Hybrid Logical Effort for Hybrid Logic Style Full Adders in Multistage Structures
One of the critical issues in the advancement of very large scale of integration circuit design is the estimation of timing behavior of the arithmetic circuits. The concept of logical effort provides a proficient approach to comprehend and assess the timing behavior of circuits with conventional CMO...
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| Veröffentlicht in: | IEEE transactions on very large scale integration (VLSI) systems 2019-05, Vol.27 (5), p.1138-1147 |
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| container_title | IEEE transactions on very large scale integration (VLSI) systems |
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| creator | basireddy, hareesh-reddy challa, Karthikeya Nikoubin, Tooraj |
| description | One of the critical issues in the advancement of very large scale of integration circuit design is the estimation of timing behavior of the arithmetic circuits. The concept of logical effort provides a proficient approach to comprehend and assess the timing behavior of circuits with conventional CMOS (C-CMOS) structure. However, this technique is not working for circuits with a hybrid structure. On the other hand, numerous circuits with the hybrid structure which are faster and consume less power than C-CMOS one have been proposed for different applications such as portable and IoT devices. In this regard, the necessity of having and use of a simple and efficient timing behavior method like conventional logical effort for analysis of the hybrid adder circuits is inevitable. This paper proposes an efficient analysis and modeling technique that enables designers to assess the timing behavior of hybrid full adder circuits at the block level and anticipate their performance in multistage circuits. The gain and selection factor are introduced as a criterion for accurate selection and optimization of the hybrid adder cells measurable on the single test bench for management of energy efficiency and performance tradeoff. The proposed method is investigated using 32-nm CMOS and FinFET technologies. |
| doi_str_mv | 10.1109/TVLSI.2018.2889833 |
| format | Article |
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The concept of logical effort provides a proficient approach to comprehend and assess the timing behavior of circuits with conventional CMOS (C-CMOS) structure. However, this technique is not working for circuits with a hybrid structure. On the other hand, numerous circuits with the hybrid structure which are faster and consume less power than C-CMOS one have been proposed for different applications such as portable and IoT devices. In this regard, the necessity of having and use of a simple and efficient timing behavior method like conventional logical effort for analysis of the hybrid adder circuits is inevitable. This paper proposes an efficient analysis and modeling technique that enables designers to assess the timing behavior of hybrid full adder circuits at the block level and anticipate their performance in multistage circuits. The gain and selection factor are introduced as a criterion for accurate selection and optimization of the hybrid adder cells measurable on the single test bench for management of energy efficiency and performance tradeoff. 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The concept of logical effort provides a proficient approach to comprehend and assess the timing behavior of circuits with conventional CMOS (C-CMOS) structure. However, this technique is not working for circuits with a hybrid structure. On the other hand, numerous circuits with the hybrid structure which are faster and consume less power than C-CMOS one have been proposed for different applications such as portable and IoT devices. In this regard, the necessity of having and use of a simple and efficient timing behavior method like conventional logical effort for analysis of the hybrid adder circuits is inevitable. This paper proposes an efficient analysis and modeling technique that enables designers to assess the timing behavior of hybrid full adder circuits at the block level and anticipate their performance in multistage circuits. The gain and selection factor are introduced as a criterion for accurate selection and optimization of the hybrid adder cells measurable on the single test bench for management of energy efficiency and performance tradeoff. The proposed method is investigated using 32-nm CMOS and FinFET technologies.</description><subject>Adders</subject><subject>Adding circuits</subject><subject>Capacitance</subject><subject>Circuit design</subject><subject>CMOS</subject><subject>Delays</subject><subject>Drivability</subject><subject>Energy management</subject><subject>hybrid CMOS</subject><subject>hybrid logical effort</subject><subject>Hybrid structures</subject><subject>input capacitance</subject><subject>Integrated circuit modeling</subject><subject>Large scale integration</subject><subject>Logic gates</subject><subject>logical effort</subject><subject>Multistage</subject><subject>Optimization</subject><subject>Portable equipment</subject><subject>Power consumption</subject><subject>Power management</subject><subject>timing behavior</subject><subject>Transistors</subject><subject>Very large scale</subject><issn>1063-8210</issn><issn>1557-9999</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2019</creationdate><recordtype>article</recordtype><sourceid>RIE</sourceid><recordid>eNpNkEFLAzEQhYMoWKt_QC8Bz1szSXY3OZbS2sKKSKvXkN0kZcvarUn20H9vakWcw8zAm_cGPoTugUwAiHzafFTr1YQSEBMqhBSMXaAR5HmZyVSXaScFywQFco1uQtgRApxLMkJvy2PtW4Orfts2usNz53ofcWr4v4LX8dhZvBi6Dk-NsT7gdo9fhi62IeqtTbofmjh4G27RldNdsHe_c4zeF_PNbJlVr8-r2bTKGirzmOVQuLIgxtS5pJICcMKB0obbGgiTUtfaUCYt06TULi-1Zo3jJTNOmNJywcbo8Zx78P3XYENUu37w-_RSUQopvpC0SFf0fNX4PgRvnTr49lP7owKiTujUDzp1Qqd-0SXTw9nUWmv_DKKgBXDKvgHb7Wnp</recordid><startdate>20190501</startdate><enddate>20190501</enddate><creator>basireddy, hareesh-reddy</creator><creator>challa, Karthikeya</creator><creator>Nikoubin, Tooraj</creator><general>IEEE</general><general>The Institute of Electrical and Electronics Engineers, Inc. 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The concept of logical effort provides a proficient approach to comprehend and assess the timing behavior of circuits with conventional CMOS (C-CMOS) structure. However, this technique is not working for circuits with a hybrid structure. On the other hand, numerous circuits with the hybrid structure which are faster and consume less power than C-CMOS one have been proposed for different applications such as portable and IoT devices. In this regard, the necessity of having and use of a simple and efficient timing behavior method like conventional logical effort for analysis of the hybrid adder circuits is inevitable. This paper proposes an efficient analysis and modeling technique that enables designers to assess the timing behavior of hybrid full adder circuits at the block level and anticipate their performance in multistage circuits. 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| ispartof | IEEE transactions on very large scale integration (VLSI) systems, 2019-05, Vol.27 (5), p.1138-1147 |
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| subjects | Adders Adding circuits Capacitance Circuit design CMOS Delays Drivability Energy management hybrid CMOS hybrid logical effort Hybrid structures input capacitance Integrated circuit modeling Large scale integration Logic gates logical effort Multistage Optimization Portable equipment Power consumption Power management timing behavior Transistors Very large scale |
| title | Hybrid Logical Effort for Hybrid Logic Style Full Adders in Multistage Structures |
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