Abstract
In the presence of several critical issues during data acquisition in industrial-informatics-based applications, like Internet of Things (IoT) and smart grid, this article proposes a novel framework based on compressive sensing (CS) and a cascade chaotic system (CCS). This framework can ensure low overhead, confidentiality, and authentication. Based on CS and the CCS, three technologies, including CCS-driven CS, CCS-driven local perturbation, and authentication mechanism, are introduced in the proposed data acquisition framework in this article. CCS-driven CS generates the measurement matrix with chaotic initial conditions and avoids the transmission of a large-size measurement matrix. CCS-driven local perturbation only perturbs a small number of elements in the original measurement matrix for each sampling and avoids the regeneration of the large-size measurement matrix. The authentication mechanism employs the authentication password and the access password to deal with the passive tampering attack and the active tampering attack, respectively. Moreover, the permutation-diffusion structure is used to encrypt the obtained measurements to enhance the security. Both theoretical and experimental analyses validate low overhead, confidentiality, and effective authentication of the proposed data acquisition framework for a number of industrial-informatics-based applications, such as IoT.
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