Download 20100425_Library_Netlists

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

page
1
page
2
page
3
page
4
page
5
page
6
Document related concepts
no text concepts found
Transcript 
Library Netlists
Inverter (ece3663Inverter)
// Cell name: ece3663Inverter
//
An inverter with sizing parameters and parameterized AD,AS,PD,PS
//
The S/D parameters assume a single-finger device
subckt ece3663Inverter VDD VSS in out
parameters wp=3u wn=1.5u ln=600n lp=600n mult=1
MP (out in VDD VDD) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp ps=3u+wp
MN (out in VSS VSS) ami06N w=wn l=ln as=1.5u*wn ad=1.5u*wn ps=3u+wn
ends ece3663Inverter
// End of subcircuit definition
pd=3u+wp m=mult
pd=3u+wn m=mult
2-input NAND (ece3663NAND2)
// Cell name: ece3663NAND2
// modified by Team XOR on 3/31/10 to fix naming convention and size for equal PUN/PDN resistances
subckt ece3663NAND2 Vdd Vss InA InB Out
parameters wp=3u wn=1.5u ln=600n lp=600n mult=1
P1 (Out InB Vdd Vdd) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp ps=3u+wp \
pd=3u+wp m=mult
P0 (Out InA Vdd Vdd) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp ps=3u+wp \
pd=3u+wp m=mult
N1 (net18 InB Vss Vss) ami06N w=2*wn l=ln as=1.5u*2*wn ad=1.5u*2*wn ps=3u+2*wn \
pd=3u+2*wn m=mult
N0 (Out InA net18 Vss) ami06N w=2*wn l=ln as=1.5u*2*wn ad=1.5u*2*wn \
ps=3u+2*wn pd=3u+2*wn m=mult
ends ece3663NAND2
// End of subcircuit definition.
2-input NOR (ece3663NOR2)
// Cell name: ece3663NOR2
// Modified by Team XOR on 3/31/10 to fix naming convention and size for equal PUN/PDN resistances
subckt ece3663NOR2 Vdd Vss InA InB Out
parameters wp=3u wn=1.5u ln=600n lp=600n mult=1
P1 (Out InB net10 Vdd) ami06P w=2*wp l=lp as=1.5u*2*wp ad=1.5u*2*wp ps=3u+2*wp \
pd=3u+2*wp m=mult
P0 (net10 InA Vdd Vdd) ami06P w=2*wp l=lp as=1.5u*2*wp ad=1.5u*2*wp ps=3u+2*wp \
pd=3u+2*wp m=mult
N1 (Out InB Vss Vss) ami06N w=wn l=lp as=1.5u*wn ad=1.5u*wn \
ps=3u+wn pd=3u+wn m=mult
N0 (Out InA Vss Vss) ami06N w=wn l=lp as=1.5u*wn ad=1.5u*wn \
ps=3u+wn pd=3u+wn m=mult
ends ece3663NOR2
// End of subcircuit definition.
2-input AND (ece3663AND2)
// Cell name: ece3663AND2
// Implementation: NAND in series w/ inverter
// Modified 3/17/2010 by Team Mux to correct faults in netlist parameters
// Modified 4/4/2010 by Team Mux to conform to class conventions
subckt ece3663AND2 Vdd Vss InA InB Out
parameters wp=3u wn=1.5u ln=600n lp=600n mult=1
P2 (Out net049 Vdd Vdd) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp \
ps=3u+wp pd=3u+wp m=mult region=sat
P1 (net049 InB Vdd Vdd) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp \
ps=3u+wp pd=3u+wp m=mult region=sat
P0 (net049 InA Vdd Vdd) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp \
ps=3u+wp pd=3u+wp m=mult region=sat
N2 (Out net049 Vss Vss) ami06N w=wn l=ln as=1.5u*wn ad=1.5u*wn \
ps=3u+wn pd=3u+wn m=mult region=sat
N1 (net22 InB Vss Vss) ami06N w=2*wn l=ln as=1.5u*2*wn ad=1.5u*2*wn \
ps=3u+2*wn pd=3u+2*wn m=mult region=sat
N0 (net049 InA net22 Vss) ami06N w=2*wn l=ln as=1.5u*2*wn \
ad=1.5u*2*wn ps=3u+2*wn pd=3u+2*wn m=mult region=sat
ends ece3663AND2
2-input OR (ece3663OR2)
// Cell name: ece3663OR2
//
//
//
//
Implementation: NOR in series with inverter
Modified 3/17/2010 by Team MUX to standardize transistor names
Modified 3/31/2010 by Team XOR to fix naming convention and size for equal PUN/PDN resistances
Modified 4/4/2010 by Team MUX to fix wrong bulk connection and conform to class conventions
subckt ece3663OR2 Vdd Vss InA InB Out
parameters wp=3u wn=1.5u ln=600n lp=600n mult=1
P2 (Out net21 Vdd Vdd) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp ps=3u+wp \
pd=3u+wp m=mult region=sat
P1 (net21 InB net10 Vdd) ami06P w=2*wp l=lp as=1.5u*2*wp ad=1.5u*2*wp ps=3u+2*wp \
pd=3u+2*wp m=mult region=sat
P0 (net10 InA Vdd Vdd) ami06P w=2*wp l=lp as=1.5u*2*wp ad=1.5u*2*wp ps=3u+2*wp \
pd=3u+2*wp m=mult region=sat
N2 (Out net21 Vss Vss) ami06N w=wn l=lp as=1.5u*wn ad=1.5u*wn \
ps=3u+wn pd=3u+wn m=mult region=sat
N1 (net21 InB Vss Vss) ami06N w=wn l=lp as=1.5u*wn ad=1.5u*wn \
ps=3u+wn pd=3u+wn m=mult region=sat
N0 (net21 InA Vss Vss) ami06N w=wn l=lp as=1.5u*wn ad=1.5u*wn \
ps=3u+wn pd=3u+wn m=mult region=sat
ends ece3663OR2
2-input XOR (ece3663XOR2)
// Cell name: ece3663XOR2
// An implementation of a two input XOR =A'*B+A*B'=((A'*B)'*(A*B')')'
//
//
//
//
Inputs to the XOR are named "A" and "B"
Output of the XOR is named "out"
High voltage is named "VDD"
Low voltage (ground) is named "VSS"
//subsubcircuit inverters used have been sized to make worst-case PUN resistance and worst-case
PDN resistance the same
//subsubcircuit NANDs used have been sized to make worst-case PUN resistance and worst-case PDN
resistance the same
//edited by Team ADD at 10:38 p.m. on Sunday, 4 April 2010
subckt ece3663XOR2 VDD VSS A B out
parameters wpGlobal=3u wnGlobal=1.5u lnGlobal=600n lpGlobal=600n multGlobal=1
//subsubcircuits that invert the inputs
//inverter for input A
invA (VDD VSS A notA) ece3663Inverter wp=wpGlobal wn=wnGlobal ln=lnGlobal lp=lpGlobal
mult=multGlobal
//inverter for input B
invB (VDD VSS B notB) ece3663Inverter wp=wpGlobal wn=wnGlobal ln=lnGlobal lp=lpGlobal
mult=multGlobal
//basically first input NAND
p1comma1 (intermediate1 notA VDD VDD) ami06P w=wpGlobal l=lpGlobal as=1.5u*wpGlobal
ad=1.5u*wpGlobal ps=3u+wpGlobal pd=3u+wpGlobal m=multGlobal
p1comma2 (intermediate1 B VDD VDD) ami06P w=wpGlobal l=lpGlobal as=1.5u*wpGlobal
ad=1.5u*wpGlobal ps=3u+wpGlobal pd=3u+wpGlobal m=multGlobal
n1comma1 (intermediate1 notA node1 VSS) ami06N w=2*wnGlobal l=lnGlobal as=1.5u*2*wnGlobal
ad=1.5u*2*wnGlobal ps=3u+2*wnGlobal pd=3u+2*wnGlobal m=multGlobal
n1comma2 (node1 B VSS VSS) ami06N w=2*wnGlobal l=lnGlobal as=1.5u*2*wnGlobal ad=1.5u*2*wnGlobal
ps=3u+2*wnGlobal pd=3u+2*wnGlobal m=multGlobal
//basically second input NAND
p2comma1 (intermediate2 A VDD VDD) ami06P w=wpGlobal l=lpGlobal as=1.5u*wpGlobal
ad=1.5u*wpGlobal ps=3u+wpGlobal pd=3u+wpGlobal m=multGlobal
p2comma2 (intermediate2 notB VDD VDD) ami06P w=wpGlobal l=lpGlobal as=1.5u*wpGlobal
ad=1.5u*wpGlobal ps=3u+wpGlobal pd=3u+wpGlobal m=multGlobal
n2comma1 (intermediate2 A node2 VSS) ami06N w=2*wnGlobal l=lnGlobal as=1.5u*2*wnGlobal
ad=1.5u*2*wnGlobal ps=3u+2*wnGlobal pd=3u+2*wnGlobal m=multGlobal
n2comma2 (node2 notB VSS VSS) ami06N w=2*wnGlobal l=lnGlobal as=1.5u*2*wnGlobal
ad=1.5u*2*wnGlobal ps=3u+2*wnGlobal pd=3u+2*wnGlobal m=multGlobal
//basically third combining/output NAND
p3comma1 (out intermediate1 VDD VDD) ami06P w=wpGlobal l=lpGlobal as=1.5u*wpGlobal
ad=1.5u*wpGlobal ps=3u+wpGlobal pd=3u+wpGlobal m=multGlobal
p3comma2 (out intermediate2 VDD VDD) ami06P w=wpGlobal l=lpGlobal as=1.5u*wpGlobal
ad=1.5u*wpGlobal ps=3u+wpGlobal pd=3u+wpGlobal m=multGlobal
n3comma1 (out intermediate1 node3 VSS) ami06N w=2*wnGlobal l=lnGlobal as=1.5u*2*wnGlobal
ad=1.5u*2*wnGlobal ps=3u+2*wnGlobal pd=3u+2*wnGlobal m=multGlobal
n3comma2 (node3 intermediate2 VSS VSS) ami06N w=2*wnGlobal l=lnGlobal as=1.5u*2*wnGlobal
ad=1.5u*2*wnGlobal ps=3u+2*wnGlobal pd=3u+2*wnGlobal m=multGlobal
ends ece3663XOR2
// End of subcircuit definition
2-input XNOR (ece3663XNOR2)
// Cell Name: ece3663XNOR2
// Edited by Team XOR: a 2-input XNOR gate built from other subcircuits
// Has tunable parameters including: wp, wn, lp, ln, and m
// Has parameterized AS, AD, PS, PD
// Implements the function:
XNOR = ((F*G)')'
// where F = B + A'B' and G = A + A'B'
//
//
//
//
not the most efficient implementation, but this is what the 2008 group chose to do.
originally this was made of 18 discrete transistors with a ridiculous netlist that was
very difficult to understand. we've improved this by "packaging" the transistors into
the gates they had essentially created.
subckt ece3663XNOR2 (VDD VSS A B Out)
parameters wp0=3u wn0=1.5u lp0=600n ln0=600n mult0=1
NOR (VDD VSS A B center) ece3663NOR2 wp=wp0 wn=wn0 lp=lp0 ln=ln0 mult=mult0
ORtop (VDD VSS B center F) ece3663OR2 wp=wp0 wn=wn0 lp=lp0 ln=ln0 mult=mult0
ORbottom (VDD VSS A center G) ece3663OR2 wp=wp0 wn=wn0 lp=lp0 ln=ln0 mult=mult0
NAND (VDD VSS F G Outbar) ece3663NAND2 wp=wp0 wn=wn0 lp=lp0 ln=ln0 mult=mult0
INVERTER (VDD VSS Outbar Out) ece3663Inverter wp=wp0 wn=wn0 lp=lp0 ln=ln0 mult=mult0
ends ece3663XNOR2
3-input NAND (ece3663NAND3)
// Cell name: NAND3
// View name: schematic
// Edited by group NOR: 3 input NAND gate with tunable wp, wn, lp, ln, and m
//
Sized for equal pull-up, pull-down to Inv
subckt ece3663NAND3 (VDD VSS A B C OUT)
parameters wp=3u wn=4.5u ln=600n lp=600n mult=1
MNC (NETCB C VSS VSS) ami06N w=wn l=ln as=1.5u*wn ad=1.5u*wn ps=3u+wn \
pd=3u+wn m=mult region=sat
MNB (NETBA B NETCB VSS) ami06N w=wn l=ln as=1.5u*wn ad=1.5u*wn ps=3u+wn \
pd=3u+wn m=mult region=sat
MNA (OUT A NETBA VSS) ami06N w=wn l=ln as=1.5u*wn ad=1.5u*wn ps=3u+wn \
pd=3u+wn m=mult region=sat
MPC (OUT C VDD VDD) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp ps=3u+wp \
pd=3u+wp m=mult region=sat
MPB (OUT B VDD VDD) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp ps=3u+wp \
pd=3u+wp m=mult region=sat
MPA (OUT A VDD VDD) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp ps=3u+wp \
pd=3u+wp m=mult region=sat
ends ece3663NAND3
//END OF subcircuit definition
3-input NOR (ece3663NOR3)
// Cell name: NOR3
// View name: schematic
// Edited by group NOR: 3 input NOR gate with tunable wp, wn, lp, ln, and m
//
Sized for equal pull-up, pull-down to Inv
subckt ece3663NOR3 (VDD VSS A B C out)
parameters wp=9u wn=1.5u ln=600n lp=600n mult=1
MPa (netab A VDD VDD) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp ps=3u+wp \
pd=3u+wp m=mult
MPb (netbc B netab VDD) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp ps=3u+wp \
pd=3u+wp m=mult
MPc (out C netbc VDD) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp ps=3u+wp \
pd=3u+wp m=mult
MNa (out A VSS VSS) ami06N w=wn l=ln as=1.5u*wn ad=1.5u*wn ps=3u+wn \
pd=3u+wn m=mult
MNb (out B VSS VSS) ami06N w=wn l=ln as=1.5u*wn ad=1.5u*wn ps=3u+wn \
pd=3u+wn m=mult
MNc (out C VSS VSS) ami06N w=wn l=ln as=1.5u*wn ad=1.5u*wn ps=3u+wn \
pd=3u+wn m=mult
ends ece3663NOR3
// End of subcircuit definition.
3-input AND (ece3663AND3)
// Cell name: AND3
// View name: schematic
// Edited by group NOR: 3 input AND gate with tunable wp, wn, and m
//
sized for pull-up/pull-down equal to inverter
subckt ece3663AND3 (VDD VSS A B C OUT)
parameters wpA=3u wnA=1.5u multA=1
NAND (VDD VSS A B C Invertin) ece3663NAND3 wp=wpA wn=wnA*3 mult=multA
Inv (VDD VSS Invertin OUT) ece3663Inverter wp=wpA wn=wnA mult=multA
ends ece3663AND3
//end of subcircuit definition
3-input OR (ece3663OR3)
// Cell name: OR3
// View name: schematic
// Edited by group NOR: 3 input OR gate with tunable wp, wn, and m
//
sized for pull-up/pull-down equal to inverter
subckt ece3663OR3 (VDD VSS A B C out)
parameters wpO=3u wnO=1.5u multO=1
NOR (VDD VSS A B C Invertin) ece3663NOR3 wp=wpO*3 wn=wnO mult=multO
Inv (VDD VSS Invertin out) ece3663Inverter wp=wpO wn=wnO mult=multO
ends ece3663OR3
// End of subcircuit definition.
2:1 MUX (ece3663MUX2to1)
// Cell name: ece3663MUX2to1
// Modified by: Team NAND
// improvement: resized NMOS transistors to reduce transmission delay
// 4/23/10 - conformed to class naming convention
//
- fixed sizing mistakes for area and perimeter for NMOS
subckt ece3663MUX2to1 VDD VSS in0 in1 Select out
parameters wp=3u wn=1.5u ln=600n lp=600n mult=1
I0 (VDD VSS Select selectBar) ece3663Inverter wn=wn wp=wp mult=mult
P5 (net15 Select VDD VDD) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp ps=3u+wp \
pd=3u+wp m=mult
P4 (net15 in1 VDD VDD) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp ps=3u+wp \
pd=3u+wp m=mult
P3 (out net15 VDD VDD) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp ps=3u+wp \
pd=3u+wp m=mult
P2 (out net31 VDD VDD) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp ps=3u+wp \
pd=3u+wp m=mult
P1 (net31 in0 VDD VDD) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp ps=3u+wp \
pd=3u+wp m=mult
P0 (net31 selectBar VDD VDD) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp ps=3u+wp \
pd=3u+wp m=mult
N5 (net35 net15 VSS VSS) ami06N w=wn*2 l=ln as=1.5u*2*wn ad=1.5u*2*wn ps=3u+wn*2 \
pd=3u+wn*2 m=mult
N4 (out net31 net35 VSS) ami06N w=wn*2 l=ln as=1.5u*2*wn ad=1.5u*2*wn ps=3u+wn*2 \
pd=3u+wn*2 m=mult
N3 (net43 Select VSS VSS) ami06N w=wn*2 l=ln as=1.5u*2*wn ad=1.5u*2*wn ps=3u+wn*2 \
pd=3u+wn*2 m=mult
N2 (net15 in1 net43 VSS) ami06N w=wn*2 l=ln as=1.5u*2*wn ad=1.5u*2*wn ps=3u+wn*2 \
pd=3u+wn*2 m=mult
N1 (net31 selectBar net55 VSS) ami06N w=wn*2 l=ln as=1.5u*2*wn ad=1.5u*2*wn ps=3u+wn*2 \
pd=3u+wn*2 m=mult
N0 (net55 in0 VSS VSS) ami06N w=wn*2 l=ln as=1.5u*2*wn ad=1.5u*2*wn ps=3u+wn*2 \
pd=3u+wn*2 m=mult
ends ece3663MUX2to1
//end subcircuit definition
4:1 MUX (ece3663MUX4to1)
//Cell name: ece3663MUX4to1
// Modified by: Team NAND
// fixed ability to size mux with variables
// 4/23/10 - conformed to class naming convention
subckt ece3663MUX4to1 VDD VSS in00 in01 in10 in11 Select0 Select1 out
parameters wp=3u wn=1.5u ln=600n lp=600n mult=1
I0 (VDD VSS in00 in01 Select0 net75) ece3663MUX2to1 wn=wn wp=wp mult=mult
I1 (VDD VSS in10 in11 Select0 net79) ece3663MUX2to1 wn=wn wp=wp mult=mult
I2 (VDD VSS net75 net79 Select1 out) ece3663MUX2to1 wn=wn wp=wp mult=mult
ends ece3663MUX4to1
//end subcircuit definition
Transmission Gate (ece3663tgate)
// Cell name: ece3663tgate
// Modified by: Team NAND
// Added ability to control the size of tgate with variables wn and wp.
// 4/23/10 - conformed to class naming convention
//
- fixed wp and wn sizing mistakes
subckt ece3663tgate VDD VSS in pass out
parameters wp=3u wn =1.5u ln=600n lp=600n mult=1
I3 (VDD VSS pass pass_inv) ece3663Inverter wn=wn wp=wp mult=mult
N0 (in pass out VSS) ami06N w=wn l=ln as=1.5u*wn ad=1.5u*wn ps=3u+wn \
pd=3u+wn m=mult region=sat
P0 (out pass_inv in VDD) ami06P w=wp l=lp as=1.5u*wp ad=1.5u*wp ps=3u+wp \
pd=3u+wp m=mult region=sat
ends ece3663tgate
//end of subcircuit definition
TGate MUX (ece3663tGateMux)
// Cell: ece3663tGateMux
// Modified by: Team NAND
// added ability to control sizing from variables wn and wp.
// 4/23/10 - conformed to class naming convention
subckt ece3663tGateMux VDD VSS in0 in1 select out
parameters wp=3u wn=1.5u ln=600n lp=600n mult=1
I0 (VDD VSS in0 selectPrime out) ece3663tgate wn=wn wp=wp mult=mult
I1 (VDD VSS in1 select out) ece3663tgate wn=wn wp=wp mult=mult
I2 (VDD VSS select selectPrime) ece3663Inverter wn=wn wp=wp mult=mult
ends ece3663tGateMux
//end of subcircuit definition
Related documents