Paper Info
Title
A Process Algebra for Reasoning About Quantum Security
Abstract
We present a process algebra for specifying and reasoning about quantum security protocols. Since the computational power of the protocol agents must be restricted to quantum polynomial-time, we introduce the logarithmic cost quantum random access machine (QRAM) similar to [S.A. Cook, R.A. Reckhow, Time bounded random access machines, Journal of Computer and System Sciences 7 (1973) 354-375, E. Knill, Conventions for quantum pseudocode, Technical Report LAUR-96-2724, Los Alamos National Laboratory (1996)], and incorporate it in the syntax of the algebra. Probabilistic transition systems give the semantic for the process algebra. Term reduction is stochastic because quantum computation is probabilistic and, moreover, we consider a uniform scheduler to resolve non-deterministic choices. With the purpose of defining security properties, we introduce observational equivalence and quantum computational indistinguishability, and show that the latter is a congruence relation. A simple corollary of this result asserts that any security property defined via emulation is compositional. Finally, we illustrate our approach by establishing the concept of quantum zero-knowledge protocol.
Year
DOI
Venue
2007
10.1016/j.entcs.2006.12.009
Electr. Notes Theor. Comput. Sci.
Keywords
Field
DocType
polynomial time,process algebra,security protocol,zero knowledge,zero knowledge proof,quantum computer
Quantum Turing machine,Quantum probability,Discrete mathematics,Quantum process,Computer science,Quantum computer,Theoretical computer science,Quantum algorithm,Quantum capacity,Quantum operation,Quantum network
Journal
Volume
ISSN
Citations 
170,
1571-0661
13
PageRank 
References 
Authors
0.69
9
2
Name
Order
Citations
PageRank
Pedro Adão1181.13
Paulo Mateus2334.55