Designing of Asynchronous Viterbi Decoder for Low Power Consumption using Handshaking Protocol: A Technical Review
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This document reviews various methods for designing asynchronous Viterbi decoders for low power consumption using handshaking protocols. It describes synchronous and asynchronous design methodologies for Viterbi decoders and different handshaking protocols that can be used to synchronize asynchronous components and reduce power consumption. Specifically, it discusses the LEDR handshaking protocol, which can enhance throughput and is delay-insensitive. The document analyzes several papers that propose techniques like LEDR encoding, reduced switching activity decoding, and asynchronous circuits to decrease power usage in Viterbi decoder components like the add-compare-select and state metric update units.
![International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395 -0056
Volume: 04 Issue: 02 | Feb -2017 www.irjet.net p-ISSN: 2395-0072
© 2017, IRJET | Impact Factor value: 5.181 | ISO 9001:2008 Certified Journal | Page 170
Designing of Asynchronous Viterbi Decoder for Low Power
Consumption using Handshaking Protocol: A Technical Review
Ms. Sneha T. Shende1, Asst. Prof. S.K.Tadse2
1 Research Scholar , Electronics and Telecommunication Department, GHRCE, Nagpur, Maharashtra, India
2Assosiate Professor, Electronics and Telecommunication Department, GHRCE, Nagpur, Maharashtra, India
1shende_sneha.ghrcemtechcom@raisoni.net,2surekha.tadse@raisoni.net
---------------------------------------------------------------------***---------------------------------------------------------------------
Abstract - This paper gives a review on various methods
used for designing of Asynchronous Viterbi Decoder for low
power consumption using different handshaking protocol. It
gives an idea about various decoding techniques for reducing
reoccurring memory operations and repeating switching
activity. This paper describes the synchronous and
asynchronous design methodology of Viterbi Decoder for low
power consumption. Here it also states the different
handshaking protocol for making Asynchronous Viterbi
Decoder to Synchronize and to communicate with different
units of Viterbi Decoder for low power consumption. This
paper also gives a brief idea about various decoding
techniques for designing of Viterbi Decoder.
Key Words: Asynchronous Viterbi decoder, Handshaking
Protocol, Convolutional Encoder.
1.INTRODUCTION
Viterbi decoding has the advantage of the fixed decoding
time. Now a days about one billion cellphones are using
Viterbi decoder, and it is the most probably the highest
number in any application. The current consumer of VA
processor is digital video broadcast systems. A Viterbi
decoder with convolutional decodingisa FECtechniqueused
for a channel that transmits corrupted signals. The FECadds
some redundant bits to increase the capacity of the channel.
A famous approach adopted in the Viterbi Decoder design is
Asynchronous or the timing strategy as it saves power as it
have to generate global clock for the system. In Viterbi
decoder is decoded by the following two well known
methods known as the (TBM) and (REM). The switching
activity problem of Viterbi Decoder can be reduced by
combining TB and REM that is (HREM). Further (MTHREM)
has been employed for low switching activity.
2. TECHNICAL REVIEW
In this paper[1] the comparative study of asynchronous and
synchronous design methodology is done. This paper
describes the different decoding techniques for Viterbi
decoder which reduces the switching activityandnumberof
memory operations. It states the handshaking protocol to
make synchronous system asynchronous to communicate
with the various units of VD.
Paper [2] describes reconfiguration for FPGA cells are done.
FPGA consumes high static and high dynamic power. So to
reduce this static and dynamic power LEDR Architecture is
used. In this system if any device is not in use or the
transistors are not active then they are set at sleep mode
immediately. The functional unitaresettolowleakagemode
to reduce the power. LEDR is two phase dual rail encoding in
which spacer not necessary. Low power consumption and
high throughput is achieved as number of signal transitions
are reduced. Power analysis is carried out and is found out
as 7mWatt.
In this paper [3] a low power designing of FPGA is doneusing
two types of encoding. LEDR encoding at input side and 4-
Phase Dual Rail Encoding is at output side, as first method
gives high through and reduced power consumption and
second method gives reduced area. As FPGA clock network
consist of significantly more registers and thus it consumes
more power. So to solve this clock problem, here
asynchronous FPGA’s are proposed. The number of input
output blocks and LUT’s are reduced in proposed method
and delay is increased here. The conventional logicblock has
the problem of detecting the data. Here the data is detected
at inaccurate timing hence power consumptionincreases.So
in this architecture this problem is overcome and power
reduction achieved.
A new AFPGA’s architecture is described ingivenpaper[4] to
reduce the power consumption. As FPGA have more
registers for high programming and complicated switching
blocks. The dynamic power consumed by switching block
and clock signal is dominant. So asynchronous bit-serial](https://image.slidesharecdn.com/irjet-v4i231-171113092337/85/Designing-of-Asynchronous-Viterbi-Decoder-for-Low-Power-Consumption-using-Handshaking-Protocol-A-Technical-Review-1-320.jpg)
![International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395 -0056
Volume: 04 Issue: 02 | Feb -2017 www.irjet.net p-ISSN: 2395-0072
© 2017, IRJET | Impact Factor value: 5.181 | ISO 9001:2008 Certified Journal | Page 171
architecture is given here to reduce the powerconsumption.
To make operation independent of data-path length LEDR
encoding is used here and expresses its area efficient
implementing system. In this paper 90 nm CMOStechnology
is used to implementasynchronousfieldprogrammable VLSI
system and as compared to dual rail and 4-phase encoding
the transistors count for each cell in FPVLSI is only 13%
large. And power consumption per unit cell is 58%.
This paper [5] implements high throughput and moderate
area of constraint length K=3, and code ret R=1/2 hand
decision parallel Viterbi decoder. The ACS delay latency is
reduce using designing ACS unit with the help of new look
ahead carry adder and digital comparator. The advantage of
REM and TBM are combined for reducing the required area
and decoder latency Viterbi Decoder. Thedescribeddecoder
operates at 250 Mhz. The proposed ACS architecture have
67.07% improved latency deduction when we compared it
to conventional ACS architecture and output is Gbps and
improvement in area is 73.03% to 92.46% is achieved.
In this paper[6] gives in VLSI integratedcircuitusedinmobile
communication systems reducing the power consumption
has become a fundamental design goal. Thus Asynchronous
design is becoming more attractivethanthatofSynchronous
as it achieves high speed and low power consumption.Given
paper focuses on design of VLSI architecture of Viterbi
Decoder using low power VLSI technologies with self time
controlled and voltage switch logic techniques. Here
Request-Acknowledge Handshake pair controls the
communication within the decoder blocks and signals to
ensure that valid data is ready and it has been acceptedafter
designing the simulation results gives 90% power reduction
using asynchronous design comparison with synchronous
design.
In this paper [7] the comparison of existing DI 2-phase
protocol in reference with speed, power and coding
efficiency is given for practical implementations.Nowa days,
communication protocols are receiving tremendous
attention. The given energy saving 2-phase protocol are
LEDR, LETS and TrasEnc. Here comprehensive comparison
encoder/decoder is performed with respect to static power,
dynamic energy and propogation delay. Results shows that
LEDR has the most lightweight and fastest implementation.
In this paper [8] gives the interconnection implementation
foe delay insensitive variations and LEDR encoding.InLEDR
complete decode and detectioning circuit is fast, and simple.
Because the decoding and level based detection and not
based on transition. Here LEDR encoding is chosen as
compared to normal decoding. Thus communicationlatency
of the LEDR interconnect reduced to half when compared to
conventional LEDR interconnect. Its current mode signaling
implies it to achieve more speed by not using pipelining and
repeaters. And thus the throughputofthe1GBPSforone pair
of wire is 5mm of total length of the wire.
In this paper[9] the four-phase dual-rail encode and LEDR
encode is combined for presenting asynchronous FPGA. To
achieve small area and less power for functional units 4-
phase dual-rail encoding is used here and for achieving high
throughput and less power for data transfer LEDR encoding
is used here. In this paper the given fabrication of FPGA is
done using the e-shuttle 65 mm CMOS processor&operated
in 870MHz. Here the results achieved shows impliesthat the
power consumption of the system is reduced to 38% for
workload of 15%.
In this Paper[10] the LETS that is delay insensitive data
encode technique used in global communication is evolved.
LET$ is the generalizing technique of LEDR that is it was
non-return to zero encode scheme. Here one outofthegiven
two wires changes the information of data bit per
transaction. It has the potential power and throughput
advantage. Its advantage is because of few railing switches
and non return-to-zero plane. In this paper 1-out of-4 LETS
codes have been proposed and hardware completing
detection technique is introduced. Finally the simplest way
for generation of such code is given.
3. CONCLUSIONS
Here in this literature survey thedifferentmethodsare
given to design asynchronous Viterbi decoder for low
power consumption. It also compares the
asynchronous with synchronous methodologies and
gives different techniquesforViterbidecoder.Toavoid
the unnecessary memory operations the reduced
switching activity techniques and different
handshaking protocol are given in this literature
survey. The ACS and SMU units of Viterbi decoder
consumes more power, so we have to take care for
optimization of these units. And for this we have to
consider some points such as switching activity,
bandwidth, timing, throughput, overhead etc. This
literature survey concentrates on the LEDR
handshaking protocol. It enhances the throughput of
coding and it is delay insensitive.
REFERENCES
1.Surekha Tadse, “Asynchronous Viterbi Decoder for low
power consumption: A Technical Review”, Inventi Rapid:
Telecom Vol. 2014, Issu 1, [ISSN 2278-6341]
2. N. Rajagopala Krishnan , K. Sivasuparamanyam,“A
Reconfigurable Low Power FPGA design with Autonomous](https://image.slidesharecdn.com/irjet-v4i231-171113092337/85/Designing-of-Asynchronous-Viterbi-Decoder-for-Low-Power-Consumption-using-Handshaking-Protocol-A-Technical-Review-2-320.jpg)
![International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395 -0056
Volume: 04 Issue: 02 | Feb -2017 www.irjet.net p-ISSN: 2395-0072
© 2017, IRJET | Impact Factor value: 5.181 | ISO 9001:2008 Certified Journal | Page 172
power gating and LEDR encoding”, Proceeding of 7th
International Conference on Intelligent System and Control
[ISCO 2013].
3.K. Naveena , N. Kirthika , “ A Low Power Asynchronous
FPGA witj Power Gating and Dual Rail Encoding”, IJCSET,
March 2012, Vol. 2, Issu 3,949-952.
4. Masanori Hariyama, Shota Ishihara , Chang Chia Wei,
Michitaka Kameyama, “A FieldProgrammableVLSIBased on
an Asynchronous Bit-Serial Architecture”, IEEE Asian Solid-
State Circuits conference, November 12-14, 2007/ Jeju,
Korea
5. Narayan V. Sugur, Saroja V. Siddamal, Samba Sivam
Vemala, “Design and implementation of High Throughput
and Area Efficient Hard Decision Viterbi Decoder in 65 nm
Technology”, 2014 27th International Conference on VLSI
Design and 2014 13th International conference on
Embedded System
6. T.Kalavathidevi, C. Venkatesh, “ Low Power VLSI
Architecture of Viterbi Decoder using Asynchronous
Precharge Buffer Dual-Rail Techniques”, 2012/No. 2(34),
ISSN 1512-1232
7. Markus Schutz, Florian Huemer, Andreas Steininger, “ A
Practical comparison of 2-Phase Delay Insensitive
Communication Protocol”, Austrian Workshop on
Microelectronics,
DOI 10.1109/ Austrochip.2015.11
8. Ethiopia Nigussie, Juha Plosila, Jouni Isoaho, “Current
Mode On-Chip Interconnect usingLevel-EncodedTwo-Phase
Dual-Rail Encoding”, 1-4244-0921-7107, 2007 IEEE
9. Yoshiya Komotsu, Shota Ishihara, Masanori Hariyama,
Michitaka Kameyama, “ An Implementation of an
Asynchronous FPGA Based on LEDR/ Four-Phase Dual-Rail
Hybrid Architecture”, 978-1-4244-7516-2/11, 2011 IEEE
10. Peggy B. McGee, Melinda Y. Agyekam, Moustafa A.
Mohamed, Steven M. Nowick, “ A Level-Encoded Transition
Signaling Protocol for High-Throughput Asynchronous
Global Communication”,
DOI 10.1109/ASYNC.2008.24 IEEE
BIOGRAPHIES
Sneha Shende received the B.E.
degree in Electronics &
telecommunication Engineering
from Smt. Radhikatai Pandav
College of Engineering, Nagpur in
2014 and pursuing MTech degree
in Communication Engineering
from G. H. Raisoni College of
Engineering, Nagpur respectively.
Her current research interest
includes wireless communication
and systems.
Surekha Tadse received the B.E.
degree in Electronics Engineering
from B.D. College of Engineeing,
Nagpur and MTech in Electronics
from Y.C.C.E, Nagpur and pursuing
Ph.D from G.H. Raisoni College of
Engineering, Nagpur. In 2010, she
joined the department of
Electronics & Telecommunication
Engineering, G. H. Raisoni College
of Engineering, Nagpur, as a
Lecturer. Her field ofspecialization
includes Communication and
Digital Image Processing. She is a
member of IEEE, ISTE, IETE.](https://image.slidesharecdn.com/irjet-v4i231-171113092337/85/Designing-of-Asynchronous-Viterbi-Decoder-for-Low-Power-Consumption-using-Handshaking-Protocol-A-Technical-Review-3-320.jpg)
Designing of Asynchronous Viterbi Decoder for Low Power Consumption using Handshaking Protocol: A Technical Review
- 1. International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395 -0056 Volume: 04 Issue: 02 | Feb -2017 www.irjet.net p-ISSN: 2395-0072 © 2017, IRJET | Impact Factor value: 5.181 | ISO 9001:2008 Certified Journal | Page 170 Designing of Asynchronous Viterbi Decoder for Low Power Consumption using Handshaking Protocol: A Technical Review Ms. Sneha T. Shende1, Asst. Prof. S.K.Tadse2 1 Research Scholar , Electronics and Telecommunication Department, GHRCE, Nagpur, Maharashtra, India 2Assosiate Professor, Electronics and Telecommunication Department, GHRCE, Nagpur, Maharashtra, India 1shende_sneha.ghrcemtechcom@raisoni.net,2surekha.tadse@raisoni.net ---------------------------------------------------------------------***--------------------------------------------------------------------- Abstract - This paper gives a review on various methods used for designing of Asynchronous Viterbi Decoder for low power consumption using different handshaking protocol. It gives an idea about various decoding techniques for reducing reoccurring memory operations and repeating switching activity. This paper describes the synchronous and asynchronous design methodology of Viterbi Decoder for low power consumption. Here it also states the different handshaking protocol for making Asynchronous Viterbi Decoder to Synchronize and to communicate with different units of Viterbi Decoder for low power consumption. This paper also gives a brief idea about various decoding techniques for designing of Viterbi Decoder. Key Words: Asynchronous Viterbi decoder, Handshaking Protocol, Convolutional Encoder. 1.INTRODUCTION Viterbi decoding has the advantage of the fixed decoding time. Now a days about one billion cellphones are using Viterbi decoder, and it is the most probably the highest number in any application. The current consumer of VA processor is digital video broadcast systems. A Viterbi decoder with convolutional decodingisa FECtechniqueused for a channel that transmits corrupted signals. The FECadds some redundant bits to increase the capacity of the channel. A famous approach adopted in the Viterbi Decoder design is Asynchronous or the timing strategy as it saves power as it have to generate global clock for the system. In Viterbi decoder is decoded by the following two well known methods known as the (TBM) and (REM). The switching activity problem of Viterbi Decoder can be reduced by combining TB and REM that is (HREM). Further (MTHREM) has been employed for low switching activity. 2. TECHNICAL REVIEW In this paper[1] the comparative study of asynchronous and synchronous design methodology is done. This paper describes the different decoding techniques for Viterbi decoder which reduces the switching activityandnumberof memory operations. It states the handshaking protocol to make synchronous system asynchronous to communicate with the various units of VD. Paper [2] describes reconfiguration for FPGA cells are done. FPGA consumes high static and high dynamic power. So to reduce this static and dynamic power LEDR Architecture is used. In this system if any device is not in use or the transistors are not active then they are set at sleep mode immediately. The functional unitaresettolowleakagemode to reduce the power. LEDR is two phase dual rail encoding in which spacer not necessary. Low power consumption and high throughput is achieved as number of signal transitions are reduced. Power analysis is carried out and is found out as 7mWatt. In this paper [3] a low power designing of FPGA is doneusing two types of encoding. LEDR encoding at input side and 4- Phase Dual Rail Encoding is at output side, as first method gives high through and reduced power consumption and second method gives reduced area. As FPGA clock network consist of significantly more registers and thus it consumes more power. So to solve this clock problem, here asynchronous FPGA’s are proposed. The number of input output blocks and LUT’s are reduced in proposed method and delay is increased here. The conventional logicblock has the problem of detecting the data. Here the data is detected at inaccurate timing hence power consumptionincreases.So in this architecture this problem is overcome and power reduction achieved. A new AFPGA’s architecture is described ingivenpaper[4] to reduce the power consumption. As FPGA have more registers for high programming and complicated switching blocks. The dynamic power consumed by switching block and clock signal is dominant. So asynchronous bit-serial
- 2. International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395 -0056 Volume: 04 Issue: 02 | Feb -2017 www.irjet.net p-ISSN: 2395-0072 © 2017, IRJET | Impact Factor value: 5.181 | ISO 9001:2008 Certified Journal | Page 171 architecture is given here to reduce the powerconsumption. To make operation independent of data-path length LEDR encoding is used here and expresses its area efficient implementing system. In this paper 90 nm CMOStechnology is used to implementasynchronousfieldprogrammable VLSI system and as compared to dual rail and 4-phase encoding the transistors count for each cell in FPVLSI is only 13% large. And power consumption per unit cell is 58%. This paper [5] implements high throughput and moderate area of constraint length K=3, and code ret R=1/2 hand decision parallel Viterbi decoder. The ACS delay latency is reduce using designing ACS unit with the help of new look ahead carry adder and digital comparator. The advantage of REM and TBM are combined for reducing the required area and decoder latency Viterbi Decoder. Thedescribeddecoder operates at 250 Mhz. The proposed ACS architecture have 67.07% improved latency deduction when we compared it to conventional ACS architecture and output is Gbps and improvement in area is 73.03% to 92.46% is achieved. In this paper[6] gives in VLSI integratedcircuitusedinmobile communication systems reducing the power consumption has become a fundamental design goal. Thus Asynchronous design is becoming more attractivethanthatofSynchronous as it achieves high speed and low power consumption.Given paper focuses on design of VLSI architecture of Viterbi Decoder using low power VLSI technologies with self time controlled and voltage switch logic techniques. Here Request-Acknowledge Handshake pair controls the communication within the decoder blocks and signals to ensure that valid data is ready and it has been acceptedafter designing the simulation results gives 90% power reduction using asynchronous design comparison with synchronous design. In this paper [7] the comparison of existing DI 2-phase protocol in reference with speed, power and coding efficiency is given for practical implementations.Nowa days, communication protocols are receiving tremendous attention. The given energy saving 2-phase protocol are LEDR, LETS and TrasEnc. Here comprehensive comparison encoder/decoder is performed with respect to static power, dynamic energy and propogation delay. Results shows that LEDR has the most lightweight and fastest implementation. In this paper [8] gives the interconnection implementation foe delay insensitive variations and LEDR encoding.InLEDR complete decode and detectioning circuit is fast, and simple. Because the decoding and level based detection and not based on transition. Here LEDR encoding is chosen as compared to normal decoding. Thus communicationlatency of the LEDR interconnect reduced to half when compared to conventional LEDR interconnect. Its current mode signaling implies it to achieve more speed by not using pipelining and repeaters. And thus the throughputofthe1GBPSforone pair of wire is 5mm of total length of the wire. In this paper[9] the four-phase dual-rail encode and LEDR encode is combined for presenting asynchronous FPGA. To achieve small area and less power for functional units 4- phase dual-rail encoding is used here and for achieving high throughput and less power for data transfer LEDR encoding is used here. In this paper the given fabrication of FPGA is done using the e-shuttle 65 mm CMOS processor&operated in 870MHz. Here the results achieved shows impliesthat the power consumption of the system is reduced to 38% for workload of 15%. In this Paper[10] the LETS that is delay insensitive data encode technique used in global communication is evolved. LET$ is the generalizing technique of LEDR that is it was non-return to zero encode scheme. Here one outofthegiven two wires changes the information of data bit per transaction. It has the potential power and throughput advantage. Its advantage is because of few railing switches and non return-to-zero plane. In this paper 1-out of-4 LETS codes have been proposed and hardware completing detection technique is introduced. Finally the simplest way for generation of such code is given. 3. CONCLUSIONS Here in this literature survey thedifferentmethodsare given to design asynchronous Viterbi decoder for low power consumption. It also compares the asynchronous with synchronous methodologies and gives different techniquesforViterbidecoder.Toavoid the unnecessary memory operations the reduced switching activity techniques and different handshaking protocol are given in this literature survey. The ACS and SMU units of Viterbi decoder consumes more power, so we have to take care for optimization of these units. And for this we have to consider some points such as switching activity, bandwidth, timing, throughput, overhead etc. This literature survey concentrates on the LEDR handshaking protocol. It enhances the throughput of coding and it is delay insensitive. REFERENCES 1.Surekha Tadse, “Asynchronous Viterbi Decoder for low power consumption: A Technical Review”, Inventi Rapid: Telecom Vol. 2014, Issu 1, [ISSN 2278-6341] 2. N. Rajagopala Krishnan , K. Sivasuparamanyam,“A Reconfigurable Low Power FPGA design with Autonomous
- 3. International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395 -0056 Volume: 04 Issue: 02 | Feb -2017 www.irjet.net p-ISSN: 2395-0072 © 2017, IRJET | Impact Factor value: 5.181 | ISO 9001:2008 Certified Journal | Page 172 power gating and LEDR encoding”, Proceeding of 7th International Conference on Intelligent System and Control [ISCO 2013]. 3.K. Naveena , N. Kirthika , “ A Low Power Asynchronous FPGA witj Power Gating and Dual Rail Encoding”, IJCSET, March 2012, Vol. 2, Issu 3,949-952. 4. Masanori Hariyama, Shota Ishihara , Chang Chia Wei, Michitaka Kameyama, “A FieldProgrammableVLSIBased on an Asynchronous Bit-Serial Architecture”, IEEE Asian Solid- State Circuits conference, November 12-14, 2007/ Jeju, Korea 5. Narayan V. Sugur, Saroja V. Siddamal, Samba Sivam Vemala, “Design and implementation of High Throughput and Area Efficient Hard Decision Viterbi Decoder in 65 nm Technology”, 2014 27th International Conference on VLSI Design and 2014 13th International conference on Embedded System 6. T.Kalavathidevi, C. Venkatesh, “ Low Power VLSI Architecture of Viterbi Decoder using Asynchronous Precharge Buffer Dual-Rail Techniques”, 2012/No. 2(34), ISSN 1512-1232 7. Markus Schutz, Florian Huemer, Andreas Steininger, “ A Practical comparison of 2-Phase Delay Insensitive Communication Protocol”, Austrian Workshop on Microelectronics, DOI 10.1109/ Austrochip.2015.11 8. Ethiopia Nigussie, Juha Plosila, Jouni Isoaho, “Current Mode On-Chip Interconnect usingLevel-EncodedTwo-Phase Dual-Rail Encoding”, 1-4244-0921-7107, 2007 IEEE 9. Yoshiya Komotsu, Shota Ishihara, Masanori Hariyama, Michitaka Kameyama, “ An Implementation of an Asynchronous FPGA Based on LEDR/ Four-Phase Dual-Rail Hybrid Architecture”, 978-1-4244-7516-2/11, 2011 IEEE 10. Peggy B. McGee, Melinda Y. Agyekam, Moustafa A. Mohamed, Steven M. Nowick, “ A Level-Encoded Transition Signaling Protocol for High-Throughput Asynchronous Global Communication”, DOI 10.1109/ASYNC.2008.24 IEEE BIOGRAPHIES Sneha Shende received the B.E. degree in Electronics & telecommunication Engineering from Smt. Radhikatai Pandav College of Engineering, Nagpur in 2014 and pursuing MTech degree in Communication Engineering from G. H. Raisoni College of Engineering, Nagpur respectively. Her current research interest includes wireless communication and systems. Surekha Tadse received the B.E. degree in Electronics Engineering from B.D. College of Engineeing, Nagpur and MTech in Electronics from Y.C.C.E, Nagpur and pursuing Ph.D from G.H. Raisoni College of Engineering, Nagpur. In 2010, she joined the department of Electronics & Telecommunication Engineering, G. H. Raisoni College of Engineering, Nagpur, as a Lecturer. Her field ofspecialization includes Communication and Digital Image Processing. She is a member of IEEE, ISTE, IETE.