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Topics
Basic fabrication steps
 Transistor structures
 Basic transistor behavior

Modern VLSI Design 2e: Chapter 2
Copyright  1998 Prentice Hall PTR
Fabrication services

Educational services:
–
–
–
–

U.S.: MOSIS
EC: EuroPractice
Taiwan: CIC
Japan: VDEC
Foundry = fabrication line for hire.
Modern VLSI Design 2e: Chapter 2
Copyright  1998 Prentice Hall PTR
l-based design
l is the size of a minimum feature.
 Specifying l particularizes the scalable
rules.
 Parasitics are generally not specified in
lunits
 In our 0.5 micron process, l = 0.25
microns.

Modern VLSI Design 2e: Chapter 2
Copyright  1998 Prentice Hall PTR
Fabrication processes

IC built on silicon substrate:
–
–
some structures diffused into substrate;
other structures built on top of substrate.
Substrate regions are doped with n-type and
p-type impurities. (n+ = heavily doped)
 Wires made of polycrystalline silicon
(poly), multiple layers of aluminum (metal).
 Silicon dioxide (SiO2) is insulator.

Modern VLSI Design 2e: Chapter 2
Copyright  1998 Prentice Hall PTR
Photolithography
Mask patterns are put on wafer using photosensitive material:
Modern VLSI Design 2e: Chapter 2
Copyright  1998 Prentice Hall PTR
Process steps
First place tubs to provide properly-doped
substrate for n-type, p-type transistors:
p-tub
p-tub
substrate
Modern VLSI Design 2e: Chapter 2
Copyright  1998 Prentice Hall PTR
Process steps, cont’d.
Pattern polysilicon before diffusion regions:
poly
p-tub
Modern VLSI Design 2e: Chapter 2
gate oxide
poly
p-tub
Copyright  1998 Prentice Hall PTR
Process steps, cont’d
Add diffusions, performing self-masking:
poly
n+
p-tub
Modern VLSI Design 2e: Chapter 2
poly
n+
p+
p-tub
p+
Copyright  1998 Prentice Hall PTR
Process steps, cont’d
Start adding metal layers:
metal 1
metal 1
vias
poly
n+
p-tub
Modern VLSI Design 2e: Chapter 2
n+
poly
p+
p-tub
p+
Copyright  1998 Prentice Hall PTR
Transistor structure
n-type transistor:
Modern VLSI Design 2e: Chapter 2
Copyright  1998 Prentice Hall PTR
Transistor layout
n-type (tubs may vary):
L
w
Modern VLSI Design 2e: Chapter 2
Copyright  1998 Prentice Hall PTR
Drain current characteristics
Modern VLSI Design 2e: Chapter 2
Copyright  1998 Prentice Hall PTR
0.5 m transconductances
From a 0.5 micron process:
 n-type:
–
–

kn’ = 73 A/V2
Vtn = 0.7 V
p-type:
–
–
kp’ = 21 A/V2
Vtp = -0.8 V
Modern VLSI Design 2e: Chapter 2
Copyright  1998 Prentice Hall PTR
Current through a transistor
Use 0.5 m parameters. Let W/L = 3/2.
Measure at boundary between linear and
saturation regions.
 Vgs = 2V:
Id 0.5k’(W/L)(Vgs-Vt)2= 93 A

Vgs = 5V:
Id = 1 mA
Modern VLSI Design 2e: Chapter 2
Copyright  1998 Prentice Hall PTR
Basic transistor parasitics
Gate to substrate, also gate to source/drain.
 Source/drain capacitance, resistance.

Modern VLSI Design 2e: Chapter 2
Copyright  1998 Prentice Hall PTR
Basic transistor parasitics, cont’d
Gate capacitance Cg. Determined by active
area.
 Source/drain overlap capacitances Cgs, Cgd.
Determined by source/gate and drain/gate
overlaps. Independent of transistor L.

–

Cgs = Col W
Gate/bulk overlap capacitance.
Modern VLSI Design 2e: Chapter 2
Copyright  1998 Prentice Hall PTR
Latch-up
CMOS ICs have parastic silicon-controlled
rectifiers (SCRs).
 When powered up, SCRs can turn on,
creating low-resistance path from power to
ground. Current can destroy chip.
 Early CMOS problem. Can be solved with
proper circuit/layout structures.

Modern VLSI Design 2e: Chapter 2
Copyright  1998 Prentice Hall PTR
Parasitic SCR
circuit
Modern VLSI Design 2e: Chapter 2
I-V behavior
Copyright  1998 Prentice Hall PTR
Parasitic SCR structure
Modern VLSI Design 2e: Chapter 2
Copyright  1998 Prentice Hall PTR
Solution to latch-up
Use tub ties to connect tub to power rail. Use
enough to create low-voltage connection.
Modern VLSI Design 2e: Chapter 2
Copyright  1998 Prentice Hall PTR
Tub tie layout
p+
metal (VDD)
p-tub
Modern VLSI Design 2e: Chapter 2
Copyright  1998 Prentice Hall PTR