Design of a 3-D stacked floating-point adder

Jubee Tada; Ryusuke Egawa; Hiroaki Kobayashi

doi:10.1109/3DIC.2013.6702390

Design of a 3-D stacked floating-point adder

Jubee Tada, Ryusuke Egawa, Hiroaki Kobayashi

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

1 Citation (Scopus)

Abstract

Three-dimensional (3-D) stacked integrated circuit (SIC) technologies have been expected to overcome the limitation in the design of microprocessors integrated by two-dimensional (2-D) implementations. 3-D SIC technologies enable to stack multiple integrated silicon layers. In the design of 3-D stacked arithmetic units, the circuits are partitioned into several subcircuits, and each sub-circuit is placed on one layer. In order to exploit the potential of the 3-D SIC, a sophisticated partitioning should be required. In this paper, four partitioning patterns for a 3-D stacked floating-point adder are proposed, which are based on two basic ideas. One idea focuses on the structure of a 2-path floating point adder, and the other idea focuses on the large barrel shifters. Four implementations of a 3-D stacked double-precision floating-point adder are designed based on these partitioning patterns and evaluated. Experimental results show that the 3D stacked double precision floating-point adder implemented on four layers achieves up to a 16.4% delay reduction compared to the 2-D implementation.

Original language	English
Title of host publication	2013 IEEE International 3D Systems Integration Conference, 3DIC 2013
DOIs	https://doi.org/10.1109/3DIC.2013.6702390
Publication status	Published - 2013 Dec 1
Event	2013 IEEE International 3D Systems Integration Conference, 3DIC 2013 - San Francisco, CA, United States Duration: 2013 Oct 2 → 2013 Oct 4

Publication series

Name	2013 IEEE International 3D Systems Integration Conference, 3DIC 2013

Other

Other	2013 IEEE International 3D Systems Integration Conference, 3DIC 2013
Country/Territory	United States
City	San Francisco, CA
Period	13/10/2 → 13/10/4

ASJC Scopus subject areas

Computer Graphics and Computer-Aided Design
Computer Science Applications

Access to Document

10.1109/3DIC.2013.6702390

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Tada, J, Egawa, R & Kobayashi, H 2013, Design of a 3-D stacked floating-point adder. in 2013 IEEE International 3D Systems Integration Conference, 3DIC 2013., 6702390, 2013 IEEE International 3D Systems Integration Conference, 3DIC 2013, 2013 IEEE International 3D Systems Integration Conference, 3DIC 2013, San Francisco, CA, United States, 13/10/2. https://doi.org/10.1109/3DIC.2013.6702390

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title = "Design of a 3-D stacked floating-point adder",

abstract = "Three-dimensional (3-D) stacked integrated circuit (SIC) technologies have been expected to overcome the limitation in the design of microprocessors integrated by two-dimensional (2-D) implementations. 3-D SIC technologies enable to stack multiple integrated silicon layers. In the design of 3-D stacked arithmetic units, the circuits are partitioned into several subcircuits, and each sub-circuit is placed on one layer. In order to exploit the potential of the 3-D SIC, a sophisticated partitioning should be required. In this paper, four partitioning patterns for a 3-D stacked floating-point adder are proposed, which are based on two basic ideas. One idea focuses on the structure of a 2-path floating point adder, and the other idea focuses on the large barrel shifters. Four implementations of a 3-D stacked double-precision floating-point adder are designed based on these partitioning patterns and evaluated. Experimental results show that the 3D stacked double precision floating-point adder implemented on four layers achieves up to a 16.4% delay reduction compared to the 2-D implementation.",

author = "Jubee Tada and Ryusuke Egawa and Hiroaki Kobayashi",

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doi = "10.1109/3DIC.2013.6702390",

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series = "2013 IEEE International 3D Systems Integration Conference, 3DIC 2013",

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AU - Tada, Jubee

AU - Egawa, Ryusuke

AU - Kobayashi, Hiroaki

PY - 2013/12/1

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N2 - Three-dimensional (3-D) stacked integrated circuit (SIC) technologies have been expected to overcome the limitation in the design of microprocessors integrated by two-dimensional (2-D) implementations. 3-D SIC technologies enable to stack multiple integrated silicon layers. In the design of 3-D stacked arithmetic units, the circuits are partitioned into several subcircuits, and each sub-circuit is placed on one layer. In order to exploit the potential of the 3-D SIC, a sophisticated partitioning should be required. In this paper, four partitioning patterns for a 3-D stacked floating-point adder are proposed, which are based on two basic ideas. One idea focuses on the structure of a 2-path floating point adder, and the other idea focuses on the large barrel shifters. Four implementations of a 3-D stacked double-precision floating-point adder are designed based on these partitioning patterns and evaluated. Experimental results show that the 3D stacked double precision floating-point adder implemented on four layers achieves up to a 16.4% delay reduction compared to the 2-D implementation.

AB - Three-dimensional (3-D) stacked integrated circuit (SIC) technologies have been expected to overcome the limitation in the design of microprocessors integrated by two-dimensional (2-D) implementations. 3-D SIC technologies enable to stack multiple integrated silicon layers. In the design of 3-D stacked arithmetic units, the circuits are partitioned into several subcircuits, and each sub-circuit is placed on one layer. In order to exploit the potential of the 3-D SIC, a sophisticated partitioning should be required. In this paper, four partitioning patterns for a 3-D stacked floating-point adder are proposed, which are based on two basic ideas. One idea focuses on the structure of a 2-path floating point adder, and the other idea focuses on the large barrel shifters. Four implementations of a 3-D stacked double-precision floating-point adder are designed based on these partitioning patterns and evaluated. Experimental results show that the 3D stacked double precision floating-point adder implemented on four layers achieves up to a 16.4% delay reduction compared to the 2-D implementation.

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M3 - Conference contribution

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ER -

Design of a 3-D stacked floating-point adder

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