Improving the Efficiency of Quantum Circuits for Information Set Decoding

The NIST Post-Quantum standardization initiative, that entered its fourth round, aims to select asymmetric cryptosystems secure against attacker equipped with a quantum computer. Code-based cryptosystems are a promising option for Post-Quantum Cryptography (PQC), as neither classical nor quantum algorithms provide polynomial time solvers for its underlying hard problems. Indeed, to provide sound alternatives to lattice-based cryptosystems, NIST advanced all round 3 code-based cryptosystems to round 4. We present a complete implementation of a quantum circuit based on the Information Set Decoding (ISD) strategy, the best known one against code-based cryptosystems, providing quantitative measures for the security margin achieved with respect to the quantum-accelerated key recovery on AES, targeting both the current state-of-the-art approach and the NIST estimates. Our work improves the state-of-the-art, reducing the circuit depth from 2¹⁹ to 2³⁰ for all the parameters of the NIST selected cryptosystems. We further analyse recently proposed optimizations, showing that the overhead introduced by their implementation overcomes their asymptotic advantages. Finally, we address the concern brought forward in the latest NIST report on the parameters choice for the McEliece cryptosystem, showing that the parameter choice yields a computational effort which is slightly below the required target level

Health Care Resource Utilization Costs Related to Anaemia Management in Chronic Kidney Disease Non-Dialysed Patients: A Retrospective Clinical and Administrative Database Analysis

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Supporting Concurrency and Multiple Indexes in Private Access to Outsourced Data

Data outsourcing has recently emerged as a successful solution allowing individuals and organizations to delegate data and service management to external third parties. A major challenge in the data outsourcing scenario is how to guarantee proper privacy protection against the external server. Recent promising approaches rely on the organization of data in indexing structures that use encryption and the dynamic allocation of encrypted data to physical blocks for destroying the otherwise static relationship between data and the blocks in which they are stored. However, dynamic data allocation implies the need to re-write blocks at every read access, thus requesting exclusive locks that can affect concurrency. Also, these solutions only support search conditions on the values of the attribute used for building the indexing structure. In this paper, we present an approach that overcomes such limitations by extending the recently proposed shuffle index structure with support for concurrency and multiple indexes. Support for concurrency relies on the use of several differential versions of the data index that are periodically reconciled and applied to the main data structure. Support for multiple indexes relies on the definition of secondary shuffle indexes that are then combined with the primary index in a single data structure whose content and allocation is unintelligible to the server. We show how using such differential versions and combined index structure guarantees privacy, provides support for concurrent accesses and multiple search conditions, and considerably increases the performance of the system and the applicability of the proposed solution

Status of Salerno Laboratory (Measurements in Nuclear Emulsion)

A report on the analysis work in the Salerno Emulsion Laboratory is presented. It is related to the search for nu_mu->nu_tau oscillations in CHORUS experiment, the calibrations in the WANF (West Area Neutrino Facility) at Cern and tests and preparation for new experiments.Comment: Proc. The First International Workshop of Nuclear Emulsion Techniques (12-24 June 1998, Nagoya, Japan), 15 pages, 11 figure