loop))
        print()
        #print( min(x for x,y in loop) )
    #mask[5,5] = 0
    with open('/tmp/test2.pbm', 'wt') as f:
        write_pbm(f, mask.data)
Esempio n. 8
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    def run(self):
        zsize = self.thickness

        pad = self.wall
        diameter = zsize - pad * 2

        self.log.log('Thickness: %.1fmm\n' % zsize)
        self.log.log('Min wall thickness: %.1fmm\n' % pad)
        self.log.log('Hole diameter: %.1fmm\n' % diameter)

        negatives = []
        lengths = []
        xs = []
        for i, note in enumerate(SCALE):
            print 'Make hole %d / %d' % (i + 1, len(SCALE))
            length = design.wavelength(
                note, self.transpose) * 0.25 + LENGTH_CORRECTION * diameter
            x = i * (diameter + pad)
            lengths.append(length)
            xs.append(x)
            hole = make_hole(diameter, length)
            hole.move(x, 0, 0)
            negatives.append(hole)

        string_hole_diameter = diameter * 1.5
        string_hole_loop = shape.circle(string_hole_diameter)
        string_hole = shape.extrusion([-zsize, zsize],
                                      [string_hole_loop, string_hole_loop])
        string_hole.rotate(1, 0, 0, 90)

        xlow = xs[0] - zsize
        #xmid = xs[-1]*0.5
        xhigh = xs[-1] + zsize

        zhigh = lengths[0] + zsize * 0.5
        #zmid  = max(lengths[-1]+zsize*0.5, zhigh-(xhigh-xmid))

        trim = min(xhigh - xlow, zhigh) * 0.5

        #string_x = (xmid+xhigh)*0.5 - diameter
        #string_z = (zmid+zhigh)*0.5 - diameter
        #string_z = lengths[3] + diameter*2
        #string_x = xhigh-trim*0.5-diameter
        #string_z = zhigh-trim*0.5-diameter

        a = math.pi * -5 / 8
        d = diameter * 1.5
        string_x = xhigh - trim + math.cos(a) * d
        string_z = zhigh + math.sin(a) * d

        string_hole.move(string_x, 0, string_z)

        #p = pad*0.5
        #loop = shape.Loop([(0,p),(p*2,-p),(-p*2,p)])
        #r = diameter-pad
        #stick = shape.extrusion([-r,r],[loop,loop])
        #
        #for i in xrange(-1,len(SCALE)+2):
        #    for j in xrange(int(zhigh / (diameter+pad))+1):
        #        x = (i-0.5)*(diameter+pad)
        #        z = r + j*(diameter+pad)
        #        c = stick.copy()
        #        if (i^j)&1:
        #            c.rotate(0,1,0,90)
        #        c.move(x,-diameter*0.5-pad,z)
        #        negatives.append(c)

        loop = shape.Loop([(xlow, 0), (xhigh, 0), (xhigh, zhigh - trim),
                           (xhigh - trim, zhigh), (xlow, zhigh)])

        bev = zsize / 4.0
        loop_bevel = shape.Loop([(xlow, bev), (xhigh, bev),
                                 (xhigh, zhigh - trim), (xhigh - trim, zhigh),
                                 (xlow, zhigh)])

        #mask = loop.mask(RES)

        #amount = diameter * 0.5
        #op = shape.circle(amount).mask(RES)
        #mask = mask.open(op)

        #loop = mask.trace(RES)[0]

        #sloop = mask.erode(op).trace(RES)[0]

        #z1 = zsize*0.5-amount
        z2 = zsize * 0.5

        #positive = shape.extrusion([-z2,z2],[loop,loop])
        positive = shape.extrusion([-z2, -z2 + bev, z2 - bev, z2],
                                   [loop_bevel, loop, loop, loop_bevel])
        positive.rotate(1, 0, 0, 90)

        negative = string_hole.copy()
        for i, item in enumerate(negatives):
            print 'Merge %d / %d' % (i + 1, len(negatives))
            negative.add(item)

        del negatives

        instrument = positive.copy()

        print 'Remove holes from instrument'
        instrument.remove(negative)

        del positive
        del negative

        instrument.rotate(1, 0, 0, 90)
        extent = instrument.extent()

        copy = instrument.copy()
        copy.rotate(0, 0, 1, -45)
        cextent = copy.extent()
        copy.move(-(cextent.xmin + cextent.xmax) * 0.5,
                  -(cextent.ymin + cextent.ymax) * 0.5, -cextent.zmin)
        self.save(copy, 'instrument')
        del copy

        top = shape.block(extent.xmin - 1, extent.xmax + 1, extent.ymin - 1,
                          extent.ymax + 1, 0, extent.zmax + 1)
        bottom = shape.block(extent.xmin - 1, extent.xmax + 1, extent.ymin - 1,
                             extent.ymax + 1, extent.zmin - 1, 0)

        top.clip(instrument)
        bottom.clip(instrument)
        top.rotate(1, 0, 0, 180)
        top.move(0, 4, 0)
        bottom.add(top)
        pattern = bottom

        del top
        del bottom

        pattern.move(0, 0, z2)
        pattern.rotate(0, 0, 1, -90)

        bit_pad = 4.0
        extra_depth = 3.0
        a = bit_pad
        b = bit_pad + z2 / 10.0
        pad_cone = shape.extrude_profile(
            profile.Profile([-extra_depth, 0, z2], [a * 2, a * 2, b * 2]),
            cross_section=lambda d: shape.circle(d, 16))

        extra = b + 0.5

        extent = pattern.extent()
        mill = shape.block(
            extent.xmin - extra,
            extent.xmax + extra,
            extent.ymin - extra,
            extent.ymax + extra,
            -extra_depth,
            z2,
        )

        mill.remove(pattern.polygon_mask().to_3().minkowski_sum(pad_cone))
        mill.add(pattern)

        del pad_cone
        del pattern

        self.save(mill, 'mill')
Esempio n. 9
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pygame.display.set_caption('Hex')

# Set display
size = width, height = (601,301)
screen = pygame.display.set_mode(size,pygame.RESIZABLE)
pygame.event.post( pygame.event.Event(pygame.VIDEORESIZE, {'size': size}))

while exit != True:
	event = pygame.event.wait()
	if (event.type == pygame.QUIT) or ((event.type == pygame.KEYDOWN) and (event.key == pygame.K_q)):
		exit = True
	elif event.type == pygame.VIDEORESIZE:
		screen = pygame.display.set_mode(event.size,pygame.RESIZABLE)
		size = width, height = event.size
	elif event.type == pygame.MOUSEBUTTONDOWN:
		pass
	else:
		continue

	# Load background
	size = width, height = screen.get_size()
	background = pygame.Surface(size)
	background = background.convert()
	background.fill((0,0,50))

	mygrid = newgrid(shape.circle(3), (width - 20, height - 20))

	screen.blit(background, (0,0))
	screen.blit(mygrid.surface, (10,10))
	pygame.display.flip()
sys.exit()
Esempio n. 10
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#!usr/bin/python3

import shape

a = shape.Point()

print(repr(a))

b = shape.Point(3,4)

print(str(b))

print("{0}".format(b.distance_from_origin()))

b.x = -19
print(str(b))

p = shape.Point(28, 45)
c = shape.circle(5, 28, 45)

print(p.distance_from_origin())

print(c.distance_from_origin())

Esempio n. 11
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File: mask.py Progetto: pfh/demakein
    # for line in process.stdout:
    #     parts = line.rstrip().split()
    #     if parts[0] != 'TYPE:': continue
    #     assert parts[2] == 'X:' and parts[4] == 'Y:'
    #     if parts[1] == '2': continue
    #     if parts[1] == '3':
    #          loop = [ ]
    #          loops.append(loop)
    #     loop.append( (0.5+mask.x+int(parts[3])*0.01,0.5+mask.y+int(parts[5])*0.01) )
    # return [ shape.Loop(item[::-1]) for item in loops ]


if __name__ == "__main__":
    import shape

    loop = shape.Loop(shape.circle(50.0)[:50])
    with open("/tmp/test.pbm", "wt") as f:
        write_pbm(f, loop.mask(1.0).data)
    print(max(x for x, y in loop) - min(x for x, y in loop))
    for i in range(10):
        mask = loop.mask(1.0)
        with open("/tmp/test2.pbm", "wt") as f:
            write_pbm(f, mask.data)
        [loop] = trace(mask)
        print(max(x for x, y in loop), min(x for x, y in loop))
        print(max(y for x, y in loop), min(y for x, y in loop))
        print()
        # print( min(x for x,y in loop) )
    # mask[5,5] = 0
    with open("/tmp/test2.pbm", "wt") as f:
        write_pbm(f, mask.data)
Esempio n. 12
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import shape

r = (int(input("enter radious:")))
obj = shape.circle(r)
obj.area(r)
import shape

if __name__ == '__main__':

    cerchio = shape.circle(10)
    pentagono = shape.pentagons(5)
    rettangolo = shape.rectangle(5,2)
    quadrato = shape.square(2)
    triangolo = shape.triangoloeq(3)
    listOfShapes = [cerchio, pentagono, rettangolo, quadrato, triangolo]
    print(listOfShapes)
    print(cerchio.calculate_area(), pentagono.calculate_area(), rettangolo.calculate_area(), quadrato.calculate_area(), triangolo.calculate_area())
    print([x.calculate_area() for x in  shape.shape.sortarea(listOfShapes)])
Esempio n. 14
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File: pack.py Progetto: pfh/demakein
    def render(self, bit_diameter, bit_pad):
        xsize = self.xsize
        ysize = self.ysize

        a = bit_pad
        b = bit_pad + self.zsize / 10.0
        pad_cone = shape.extrude_profile(
            profile.Profile([0, self.zsize], [a * 2, b * 2], [a * 2, b * 2]),
            cross_section=lambda d: shape.circle(d, 16))
        pad_cylinder = shape.extrude_profile(
            profile.Profile([0, self.zsize + bit_diameter], [a * 2, a * 2],
                            [a * 2, a * 2]),
            cross_section=lambda d: shape.circle(d, 16))

        pad = 0.5 + self.zsize / 10.0

        upper = shape.block(-pad, xsize + pad, -pad, ysize + pad, 0,
                            self.zsize)

        print 'Cut holes'

        for i, (x, y, packable) in enumerate(self.items):
            if packable.use_upper:
                flat = packable.mask.to_3()
                flat.move(x, y, 0)
                minsum = flat.minkowski_sum(pad_cone)
                upper.remove(minsum)

        print 'Put things in them'

        for x, y, packable in self.items:
            if packable.use_upper:
                temp = packable.shapes[0].copy()
                temp.move(x, y, 0)
                upper.add(temp)

        bol = int(self.xsize / 10.0)
        bol_width = 1.0
        # 0.5 seemed to allow shifting on a sop flute
        bol_height = 1.0
        # 0.5 was too low, middle piece tore loose in final pass of
        # contour finishing (x-scan of horizontal-like surfaces)
        xmins = [x for x, y, packable in self.items]
        xmaxs = [x + packable.extent.xmax for x, y, packable in self.items]
        margin = bol_width + bit_diameter + 0.25

        potential_bols = [((i + 0.5) * xsize / bol, 0, ysize)
                          for i in xrange(bol)]
        bols = []
        while potential_bols:
            pos, y_low, y_high = potential_bols.pop()
            for i, (x, y, packable) in enumerate(self.items):
                if pos-margin <= xmins[i] <= pos+margin or \
                   pos-margin <= xmaxs[i] <= pos+margin:
                    low = y - bit_diameter
                    high = y + packable.extent.ymax + bit_diameter
                    if low <= y_low and y_high <= high:
                        break
                    elif y_low < low and high < y_high:
                        potential_bols.append((pos, y_low, low))
                        potential_bols.append((pos, high, y_high))
                        break
                    elif y_low < low < y_high <= high:
                        potential_bols.append((pos, y_low, low))
                        break
                    elif low < y_low < high <= y_high:
                        potential_bols.append((pos, high, y_high))
                        break
            else:
                bols.append((pos, y_low, y_high))

        for pos, y_low, y_high in bols:
            upper.add(
                shape.block(
                    pos - bol_width * 0.5,
                    pos + bol_width * 0.5,
                    y_low,
                    y_high,
                    #0,ysize,
                    #-bit_diameter*0.6, bol_height,
                    0,
                    bol_height,
                ))

        print 'Underside'

        # Cut the bottom of upper with lower, to depth    bit_diameter
        lower = shape.block(-pad, xsize + pad, -pad, ysize + pad, bit_diameter,
                            self.zsize)
        lower.add(upper)

        print 'Remove bores'

        for x, y, packable in self.items:
            temp = packable.shapes[1].copy()
            temp.move(x, y, 0)

            flat = packable.mask.to_3()
            flat.move(x, y, 0)
            minsum = flat.minkowski_sum(pad_cylinder)
            temp.clip(minsum)

            lower.remove(temp)

        lower.rotate(0, 1, 0, 180)

        return lower, upper