IEICE TRANSACTIONS on Information
Strongly Secure Scan Design Using Generalized Feed Forward Shift Registers
Summary :
In our previous work [12], [13], we introduced generalized feed-forward shift registers (GF2SR, for short) to apply them to secure and testable scan design, where we considered the security problem from the viewpoint of the complexity of identifying the structure of GF2SRs. Although the proposed scan design is secure in the sense that the structure of a GF2SR cannot be identified only from the primary input/output relation, it may not be secure if part of the contents of the circuit leak out. In this paper, we introduce a more secure concept called strong security such that no internal state of strongly secure circuits leaks out, and present how to design such strongly secure GF2SRs.
- Publication
- IEICE TRANSACTIONS on Information Vol.E98-D No.10 pp.1852-1855
- Publication Date
- 2015/10/01
- Publicized
- 2015/06/24
- Online ISSN
- 1745-1361
- DOI
- 10.1587/transinf.2015EDL8100
- Type of Manuscript
- LETTER
- Category
- Dependable Computing
Authors
Hideo FUJIWARA
Osaka Gakuin University
Katsuya FUJIWARA
Akita University
Keyword
Latest Issue
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Hideo FUJIWARA, Katsuya FUJIWARA, "Strongly Secure Scan Design Using Generalized Feed Forward Shift Registers" in IEICE TRANSACTIONS on Information,
vol. E98-D, no. 10, pp. 1852-1855, October 2015, doi: 10.1587/transinf.2015EDL8100.
Abstract: In our previous work [12], [13], we introduced generalized feed-forward shift registers (GF2SR, for short) to apply them to secure and testable scan design, where we considered the security problem from the viewpoint of the complexity of identifying the structure of GF2SRs. Although the proposed scan design is secure in the sense that the structure of a GF2SR cannot be identified only from the primary input/output relation, it may not be secure if part of the contents of the circuit leak out. In this paper, we introduce a more secure concept called strong security such that no internal state of strongly secure circuits leaks out, and present how to design such strongly secure GF2SRs.
URL: https://global.ieice.org/en_transactions/information/10.1587/transinf.2015EDL8100/_p
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@ARTICLE{e98-d_10_1852,
author={Hideo FUJIWARA, Katsuya FUJIWARA, },
journal={IEICE TRANSACTIONS on Information},
title={Strongly Secure Scan Design Using Generalized Feed Forward Shift Registers},
year={2015},
volume={E98-D},
number={10},
pages={1852-1855},
abstract={In our previous work [12], [13], we introduced generalized feed-forward shift registers (GF2SR, for short) to apply them to secure and testable scan design, where we considered the security problem from the viewpoint of the complexity of identifying the structure of GF2SRs. Although the proposed scan design is secure in the sense that the structure of a GF2SR cannot be identified only from the primary input/output relation, it may not be secure if part of the contents of the circuit leak out. In this paper, we introduce a more secure concept called strong security such that no internal state of strongly secure circuits leaks out, and present how to design such strongly secure GF2SRs.},
keywords={},
doi={10.1587/transinf.2015EDL8100},
ISSN={1745-1361},
month={October},}
Copy
TY - JOUR
TI - Strongly Secure Scan Design Using Generalized Feed Forward Shift Registers
T2 - IEICE TRANSACTIONS on Information
SP - 1852
EP - 1855
AU - Hideo FUJIWARA
AU - Katsuya FUJIWARA
PY - 2015
DO - 10.1587/transinf.2015EDL8100
JO - IEICE TRANSACTIONS on Information
SN - 1745-1361
VL - E98-D
IS - 10
JA - IEICE TRANSACTIONS on Information
Y1 - October 2015
AB - In our previous work [12], [13], we introduced generalized feed-forward shift registers (GF2SR, for short) to apply them to secure and testable scan design, where we considered the security problem from the viewpoint of the complexity of identifying the structure of GF2SRs. Although the proposed scan design is secure in the sense that the structure of a GF2SR cannot be identified only from the primary input/output relation, it may not be secure if part of the contents of the circuit leak out. In this paper, we introduce a more secure concept called strong security such that no internal state of strongly secure circuits leaks out, and present how to design such strongly secure GF2SRs.
ER -
English
