ext/dsent/tech/tech_models/Bulk32LVT.model - public/gem5 - Git at Google

 # Copyright (c) 2012 Massachusetts Institute of Technology
 #
 # Permission is hereby granted, free of charge, to any person obtaining a copy
 # of this software and associated documentation files (the "Software"), to deal
 # in the Software without restriction, including without limitation the rights
 # to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
 # copies of the Software, and to permit persons to whom the Software is
 # furnished to do so, subject to the following conditions:
 #
 # The above copyright notice and this permission notice shall be included in
 # all copies or substantial portions of the Software.
 #
 # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 # IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 # FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
 # AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 # LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
 # OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
 # THE SOFTWARE.

 # WARNING: Most commercial fabs will not be happy if you release their exact
 # process information! If you derive these numbers through SPICE models,
 # the process design kit, or any other confidential material, please round-off
 # the values and leave the process name unidentifiable by fab (i.e. call it
 # Bulk90LVT instead of TSMC90LVT) if you release parameters publicly. This
 # rule may not apply for open processes, but you may want to check.

 # All units are in SI, (volts, meters, kelvin, farads, ohms, amps, etc.)

 # This file contains the model for a bulk 32nm LVT process
 Name = Bulk32LVT

 # Supply voltage used in the circuit and for characterizations (V)
 Vdd = 0.9
 # Temperature (K)
 Temperature = 340

 # =============================================================================
 # Parameters for transistors
 # =============================================================================

 # Contacted gate pitch (m)
 Gate->PitchContacted = 0.160e-6

 # Min gate width (m)
 Gate->MinWidth = 0.120e-6

 # Gate cap per unit width (F/m)
 Gate->CapPerWidth = 0.950e-9
 # Source/Drain cap per unit width (F/m)
 Drain->CapPerWidth = 0.640e-9

 # Parameters characterization temperature (K)
 Nmos->CharacterizedTemperature = 300.0
 Pmos->CharacterizedTemperature = 300.0

 #------------------------------------------------------------------------------
 # I_Eff definition in Na, IEDM 2002
 #       I_EFF = (I(VG = 0.5, VD = 1.0) + I(VG = 1.0, VD = 0.5))/2
 #       R_EFF = VDD / I_EFF * 1 / (2 ln(2))
 # This is generally accurate for when input and output transition times
 # are similar, which is a reasonable case after timing optimization
 #------------------------------------------------------------------------------
 # Effective resistance (Ohm-m)
 Nmos->EffResWidth = 0.890e-3
 Pmos->EffResWidth = 1.270e-3

 #------------------------------------------------------------------------------
 # The ratio of extra effective resistance with each additional stacked
 # transistor
 #       EffResStackRatio = (R_EFF_NAND2 - R_EFF_INV) / R_EFF_INV)
 # For example, inverter has an normalized effective drive resistance of 1.0.
 # A NAND2 (2-stack) will have an effective drive of 1.0 + 0.7, a NAND3 (3-stack)
 # will have an effective drive of 1.0 + 2 * 0.7. Use NORs for Pmos. This fit
 # works relatively well up to 4 stacks. This value will change depending on the
 # VDD used.
 #------------------------------------------------------------------------------
 # Effective resistance stack ratio
 Nmos->EffResStackRatio = 0.78
 Pmos->EffResStackRatio = 0.66

 #------------------------------------------------------------------------------
 # I_OFF defined as |I_DS| for |V_DS| = V_DD and |V_GS| = 0.0
 #       Minimum off current is used as a second fit point, since I_OFF often
 #       stops scaling with transistor width below some threshold
 #------------------------------------------------------------------------------
 # Off current per width (A/m)
 Nmos->OffCurrent = 100e-3
 Pmos->OffCurrent = 100e-3

 # Minimum off current (A)
 Nmos->MinOffCurrent = 100e-9
 Pmos->MinOffCurrent = 20e-9

 # Subthreshold swing (V/dec)
 Nmos->SubthresholdSwing = 0.100
 Pmos->SubthresholdSwing = 0.100

 # DIBL factor (V/V)
 Nmos->DIBL = 0.150
 Pmos->DIBL = 0.150

 # Subthreshold leakage temperature swing (K/dec)
 Nmos->SubthresholdTempSwing = 100
 Pmos->SubthresholdTempSwing = 100
 #------------------------------------------------------------------------------

 # =============================================================================
 # Parameters for interconnect
 # =============================================================================

 Wire->AvailableLayers = [Metal1,Local,Intermediate,Global]

 # Metal 1 Wire (used for std cell routing only)
 # Min width (m)
 Wire->Metal1->MinWidth = 55e-9
 # Min spacing (m)
 Wire->Metal1->MinSpacing = 55e-9
 # Resistivity (Ohm-m)
 Wire->Metal1->Resistivity = 4.00e-8
 # Metal thickness (m)
 Wire->Metal1->MetalThickness = 100.0e-9
 # Dielectric thickness (m)
 Wire->Metal1->DielectricThickness = 100.0e-9
 # Dielectric constant
 Wire->Metal1->DielectricConstant = 3.2

 # Local wire, 1.0X of the M1 pitch
 # Min width (m)
 Wire->Local->MinWidth = 55e-9
 # Min spacing (m)
 Wire->Local->MinSpacing = 55e-9
 # Resistivity (Ohm-m)
 Wire->Local->Resistivity = 4.00e-8
 # Metal thickness (m)
 Wire->Local->MetalThickness = 100.0e-9
 # Dielectric thickness (m)
 Wire->Local->DielectricThickness = 100.0e-9
 # Dielectric constant
 Wire->Local->DielectricConstant = 3.2

 # Intermediate wire, 2.0X the M1 pitch
 # Min width (m)
 Wire->Intermediate->MinWidth = 110e-9
 # Min spacing (m)
 Wire->Intermediate->MinSpacing = 110e-9
 # Resistivity (Ohm-m)
 Wire->Intermediate->Resistivity = 2.60e-8
 # Metal thickness (m)
 Wire->Intermediate->MetalThickness = 200e-9
 # Dielectric thickness (m)
 Wire->Intermediate->DielectricThickness = 170e-9
 # Dielectric constant
 Wire->Intermediate->DielectricConstant = 3.00

 # Global wire, 3.0X the M1 pitch
 # Min width (m)
 Wire->Global->MinWidth = 160e-9
 # Min spacing (m)
 Wire->Global->MinSpacing = 160e-9
 # Resistivity (Ohm-m)
 Wire->Global->Resistivity = 2.30e-8
 # Metal thickness (m)
 Wire->Global->MetalThickness = 280e-9
 # Dielectric thickness (m)
 Wire->Global->DielectricThickness = 250e-9
 # Dielectric constant
 Wire->Global->DielectricConstant = 2.80

 # =============================================================================
 # Parameters for Standard Cells
 # =============================================================================

 # The height of the standard cell is usually a multiple of the vertical
 # M1 pitch (tracks). By definition, an X1 size cell has transistors
 # that fit exactly in the given cell height without folding, or leaving
 # any wasted vertical area

 # Reasonable values for the number of M1 tracks that we have seen are 8-14
 StdCell->Tracks = 11
 # Height overhead due to supply rails, well spacing, etc. Note that this will grow
 # if the height of the standard cell decreases!
 StdCell->HeightOverheadFactor = 1.400

 # Sets the available sizes of each standard cell. Keep in mind that
 # 1.0 is the biggest cell without any transistor folding
 StdCell->AvailableSizes = [1.0, 1.4, 2.0, 3.0, 4.0, 6.0, 8.0, 10.0, 12.0, 16.0]
	# Copyright (c) 2012 Massachusetts Institute of Technology
	#
	# Permission is hereby granted, free of charge, to any person obtaining a copy
	# of this software and associated documentation files (the "Software"), to deal
	# in the Software without restriction, including without limitation the rights
	# to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
	# copies of the Software, and to permit persons to whom the Software is
	# furnished to do so, subject to the following conditions:
	#
	# The above copyright notice and this permission notice shall be included in
	# all copies or substantial portions of the Software.
	#
	# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
	# IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
	# FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
	# AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
	# LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
	# OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
	# THE SOFTWARE.

	# WARNING: Most commercial fabs will not be happy if you release their exact
	# process information! If you derive these numbers through SPICE models,
	# the process design kit, or any other confidential material, please round-off
	# the values and leave the process name unidentifiable by fab (i.e. call it
	# Bulk90LVT instead of TSMC90LVT) if you release parameters publicly. This
	# rule may not apply for open processes, but you may want to check.

	# All units are in SI, (volts, meters, kelvin, farads, ohms, amps, etc.)

	# This file contains the model for a bulk 32nm LVT process
	Name = Bulk32LVT

	# Supply voltage used in the circuit and for characterizations (V)
	Vdd = 0.9
	# Temperature (K)
	Temperature = 340

	# =============================================================================
	# Parameters for transistors
	# =============================================================================

	# Contacted gate pitch (m)
	Gate->PitchContacted = 0.160e-6

	# Min gate width (m)
	Gate->MinWidth = 0.120e-6

	# Gate cap per unit width (F/m)
	Gate->CapPerWidth = 0.950e-9
	# Source/Drain cap per unit width (F/m)
	Drain->CapPerWidth = 0.640e-9

	# Parameters characterization temperature (K)
	Nmos->CharacterizedTemperature = 300.0
	Pmos->CharacterizedTemperature = 300.0

	#------------------------------------------------------------------------------
	# I_Eff definition in Na, IEDM 2002
	# I_EFF = (I(VG = 0.5, VD = 1.0) + I(VG = 1.0, VD = 0.5))/2
	# R_EFF = VDD / I_EFF * 1 / (2 ln(2))
	# This is generally accurate for when input and output transition times
	# are similar, which is a reasonable case after timing optimization
	#------------------------------------------------------------------------------
	# Effective resistance (Ohm-m)
	Nmos->EffResWidth = 0.890e-3
	Pmos->EffResWidth = 1.270e-3

	#------------------------------------------------------------------------------
	# The ratio of extra effective resistance with each additional stacked
	# transistor
	# EffResStackRatio = (R_EFF_NAND2 - R_EFF_INV) / R_EFF_INV)
	# For example, inverter has an normalized effective drive resistance of 1.0.
	# A NAND2 (2-stack) will have an effective drive of 1.0 + 0.7, a NAND3 (3-stack)
	# will have an effective drive of 1.0 + 2 * 0.7. Use NORs for Pmos. This fit
	# works relatively well up to 4 stacks. This value will change depending on the
	# VDD used.
	#------------------------------------------------------------------------------
	# Effective resistance stack ratio
	Nmos->EffResStackRatio = 0.78
	Pmos->EffResStackRatio = 0.66

	#------------------------------------------------------------------------------
	# I_OFF defined as \|I_DS\| for \|V_DS\| = V_DD and \|V_GS\| = 0.0
	# Minimum off current is used as a second fit point, since I_OFF often
	# stops scaling with transistor width below some threshold
	#------------------------------------------------------------------------------
	# Off current per width (A/m)
	Nmos->OffCurrent = 100e-3
	Pmos->OffCurrent = 100e-3

	# Minimum off current (A)
	Nmos->MinOffCurrent = 100e-9
	Pmos->MinOffCurrent = 20e-9

	# Subthreshold swing (V/dec)
	Nmos->SubthresholdSwing = 0.100
	Pmos->SubthresholdSwing = 0.100

	# DIBL factor (V/V)
	Nmos->DIBL = 0.150
	Pmos->DIBL = 0.150

	# Subthreshold leakage temperature swing (K/dec)
	Nmos->SubthresholdTempSwing = 100
	Pmos->SubthresholdTempSwing = 100
	#------------------------------------------------------------------------------

	# =============================================================================
	# Parameters for interconnect
	# =============================================================================

	Wire->AvailableLayers = [Metal1,Local,Intermediate,Global]

	# Metal 1 Wire (used for std cell routing only)
	# Min width (m)
	Wire->Metal1->MinWidth = 55e-9
	# Min spacing (m)
	Wire->Metal1->MinSpacing = 55e-9
	# Resistivity (Ohm-m)
	Wire->Metal1->Resistivity = 4.00e-8
	# Metal thickness (m)
	Wire->Metal1->MetalThickness = 100.0e-9
	# Dielectric thickness (m)
	Wire->Metal1->DielectricThickness = 100.0e-9
	# Dielectric constant
	Wire->Metal1->DielectricConstant = 3.2

	# Local wire, 1.0X of the M1 pitch
	# Min width (m)
	Wire->Local->MinWidth = 55e-9
	# Min spacing (m)
	Wire->Local->MinSpacing = 55e-9
	# Resistivity (Ohm-m)
	Wire->Local->Resistivity = 4.00e-8
	# Metal thickness (m)
	Wire->Local->MetalThickness = 100.0e-9
	# Dielectric thickness (m)
	Wire->Local->DielectricThickness = 100.0e-9
	# Dielectric constant
	Wire->Local->DielectricConstant = 3.2

	# Intermediate wire, 2.0X the M1 pitch
	# Min width (m)
	Wire->Intermediate->MinWidth = 110e-9
	# Min spacing (m)
	Wire->Intermediate->MinSpacing = 110e-9
	# Resistivity (Ohm-m)
	Wire->Intermediate->Resistivity = 2.60e-8
	# Metal thickness (m)
	Wire->Intermediate->MetalThickness = 200e-9
	# Dielectric thickness (m)
	Wire->Intermediate->DielectricThickness = 170e-9
	# Dielectric constant
	Wire->Intermediate->DielectricConstant = 3.00

	# Global wire, 3.0X the M1 pitch
	# Min width (m)
	Wire->Global->MinWidth = 160e-9
	# Min spacing (m)
	Wire->Global->MinSpacing = 160e-9
	# Resistivity (Ohm-m)
	Wire->Global->Resistivity = 2.30e-8
	# Metal thickness (m)
	Wire->Global->MetalThickness = 280e-9
	# Dielectric thickness (m)
	Wire->Global->DielectricThickness = 250e-9
	# Dielectric constant
	Wire->Global->DielectricConstant = 2.80

	# =============================================================================
	# Parameters for Standard Cells
	# =============================================================================

	# The height of the standard cell is usually a multiple of the vertical
	# M1 pitch (tracks). By definition, an X1 size cell has transistors
	# that fit exactly in the given cell height without folding, or leaving
	# any wasted vertical area

	# Reasonable values for the number of M1 tracks that we have seen are 8-14
	StdCell->Tracks = 11
	# Height overhead due to supply rails, well spacing, etc. Note that this will grow
	# if the height of the standard cell decreases!
	StdCell->HeightOverheadFactor = 1.400

	# Sets the available sizes of each standard cell. Keep in mind that
	# 1.0 is the biggest cell without any transistor folding
	StdCell->AvailableSizes = [1.0, 1.4, 2.0, 3.0, 4.0, 6.0, 8.0, 10.0, 12.0, 16.0]