Pushing the Limits Further: Sub-Atomic AES

Markus Stefan Wamser; Georg Sigl

doi:10.1007/978-3-030-15663-3_11

Pushing the Limits Further: Sub-Atomic AES

Markus Stefan Wamser, Georg Sigl

Chair of Security in Information Technology

Technical University of Munich

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

Abstract

The recent trend to connect a plethora of sensors, embedded and ubiquitous systems with low computing power, in short the rise of the Internet of Things, has created a great demand for compact, lightweight and cheap to produce implementations of cryptographic primitives. One approach to meet this demand is the development and standardisation of new tailored primitives, most prominently PRESENT. Yet, the wide proliferation of the Advanced Encryption Standard and the trust it earned through its long history of withstanding cryptanalysis spurred anew the search for small, lightweight implementations of AES. Among the smallest published architectures is the AtomicAES design by Banik et al., who reported a design size of just over 2000 GE. Here we present a new 8-bit serial architecture that has been designed from careful observation of the minimum required connections between storage elements to support all dataflows required for execution of the algorithm. While we reach similar conclusions to previous publications, the new architecture enables us to push the area requirement for a fully featured AES primitive further down by more than 8% from the area requirement of AtomicAES while offering more functionality. Along the way we also answer in the affirmative the open question whether the AES reverse keyschedule can be implemented with negligible hardware overhead based on the forward keyschedule. Our design sets a new record for an 8-bit serial architecture with full functionality for encryption and decryption including the keyschedule, as well as for a sole encryption architecture. Furthermore our design is flexible enough to allow scaling the S-Box architecture from single-cycle to multi-stage pipelined approaches as are required for high operation frequencies or for protection against side-channel attacks. We demonstrate this by instantiating the design with a serial version of the S-Box to reduce the area requirement even further.

Original language	English
Title of host publication	VLSI-SoC
Subtitle of host publication	Opportunities and Challenges Beyond the Internet of Things - 25th IFIP WG 10.5/IEEE International Conference on Very Large Scale Integration, VLSI-SoC 2017, Revised and Extended Selected Papers
Editors	Michail Maniatakos, Ibrahim Abe M. Elfadel, Matteo Sonza Reorda, H. Fatih Ugurdag, José Monteiro, Ricardo Reis
Publisher	Springer New York LLC
Pages	220-239
Number of pages	20
ISBN (Print)	9783030156626
DOIs	https://doi.org/10.1007/978-3-030-15663-3_11
State	Published - 2019
Event	25th IFIP/IEEE International Conference on Very Large Scale Integration, VLSI-SoC 2017 - Abu Dhabi, United Arab Emirates Duration: 23 Oct 2017 → 25 Oct 2017

Publication series

Name	IFIP Advances in Information and Communication Technology
Volume	500
ISSN (Print)	1868-4238
ISSN (Electronic)	1868-422X

Conference

Conference	25th IFIP/IEEE International Conference on Very Large Scale Integration, VLSI-SoC 2017
Country/Territory	United Arab Emirates
City	Abu Dhabi
Period	23/10/17 → 25/10/17

Keywords

8-bit-serial
AES
ASIC
Block cypher
Lightweight
S-Box

Access to Document

10.1007/978-3-030-15663-3_11

Cite this

Wamser, M. S., & Sigl, G. (2019). Pushing the Limits Further: Sub-Atomic AES. In M. Maniatakos, I. A. M. Elfadel, M. Sonza Reorda, H. F. Ugurdag, J. Monteiro, & R. Reis (Eds.), VLSI-SoC: Opportunities and Challenges Beyond the Internet of Things - 25th IFIP WG 10.5/IEEE International Conference on Very Large Scale Integration, VLSI-SoC 2017, Revised and Extended Selected Papers (pp. 220-239). (IFIP Advances in Information and Communication Technology; Vol. 500). Springer New York LLC. https://doi.org/10.1007/978-3-030-15663-3_11

Wamser, Markus Stefan ; Sigl, Georg. / Pushing the Limits Further : Sub-Atomic AES. VLSI-SoC: Opportunities and Challenges Beyond the Internet of Things - 25th IFIP WG 10.5/IEEE International Conference on Very Large Scale Integration, VLSI-SoC 2017, Revised and Extended Selected Papers. editor / Michail Maniatakos ; Ibrahim Abe M. Elfadel ; Matteo Sonza Reorda ; H. Fatih Ugurdag ; José Monteiro ; Ricardo Reis. Springer New York LLC, 2019. pp. 220-239 (IFIP Advances in Information and Communication Technology).

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abstract = "The recent trend to connect a plethora of sensors, embedded and ubiquitous systems with low computing power, in short the rise of the Internet of Things, has created a great demand for compact, lightweight and cheap to produce implementations of cryptographic primitives. One approach to meet this demand is the development and standardisation of new tailored primitives, most prominently PRESENT. Yet, the wide proliferation of the Advanced Encryption Standard and the trust it earned through its long history of withstanding cryptanalysis spurred anew the search for small, lightweight implementations of AES. Among the smallest published architectures is the AtomicAES design by Banik et al., who reported a design size of just over 2000 GE. Here we present a new 8-bit serial architecture that has been designed from careful observation of the minimum required connections between storage elements to support all dataflows required for execution of the algorithm. While we reach similar conclusions to previous publications, the new architecture enables us to push the area requirement for a fully featured AES primitive further down by more than 8% from the area requirement of AtomicAES while offering more functionality. Along the way we also answer in the affirmative the open question whether the AES reverse keyschedule can be implemented with negligible hardware overhead based on the forward keyschedule. Our design sets a new record for an 8-bit serial architecture with full functionality for encryption and decryption including the keyschedule, as well as for a sole encryption architecture. Furthermore our design is flexible enough to allow scaling the S-Box architecture from single-cycle to multi-stage pipelined approaches as are required for high operation frequencies or for protection against side-channel attacks. We demonstrate this by instantiating the design with a serial version of the S-Box to reduce the area requirement even further.",

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Wamser, MS & Sigl, G 2019, Pushing the Limits Further: Sub-Atomic AES. in M Maniatakos, IAM Elfadel, M Sonza Reorda, HF Ugurdag, J Monteiro & R Reis (eds), VLSI-SoC: Opportunities and Challenges Beyond the Internet of Things - 25th IFIP WG 10.5/IEEE International Conference on Very Large Scale Integration, VLSI-SoC 2017, Revised and Extended Selected Papers. IFIP Advances in Information and Communication Technology, vol. 500, Springer New York LLC, pp. 220-239, 25th IFIP/IEEE International Conference on Very Large Scale Integration, VLSI-SoC 2017, Abu Dhabi, United Arab Emirates, 23/10/17. https://doi.org/10.1007/978-3-030-15663-3_11

Pushing the Limits Further: Sub-Atomic AES. / Wamser, Markus Stefan; Sigl, Georg.
VLSI-SoC: Opportunities and Challenges Beyond the Internet of Things - 25th IFIP WG 10.5/IEEE International Conference on Very Large Scale Integration, VLSI-SoC 2017, Revised and Extended Selected Papers. ed. / Michail Maniatakos; Ibrahim Abe M. Elfadel; Matteo Sonza Reorda; H. Fatih Ugurdag; José Monteiro; Ricardo Reis. Springer New York LLC, 2019. p. 220-239 (IFIP Advances in Information and Communication Technology; Vol. 500).

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

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N2 - The recent trend to connect a plethora of sensors, embedded and ubiquitous systems with low computing power, in short the rise of the Internet of Things, has created a great demand for compact, lightweight and cheap to produce implementations of cryptographic primitives. One approach to meet this demand is the development and standardisation of new tailored primitives, most prominently PRESENT. Yet, the wide proliferation of the Advanced Encryption Standard and the trust it earned through its long history of withstanding cryptanalysis spurred anew the search for small, lightweight implementations of AES. Among the smallest published architectures is the AtomicAES design by Banik et al., who reported a design size of just over 2000 GE. Here we present a new 8-bit serial architecture that has been designed from careful observation of the minimum required connections between storage elements to support all dataflows required for execution of the algorithm. While we reach similar conclusions to previous publications, the new architecture enables us to push the area requirement for a fully featured AES primitive further down by more than 8% from the area requirement of AtomicAES while offering more functionality. Along the way we also answer in the affirmative the open question whether the AES reverse keyschedule can be implemented with negligible hardware overhead based on the forward keyschedule. Our design sets a new record for an 8-bit serial architecture with full functionality for encryption and decryption including the keyschedule, as well as for a sole encryption architecture. Furthermore our design is flexible enough to allow scaling the S-Box architecture from single-cycle to multi-stage pipelined approaches as are required for high operation frequencies or for protection against side-channel attacks. We demonstrate this by instantiating the design with a serial version of the S-Box to reduce the area requirement even further.

AB - The recent trend to connect a plethora of sensors, embedded and ubiquitous systems with low computing power, in short the rise of the Internet of Things, has created a great demand for compact, lightweight and cheap to produce implementations of cryptographic primitives. One approach to meet this demand is the development and standardisation of new tailored primitives, most prominently PRESENT. Yet, the wide proliferation of the Advanced Encryption Standard and the trust it earned through its long history of withstanding cryptanalysis spurred anew the search for small, lightweight implementations of AES. Among the smallest published architectures is the AtomicAES design by Banik et al., who reported a design size of just over 2000 GE. Here we present a new 8-bit serial architecture that has been designed from careful observation of the minimum required connections between storage elements to support all dataflows required for execution of the algorithm. While we reach similar conclusions to previous publications, the new architecture enables us to push the area requirement for a fully featured AES primitive further down by more than 8% from the area requirement of AtomicAES while offering more functionality. Along the way we also answer in the affirmative the open question whether the AES reverse keyschedule can be implemented with negligible hardware overhead based on the forward keyschedule. Our design sets a new record for an 8-bit serial architecture with full functionality for encryption and decryption including the keyschedule, as well as for a sole encryption architecture. Furthermore our design is flexible enough to allow scaling the S-Box architecture from single-cycle to multi-stage pipelined approaches as are required for high operation frequencies or for protection against side-channel attacks. We demonstrate this by instantiating the design with a serial version of the S-Box to reduce the area requirement even further.

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Wamser MS, Sigl G. Pushing the Limits Further: Sub-Atomic AES. In Maniatakos M, Elfadel IAM, Sonza Reorda M, Ugurdag HF, Monteiro J, Reis R, editors, VLSI-SoC: Opportunities and Challenges Beyond the Internet of Things - 25th IFIP WG 10.5/IEEE International Conference on Very Large Scale Integration, VLSI-SoC 2017, Revised and Extended Selected Papers. Springer New York LLC. 2019. p. 220-239. (IFIP Advances in Information and Communication Technology). doi: 10.1007/978-3-030-15663-3_11

Pushing the Limits Further: Sub-Atomic AES

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Keywords

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