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Topics
Pseudo-nMOS gates.
 DCVS logic.
 Domino gates.

Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
Pseudo-nMOS

Uses a p-type as a resistive pullup, n-type
network for pulldowns.
Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
Characteristics
Consumes static power.
 Has much smaller pullup network than
static gate.
 Pulldown time is longer because pullup is
fighting.

Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
Output voltages
Logic 1 output is always at VDD.
 Logic 0 output is above Vss.
 VOL = 0.25 (VDD - VSS) is one plausible
choice.

Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
Producing output voltages
For logic 0 output, pullup and pulldown
form a voltage divider.
 Must choose n, p transistor sizes to create
effective resistances of the required ratio.
 Effective resistance of pulldown network
must be comptued in worst case—series ntypes means larger transistors.

Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
Transistor ratio calculation

In steady state logic 0 output:
– pullup is in linear region,Vds = Vout - (VDD VSS) ;
– pulldown is in saturation.

Pullup and pulldown have same current
flowing through them.
Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
Transistor ratio, cont’d.

Equate two currents:
– Idp = Idd.

Using 0.5 mm parameters, 3.3V power
supply:
– Wp/Lp / Wn/Ln = 3.9.
Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
DCVS logic
DCVSL = differential cascode voltage
logic.
 Static logic—consumes no dynamic power.
 Uses latch to compute output quickly.
 Requires true/complement inputs, produces
true/complement outputs.

Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
DCVS structure
Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
DCVS operation
Exactly one of true/complement pulldown
networks will complete a path to the power
supply.
 Pulldown network will lower output
voltage, turning on other p-type, which also
turns off p-type for node which is going
down.

Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
DCVS example
Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
Precharged logic
Precharged logic uses stored charge to help
evaluation.
 Precharge node, selectively discharge it.
 Take advantage of higher speed of n-types.
 Requires multiple phases for evaluation.

Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
Domino logic

Uses precharge clock to compute output in
two phases:
– precharge;
– evaluate.

Is not a complete logic family—cannot
invert.
Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
Domino gate structure
Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
Domino phases
Controlled by clock .
 Precharge: p-type pullup precharges the
storage node; inverter ensures that output
goes low.
 Evaluate: storage node may be pulled down,
so output goes up.

Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
Domino buffer

Output inverter is needed for two reasons:
– make sure that outputs start low, go high so that
domino output can be connected to another
domino gate;
– protects storage node from outside influence.
Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
Domino operation
Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
Domino effect
Gate outputs fall in sequence:
gate 1
Modern VLSI Design 3e: Chapter 3
gate 2
gate 3
Copyright  1998, 2002 Prentice Hall PTR
Monotonicity

Domino gates inputs must be monotonically
increasing: glitch causes storage node to
discharge.
Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
Output buffer

Inverting buffer isolates storage node.
Storage node and inverter have correlated
values.
Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
Using domino logic

Can rewrite logic expression using De
Morgan’s Laws:
– (a + b)’ = a’b’
– (ab)’ = a’ + b’

Add inverters to network inputs/outputs as
required.
Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR
Domino and stored charge
Charge can be stored in source/drain
connections between pulldowns.
 Stored charge can be sufficient to affect
precharge node.
 Can be averted by precharging the internal
pulldown network nodes along with the
precharge node.

Modern VLSI Design 3e: Chapter 3
Copyright  1998, 2002 Prentice Hall PTR