Transcript Slide 1

Design and Implementation of VLSI Systems
(EN1600)
Lecture 20: Combinational Circuit Design (2/3)
Prof. Sherief Reda
Division of Engineering, Brown University
Spring 2008
[sources: Weste/Addison Wesley – Rabaey/Pearson]
S. Reda EN160 SP’08
Let’s get rid of pMOS
 Reduced the capacitance and improved the delay
 Increased static power consumption
Implementing a large resistive load in CMOS is not readily available
[see subsection 2.5.4]
S. Reda EN160 SP’08
2. Pseudo-nMOS circuits
• Use a pull-up transistor that is always ON
• Issues:
– Ratio or relative strength
– Make pMOS about ¼ effective strength of pulldown network
[see subsection 2.5.4]
S. Reda EN160 SP’08
Logical effort of pseudo-nMOS gates
• Design for unit current on output to compare with unit inverter.
• pMOS fights nMOS
• psuedo-nMOS is slower on the average than CMOS but it works
well for wide NOR gates
logical effort independent of
number of inputs!
S. Reda EN160 SP’08
Pseudo-nMOS power
en
Y
A
B
C
• Pseudo-nMOS draws power whenever Y = 0
– Called static power P = I•VDD
– A few mA / gate * 1M gates would be a problem
– This is why nMOS went extinct!
• Use pseudo-nMOS sparingly for wide NORs
• Turn off pMOS when not in use
S. Reda EN160 SP’08
Ganged CMOS
Traditional pseudo-nMOS
• When A=B=0:
• both pMOS turn on in parallel pulling the output high fast
• When both inputs are ‘1’:
• both pMOS transistors turn off saving power over psuedo-nMOS
• When one is ‘1’ or one is ‘0’ then it is just like the pseudo-nMOS case
S. Reda EN160 SP’08
3. Cascode Voltage Switch Logic (CVSL)
• Seeks the performance of pseudo-nMOS without the static power
consumption
• CVSL disadvantages:
– Require input complement
– NAND gate structures can be tall and slow
S. Reda EN160 SP’08
4. Pass Transistor Logic
B
A
B
F = AB
0
Advantage:
• just uses two transistors
Problem:
• ‘1’ is not passed perfectly
• cannot the output to the input of another gate
S. Reda EN160 SP’08
Complementary Pass Transistor Logic (CPTL)
A
A
B
B
Pass-Transistor
F
Network
(a)
A
A
B
B
B
Inverse
Pass-Transistor
Network
B
B
A
F
B
B
A
A
B
F=AB
A
B
F=A+B
F=AB
AND/NAND
A
F=A
(b)
A
A
B
B
F=A+B
B
OR/NOR
A
F=A
EXOR/NEXOR
• Complementary data inputs and outputs are available
• Very suitable for XOR realization (compare to traditional CMOS)
• Interconnect overhead to route the signal and its complement
S. Reda EN160 SP’08
Possible solution: interface to a CMOS inverter
3.0
In
In
VDD
Voltage [V]
1.5m/0.25m
x
Out
0.5m/0.25m
0.5m/0.25m
2.0
Out
x
1.0
0.00
0.5
1
1.5
2
Time [ns]
Threshold voltage loss causes static power consumption
V DD
V DD
Level Restorer
Mr
B
A
Mn
M2
X
Out
(AKA Lean Integration
with Pass Transistors
- LEAP)
M1
A better design: full swing; reduces static power
S. Reda EN160 SP’08
Pass Transistor Logic with transmission gates
• In pass-transistor circuits, inputs are also applied to the
source/drain terminals.
• Circuits are built using transmission gates.
Problem:
• Non-restoring logic.
• Traditional CMOS “rejuvenates” signals
S. Reda EN160 SP’08
Restoring Pass Transistor Logic
S
A
VDD
M2
F
S
M1
B
S
S. Reda EN160 SP’08
Circuit Families
 Static CMOS
 Ratioed Circuits
 Cascode Voltage Switch Logic
 Pass-transistor Circuits
 Dynamic Circuits
S. Reda EN160 SP’08