TY - GEN
T1 - Application of mismatched cellular nonlinear networks for physical cryptography
AU - Csaba, György
AU - Ju, Xueming
AU - Ma, Zhiqian
AU - Chen, Qingqing
AU - Porod, Wolfgang
AU - Schmidhuber, Jürgen
AU - Schlichtmann, Ulf
AU - Lugli, Paolo
AU - Rührmair, Ulrich
PY - 2010
Y1 - 2010
N2 - This paper proposes the use of Cellular Non-Linear Networks (CNNs) as physical uncloneable functions (PUFs). We argue that analog circuits offer higher security than existing digital PUFs and that the CNN paradigm allows us to build large, unclonable, and scalable analog PUFs, which still show a stable and repeatable input-output behavior. CNNs are dynamical arrays of locally-interconected cells, with a cell dynamics that depends upon the interconnection strengths to their neighbors. They can be designed to evolve in time according to partial differential equations. If this equation describes a physical phenomenon, then the CNN can simulate a complex physical system on-chip. This can be exploited to create electrical PUFs with high relevant structural information content. To illustrate our paradigm at work, we design a circuit that directly emulates nonlinear wave propagation phenomena in a random media. It effectively translates the complexity of optical PUFs into electrical circuits.
AB - This paper proposes the use of Cellular Non-Linear Networks (CNNs) as physical uncloneable functions (PUFs). We argue that analog circuits offer higher security than existing digital PUFs and that the CNN paradigm allows us to build large, unclonable, and scalable analog PUFs, which still show a stable and repeatable input-output behavior. CNNs are dynamical arrays of locally-interconected cells, with a cell dynamics that depends upon the interconnection strengths to their neighbors. They can be designed to evolve in time according to partial differential equations. If this equation describes a physical phenomenon, then the CNN can simulate a complex physical system on-chip. This can be exploited to create electrical PUFs with high relevant structural information content. To illustrate our paradigm at work, we design a circuit that directly emulates nonlinear wave propagation phenomena in a random media. It effectively translates the complexity of optical PUFs into electrical circuits.
KW - Analog circuits
KW - Cellular nonlinear networks (CNN)
KW - Physical cryptography
KW - Physical uncloneable functions (PUF)
UR - http://www.scopus.com/inward/record.url?scp=77952339214&partnerID=8YFLogxK
U2 - 10.1109/cnna.2010.5430303
DO - 10.1109/cnna.2010.5430303
M3 - Conference contribution
AN - SCOPUS:77952339214
SN - 9781424466795
T3 - 2010 12th International Workshop on Cellular Nanoscale Networks and their Applications, CNNA 2010
BT - 2010 12th International Workshop on Cellular Nanoscale Networks and their Applications, CNNA 2010
PB - IEEE Computer Society
T2 - 2010 12th International Workshop on Cellular Nanoscale Networks and their Applications, CNNA 2010
Y2 - 3 February 2010 through 5 February 2010
ER -