def _normalize(self):
if self._normalized == True:
raise ValueError("Already normalized")
p = self.idt.pitch
active_area_x = self.idt.active_area.x
anchor_x = self.anchor.size.x
anchor_y = self.anchor.size.y
self.idt.y_offset = self.idt.y_offset / p
# self.idt.length=self.idt.length/p
self.bus.size = pt.Point(self.bus.size.x, self.bus.size.y / p)
self.etchpit.x = self.etchpit.x / active_area_x
self.anchor.size = pt.Point(self.anchor.size.x / active_area_x,
self.anchor.size.y / p)
self.anchor.metalized = pt.Point(
self.anchor.metalized.x / anchor_x,
self.anchor.metalized.y / anchor_y)
self._normalized = True
def _denormalize(self):
if self._normalized == False:
raise ValueError("Already denormalized")
p = self.idt.pitch
self.idt.y_offset = self.idt.y_offset * p
self.bus.size = pt.Point(self.bus.size.x, self.bus.size.y * p)
active_area_x = self.idt.active_area.x
self.etchpit.x = self.etchpit.x * active_area_x
self.anchor.size=pt.Point(\
self.anchor.size.x*active_area_x,\
self.anchor.size.y*p)
self.anchor.metalized = pt.Point(
self.anchor.metalized.x * self.anchor.size.x,
self.anchor.metalized.y * self.anchor.size.y)
self._normalized = False
return self
def probe_dut_distance(self):
base_dist=self.idt.probe_distance
if hasattr(self,'pad'):
base_dist=pt.Point(base_dist.x,self.pad.size+self.pad.distance+base_dist.y)
if hasattr(self.probe,'pad'):
base_dist=pt.Point(base_dist.x,self.probe.pad.size+self.probe.pad.distance+base_dist.y)
return base_dist
def _setup_probe(self,device_cell):
top_ports=[pt.Point(p.midpoint) for p in ppt.find_ports(device_cell,'top',depth=0)]
bottom_ports=[pt.Point(p.midpoint) for p in ppt.find_ports(device_cell,'bottom',depth=0)]
top_port_midpoint=st.get_centroid(*top_ports)
bottom_port_midpoint=st.get_centroid(*bottom_ports)
self.probe.offset=pt.Point(
(top_port_midpoint.x-bottom_port_midpoint.x),
(top_port_midpoint.y-bottom_port_midpoint.y)+2*self.probe_dut_distance.y)
def _bbox_mod(self, bbox):
LayoutPart._bbox_mod(self, bbox)
ll = pt.Point(bbox[0])
ur = pt.Point(bbox[1])
if any([_ == 'top' for _ in side]):
ur = ur - pt.Point(0, float(self.pad.size + self.pad.distance))
if any([_ == 'bottom' for _ in side]):
ll = ll + pt.Point(0, float(self.pad.size + self.pad.distance))
return (ll.coord, ur.coord)
def probe_conn_distance(self):
tot_distance = self.probe_dut_distance
return pt.Point(tot_distance.x, tot_distance.y * 3 / 4)
def active_area(self):
active_area = super().active_area
return pt.Point(active_area.x * self.n_blocks, active_area.y)
def connect_ports(cell: Device,
tag: str = 'top',
layers: tuple = (LayoutDefault.layerTop, ),
distance: float = 10.0,
metal_width: float = None):
''' connects all the ports in the cell with name matching a tag.
Parameters:
-----------
cell : Device
tag: str
conn_dist: pt.Point
offset from port location
layer : tuple.
Returns:
----------
cell : Device
contains routings and connection port
'''
import pirel.pcells as pc
ports = pt._find_ports(cell, tag, depth=0)
ports.sort(key=lambda x: x.midpoint[0])
ports_centroid = pt._get_centroid_ports(ports)
if len(ports) == 1:
raise ValueError("pm.connect_ports() : len(ports) must be >1 ")
if metal_width is None:
metal_width = ports_centroid.width
port_mid_norm = pt.Point(ports_centroid.normal[1]) - pt.Point(
ports_centroid.normal[0])
midpoint_projected = Point(
ports_centroid.midpoint) + port_mid_norm * (distance + metal_width)
pad_side = ports_centroid.width
new_port = Port(name=tag,
orientation=ports_centroid.orientation,
width=ports_centroid.width,
midpoint=midpoint_projected.coord)
output_cell = Device()
for p in ports:
straight_conn = output_cell << pt._draw_multilayer(
'compass',
layers,
size=(p.width, abs(midpoint_projected.y - p.midpoint[1])))
straight_conn.connect("S", p)
cross_conn = output_cell << pt._draw_multilayer(
'compass', layers, size=(output_cell.xsize, metal_width))
cross_conn.connect('S', new_port, overlap=metal_width)
output = pt.join(output_cell)
output.add_port(new_port)
return output
def __init__(self, *a, **kw):
super().__init__(*a, **kw)
self.connector_distance = pt.Point(0, 100)
import pirel.tools as pt
import pirel.addOns.standard_parts as ps
# t=pc.TwoPortRes('hey')
#
# t.view()
# exit()
t_aux = pm.addTwoPortProbe(pm.makeArray(pm.makeScaled(pc.TwoPortRes), 2),
probe=pm.makeTwoPortProbe(
pm.addLargeGround(pc.GSGProbe)))('hey')
# t_aux=pm.makeSMDCoupledFilter(pc.TwoPortRes,
# smd=pm.addPassivation(pc.SMD))('hey')
# t_aux=pm.addPassivation(pc.SMD)('hey')
# t_aux['Layer']=pt.LayoutDefault.layerBottom
t_aux.spacing = pt.Point(0, 250)
t_aux.gnd_routing_width = 150
# t_aux.smd.passivation_layer=(3,)
# t_aux.smd.set_01005()
# t_aux.smd.passivation_scale=pt.Point(2.5,1.5)
# t_aux.smd.passivation_margin=pt.Point(50,50)
t_aux.anchor.n = 1
t_aux.gndvia.size = 25
# t_aux.anchor.n=1
# t_aux.probe.ground_size=200
# t_aux['IDTLength']=250
# t_aux['AnchorSizeX']=0.2
# t_aux['AnchorSizeY']=5
# t_aux['IDTPitch']=7
# print(t)
import pirel.addOns.standard_parts as ps
# t=pc.TwoPortRes('hey')
#
# t.view()
# exit()
t_aux = pm.addTwoPortProbe(
pm.makeSMDCoupledFilter(pm.makeArray(pm.makeScaled(pc.TwoPortRes), 2),
smd=pm.addPassivation(pc.SMD)),
probe=pm.makeTwoPortProbe(pm.addLargeGround(pc.GSGProbe)))('hey')
# t_aux=pm.makeSMDCoupledFilter(pc.TwoPortRes,
# smd=pm.addPassivation(pc.SMD))('hey')
# t_aux=pm.addPassivation(pc.SMD)('hey')
# t_aux['Layer']=pt.LayoutDefault.layerBottom
t_aux.spacing = pt.Point(0, 250)
t_aux.gnd_routing_width = 150
t_aux.smd.passivation_layer = (3, )
t_aux.smd.set_01005()
t_aux.smd.passivation_scale = pt.Point(2.5, 1.5)
t_aux.smd.passivation_margin = pt.Point(50, 50)
t_aux.anchor.n = 1
t_aux.gndvia.size = 25
# t_aux.anchor.n=1
# t_aux.probe.ground_size=200
# t_aux['IDTLength']=250
# t_aux['AnchorSizeX']=0.2
# t_aux['AnchorSizeY']=5
# t_aux['IDTPitch']=7
# print(t)
