Physical unclonable functions PUFs can be used as a cost-effective means to store cryptographic k... more Physical unclonable functions PUFs can be used as a cost-effective means to store cryptographic key material in an unclonable way. In coating PUFs, keys are generated from capacitance measurements of a coating containing many randomly distributed particles with different dielectric ...
We revisit the notion of Kolmogorov-Sinai entropy for classical dynamical systems in terms of an ... more We revisit the notion of Kolmogorov-Sinai entropy for classical dynamical systems in terms of an algebraic formalism. This is the starting point for defining the entropy for general non-commutative systems. Hereby typical quantum tools are introduced in the statistical description of classical dynamical systems. We illustrate the power of these techniques by providing a simple, self-contained proof of the entropy formula for general automorphisms of n-dimensional tori.
Physical unclonable functions PUFs can be used as a cost-effective means to store cryptographic k... more Physical unclonable functions PUFs can be used as a cost-effective means to store cryptographic key material in an unclonable way. In coating PUFs, keys are generated from capacitance measurements of a coating containing many randomly distributed particles with different dielectric ...
We revisit the notion of Kolmogorov-Sinai entropy for classical dynamical systems in terms of an ... more We revisit the notion of Kolmogorov-Sinai entropy for classical dynamical systems in terms of an algebraic formalism. This is the starting point for defining the entropy for general non-commutative systems. Hereby typical quantum tools are introduced in the statistical description of classical dynamical systems. We illustrate the power of these techniques by providing a simple, self-contained proof of the entropy formula for general automorphisms of n-dimensional tori.
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Papers by Pim Tuyls