The low power has been the main concern for the VLSI industry with the technology scaling in CMOS process from 130 nm to 22nm. The presentation here gives a brief idea about the several low power VLSI techniques being used in VLSI circuits to reduce the power and delay. for any query feel free to visit us at: http://www.siliconmentor.com/
2. Introduction
• In this electronic era of miniaturization of circuitry,
there is a need of devices with less power consumption
and short delay.
• But in actual these both these parameters are
contradictory to each other. If we improve the one,
other one gets deteriorated because power delay
product remains constant.
• This suggests that there must be a different approach
to achieve desired level of power with delay in limits
which can be tolerated in circuit.
3. Why to reduce Power Consumption ?
• To optimise battery Back-Up in mobile Devices.
• To ensure stable and Optimum working of circuit.
• Implementation of integrated circuitry in a chip
results in very high power consumption and
dissipation.
• For longer device life.
4. Basic Concept Behind Power
Reduction.....!
• The power reduction approach can be implemented by
reducing the sub-threshold current which in-turn is responsible
for lower static power consumption in circuit.
• Power consumption is proportional to the sub threshold
current, if we decrease the current we can decrease the power
consumption and this current is decreased if we increase the
threshold voltage.
• So, basically to ensure less power dissipation, threshold
voltage level can be increased.
5. Low Power Strategies
• Reverse Body Biasing
• Dual Threshold CMOS
• Multi Threshold CMOS
• Sleep transistor
• Sleepy Stack
6. Reverse Body Biasing technique:
In this technique we provide voltage to the Body (Substrate) terminal of
MOSFET so that there is an increase in the threshold voltage which
further decreases the sub threshold current that ultimately helps in
reduction of the power dissipation because power is proportional to the
current.
7. Dual Threshold CMOS:
This approach is implemented by using different CMOS with different
threshold voltage to decrease the power consumption.
It mainly decreases the sub threshold leakage current.
But at the same time there is certain increase in the number of MOSFETs
which altogether increases the delay in circuit.
8. Multi Threshold CMOS:
Multiple threshold CMOS technique makes use of both high and low
threshold MOS in the same circuit. The main concern is to selectively
change the threshold voltages in order to improve the power consumption
with improved the circuit speed.
Simple method of making MOS with multiple threshold voltages is to
apply different bias voltages (VB) to the body or substrate terminal of the
transistors. Other methods include changing the thickness of gate oxide
or dopant concentration in the MOS channel.
This approach overcomes the speed limitation which is present in DT
CMOS
9. Sleep Transistor:
• In this technique, the sleep
transistors having high threshold
value is inserted between the Vdd
and the pull up network and
another transistor is inserted
between the pull down network
and ground.
• These transistors switch ON when
circuit is ON and switch off when
circuit is idle. By cutting off the
power supply, this can reduce the
leakage power.
• But when it is in cut off state, it
does not hold states, it destruct the
states.
10. Sleepy Stack approach:
• This technique divides the single transistor into two half-size
transistors. In this approach every half-transistor is added in series
so that there is small leakage current.
• It also adds sleepy transistors to disconnect the power supply
and ground from the network so that there is no power
consumption in off mode.
11. • If you still have any query about low power design
approach in VLSI then no need to worry just contact
us and get the answers for your all question.
• And if you are a M.tech or PhD students and seeking
guidance for your VLSI projects then contact us to get
instant help.
12. About Us
• Company : SiliconMentor
• Website: http://www.siliconmentor.com/