Design automation tools and libraries for low power digital design

Rahman, Mostafizur; Afonso, Ryan; Tennakoon, Hiran; Sechen, Carl

doi:10.1109/dcas.2010.5955034

Cited by 9 publications

(3 citation statements)

References 9 publications

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“…This incurs long turnaround time with significant human effort in transistor-level placement and routing when creating cell libraries. Automated transistor-sizing tools have been introduced for the provision of fine-tuned drive strength options, mainly focusing on low power design solutions [4]- [7]. Furthermore, on-demand transistor sizers [8] [9] have been developed for real-time library generation working in the digital EDA flow from logic synthesis to physical design.…”

Section: Introductionmentioning

confidence: 99%

Multi-Objective Digital Design Optimization via Improved Drive Granularity Standard Cells

Cao

Bale

Trefzer

2021

IEEE Trans. Circuits Syst. I

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Section: Introductionmentioning

confidence: 99%

Multi-Objective Digital Design Optimization via Improved Drive Granularity Standard Cells

Cao

Bale

Trefzer

2021

IEEE Trans. Circuits Syst. I

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“…Related to the power optimization, at the physical implementation, many technics are used targeting both leakage and dynamic power. [10,11] Gives some technics to reduce power on the cells' element. [12,13] present new technics for power optimization on the design network.…”

Section: Introductionmentioning

confidence: 99%

A New Wire Optimization Approach for Power Reduction in Advanced Technology Nodes

Benallal¹,

Cherif²,

Chentouf³

et al. 2019

Adv. sci. technol. eng. syst. j.

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In advanced technologies nodes, starting from 28 nm to 7 nm and below, the power consumed of integrated circuits (ICs) becomes a big concern. Consequently, actual electronic design automation (EDA) tools are facing many challenges to have low power, reduced area and keep having required performance. To reach required success criteria, and because each picosecond and each picowatt counts, continuous development of new optimization technics is necessary. In this paper, we put to the experiment and analysis a new technic to reduce IC consumed power by optimizing its interconnections (nets). We propose an optimal algorithm and enhance it for a better compromise between having less consumed power and keep having a good design rout-ability. The new wire optimization technic based on an optimal choice of target nets for optimization: which is the list of nets consuming more than 80% of the total power in the interconnection without exceeding 30% of the total number of nets. Experiments on 14 test cases show an average total power saving of 5% on both dynamic and total power.

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“…10) The fast evolution of microelectronics fabrication processes demands a new cell library generation or a library technology migration. The well-organized systematic methodology leads to automated flow, which can reduce design time and costs, provide consistency in the cell library generation process, increase the range of simulation capabilities at the characteristics step, as well as minimize the risk of errors [11], [12]. The rest of this brief is organized as follows.…”

Section: Introductionmentioning

confidence: 99%

Energy and Area Efficient Three-Input XOR/XNORs With Systematic Cell Design Methodology

Nikoubin

Grailoo

2016

IEEE Trans. VLSI Syst.

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In this brief, we propose three efficient three-input XOR/XNOR circuits as the most significant blocks of digital systems with a new systematic cell design methodology (SCDM) in hybrid-CMOS logic style. SCDM, which is an extension of CDM, plays the essential role in designing efficient circuits. At first, it is deliberately given priority to general design goals in a base structure of circuits. This structure is generated systematically by employing binary decision diagram. After that, concerning high flexibility in design targets, SCDM aims to specific ones in the remaining three steps, which are wise selections of basic cells and amend mechanisms, as well as transistor sizing. In the end, the resultant three-input XOR/XNORs enjoy full-swing and fairly balanced outputs. They perform well with supply voltage scaling, and their critical path contains only two transistors. They also outperform their counterparts exhibiting 27%-77% reduction in average energy-delay product in HSPICE simulation based on TSMC 0.13-µm technology. The symmetric schematic topologies significantly simplify and minimize the layout, as 26%-32% improvement in area is demonstrated.Index Terms-Binary decision diagram applications, energy efficiency, hybrid-CMOS logic style, systematic design methodology, three-input XOR/XNOR circuits.

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Design automation tools and libraries for low power digital design

Cited by 9 publications

References 9 publications

Multi-Objective Digital Design Optimization via Improved Drive Granularity Standard Cells

Multi-Objective Digital Design Optimization via Improved Drive Granularity Standard Cells

A New Wire Optimization Approach for Power Reduction in Advanced Technology Nodes

Energy and Area Efficient Three-Input XOR/XNORs With Systematic Cell Design Methodology

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