Silicon on Insulator C-VTFET Based Design of low Complexity Sparse Quadrature Mirror Filter Using Differential Search Algorithm

In this paper, a 60 nm Complementary-Vertical TFET (C-VTFET) is designed using silicon on insulation technology is implemented for low power quadrature mirror filter design for different search algorithm using silvaco TCAD simulation. Various advantages of SOI have been incorporated for the realizat...

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Bibliographic Details
Published in:SILICON 2022-11, Vol.14 (17), p.11545-11560
Main Authors: Singh, Hitendra, Dwivedi, Atul Kumar, Nagaria, Deepak
Format: Article
Language:English
Subjects:
Algorithms
Chemistry
Chemistry and Materials Science
Circuit design
Complexity
Digital electronics
Electric potential
Environmental Chemistry
Evolutionary algorithms
Filter design (mathematics)
Inorganic Chemistry
Ion currents
Lasers
Materials Science
Optical Devices
Optics
Optimization
Optimization techniques
Original Paper
Photonics
Polymer Sciences
Power management
Quadratures
Search algorithms
Search methods
Silicon dioxide
Staking
Voltage
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Summary:In this paper, a 60 nm Complementary-Vertical TFET (C-VTFET) is designed using silicon on insulation technology is implemented for low power quadrature mirror filter design for different search algorithm using silvaco TCAD simulation. Various advantages of SOI have been incorporated for the realization of low-voltage with low power (LVLP) for VLSI design digital circuits. To prevent the losses of the Lattice mismatch structure, gate staking of high k -dielectric (HfO 2 ) material with SiO 2 was employed using equivalent oxide thickness method. Various engineering method incorporated to optimized the Drain-Voltage characteristics. N-Type and P-Type VTFET is considered using the mixed mode technique. The SiGe layer is employed to enhance the tunneling method of by reducing the bandgap from 1.1 eV to 0.7 eV. The highest I ON current and minimum I OFF current is reported for the proposed device is I (3.62 × 10 −4 A/μm) and (1.58 × 10 −18 A/μm) respectively. The ON/OFF current ratio out recorded as ~10 13 respectively. The reconstruction quadrature mirror filter architecture in this manuscript is computationally efficient and virtually flawless. Sparsity among the coefficients is introduced to reduce the number of multipliers and adders required to construct prototype the filter H 0 (Z), resulting in a reduction in computational complexity. A well-known population-based evolutionary optimization differential search algorithm is used to optimized the objective function. However, Levy’s differential search method is also advocated due to sluggish exploitation of traditional differential search algorithm. The suggested algorithm’s effectiveness is evaluated by comparing it to other evolutionary optimization techniques. The results demonstrate that the proposed technique outperforms previously published evolutionary optimization algorithms. The above analysis validated the proposed device are well incorporated for the execution to design low power filter design.
ISSN:1876-990X
1876-9918
DOI:10.1007/s12633-022-01858-6