Upload
alexandra-ramsey
View
215
Download
2
Embed Size (px)
Citation preview
Modern VLSI Design 3e: Chapter 2 Copyright 1998, 2002 Prentice Hall PTR
Topics
Wire and via structures. Wire parasitics. Transistor parasitics.
Modern VLSI Design 3e: Chapter 2 Copyright 1998, 2002 Prentice Hall PTR
Wires and vias
p-tub
poly poly
n+n+
metal 1
metal 3
metal 2
vias
Modern VLSI Design 3e: Chapter 2 Copyright 1998, 2002 Prentice Hall PTR
Metal migration
Current-carrying capacity of metal wire depends on cross-section. Height is fixed, so width determines current limit.
Metal migration: when current is too high, electron flow pushes around metal grains. Higher resistance increases metal migration, leading to destruction of wire.
Modern VLSI Design 3e: Chapter 2 Copyright 1998, 2002 Prentice Hall PTR
Metal migration problems and solutions
Marginal wires will fail after a small operating period—infant mortality.
Normal wires must be sized to accommodate maximum current flow:Imax = 1.5 mA/m of metal width.
Mainly applies to VDD/VSS lines.
Modern VLSI Design 3e: Chapter 2 Copyright 1998, 2002 Prentice Hall PTR
Diffusion wire capacitance
Capacitances formed by p-n junctions:
n+ (ND)
depletion region
substrate (NA)bottomwallcapacitance
sidewallcapacitances
Modern VLSI Design 3e: Chapter 2 Copyright 1998, 2002 Prentice Hall PTR
Depletion region capacitance
Zero-bias depletion capacitance:– Cj0 = si/xd.
Depletion region width:– xd0 = sqrt[(1/NA + 1/ND)2siVbi/q].
Junction capacitance is function of voltage across junction:– Cj(Vr) = Cj0/sqrt(1 + Vr/Vbi)
Modern VLSI Design 3e: Chapter 2 Copyright 1998, 2002 Prentice Hall PTR
Poly/metal wire capacitance
Two components:– parallel plate;– fringe.
plate
fringe
Modern VLSI Design 3e: Chapter 2 Copyright 1998, 2002 Prentice Hall PTR
Metal coupling capacitances
Can couple to adjacent wires on same layer, wires on above/below layers:
metal 2
metal 1 metal 1
Modern VLSI Design 3e: Chapter 2 Copyright 1998, 2002 Prentice Hall PTR
Example: parasitic capacitance measurement
n-diffusion: bottomwall=2 fF, sidewall=2 fF.
metal: plate=0.15 fF, fringe=0.72 fF.
3 m
0.75 m 1 m
1.5 m
2.5 m
Modern VLSI Design 3e: Chapter 2 Copyright 1998, 2002 Prentice Hall PTR
Wire resistance
Resistance of any size square is constant:
Modern VLSI Design 3e: Chapter 2 Copyright 1998, 2002 Prentice Hall PTR
Mean-time-to-failure
MTF for metal wires = time required for 50% of wires to fail.
Depends on current density:– proportional to j-n e Q/kT – j is current density– n is constant between 1 and 3– Q is diffusion activation energy
Modern VLSI Design 3e: Chapter 2 Copyright 1998, 2002 Prentice Hall PTR
Skin effect
At low frequencies, most of copper conductor’s cross section carries current.
As frequency increases, current moves to skin of conductor.– Back EMF induces counter-current in body of
conductor. Skin effect most important at gigahertz
frequencies.
Modern VLSI Design 3e: Chapter 2 Copyright 1998, 2002 Prentice Hall PTR
Skin effect, cont’d
Isolated conductor: Conductor and ground:
Low frequency
High frequency
Low frequency
High frequency
Modern VLSI Design 3e: Chapter 2 Copyright 1998, 2002 Prentice Hall PTR
Skin depth
Skin depth is depth at which conductor’s current is reduced to 1/3 = 37% of surface value: = 1/sqrt(f)– f = signal frequency = magnetic permeability = wire conducitvity
Modern VLSI Design 3e: Chapter 2 Copyright 1998, 2002 Prentice Hall PTR
Effect on resistance
Low frequency resistance of wire:– Rdc = 1/ wt
High frequency resistance with skin effect:– Rhf = 1/2 (w + t)
Resistance per unit length:– Rac = sqrt(Rdc 2 + Rhf2
Typically = 1.2.
Modern VLSI Design 3e: Chapter 2 Copyright 1998, 2002 Prentice Hall PTR
Transistor gate parasitics
Gate-source/drain overlap capacitance:
gate
source drain
overlap
Modern VLSI Design 3e: Chapter 2 Copyright 1998, 2002 Prentice Hall PTR
Transistor source/drain parasitics
Source/drain have significant capacitance, resistance.
Measured same way as for wires. Source/drain R, C may be included in Spice
model rather than as separate parasitics.