A high speed dynamic ripple carry adder

IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
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Volume: 09 Issue: 08 | August-2015, Available @ http://www.ijret.org 438
A HIGH SPEED DYNAMIC RIPPLE CARRY ADDER
Y. Anil Kumar1
, M. Satyanarayana2
1
Student, Department of ECE, MVGR College of Engineering, India.
2
Associate Professor, Department of ECE, MVGR College of Engineering, India.
Abstract
Adder, which is one of the basic building blocks of a processor affect the performance of the processor. There are many adder
architectures each of them have their own advantage. Ripple Carry Adder (RCA) architecture occupies the minimum area among
the other architectures with lesser power dissipation. RCA experiences more delay due to its carry propagation in critical path;
apart from the delay it also experiences glitches. Constant delay (CD) logic solves both the delay problems and glitch related
problems. CD logic, due to its pre-evaluated characteristics delivers high speed but due its bulkier nature it is used only in the
critical path. In this paper two new techniques are presented which modifies the conventional timing block (requires ten
transistors) in CD logic and two new timing blocks one with eight transistors and other with nine transistors are developed. The
CD logic with the two new timing block is used in critical path of RCA to achieve higher speed performance with lesser area
compared to conventional CD logic. The CD logic with 9-transistor timing block achieves 70% and 39% delay reduction
compared to Static and Domino logics. It also achieves 21% and 5% reduction in power dissipation and delay. The 8-transistor
version also achieves reduction of delay by 65% and 29% compared to Static and dynamic logic. The two versions of timing
blocks have their own advantages where 9-transistor version provides high speed and 8- transistor version provides lesser power
dissipation. Simulations are carried out in 130 nm at 1V power supply using mentor graphics tools.
Key Words: Critical Path, Feed Through Logic, Constant Delay logic, Pre-evaluated logic, and Timing block.
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1. INTRODUCTION
Addition is very crucial to perform fundamental arithmetic
operations. It is used extensively in many VLSI designs and
is by so far the most frequently used operation in general-
purpose system and in application-specific processors. Also,
because the operations of subtraction, multiplication,
division and address calculation usually rely on the
operation of addition, addition is often seen as an
indispensable part of the arithmetic unit. It is dubbed the
heart of any microprocessor, DSP architecture, and data
processing system.
The carry propagation from each bit to its higher position
results in a substantial delay. So the adder which lies in the
critical delay path effectively determines the system’s
overall speed. An efficient adder builds an efficient system.
This leads to increasing popularity of smaller and more
durable mobile computing and communication systems.
There are many adder architectures namely the Ripple Carry
Adder (RCA), the Carry Look-Ahead Adder (CLA), the
Carry Skip Adder (CSK), the Carry Select Adder (CSL), the
Carry Save Adder (CSA) and the Conditional Sum Adder
(COS). Each architecture has its own advantages.
Among all the adder architectures, the RCA occupies the
smallest area and offers good performance for random data
input. But the delay depends on length of carry propagation
path. As the number of inputs increases delay increases
linearly. For an n-bit RCA the delay is nT, where T is the
delay of a full adder block. The overall performance of an
RCA depends on design on Full adder block.
2. FULL ADDER BLOCK
There are many full adder (FA) architectures, where the
conventional CMOS adder uses 32 transistors, the highest
among the adders and least number of transistors required to
design a full adder are six. But the CMOS logic and
dynamic logic provides less power dissipation. But the
dynamic logic suffers from cascading problem. Domino
logic overcomes the cascading problem with an extra
inverter [3]. The cascading problem in dynamic logic and an
extra inverter overhead is compensated by NORA and
ZIPPER logic, but NORA logic suffers from charge leakage
and ZIPPER logic needs non overlapping clocks that creates
area overhead[1-2].
Some other versions of full adders include Complementary
pass transistor logic full adder, Transmission gate full adder,
17-transistor full adder, 14- transistor full adder, 10-
transistor full adder [5] etc.,
In this paper a high speed dynamic logic is proposed which
is derived from (Constant Delay) CD logic [8]. Before
discussing about CD logic, Feed Through Logic (FTL) [4]
should be understood. FTL is shown in fig. 1 overcomes the
area over head in domino logic and cascading problem in
dynamic logic. By removing the footer transistor and
placing a pre-discharge transistor parallel to output node, the
cascading problem is solved without an extra inverter. But
drawback of FTL is higher power dissipation than dynamic
and domino logic. This is due to the short circuit path from
VDD to Ground when M1 and NMOS pull down network
conducts simultaneously. CD logic overcomes the short
circuit problem in FTL with the help of an additional timing
block. This timing block prevents the pull up transistors and

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NMOS pull down logic to conduct simultaneously. The
inverter at the output is to eliminate the noise. CD LOGIC
can implement both inverting logic and non inverting logic.
Fig. 2 shows buffer implemented using constant delay logic.
In this paper six types of full adder configurations are
compared with each other, where A, B and CIN are the
inputs and COUT and SUM are the outputs. Fig. 3(a) and
3(b) shows the sum generation units, where 3(b) consumes
less power but provides more delay compared to CMOS
sum generation. Figure 4(a) – (d) shows the carry generation
units of Conventional CMOS logic, Domino logic, 10-
Transistor Full adder and CD logic respectively. Out of the 4
types of carry generation units the 10-Transistor FA requires
least number of transistors to generate carry. It generates the
inverted version of carry, so to use it in RCA the COUT
signal should be given to an inverter input. The noise in
COUT signal is removed by the inverter, to remove the noise
in SUM signal two inverters or a buffer should be added to
the SUM signal output. But this addition of inverters makes
it increase its size and power dissipation. When 10-T FA is
used in RCA, by connecting the sum output of the last stage
to a buffer, the noise at the output is reduced. CMOS logic
and Domino logic carry generation unit consumes the lesser
power. CD logic provides lesser delay above all the carry
generation units because of its pre-evaluation concept.
In this paper CD logic technique with optimized timing
block is utilized to design an 8-bit RCA. Importance of CD
logic and methods to overcome the drawbacks of CD logic
are briefly explained in the next section.
Fig -1 feed through logic (FTL)
Fig -2 Constant delay logic buffer
Fig -3 Sum generation units
Fig -4 Carry generation units
3. PROPOSED TIMING BLOCKS OF CD
LOGIC.
CD logic in D-Q mode shows high speed performance due
to its pre-evaluation nature. But when compared to domino
logic(without keeper), CD logic requires extra 11 transistors
and extra 13 compared to dynamic logic. In CD logic the
extra number of transistors is mainly due to timing block
(TB), so optimizing the timing block reduces the area
overhead and power consumption. The timing block should
be optimized in such a way that the delay should not be
increased.
Two optimized designs of timing blocks are proposed in this
paper which performs the same logical function of the
original timing block.
8-T Timing Block
In first design the number of transistors in the timing block
is reduced by two. Fig. 5 shows the original timing block
from where the transistors M1 and M3 are removed to get
the same operation performed. Fig. 6 shows the first
modification in timing block i.e., 8-T timing block. The
delay gets increased if this timing block is used because

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transistor M3 has clock as an input i.e., if CLK=’1’ then
TOUT should be pulled to zero.
Fig -5 Timing Block of CD logic
As M3 is absent in this circuit TOUT is made zero through
M2 and M1 using delay inverted clock signal. So TOUT is
inverted version of clock, i.e., when CLK=’1’ TOUT=’0’,
but with some delay. This delay makes the pre-charging
slower, which increases the delay. To reduce the delay, the
W/L ratio of pre-charge transistors should be increased. To
avoid this 9-T timing block is developed.
Fig -6 8-T timing block
9-T Timing block
In the second design one transistor is reduced as shown in
fig. 7, but the 8-T timing block has some limitations for low
leakage paths, and 9-T timing works well with the low
leakage paths but dissipates more power at high leakage
paths. The drawback in 8-T timing block is overcome by
adding transistor M3. So now, charging the TOUT node is
faster compared to that in 8-T timing block. But here the
disadvantage is more power dissipation due to extra
transistor.
Fig -7 9-T timing block
4. IMPLEMENTATION OF 8-BIT RIPPLE
CARRY ADDER
In RCA the carry chain constitute the critical path, so
speeding up the carry helps in improving the speed of the
RCA. Ripple Carry adder is subjected to a glitching
problem. Due to delay in previous stage carry signals the
glitches occur. In CD logic delay from the previous stage is
to be considered seriously as the evaluation time for this
logic type is very less. Evaluation time is said to be the
window width. The window width is equal to the three
inverter delay. Generally in dynamic logic the evaluation
time is the whole evaluation period, but in CD logic it is just
a part of the evaluation period, so the delay should be less
than the window width to prevent false logic evaluation. If
the glitches from the previous state last for the window
width period then false evaluation takes place. To eliminate
this problem the clock signal should be delayed such that the
window width period can be delayed and the glitches can be
avoided. Figure 8 shows the arrangements of inverters to
generate appropriate clock signals for each stage. CLK1,
CLK2 and CLK3are delayed clock signals for different
stages of RCA. This arrangement is only for dynamic logic,
as the static logic doesn’t operate on clock signals.
In this paper an 8-bit RCA is simulated using six different
full adder blocks. The sum generation unit same for all
adder blocks. The simulated results in Table I are of the
RCA circuit that used CMOS sum generation unit. Even
though 12-T adder provides lesser transistors and noise less
output, it creates more delay which is due to the inverters
INV1 and INV2 in fig 3(b). Due to the extra delay the clock
arrangement also should be changed. It requires three extra
delay clock signals as shown in fig 9, CLK for stage1,
CLK1 for stage2, CLK2 for stage3, CLK3 for stage4, CLK4
for stage5, CLK5 for stage6, CLK6 for stage6 and stage7.
Other full adder (FA) with 28 transistors with sizing
strongly in favour of Cout computation [6] can also be used.
A more energy-efficient pass-transistor FA design [7] can
also be used in the full adder design

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Among the compared RCA architectures even though the
10-Transistor FA RCA requires the least number of
transistors the delay is almost equal to the CMOS 32-
Transistor FA RCA and power dissipation is very high.
Considering low leakage conditions Domino logic carry
generation circuit is simulated without a keeper transistor
and that reduced 8 transistors. If the keeper transistor is
included the power dissipation would be equal to that of
CMOS 32-T FA RCA. CD logic occupies more area than
CMOS logic but it has the better power delay product. 8-T
TB CD logic even though provides more delay than CD
logic it has second least power delay product. 9-TB CD
logic is the fastest among the compared logics and having
the third least power delay product. Another logic, the
Current Comparison Domino (CCD) Logic [9] consumes
very less power which is not discussed in this paper but not
faster than CD logic.
Ripple carry adder occupies the least area among all the
other adder architectures, but has more delay when number
of inputs increases. But with modified CD logic in critical
path of RCA makes it suitable for 8-bit applications. Instead
of going to CLA it is better to opt RCA which occupies less
area with increasing speed.
Fig -8 8-bit Ripple carry adder
Figure 9 Clock signals arrangement for CD logic RCA with 12-T sum unit
Table -1 Comparison Of Rca Architectures With Different Logics
Logic type S7 Delay COUT DELAY Number of
transistors
Power Dissipation Power Delay
product (10-18
)
Conventional 32-T FA 2.113 ns 2.07 ns 276 20.5962 n Watts 43.519
Domino Logic 1.04 ns 587.718 ps 160 14.238 n Watts 14.807
CD Logic 677.780 ps 550.134 ps 300 51.191 n Watts 34.656
10-T FA 2.512 n s 2.527 ns 96 59.889 u Watts 150441
8-T TB CD logic 734.65 ps 612.456 ns 284 32.8427 n Watts 24.131
9-T TB CD logic 643.247 ps 575.767 ps 292 42.3167 n Watts 27.220

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Fig -10 Power and Delay characteristics of different types of
8-bit RCA architectures
5. CONCLUSION
In this paper different RCA architectures are analyzed. Even
though the 10-transistor FA occupies less area it failed to
reduce the power and delay. CMOS logic despite of its
bulky nature provides lesser power dissipation, but the delay
increased by 200% when compared to CD logic. Two new
techniques are employed in CD logic to reduce the power
dissipation and delay. The two techniques 8T- Timing block
and 9-T timing block used CD logic succeeded in reducing
the power dissipation compared to its predecessor but the 8-
T timing CD logic failed to reduce the delay. But the 8-T
TB CD logic has lesser delay compared to CMOS logic,
Domino Logic and 10-T FA RCA. Fig. 10 shows the Power-
Delay product and Delay characteristics graph. 8-T TB CD
logic has the better Power-Delay product among the other
CD logic versions. The 8-transistor version also achieves
reduction of delay by 65% and 29% compared to Static and
dynamic logic. But the 8-T TB version has 14% more delay
compared to 9-T TB version. Even though 8-T TB version
dissipates less power than 9-T TB version, as the main aim
is to reduce the critical path 9-T TB version is considered.
Domino logic has the lesser power delay product but the
delay is 53.4% more compared to CD logic and 61.7% more
than 9-TB CD logic. So the domino logic dissipated less
power and CD logic provides more speed. As the VLSI
domain mainly opts for high speed and low power designs,
9-TB CD logic is suitable in replacing critical path circuits
and the remaining circuit can be designed with domino logic
or some other low power logic.
REFERNCES
[1]. N. Goncalves and H. De Man, “NORA: A racefree
dynamic CMOS technique for pipelined logic
structures”, IEEE J. Solid-State Circuits, vol. 18, no. 3,
pp. 261–266, Jun. 1983.
[2]. C. Lee and E. Szeto, “Zipper CMOS”, IEEE Circuits
Syst. Mag., vol. 2,no. 3, pp. 10–16, May 1986.
[3]. Sung-mo (Steve) Kang and Yusuf Leblebici. “CMOS
Digital Integrated Circuits Analysis And Design”, 3rd
edition, WCB McGraw Hill, 2003.
[4]. V. Navarro-Botello, J. A. Montiel-Nelson, and S.
Nooshabadi, “Analysis of high-performance fast feed
through logic families in CMOS”, IEEE Trans. Circuits
Syst. II, xp. Briefs, vol. 54, no. 6, pp. 489–493, Jun.
2007.
[5]. Kiat-Seng Yeo and Kaushik Roy “Low-Voltage, Low-
Power VLSI Subsystems”, Tata McGraw-Hill Edition
2009.
[6]. N. Weste and D. Harris, “CMOS VLSI Design: A
Circuits and Systems Perspective”, 4th ed. Reading,
MA: Addison Wesley, Mar. 2010.
[7]. M. Aguirre-Hernandez and M. Linares-Aranda,
“CMOS full-adders for energy-efficient arithmetic
applications”, IEEE Trans. Very Large Scale Integr.
(VLSI) Syst., vol. 19, no. 99, pp. 1–5, Apr. 2010.
[8]. Pierce Chuang, David Li and Manoj Sachdev
“Constant Delay Logic Style” IEEE Transactions On
VLSI Systems, Vol. 21, No. 3, pp. 554-565, March
2013.
[9]. Ali Peiravi, Mohammad Asyaei, “Current-
Comparison-Based Domino: New Low-Leakage High-
Speed Domino Circuit for Wide Fan-In Gates”, IEEE
Transactions VLSI Systems, Vol. 21, No. 5,pp. 934-
943, May 2013.
BIOGRAPHIES
Yerninti Anil Kumar received B.tech
degree in Electronics and Communication
Engineering from LENDI College of Engg.
and Tech. Pursuing M.tech (VLSI) in
MVGR college of Engineering.
Dr. Moturi Satyanarayana received
B.tech in Electronics and Communication
Engineering from Nagarjuna University.
M.tech in Radar and Microwave
Engineering from Andhra University, and
PhD in Antenna Arrays from Andhra
University. Member of IETE, SEMCE, ISTE and ISOI.
0
1
2
3
4
CMOS
logic
Domino
logic
CD logic 8-T TB
CD logic
9-T TB
CD logic
Normalizedvalues
Logic types
Power and Delay characteristics
Power
Delay
product
Delay

A high speed dynamic ripple carry adder

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