def initialize(self):
self.SOCKET = TechnologyTree()
self.SOCKET.LENGTH = 50.0
self.SOCKET.WIDTH = 10.0
from picazzo3.traces.wire_wg import WireWaveguideTemplate
wide_trace_template = WireWaveguideTemplate()
wide_trace_template.Layout(core_width=0.45, cladding_width=15.0)
self.SOCKET.TRACE_TEMPLATE = wide_trace_template # Wide trace template.
# TE Grating
self.GRATING_TE = TechnologyTree()
self.GRATING_TE.N_O_LINES = 25 # Default number of lines used.
self.GRATING_TE.PERIOD = 0.63 # Default period used in the grating.
self.GRATING_TE.LINE_WIDTH = 0.315 # Default linewidth used in the grating.
self.GRATING_TE.BOX_WIDTH = 14.0 # Default box width
# TM Grating
self.GRATING_TM = TechnologyTree()
self.GRATING_TM.N_O_LINES = 16 # Default number of lines used.
self.GRATING_TM.PERIOD = 1.080 # Default period used in the grating.
self.GRATING_TM.LINE_WIDTH = 0.540 # Default linewidth used in the grating.
self.GRATING_TM.BOX_WIDTH = 14.0 # Default box width
# default
self.GRATING = self.GRATING_TE
def initialize(self):
# Socket
self.SOCKET = TechnologyTree()
self.SOCKET.LENGTH = 20.0
self.SOCKET.STRAIGHT_EXTENSION = (
0.0, 0.05
) # Default straight extentions used for the socket taper.
self.SOCKET.MARGIN_FROM_GRATING = TECH.WG.SHORT_STRAIGHT # Distance between the last grating line and the end of the socket by default
self.SOCKET.START_TRACE_TEMPLATE = TECH.PCELLS.WG.DEFAULT
self.SOCKET.TRANSITION_LENGTH = 5.0
from aeponyx.components.waveguides.wire import MSNWireWaveguideTemplate
wide_trace_template = MSNWireWaveguideTemplate(
name="LinearTransitionSocket_WGT")
wide_trace_template.Layout(core_width=17.0,
cladding_width=2 * TECH.WG.TRENCH_WIDTH +
17.0)
self.SOCKET.WIDE_TRACE_TEMPLATE = wide_trace_template # Wide trace template.
# Grating
self.GRATING = TechnologyTree()
self.GRATING.PERIOD = 1.0 # Default period used in the grating.
self.GRATING.FOCAL_DISTANCE = 20 * self.GRATING.PERIOD # Default focal distance of curved gratings.
self.GRATING.BOX_WIDTH = 15.5 # Default box width
self.GRATING.N_O_LINES = int(
floor(self.GRATING.BOX_WIDTH / self.GRATING.PERIOD))
self.GRATING.START_RADIUS = self.GRATING.FOCAL_DISTANCE - self.GRATING.BOX_WIDTH / 2.0 # Default first radius of the grating.
self.GRATING.ANGLE_SPAN = 90 # Default angle span of a curved grating when it is not boxed.
def initialize(self):
from ipkiss.process import PPLayer
from ipkiss.visualisation.display_style import DisplayStyle, DisplayStyleSet
from ipkiss.visualisation import color
self.PREDEFINED_STYLE_SETS = TechnologyTree()
# colorful purpose map
DISPLAY_BLACK = DisplayStyle(color=color.COLOR_BLACK, edgewidth=0.0)
DISPLAY_WHITE = DisplayStyle(color=color.COLOR_WHITE, edgewidth=0.0)
DISPLAY_INVERSION = DisplayStyle(color=color.COLOR_BLUE,
alpha=0.5,
edgewidth=1.0)
DISPLAY_DF = DisplayStyle(color=color.COLOR_GREEN,
alpha=0.5,
edgewidth=1.0)
DISPLAY_LF = DisplayStyle(color=color.COLOR_YELLOW,
alpha=0.5,
edgewidth=1.0)
DISPLAY_TEXT = DisplayStyle(color=color.COLOR_MAGENTA,
alpha=0.5,
edgewidth=1.0)
DISPLAY_HOLE = DisplayStyle(color=color.COLOR_RED,
alpha=0.5,
edgewidth=1.0)
DISPLAY_ALIGNMENT = DisplayStyle(color=color.COLOR_CYAN,
alpha=0.5,
edgewidth=1.0)
style_set = DisplayStyleSet()
style_set.background = DISPLAY_WHITE
process_display_order = [
TECH.PROCESS.RFC, TECH.PROCESS.FCW, TECH.PROCESS.FC,
TECH.PROCESS.WG, TECH.PROCESS.NT, TECH.PROCESS.EBW,
TECH.PROCESS.HFW, TECH.PROCESS.VGW, TECH.PROCESS.CO,
TECH.PROCESS.NBODY, TECH.PROCESS.PBODY, TECH.PROCESS.P1,
TECH.PROCESS.PPLUS, TECH.PROCESS.N1, TECH.PROCESS.NPLUS,
TECH.PROCESS.PP1, TECH.PROCESS.PP2, TECH.PROCESS.SAL,
TECH.PROCESS.MC1, TECH.PROCESS.MC2, TECH.PROCESS.MH,
TECH.PROCESS.M1, TECH.PROCESS.V12, TECH.PROCESS.M2,
TECH.PROCESS.MP1, TECH.PROCESS.MP2, TECH.PROCESS.FC2,
TECH.PROCESS.WG2, TECH.PROCESS.VO1, TECH.PROCESS.GW1,
TECH.PROCESS.GW2, TECH.PROCESS.GW3
]
for process in process_display_order:
style_set += [
(PPLayer(process, TECH.PURPOSE.LF_AREA), DISPLAY_INVERSION),
(PPLayer(process, TECH.PURPOSE.DF_AREA), DISPLAY_INVERSION),
(PPLayer(process, TECH.PURPOSE.DF.MARKER), DISPLAY_ALIGNMENT),
(PPLayer(process, TECH.PURPOSE.LF.MARKER), DISPLAY_ALIGNMENT),
(PPLayer(process, TECH.PURPOSE.LF.LINE), DISPLAY_DF),
(PPLayer(process, TECH.PURPOSE.LF.ISLAND), DISPLAY_DF),
(PPLayer(process, TECH.PURPOSE.DF.TEXT), DISPLAY_TEXT),
(PPLayer(process, TECH.PURPOSE.DF.HOLE), DISPLAY_HOLE),
(PPLayer(process, TECH.PURPOSE.DF.TRENCH), DISPLAY_LF),
(PPLayer(process, TECH.PURPOSE.DF.SQUARE), DISPLAY_HOLE),
]
self.PREDEFINED_STYLE_SETS.PURPOSE_HIGHLIGHT = style_set
def initialize(self):
self.IOFIBCOUP = TechnologyTree()
self.IOFIBCOUP.FANOUT_LENGTH = 40.0
self.IOFIBCOUP.S_BEND_ANGLE = 60.0
self.IOFIBCOUP.CONNECT_TRANSITION_LENGTH = None # automatic
self.IOFIBCOUP.FIBER_COUPLER_TRANSITION_LENGTH = None # automatic
self.DEFAULT_ADAPTER = self.IOFIBCOUP
def initialize(self):
from ipkiss.process import PPLayer
self.PREDEFINED_STYLE_SETS = TechnologyTree()
style_set = DisplayStyleSet()
style_set.background = DISPLAY_WHITE
style_set += [
# Note: the order in which the layer:color pairs are added here decides the drawing order.
(TECH.PPLAYER.MSN, DISPLAY_GREEN),
(TECH.PPLAYER.MSN_TRENCH, DISPLAY_ORANGE),
(TECH.PPLAYER.CLADDING, DISPLAY_YELLOW),
(TECH.PPLAYER.SHALLOW, DISPLAY_CYAN_SPARSE),
(TECH.PPLAYER.SHALLOW_TRENCH, DISPLAY_SCARLET),
(TECH.PPLAYER.M1, DISPLAY_COPPER),
(TECH.PPLAYER.V12, DISPLAY_CHAMPAGNE),
(TECH.PPLAYER.M2, DISPLAY_SILVER),
(TECH.PPLAYER.HT, DISPLAY_GRAY),
(TECH.PPLAYER.GE, DISPLAY_YELLOW),
(TECH.PPLAYER.CON, DISPLAY_TITANIUM_YELLOW),
(TECH.PPLAYER.SIL, DISPLAY_VIOLET),
(TECH.PPLAYER.N, DISPLAY_BLUE_SPARSE),
(TECH.PPLAYER.NPLUS, DISPLAY_BLUE),
(TECH.PPLAYER.P, DISPLAY_RED_SPARSE),
(TECH.PPLAYER.PPLUS, DISPLAY_RED),
(TECH.PPLAYER.PINREC, DISPLAY_ORANGE),
(TECH.PPLAYER.ERROR.GENERIC, DISPLAY_PURPLE),
(TECH.PPLAYER.DOC, DISPLAY_CHERRY),
(TECH.PPLAYER.NONE, DISPLAY_INVISBLE),
(TECH.PPLAYER.WIRE_TRACE, DISPLAY_MAGENTA_SPARSE),
(TECH.PPLAYER.RIB_TRACE, DISPLAY_SANGRIA_SPARSE),
]
from ipkiss.visualisation.color import Color
from numpy import linspace
style_set += [
(
i,
DisplayStyle(
color=Color(
name="gray_" + str(
i
), # Visualization for simple Layers which may be present
red=c_val,
green=c_val,
blue=c_val),
alpha=.5))
for i, c_val in enumerate(linspace(.9, 0.0, num=256))
]
self.DEFAULT_DISPLAY_STYLE_SET = style_set # required
from ipkiss.technology import get_technology TECH = get_technology() from ipkiss.technology.technology import TechnologyTree TECH.BLOCKS = TechnologyTree() TECH.BLOCKS.DEFAULT_YSPACING = 25.0 TECH.BLOCKS.DEFAULT_WIDTH = 500.0
############################################################################################ # pin/port settings: # # Contains the default port settings used by IPKISS and PICAZZO ############################################################################################ from ipkiss.technology import get_technology from ipkiss.technology.technology import TechnologyTree TECH = get_technology() TECH.PORT = TechnologyTree() TECH.PORT.DEFAULT_LAYER = TECH.PPLAYER.NONE.PIN # Default layer for drawing pins TECH.PORT.DEFAULT_LENGTH = 0.1 # Default length of a PIN
# Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. # # i-depot BBIE 7396, 7556, 7748 # # Contact: [email protected] from ipkiss.technology import get_technology from ipkiss.technology.technology import TechnologyTree, DelayedInitTechnologyTree from ipkiss.log import IPKISS_LOG as LOG TECH = get_technology() #################################################################### # DEFAULT FIBER COUPLER #################################################################### TECH.IO = TechnologyTree() class TechFibcoupTree(DelayedInitTechnologyTree): def initialize(self): ## standard gratings 1550nm def STANDARD_GRATING_1550_TE(): from picazzo.fibcoup.uniform import UniformLineGrating as _ULG from ipkiss.plugins.photonics.wg.basic import WgElDefinition std1550_grating_trench = 0.315 std1550_grating_period = 0.630 std1550_grating_n_o_periods = 25 std_lin_grating_wg_def = WgElDefinition(wg_width=10.0) G = _ULG(name="std_grating_1550", origin=(0.0, 0.0),
###############################################################################################
TECH.PROCESS = ProcessTechnologyTree()
# silicon structuring
TECH.PROCESS.FC = ProcessLayer("Fiber Couplers", "FC")
TECH.PROCESS.WG = ProcessLayer("Waveguides", "WG")
# other
TECH.PROCESS.NONE = ProcessLayer("No Specific Process Layer", "NONE")
####################################################################
# MASK
####################################################################
TECH.MASK = TechnologyTree()
TECH.MASK.POLARITY_DF = "DF"
TECH.MASK.POLARITY_LF = "LF"
####################################################################
# MASK LAYER RULES
####################################################################
# This should become process layer dependent!
TECH.TECH = TechnologyTree()
TECH.TECH.MINIMUM_LINE = 0.120
TECH.TECH.MINIMUM_SPACE = 0.120
###############################################################################################
# Pattern Purposes
###############################################################################################
# Settings for metallization
#
# The technology keys below are required keys for Ipkiss
# You can change the values or refer them to your own technology keys, but their name should not be changed
from ipkiss.technology.technology import ProcessTechnologyTree, TechnologyTree, DelayedInitTechnologyTree
from ipkiss.technology import get_technology
from ipkiss.process.layer import ProcessLayer, PatternPurpose, PPLayer
from ipkiss.geometry.shapes.basic import ShapeRectangle
TECH = get_technology()
# Metal Tree
TECH.METAL = TechnologyTree()
TECH.METAL.LINE_WIDTH = 0.5 # Default line width of metal wire
TECH.METAL.DEFAULT_PROCESS = TECH.PROCESS.M1 # Default process for metal wiring
TECH.VIAS = TechnologyTree()
TECH.VIAS.DEFAULT = TechnologyTree()
TECH.VIAS.DEFAULT.TOP_SHAPE = ShapeRectangle(
box_size=(0.6, 0.6)) # Default bottom shape (M1) for a via
TECH.VIAS.DEFAULT.VIA_SHAPE = ShapeRectangle(
box_size=(0.5, 0.5)) # Default via shape
TECH.VIAS.DEFAULT.BOTTOM_SHAPE = ShapeRectangle(
box_size=(0.6, 0.6)) # Default top shape (M2) for a via
# i-depot BBIE 7396, 7556, 7748 # # Contact: [email protected] from ipkiss.technology.technology import TechnologyLibrary, TechnologyTree, DelayedInitTechnologyTree from ipkiss.technology import get_technology from ipkiss.io.gds_layer import GdsiiLayerInputMap, GdsiiLayerOutputMap from ipkiss.process.layer import PPLayer as PPLayer TECH = get_technology() #################################################################### # DEFINED PPLayers #################################################################### TECH.PPLAYER = TechnologyTree() TECH.PPLAYER.WG = TechnologyTree() TECH.PPLAYER.FC = TechnologyTree() ### WG ### TECH.PPLAYER.WG.TRENCH = PPLayer(TECH.PROCESS.WG, TECH.PURPOSE.DF.TRENCH, name="WG_TRE") TECH.PPLAYER.WG.SQUARE = PPLayer(TECH.PROCESS.WG, TECH.PURPOSE.DF.TRENCH, name="WG_SQ") TECH.PPLAYER.WG.HOLE = PPLayer(TECH.PROCESS.WG, TECH.PURPOSE.DF.HOLE, name="WG_HEX") TECH.PPLAYER.WG.MARKER = PPLayer(TECH.PROCESS.WG,
def initialize(self):
from ipkiss.primitives import name_generator
self.NAME_GENERATOR = name_generator.CounterNameGenerator(
prefix_attribute="__name_prefix__",
counter_zero=0,
default_prefix="STRUCTURE")
TECH.ADMIN = TechAdminTree()
####################################################################
# Basic Metrics
####################################################################
TECH.METRICS = TechnologyTree()
TECH.METRICS.GRID = 5E-9
TECH.METRICS.UNIT = 1E-6
TECH.METRICS.ANGLE_STEP = 1.0
TECH.METRICS.overwrite_allowed = ["UNIT", "GRID", "ANGLE_STEP"]
####################################################################
# LAYER MAP
####################################################################
class TechGdsiiTree(DelayedInitTechnologyTree):
"""A technology tree with a GDS2 import and export layer map"""
def initialize(self):
from ipkiss.io.gds_layer import AutoGdsiiLayerOutputMap, AutoGdsiiLayerInputMap
####################################################################
# DEFAULT FIBER COUPLER
####################################################################
from ipkiss.technology import get_technology
from ipkiss.technology.technology import TechnologyTree, DelayedInitTechnologyTree
from ipkiss.log import IPKISS_LOG as LOG
from numpy import floor
TECH = get_technology()
TECH.IO = TechnologyTree()
TECH.IO.DEFAULT_FIBCOUP_SPACING = 127.0 # Default spacing between fibercouplers for IOFibCoup
###########################################################
# Straight Gratings
###########################################################
class TechFibCoupTreeStraight(DelayedInitTechnologyTree):
def initialize(self):
self.SOCKET = TechnologyTree()
self.SOCKET.LENGTH = 50.0
self.SOCKET.WIDTH = 10.0
from picazzo3.traces.wire_wg import WireWaveguideTemplate
wide_trace_template = WireWaveguideTemplate()
wide_trace_template.Layout(core_width=0.45, cladding_width=15.0)
self.SOCKET.TRACE_TEMPLATE = wide_trace_template # Wide trace template.
# TE Grating
# GDSII layer mapping
# - TECH keys defined here is used by IPKISS
############################################################################################
from ipkiss.technology import get_technology
from ipkiss.technology.technology import TechnologyTree
from ipkiss.process.layer_map import GenericGdsiiPPLayerOutputMap, GenericGdsiiPPLayerInputMap
import string
# Layer mapping
TECH = get_technology()
from ipkiss.technology.technology import DelayedInitTechnologyTree
TECH = get_technology()
TECH.GDSII = TechnologyTree()
##################################
# SETTINGS
##################################
TECH.GDSII.STRNAME_CHARACTER_DICT = {
" -./": "_"
} # Mapping for illegal characters in cell names
TECH.GDSII.STRNAME_ALLOWED_CHARACTERS = string.ascii_letters + string.digits + '_$' # Allowed characters in cell names
TECH.GDSII.MAX_COORDINATES = 200 # Max number of vertices in a path
TECH.GDSII.MAX_PATH_LENGTH = 100 # Max number of control points in a path
TECH.GDSII.MAX_VERTEX_COUNT = 4000 # Max number of vertices in a polygon
TECH.GDSII.MAX_NAME_LENGTH = 255 # Max length of a cell name
##################################
TECH.PPLAYER.SHALLOW.ALL = TECH.PPLAYER.SHALLOW | (TECH.PPLAYER.SHALLOW_TRENCH
& TECH.PPLAYER.MSN)
TECH.PPLAYER.SHALLOW.ALL.name = "SHALLOW_ALL"
TECH.PPLAYER.N.ALL = TECH.PPLAYER.N
TECH.PPLAYER.NPLUS.ALL = TECH.PPLAYER.NPLUS
TECH.PPLAYER.P.ALL = TECH.PPLAYER.P
TECH.PPLAYER.PPLUS.ALL = TECH.PPLAYER.PPLUS
TECH.PPLAYER.CON.ALL = TECH.PPLAYER.CON
TECH.PPLAYER.M1.ALL = TECH.PPLAYER.M1
# Virtual fabrication flow using Materials Stacks defined in technology/materials.py
# INVALID is used for the unsupported layers stacks
from ipkiss.plugins.vfabrication.process_flow import VFabricationProcessFlow
TECH.VFABRICATION = TechnologyTree()
# Process in the Silicon layer
TECH.VFABRICATION.PROCESS_FLOW_FEOL = VFabricationProcessFlow(
active_processes=[
TECH.PROCESS.MSN,
TECH.PROCESS.SHALLOW,
TECH.PROCESS.N,
TECH.PROCESS.NPLUS,
TECH.PROCESS.P,
TECH.PROCESS.PPLUS,
TECH.PROCESS.CON,
], # DO NOT CHANGE THE SEQUENCE OF THE ELEMENTS ! IT MUST MATCH THE SEQUENCE OF THE COLUMNS IN VFABRICATION PROPERTY process_to_material_stack_map
process_to_material_stack_map=
#SI_ALL, SHALLOW_ALL, N, NPLUS, P, PPLUS, CON
[
"""Settings for IPKISS.eda
These are required technology keys for exporting to OpenAccess (so they can be used in EDA tools that support it)
"""
try:
import oatools
HAVE_OA = True
from ipkiss.technology import get_technology
from ipkiss.technology.technology import TechnologyTree, DelayedInitTechnologyTree
from oatools.to_oa.export_layer_map import AutoOALayerExportMap, AutoOAPurposeExportMap
TECH = get_technology()
TECH.OPENACCESS = TechnologyTree()
process_map = {
TECH.PROCESS.MSN: 1,
TECH.PROCESS.SHALLOW: 2,
TECH.PROCESS.M1: 3,
TECH.PROCESS.M2: 4,
TECH.PROCESS.V12: 5,
TECH.PROCESS.SIL: 10,
TECH.PROCESS.N: 11,
TECH.PROCESS.P: 12,
TECH.PROCESS.NPLUS: 13,
TECH.PROCESS.PPLUS: 14,
TECH.PROCESS.CON: 15,
TECH.PROCESS.GE: 16,
TECH.PROCESS.NONE: 100
}
#create a dictionary with all the simulation parameters
params = dict()
#resolution for matrix discretization, used when interfacing the component's virtually fabricated geometry to CAMFR
params[
"resolution"] = 50 #this generates quite a large number of slabs, but apparently CAMFR behaves stable...
#define a window spanning the section for which we want to create a CAMFR stack
params["window_size_info"] = SizeInfo(west=-62.301,
east=-0.01,
south=-2.8,
north=2.8)
#prepare the CAMFR engine
import camfr
from pysimul.runtime.camfr_engine.camfr_engine import CamfrEngine
engine = CamfrEngine()
camfr_technology = TechnologyTree()
camfr_technology.POLARIZATION = camfr.TM # use for top-down simulations
camfr_technology.NMODES = 10 #we can see convergence when increasing the number of modes to 20, 30, ... : the result doesn't change
camfr_technology.PML = -0.05
camfr_technology.WAVELENGTH = 1.54735 #wavelength in micrometer
engine.set_camfr_settings(camfr_technology)
params["engine"] = engine
#set up the simulation
simul_camfr = aperture.create_simulation(simul_params=params)
#run the simulation and extract the fields at x = -0.01 (in the coordinate system of the original component, see the GDS)
f = simul_camfr.procedure.run(field_extraction_geometry_x_positions=[-0.01])
#look in trunk/pysimul_camfr_output for plots of the fields
print "Done with CAMFR simulation"
#------------- Simulation with Meep----------------------
from pysimul.runtime.MeepFDTD import *
TECH.MATERIAL_STACKS.MSTACK_SOI_SI_80nm.effective_index_epsilon = 1.936**2
TECH.MATERIAL_STACKS.MSTACK_SOI_SI_150nm.effective_index_epsilon = 2.539**2
TECH.MATERIAL_STACKS.MSTACK_SOI_SI_220nm.effective_index_epsilon = 2.844**2
TECH.MATERIAL_STACKS.MSTACK_SOI_SI_380nm.effective_index_epsilon = 3.158**2
TECH.MATERIAL_STACKS.MSTACK_SOI_AIR.effective_index_epsilon = 1.0
####################################################################
# VIRTUAL FABRICATION
####################################################################
from ipkiss.plugins.vfabrication.process_flow import VFabricationProcessFlow
TECH.VFABRICATION = TechnologyTree()
TECH.VFABRICATION.PROCESS_FLOW = VFabricationProcessFlow(
active_processes=[
TECH.PROCESS.RFC, TECH.PROCESS.FCW, TECH.PROCESS.FC, TECH.PROCESS.WG,
TECH.PROCESS.SLOT
], # DO NOT CHANGE THE SEQUENCE OF THE ELEMENTS ! IT MUST MATCH THE SEQUENCE OF THE COLUMNS IN VFABRICATION PROPERTY process_to_material_stack_map
process_to_material_stack_map
= #RFC, FCW, FC, WG, SLOT (SLOT process is equivalent to WG.... )
#SLOT=0
[
((0, 0, 0, 0, 0), TECH.MATERIAL_STACKS.MSTACK_SOI_SI_380nm),
((0, 0, 0, 1, 0), TECH.MATERIAL_STACKS.MSTACK_SOI_SI_380nm),
((0, 0, 1, 0, 0), TECH.MATERIAL_STACKS.MSTACK_SOI_SI_380nm
), # Only a problem if the hardmask gets etched through
((0, 0, 1, 1, 0), TECH.MATERIAL_STACKS.MSTACK_SOI_SI_380nm
# BEOL
TECH.PROCESS.EXPO = ProcessLayer("BEOL etch for waveguide exposure", "EXPO")
TECH.PROCESS.LPASS = ProcessLayer("BEOL etch for grating couplers and edge couplers", "LPASS")
TECH.PROCESS.PASS2 = ProcessLayer("Open passivation on bond pads", "PASS2")
TECH.PROCESS.TRENCH = ProcessLayer("Deep trench","TRENCH")
# Auxiliary
TECH.PROCESS.NONE = ProcessLayer(name="No specific process", extension="NONE")
###########################
# Drawing pattern purposes
###########################
from ipkiss.process.layer import PatternPurpose
TECH.PURPOSE = TechnologyTree()
# actual mask drawings
TECH.PURPOSE.DRAWING = PatternPurpose(name="Drawing", extension="DRAWING")
TECH.PURPOSE.CORE = PatternPurpose(name="Waveguide core", extension="COR")
TECH.PURPOSE.CLADDING = PatternPurpose(name="Waveguide cladding", extension="CLD")
TECH.PURPOSE.TRENCH = PatternPurpose(name="Etched trench (linear)", extension="TRE")
TECH.PURPOSE.HOLE = PatternPurpose(name="Etched hole (polygon)", extension="HOL")
TECH.PURPOSE.INVERSION = PatternPurpose(name = "Inversion", extension = "INV")
# ipkiss defined keys
TECH.PURPOSE.LF = TechnologyTree()
TECH.PURPOSE.DF = TechnologyTree()
TECH.PURPOSE.LF_AREA = PatternPurpose(name="Light-field area", extension="LFAREA")
TECH.PURPOSE.DF_AREA = PatternPurpose(name="Dark-field area", extension="DFAREA")
TECH.PURPOSE.LF.LINE = PatternPurpose(name="Light-field line", extension="LFLINE")
TECH.PURPOSE.DF.LINE = PatternPurpose(name="Dark-field line", extension="DFLINE")
TECH.PURPOSE.DF.POLYGON = PatternPurpose(name="Dark-field polygon", extension="POLYGON")
from ipkiss.technology.technology import TechnologyTree TECH = get_technology() TECH.PROCESS.HFW = TECH.PROCESS.NONE TECH.PROCESS.SIL = TECH.PROCESS.SAL TECH.PROCESS.P = TECH.PROCESS.P1 TECH.PROCESS.N = TECH.PROCESS.N1 ############################################################################################ # Modulators # # This file contains default settings for modulator devices ############################################################################################ TECH.MODULATORS = TechnologyTree() TECH.MODULATORS.PHASESHIFTER = TechnologyTree() # Defaults common to LAT and LONG PN junctions TECH.MODULATORS.PHASESHIFTER.PN = TechnologyTree() TECH.MODULATORS.PHASESHIFTER.PN.P_WIDTH = 2.0 TECH.MODULATORS.PHASESHIFTER.PN.PPLUS_OFFSET = 3.0 TECH.MODULATORS.PHASESHIFTER.PN.PPLUS_WIDTH = 2.0 TECH.MODULATORS.PHASESHIFTER.PN.PPLUS_EXTENSION = 0.25 TECH.MODULATORS.PHASESHIFTER.PN.N_WIDTH = 2.0 TECH.MODULATORS.PHASESHIFTER.PN.NPLUS_OFFSET = 3.0 TECH.MODULATORS.PHASESHIFTER.PN.NPLUS_WIDTH = 2.0 TECH.MODULATORS.PHASESHIFTER.PN.NPLUS_EXTENSION = 0.25 TECH.MODULATORS.PHASESHIFTER.PN.P_SIL_OFFSET = 3.2 TECH.MODULATORS.PHASESHIFTER.PN.P_SIL_WIDTH = 1.6 TECH.MODULATORS.PHASESHIFTER.PN.P_SIL_EXTENSION = 0.2
# # i-depot BBIE 7396, 7556, 7748 # # Contact: [email protected] from technologies.si_photonics.picazzo.default import * from ipkiss.all import * ################# STEP 1 : DEFINE THE NEW PROCESSES ############################### from ipkiss.technology.technology import TechnologyLibrary, TechnologyTree, DelayedInitTechnologyTree TECH.PROCESS.ACL = ProcessLayer("Active Cladding", "ACL") TECH.PROCESS.ACO = ProcessLayer("Active Core", "ACO") TECH.PURPOSE.ACTIVE = PatternPurpose("Active material", "ACT") TECH.PPLAYER.ACL = TechnologyTree() TECH.PPLAYER.ACO = TechnologyTree() TECH.PPLAYER.ACL.DEFAULT = ProcessPurposeLayer( TECH.PROCESS.ACL, TECH.PURPOSE.ACTIVE, name="ACL") TECH.PPLAYER.ACL.ALL = TECH.PPLAYER.ACL.DEFAULT TECH.PPLAYER.ACL.ALL.NAME = "ACL_ALL" TECH.PPLAYER.ACO.DEFAULT = ProcessPurposeLayer( TECH.PROCESS.ACO, TECH.PURPOSE.ACTIVE, name="ACO") TECH.PPLAYER.ACO.ALL = TECH.PPLAYER.ACO.DEFAULT TECH.PPLAYER.ACO.ALL.NAME = "ACO_ALL" TECH.GDSII.EXPORT_LAYER_MAP.process_layer_map[TECH.PROCESS.ACL] = 37 TECH.GDSII.EXPORT_LAYER_MAP.process_layer_map[TECH.PROCESS.ACO] = 43 TECH.GDSII.EXPORT_LAYER_MAP.purpose_datatype_map[TECH.PURPOSE.ACTIVE] = 0
def initialize(self):
from ipkiss3.pcell.trace.transitions.auto_transition.auto_transition_db import AutoTransitionDatabase
db = AutoTransitionDatabase()
self.AUTO_TRANSITION_DATABASE = db
TECH.PCELLS.TRANSITION = TransitionTree()
# Generic traces - required for Ipkiss.
# ##################################################################################################
# WARNING: The constants below are not used in the imec PDK. They're only required for IPKISS. #
# ##################################################################################################
TECH.TRACE = TechnologyTree()
TECH.TRACE.DEFAULT_LAYER = TECH.PPLAYER.WG.COR
TECH.TRACE.CONTROL_SHAPE_LAYER = TECH.PPLAYER.WG.TRACE
TECH.TRACE.BEND_RADIUS = 5.0
TECH.TRACE.DRAW_CONTROL_SHAPE = False
TECH.DEFAULT_WAVELENGTH = 1.55
TECH.WG_DEFAULTS = TechnologyTree()
TECH.WG_DEFAULTS.N_EFF = 2.4
TECH.WG_DEFAULTS.N_GROUP = 4.3
TECH.WG_DEFAULTS.LOSS_DB_PERM = 200.0
TECH.WG_DEFAULTS.CORE_LAYER = TECH.PPLAYER.WG.COR
TECH.WG.CORE_WIDTH = 0.4
# TECH.WG.CLADDING_WIDTH = 4.0
from ipkiss.all import *
from ipkiss.technology.technology import TechnologyTree
import copy
from ipkiss.process import PPLayer
from ipkiss.process.layer import ProcessLayer
from ipkiss.process.layer import PatternPurpose
from ipkiss.plugins.photonics.wg.basic import * # basic waveguides
from picazzo.io.column import * # StdIO
DT_LINE = 0
DT_SQUARE = 1
DT_HEX = 2
DT_INV = 3
MY_TECH = TechnologyTree()
MY_TECH.PROCESS = TechnologyTree()
MY_TECH.PROCESS.OL35_1 = ProcessLayer("Overlay With III-V etch 1", "OL35_1")
MY_TECH.PROCESS.OL35_2 = ProcessLayer("Overlay With III-V etch 2", "OL35_2")
MY_TECH.PROCESS.BCB_1 = ProcessLayer("Bcb etch1", "BCB_1")
MY_TECH.PROCESS.BCB_2 = ProcessLayer("Bcb etch2", "BCB_2")
MY_TECH.PROCESS.MET_1 = ProcessLayer("Metalization etch1", "MET_1")
MY_TECH.PROCESS.MET_2 = ProcessLayer("Metalization etch2", "MET_2")
MY_TECH.PROCESS.MET_3 = ProcessLayer("Metalization etch3", "MET_3")
MY_TECH.PROCESS.MET_4 = ProcessLayer("Metalization etch4", "MET_4")
MY_TECH.PURPOSE = TechnologyTree()
MY_TECH.PURPOSE.DEFAULT = PatternPurpose(name = "Default", extension = "00")
MY_OUTPUT_MAP = copy.deepcopy(TECH.GDSII.EXPORT_LAYER_MAP)
edgewidth=1.0)
DISPLAY_GREEN_SPARSE = DisplayStyle(color=color.COLOR_GREEN,
stipple=stipple.STIPPLE_LINES_DIAGONAL_L,
alpha=0.5,
edgewidth=1.0)
DISPLAY_DARKSEY_GREEN = DisplayStyle(color=color.COLOR_DARKSEA_GREEN,
stipple=stipple.STIPPLE_FILLED,
alpha=0.5,
edgewidth=1.0)
DISPLAY_DARKSEY_GREEN_SPARSE = DisplayStyle(
color=color.COLOR_DARKSEA_GREEN,
stipple=stipple.STIPPLE_LINES_DIAGONAL_L,
alpha=0.5,
edgewidth=1.0)
TECH.DISPLAY = TechnologyTree()
style_set = DisplayStyleSet()
style_set.background = DISPLAY_WHITE
process_display_order = [
TECH.PROCESS.WG, TECH.PROCESS.FC, TECH.PROCESS.SKT, TECH.PROCESS.FCW,
TECH.PROCESS.PBODY, TECH.PROCESS.NBODY, TECH.PROCESS.P1, TECH.PROCESS.N1,
TECH.PROCESS.P2, TECH.PROCESS.N2, TECH.PROCESS.PPLUS, TECH.PROCESS.NPLUS,
TECH.PROCESS.SAL, TECH.PROCESS.PCON, TECH.PROCESS.M1, TECH.PROCESS.VIA12,
TECH.PROCESS.M2, TECH.PROCESS.PASS1, TECH.PROCESS.METPASS,
TECH.PROCESS.EXPO, TECH.PROCESS.LPASS, TECH.PROCESS.PASS2,
TECH.PROCESS.TRENCH, TECH.PROCESS.NONE
]
style_set += [
############################################################################################ # Design rule and dimension settings: # # This file contains default settings which are used throughout IPKISS and PICAZZO # - Some global settings # - Per process layer settings, like minimum width, default width, default bend radius, .... ############################################################################################ from ipkiss.technology import get_technology from ipkiss.technology.technology import TechnologyTree from ipkiss.geometry.shapes.basic import ShapeRectangle from ipkiss.geometry.coord import Coord2 TECH = get_technology() TECH.TECH = TechnologyTree() TECH.TECH.MINIMUM_LINE = 0.130 TECH.TECH.MINIMUM_SPACE = 0.150 ############ # WG ############ TECH.WG = TechnologyTree() TECH.WG.CORE_WIDTH = 0.4 # Default waveguide width on WG layer (core) TECH.WG.WIRE_WIDTH = TECH.WG.CORE_WIDTH # ipkiss3 compatibility TECH.WG.CLADDING_WIDTH = 5.0 TECH.WG.SPACING = 2.0 # Default waveguide spacing (center-to-center) TECH.WG.SHORT_STRAIGHT = 2.0 # Default length of a short straight waveguide, used in routing algorithms TECH.WG.SHORT_TRANSITION_LENGTH = 5.0 # Default length of simple transitions (tapers) TECH.WG.EXPANDED_WIDTH = 0.8 # Default width of expanded waveguides (used in automatically flaring out waveguides) TECH.WG.EXPANDED_STRAIGHT = 5.0 # Default length of a straight for an expanded waveguide (used in automatically flairing out waveguides)
TECH.PROCESS.NO_INSP = ProcessLayer(name="", extension="NO_INSP")
TECH.PROCESS.MASKBRD = ProcessLayer(name="", extension="MASKBRD")
TECH.PROCESS.WAFERBRD = ProcessLayer(name="", extension="WAFERBRD")
#Required for IPKISS compatibility
TECH.PROCESS.NONE = ProcessLayer("No specific process", "NONE")
#Required for PICAZZO compatibility
TECH.PROCESS.SK = TECH.PROCESS.FC = TECH.PROCESS.SHALL
TECH.PROCESS.WG = TECH.PROCESS.FULL
###########################
# Drawing pattern purposes
###########################
from ipkiss.process.layer import PatternPurpose
TECH.PURPOSE = TechnologyTree()
# actual mask drawings
TECH.PURPOSE.DRAWETCH = PatternPurpose(name="Waveguide cladding",
extension="DRAWETCH")
TECH.PURPOSE.PERF = PatternPurpose(name="Waveguide core", extension="PERF")
TECH.PURPOSE.PERFSLOT = PatternPurpose(name="Slot etched on waveguide core",
extension="PERFSLOT")
TECH.PURPOSE.DRAWING = PatternPurpose(name="", extension="DRAWING")
# auxiliary data
TECH.PURPOSE.POLTXT = PatternPurpose(name="", extension="POLTXT")
TECH.PURPOSE.TILING = PatternPurpose(name="", extension="TILING")
TECH.PURPOSE.DATAPREP = PatternPurpose(name="", extension="DATAPREP")
TECH.PURPOSE.NOFILL = PatternPurpose(name="", extension="NOFILL")
TECH.PURPOSE.NOSIZE = PatternPurpose(name="", extension="NOSIZE")
TECH.PURPOSE.NODRC = PatternPurpose(name="", extension="NODRC")
# ipkiss defined keys
# # TECH = get_technology()
#
# import LayerDefinitions
from ipkiss.process import ProcessLayer, ProcessPurposeLayer, PatternPurpose
TECH = i3.TECH
# Create 1 new process and 2 new purposes and add them to the TECH tree
new_process = ProcessLayer(name="NEW_PROCESS", extension="NEWP")
new_purpose_1 = PatternPurpose(name="PATTERN_1", extension="PAT_1")
new_purpose_2 = PatternPurpose(name="PATTERN_2", extension="PAT_2")
TECH.PROCESS.NEW_PROCESS = new_process
TECH.PPLAYER.NEW_PROCESS = TechnologyTree()
# Combine the process and purposes into PPlayers and add them to the TECH tree.
TECH.PPLAYER.NEW_PROCESS.PP1 = ProcessPurposeLayer(process=new_process,
purpose=new_purpose_1,
name="PP1")
TECH.PPLAYER.NEW_PROCESS.PP2 = ProcessPurposeLayer(process=new_process,
purpose=new_purpose_2,
name="PP2")
# Add the layer to the GDSII import/export rules.
# These are the GDSII process and purpose numbers used in your existing gdsii files.
gdsii_maps = {
(new_process, new_purpose_1): (99, 1),
(new_process, new_purpose_2): (99, 2)
TECH.PROCESS.NONE = ProcessLayer("No specific process", "NONE")
# The following keys are required by ipkiss / picazzo but not used actively by aeponyx
TECH.PROCESS.WG = TECH.PROCESS.MSN # Required for ipkiss, picazzo
TECH.PROCESS.RWG = TECH.PROCESS.SHALLOW # Required by picazzo
TECH.PROCESS.FC = TECH.PROCESS.SHALLOW # Required by picazzo (grating couplers)
# ###############################################################
# TECH.PURPOSE: Layer Purposes
#
# Layer Purposes indicate what the meaning is of a pattern on a
# given process layer. e.g. a Line, a documentation, ...
#
# ###############################################################
TECH.PURPOSE = TechnologyTree()
TECH.PURPOSE.DRAWING = PatternPurpose(name="Drawing", extension="DRW")
TECH.PURPOSE.DRWSUB = PatternPurpose(name="Subtracted drawing",
extension="DRWSUB")
TECH.PURPOSE.BBOX = PatternPurpose(name="Bounding Box", extension="BBOX")
TECH.PURPOSE.ERROR = PatternPurpose(name="Error",
extension="ERR",
doc="Errors")
TECH.PURPOSE.PINREC = PatternPurpose(name="Pin recognition",
extension="PIN",
doc="Pin marker for extraction")
TECH.PURPOSE.TRACE = PatternPurpose(name="Trace",
extension="TRC",
doc="Control shape of trace")
