Programmable Device Circuits and Systems

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A Low Power High Speed Design Using Clustering Based Flip Flop Merging


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1 Department of Electronics and Communication Engineering, Anna University, Regional Office, Madurai, Tamilnadu, India
     

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Lower in power exploitation could be a nice challenge featured up by integrated circuit industry. the main attribute is that the clock power in circuits of VLSI. In today’s VLSI design scenario, power utilization by clocking takes up an important role particularly in style that uses deeply scaled CMOS technology. Practiced power utilization tends to be a vital constraint in trendy IC style. The beneath plan of multi bit flip flop is to reduce the inverter number by sharing among flip flop. Indulging multi bit flip flop in synchronous style is turning into a considerable technique for reducing clock power. The single bit flip flop cells uses a mutual range of inverter that possess high driving capability to drive over clock signal. Grouping of such cells to make multi bit flip flop will spare drive strength, dynamic power and space of common inverter wherever there's no compromise among the mandatory constraint among area and power. In this paper, a Hausdorff clustering algorithm is used to get nearest cluster for merging flip flops. Initially D latch is taken and distance is computed for each flip flops. Then clustering is done using the proposed algorithm. After that combination table is constructed. Finally merging is done. The multi bit technique is introduced in FIR circuit to minimize power moreover as area. In line with the experimental results, our algorithm considerably reduces clock power by 19.8% and it is found that total gate count is reduced from 176 to 132. The delay is curtailed upto 1.9ns which consequently increase the speed.

Keywords

Clock Power, Hausdorff, Manhattan Distance, Merging, Multi Bit Flip Flop.
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  • A Low Power High Speed Design Using Clustering Based Flip Flop Merging

Abstract Views: 209  |  PDF Views: 3

Authors

I. Divona Priscilla
Department of Electronics and Communication Engineering, Anna University, Regional Office, Madurai, Tamilnadu, India
R. Arun Prasath
Department of Electronics and Communication Engineering, Anna University, Regional Office, Madurai, Tamilnadu, India

Abstract


Lower in power exploitation could be a nice challenge featured up by integrated circuit industry. the main attribute is that the clock power in circuits of VLSI. In today’s VLSI design scenario, power utilization by clocking takes up an important role particularly in style that uses deeply scaled CMOS technology. Practiced power utilization tends to be a vital constraint in trendy IC style. The beneath plan of multi bit flip flop is to reduce the inverter number by sharing among flip flop. Indulging multi bit flip flop in synchronous style is turning into a considerable technique for reducing clock power. The single bit flip flop cells uses a mutual range of inverter that possess high driving capability to drive over clock signal. Grouping of such cells to make multi bit flip flop will spare drive strength, dynamic power and space of common inverter wherever there's no compromise among the mandatory constraint among area and power. In this paper, a Hausdorff clustering algorithm is used to get nearest cluster for merging flip flops. Initially D latch is taken and distance is computed for each flip flops. Then clustering is done using the proposed algorithm. After that combination table is constructed. Finally merging is done. The multi bit technique is introduced in FIR circuit to minimize power moreover as area. In line with the experimental results, our algorithm considerably reduces clock power by 19.8% and it is found that total gate count is reduced from 176 to 132. The delay is curtailed upto 1.9ns which consequently increase the speed.

Keywords


Clock Power, Hausdorff, Manhattan Distance, Merging, Multi Bit Flip Flop.