Maximilian Schöffel scite author profile

Maximilian Schöffel

5Publications

14Citation Statements Received

37Citation Statements Given

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Affiliations

University of Kaiserslautern

Publications

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Secure IoT in the Era of Quantum Computers—Where Are the Bottlenecks?

Schöffel

Lauer

Rheinländer

et al. 2022

Sensors

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Recent progress in quantum computers severely endangers the security of widely used public-key cryptosystems and of all communication that relies on it. Thus, the US NIST is currently exploring new post-quantum cryptographic algorithms that are robust against quantum computers. Security is seen as one of the most critical issues of low-power IoT devices—even with pre-quantum public-key cryptography—since IoT devices have tight energy constraints, limited computational power and strict memory limitations. In this paper, we present, to the best of our knowledge, the first in-depth investigation of the application of potential post-quantum key encapsulation mechanisms (KEMs) and digital signature algorithms (DSAs) proposed in the related US NIST process to a state-of-the-art, TLS-based, low-power IoT infrastructure. We implemented these new KEMs and DSAs in such a representative infrastructure and measured their impact on energy consumption, latency and memory requirements during TLS handshakes on an IoT edge device. Based on our investigations, we gained the following new insights. First, we show that the main contributor to high TLS handshake latency is the higher bandwidth requirement of post-quantum primitives rather than the cryptographic computation itself. Second, we demonstrate that a smart combination of multiple DSAs yields the most energy-, latency- and memory-efficient public key infrastructures, in contrast to NIST’s goal to standardize only one algorithm. Third, we show that code-based, isogeny-based and lattice-based algorithms can be implemented on a low-power IoT edge device based on an off-the-shelf Cortex M4 microcontroller while maintaining viable battery runtimes. This is contrary to much research that claims dedicated hardware accelerators are mandatory.

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On the Energy Costs of Post-Quantum KEMs in TLS-based Low-Power Secure IoT

Schöffel

Lauer

Rheinländer

et al. 2021

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Exploration of Thermoelectric Energy Harvesting for Secure, TLS-Based Industrial IoT Nodes

Lauer

Schöffel

Rheinländer

et al. 2023

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Code-based Cryptography in IoT: A HW/SW Co-Design of HQC

Schöffel¹,

Feldmann²,

Wehn³

2023

Preprint

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Recent advances in quantum computing pose a serious threat on the security of widely used public-key cryptosystems. Thus, new post-quantum cryptographic algorithms have been proposed as part of the associated US NIST process to enable secure, encrypted communication in the age of quantum computing. Many hardware accelerators for structured latticebased algorithms have already been published to meet the strict power, area and latency requirements of low-power IoT edge devices. However, the security of these algorithms is still uncertain. Currently, many new attacks against the lattice structure are investigated to judge on their security. In contrast, code-based algorithms, which rely on deeply explored security metrics and are appealing candidates in the NIST process, have not yet been investigated to the same depth in the context of IoT due to the computational complexity and memory footprint of state-of-theart software implementations.In this paper, we present to the best of our knowledge the first HW/SW co-design based implementation of the codebased Hamming Quasi Cyclic Key-Encapsulation Mechanism. We profile and evaluate this algorithm in order to explore the trade-off between software optimizations, tightly coupled hardware acceleration by instruction set extension and modular, loosely coupled accelerators. We provide detailed results on the energy consumption and performance of our design and compare it to existing implementations of lattice-and code-based algorithms. The design was implemented in two technologies: FPGA and ASIC. Our results show that code-based algorithms are valid alternatives in low-power IoT from an implementation perspective.

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Code-based Cryptography in IoT: A HW/SW Co-Design of HQC

Schöffel

Feldmann

Wehn

2022

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