Securing the IoT : introducing an evaluation platform for secure elements

Zimmerli, Lea; Schläpfer, Tobias; Rüst, Andreas

doi:10.21256/zhaw-18794

Cited by 1 publication

(1 citation statement)

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“…Nevertheless, these secure elements can also support a (D)TLS stack running on the MCU, making them very versatile. Further theoretical foundations concerning secure elements can be found in our previously released papers: chapter II "Secure Elements" in "Security on IoT Devices with Secure Elements" [2] and "Securing the IoT: Introducing an Evaluation Platform for Secure Elements" [3].…”

Section: Secure Elementsmentioning

confidence: 99%

Performance Analysis of Secure Elements for IoT

Noseda

Zimmerli

Schläpfer³

et al. 2021

IoT

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New protocol stacks provide wireless IPv6 connectivity down to low power embedded IoT devices. From a security point of view, this leads to high exposure of such IoT devices. Consequently, even though they are highly resource-constrained, these IoT devices need to fulfil similar security requirements as conventional computers. The challenge is to leverage well-known cybersecurity techniques for such devices without dramatically increasing power consumption (and therefore reducing battery lifetime) or the cost regarding memory sizes and required processor performance. Various semiconductor vendors have introduced dedicated hardware devices, so-called secure elements that address these cryptographic challenges. Secure elements provide tamper-resistant memory and hardware-accelerated cryptographic computation support. Moreover, they can be used for mutual authentication with peers, ensuring data integrity and confidentiality, and various other security-related use cases. Nevertheless, publicly available performance figures on energy consumption and execution times are scarce. This paper introduces the concept of secure elements and provides a measurement setup for selected individual cryptographic primitives and a DTLS handshake over CoAPs in a realistic use case. Consequently, the paper presents quantitative results for the performance of five secure elements. Based on these results, we discuss the characteristics of the individual secure elements and supply developers with the information needed to select a suitable secure element for a specific application.

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Section: Secure Elementsmentioning

confidence: 99%