Abstract: In this paper, a 28T full adder using MTCMOS technique design is proposed. Combinational logic has extensive applications in quantum computing, low power VLSI design and optical computing. Reducing power dissipation is one of the most principle subjects in VLSI design today. The subthreshold leakage current becomes a large component of total power dissipation. Low- power design techniques proposed to minimize the active leakage power in nanoscale CMOS very large scale integration (VLSI) systems. In this paper the active power and delay of full adder is analyzed with or without MTCMOS. The power and delay evaluation has been carried out using extensive simulation on the HSPICE circuit simulator. The simulation results are based on 32nm and 45nm Berkeley Predictive Technology Model (BPTM). By using MTCMOS technique in full adder a reduction is observed in the active power is 98.3% in 32nm and 99.1% in 45nm. The reduction in the delay is the 21% for sum output and 25% for carry output in

• Publication Date: 25-May-2014
• DOI: 10.15224/978-1-63248-028-6-02-100
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Abstract: Conventionally, the control strategy of a Fuel Injection Management system is created in the form of hand written Embedded C codes; this cannot be understood by the personnel of other disciplines working on the system. In this paper, the methods to implement model based design for the same control strategy along with production code generation has been discussed, along with the benefits of the model based design adaptation

• Publication Date: 25-May-2014
• DOI: 10.15224/978-1-63248-028-6-01-101
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