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ABOUT
Seeking a position to utilize my skills and abilities with professional growth while being resourceful, innovative, hardworking and flexible. Also, having the ability to deal with people diplomatically and a willingness to learn.
Research Interests
Quantum Dot Cellular Automata, FPGA based system design, Smart sensor network and IOT, Artificial Intelligence and Machine Learning
Copyright
QCA Architecture of a Multilayer Content Addressable Memory Cell for Superior Processing Speed
Quantum-dot Cellular Automata (QCA) has been presented as rising nanotechnology for future circuit plans. This innovation is perhaps the right option in contrast to the CMOS circuits. The key building squares of various circuits in QCA are the inverter and majority voter gate. Additionally, in later applications, low-power models have proved to be very significant. We also have to reconfigure low-control components. In the present context we propose a Content Addressable Memory (CAM) cell that may be utilized in very high speed searching applications unlike single layer applications where searching speed is not very efficient. The proposed plan shows a significant improvement in terms of design complexity, area usage and energy consumption.
Copyright
Quantum Dot Cellular Automata-Based Secure Nano Communication Network
QCA “Quantum Dot-Cellular Automata” is another nanotechnology model, which fills in an elective answer for CMOS that have numerous actual cutoff points and heaps of hardware limits. QCA is a semiconductor less innovation as well as data is passed dependent on electron charge and by common electrostatic repugnance among them. QCA has exceptionally higher gadget thickness, quicker exchanging speed timing and very low force utilization. QCA circuits in cryptographic application may assume a significant part. Both unscrambling as well as encryption measure is executed utilizing rationale circuit based on QCA. The research paper depicts fundamental method for creating figure text in QCA, which may be useful in secure nancommunication based on QCA. The results’ execution along with testing is carried out by utilizing QCA Designer-2.0.3.
Copyright
Quantum Dot Cellular Automata-Based Parity Generator with Secure Communication Gateway
Quantum-Dot Cellular Automata (QCA) has arisen as a potential option in contrast to CMOS in the late time of nanotechnology. Some appealing high-lights of QCA incorporate incredibly low force utilization and dissemination, high gadget pressing thickness, high velocity (arranged by THz). QCA based plans of normal advanced modules were concentrated broadly in the ongoing past. Equality generator and equality checker circuits assume a significant part in blunder discovery and subsequently, go about as fundamental segments in correspondence circuits. In any case, not very many endeavours were made for an efficient plan of QCA-based equality generator as well as equality checker circuits up until now. In addition, these current plans need functional feasibility as they bargain a ton with normally acknowledged plan measurements like territory, postponement, intricacy, and manufacturing cost. This article depicts new plans for equality generator and equality checker circuits in QCA which beat every one of the current plans as far as previously mentioned measurements. The proposed plans can likewise be effortlessly reached out to deal with an enormous number of contributions with a straight expansion in territory and inactivity.
Conference Proceeding
Secure Communication Gateway with Parity Generator Implementation in QCA Platform
The proposed circuit is relevant for prediction of nature in cryptographic architecture for QCA based secure nano communication framework has proposed the secure communication cryptographic framework by exploiting the proposed circuit in this work. Thus, it may be reproducing the more enhanced the suitable
prediction for the architecture of the proposed and authenticated symmetric cryptographic model in this proposed work. Actually, in this work, we have to implement such kind of circuit that is also utilized for secure communication.For parity generator, we have already considered the several Inputs and output,
and mainly consider for checking any error in bitstream but the major consideration is been depicted the realization of Pseudorandom Binary Sequence (PRBS)
which is used as a keystream for the nano communication and act the suitable,one for bit changes for every interval of time. This work is being considered for a secure way to predict a large number of cells is consist of the majority gate in the inverter. In Table six majority gate and four inverters, we have to consider. But to a large extent that is to utilize the channel coding application, it is required only one parity generator and the complexity is 14 majority gates and four inverters. Thus, we proposed a secure way to require a more efficient channel coding application in Quantum Dot Cellular Automata (QCA) framework.