A Highly Regular and Scalable AES Hardware Architecture

Stefan Mangard; Manfred Aigner; Sandra Dominikus

doi:10.1109/TC.2003.1190589

A Highly Regular and Scalable AES Hardware Architecture

Stefan Mangard, Manfred Aigner, Sandra Dominikus

Institute of Applied Information Processing and Communications (7050)

Research output: Contribution to journal › Article › peer-review

Abstract

This article presents a highly regular and scalable AES hardware architecture, suited for full-custom as well as for semicustom design flows. Contrary to other publications, a complete architecture (even including CBC mode) that is scalable in terms of throughput and in terms of the used key size is described. Similarities of encryption and decryption are utilized to provide a high level of performance using only a relatively small area (10,799 gate equivalents for the standard configuration). This performance is reached by balancing the combinational paths of the design. No other published AES hardware architecture provides similar balancing or a comparable regularity. Implementations of the fastest configuration of the architecture provide a throughput of 241 Mbits/sec on a 0.6 /spl mu/m CMOS process using standard cells.

Original language	English
Pages (from-to)	483-491
Journal	IEEE Transactions on Computers
Volume	52
Issue number	4
DOIs	https://doi.org/10.1109/TC.2003.1190589
Publication status	Published - 2003

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10.1109/TC.2003.1190589

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title = "A Highly Regular and Scalable AES Hardware Architecture",

abstract = "This article presents a highly regular and scalable AES hardware architecture, suited for full-custom as well as for semicustom design flows. Contrary to other publications, a complete architecture (even including CBC mode) that is scalable in terms of throughput and in terms of the used key size is described. Similarities of encryption and decryption are utilized to provide a high level of performance using only a relatively small area (10,799 gate equivalents for the standard configuration). This performance is reached by balancing the combinational paths of the design. No other published AES hardware architecture provides similar balancing or a comparable regularity. Implementations of the fastest configuration of the architecture provide a throughput of 241 Mbits/sec on a 0.6 /spl mu/m CMOS process using standard cells.",

author = "Stefan Mangard and Manfred Aigner and Sandra Dominikus",

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AB - This article presents a highly regular and scalable AES hardware architecture, suited for full-custom as well as for semicustom design flows. Contrary to other publications, a complete architecture (even including CBC mode) that is scalable in terms of throughput and in terms of the used key size is described. Similarities of encryption and decryption are utilized to provide a high level of performance using only a relatively small area (10,799 gate equivalents for the standard configuration). This performance is reached by balancing the combinational paths of the design. No other published AES hardware architecture provides similar balancing or a comparable regularity. Implementations of the fastest configuration of the architecture provide a throughput of 241 Mbits/sec on a 0.6 /spl mu/m CMOS process using standard cells.

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A Highly Regular and Scalable AES Hardware Architecture

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Crypto Module with USB Interface (USB_CRYPT)

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A Highly Regular and Scalable AES Hardware Architecture

Abstract

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Crypto Module with USB Interface (USB_CRYPT)

VLSI Design

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