The basic building block of any digital operation is addition. This paper compares fully automatic and proposed semicustom layout design; the proposed design has been optimized for power consumption, low area and high speed. Power consumption and area are the major design issue for a designer. All the design result of fully custom and proposed semicustom design taken at 1.2V. In this the circuit simulation has been done on DSCH3 and layout simulation on Microwind3.1.
Layout Design of Low Power Half Adder using 90nm Technology
1. Int. Journal of Electrical & Electronics Engg. Vol. 2, Spl. Issue 1 (2015) e-ISSN: 1694-2310 | p-ISSN: 1694-2426
97 NITTTR, Chandigarh EDIT-2015
Layout Design of Low Power Half Adder using
90nm Technology
Neha Yadav
Department of ECE, National Institute of Technical Teachers’ Training & Research Chandigarh, India
neha.yadav075@gmail.com
Abstract: The basic building block of any digital operation is
addition. This paper compares fully automatic and proposed
semicustom layout design; the proposed design has been
optimized for power consumption, low area and high speed.
Power consumption and area are the major design issue for a
designer. All the design result of fully custom and proposed
semicustom design taken at 1.2V. In this the circuit
simulation has been done on DSCH3 and layout simulation on
Microwind3.1.
Keywords: Half Adder, CMOS circuit, VLSI, Microwind 3.1
power dissipation, logic gates, delay
1. INTRODUCTION
Addition is the basic operation which is applied various
field of VLSI, such as application specific DSP
architecture and microcontrollers; half adder is used to
adding two binary numbers, as we know that addition is
the base of other operation also like subtraction,
multiplication, division and address calculation.[1]
sometimes we required to increasing the speed of the
circuit it need parallel operation compare to series
operations, then we need no. of CMOS for designing the
layout of that particular circuit which increases the area
and power consumption.
So the factor like power, area and speed depends upon the
no. of CMOS and the circuit complexity. Arithmetic
operation like multiplication done by ALU, and it is
depending on addition. [1, 2]. Recently the work on low
power VLSI system has high demand because of limited
amount of power available in case of mobile
communication. [1]
So designer facing more constraint with the high speed low
power area efficiency and high performance [1]. Here we
propose a new design of half adder circuit using CMOS.
The strength of a signal is measured by how closely it
approximates an ideal voltage source [3, 4]
VLSI implementation, major problem are heat dissipation
and power consumption. So it is required to reduce power
supply voltage. Area, delay and power dissipation have
emerged as the major problem of the designers. [4, 5] So in
this paper the main point is the performance like
robustness, and delay silicon area and power consumption.
[6, 7]
2. CMOS HALF ADDER DESIGN
Half adder is used to addition of two binary no. A, B are
with its sum and carry. The output of sum of A and B is
XOR and carry of A and B is output of AND gate. Half
Adder is also use for two or more bit for parallel addition,
which increases the operation time of the circuit in two bit
parallel adder and the operation of two bit adder is same as
the half adder shown below:
Sum= A XOR B
Carry= A AND B
Table.1 Truth table of half adder
Fig.1 Sum=A’B+AB’
Boolean Expression of Sum
Boolean expression is obtained using k map, which is
filled by truth table output. It is in SOP form which is
based on min terms.
Boolean Expression of Carry
Boolean Expression of Carry is obtained same as Boolean
Expression of Sum with k map using truth table output.
0 0
0 1
Fig.2 Carry=AB
So from the Boolean expression circuit of half adder at
gate level and at CMOS level are designs with DSCH
shown below. Fig.3 shows gate level design and fig.4
equivalent CMOS logic design. The simulated output of
CMOS circuit using DSCH is given in fig.5.the simulated
A B Sum Carry
0 0 0 0
0 1 1 0
1 0 1 0
1 1 1 1
0 1
1 0
1
B
A
0
10
1
A0
10
B
2. Int. Journal of Electrical & Electronics Engg. Vol. 2, Spl. Issue 1 (2015) e-ISSN: 1694-2310 | p-ISSN: 1694-2426
NITTTR, Chandigarh EDIT -2015 98
output at gate and CMOS level are same but CMOS circuit
design is more efficient because it opens the path for
layout design of the required circuit. With the help of
CMOS circuit firstly stick diagram of circuit has made and
then with the help of stick diagram layout of given circuit
has been designed. Stick diagram shows different layers
with different colours and it is shown same in layout
design whether it is fully automatic layout design or
semicustom layout design. In semicustom layout design
library components are used for layout designing example
NMOS and PMOS which reduces the time for
manufacture.
Fig.3 Half adder with XOR and AND gate
Fig.4 Half Adder using CMOS
Fig.5 simulated output of CMOS design
3. LAYOUT DESIGN SIMULATIONS
Full automatic layout has been generated on
Microwind3.1. After compile verilog file generated on
DSCH. In DSCH first we have to draw schematic design
and after saving this circuit make verilog file. It gives an
idea about all PMOS and NMOS connection with ground
and supply voltage. It gives also gives an idea about
interconnections between two different metals, between
metal and polysilicon also about lambda rule to design our
desire logic circuit. Layout of fully automatic design with
its simulated output is shown in fig.6 and fig.7.
Fig.6 Fully Automatic Layout Design
Fig.7 Output of Fully Automatic Layout Design
Semicustom design layout using CMOS logic with8 MOS
devices and its simulated output is shown in fig.8 and fig.9
3. Int. Journal of Electrical & Electronics Engg. Vol. 2, Spl. Issue 1 (2015) e-ISSN: 1694-2310 | p-ISSN: 1694-2426
99 NITTTR, Chandigarh EDIT-2015
Fig.8 Proposed Semi Custom Layout
Fig.9 Proposed semi custom layout output
4. RESULT ANALYSIS
Comparative analysis between various types of design
layout of half adder is shown in table.2.Comparison
aspects are based on power dissipation, effective area,
delay and number of transistors used. From the table it is
obvious that layout design using semicustom is better than
the layout design of fully automatic. Area and power semi
custom layout design improves more in percentage (%).
In the table.2 we are comparing area, power, delay and the
no. of gate between fully automatic layout and semicustom
layout designs which shows that area, power and delay
with same no. of gates are less in semicustom than fully
automatic. From the table power and delay improved more
than 25% compare to fully automatic layout design and
area remains only which are less than one third of fully
automatic layout design.
Table and graph of result of fully custom layout design and proposed
semi custom layout design
parameters
Fully Automatic
Design
Semicustom
Design
Power 847nW 678nW
Area 132.7μm² 42 μm²
Delay 29ps 11ps
CMOS 8(no. of CMOS) 8
Table .2 Analyses of different parameters
Figure shows graph of fully automatic and semicustom
layout design with various parameters like power, area,
delay and no. of CMOS. Graph describe comparison
between fully automatic and semicustom layout design and
it is observed that semicustom is more optimum lay out
design.
Fig.10 Graphical Analyses of different parameters
5. CONCLUSION
It is observed from the result that the proposed layout
design is area efficient, low power consumption with high
speed and high performance compare to fully automatic
layout design. So semicustom layout design is very useful
technique to reduce the effective area on a chip, number of
transistors, delay and power dissipation. Semicustom
layout design is optimum than fully automatic layout
design.
REFERENCES
[1]. Pardeep Kumar, Susmita Mishra, Amrita Singh “Study of
existing Full Adders and To Design a LPFA (Low Power Full
Adder)”. International Journal of Engineering Research and
Applications (IJERA) ISSN: 2248-9622 Vol. 3, Issue 3, May-
Jun 2013, pp.509-513
[2]. Chakshu Goel, Puneet Jain, Gurjeevan Singh “Design and
Simulation of Low Power CMOS Adder Cell at 180nm using
Tanner Tool”. International journal of Computer Applications
(0975 – 8887) Volume 62– No.16, January 2013
[3]. M.Geetha Priya K.Baskaran “Low Power Full Adder with
Reduced Transistor Count”. International Journal of
Engineering Trends and Technology (IJETT) Volume 4, Issue
5, May 2013
0
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power area delay no. Of
cmos
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semi custom
4. Int. Journal of Electrical & Electronics Engg. Vol. 2, Spl. Issue 1 (2015) e-ISSN: 1694-2310 | p-ISSN: 1694-2426
NITTTR, Chandigarh EDIT -2015 100
[4]. MICHAEL J. BATEK and JOHN P. HAYES, “Optimal
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[5]. Zhanfeng Zhang, Liyuan Sheng, Wenming Jiang, Shuai Tong,
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[6]. Habsah Abdul Shaer, Md. Mamun, Mohd. Marufuzzaman and
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[7]. R.UMA, Vidya Vijayan, M. Mohanapriya, Sharon Paul,
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ACKNOWLEDGMENT
Author would like to thank Mr. Rajesh Mehra, assistant professor
of electronics and communication engineering department,
National Institute of Technical Teachers’ Training & Research,
Panjab University Chandigarh, India for their constant
inspirations, support and helpful suggestions throughout this
research work.
ABOUT AUTHOR
Neha Yadav completes the Bachelors of Technology degree in
Electronics and Communication Engineering from U.I.E.T.
C.S.J.M. University Kanpur. She is pursuing M.tech from
National Institute of Technical Teachers’ Training & Research,
Panjab University Chandigarh.