An Ultra-Compact Pure Magnetic Arbiter PUF With High Reliability and Low Power Consumption

Due to the rugged environmental factors in IoT applications and constrained on-chip resources, PUF, as a critical hardware primitive, is a promising solution for key storage, authentication, and ID generation. The existing CMOS-based Arbiter PUFs mainly suffer from low reliability and vulnerability against modeling attacks due to metastability of flipflops and linearity of additive path delays, respectively. Techniques that have been used to enhance the reliability mainly increased the area occupation. Recentlymagnetic tunnel junction (MTJ) devices have been widely investigated in various circuits. In this article, the proposed PUF utilizes mCell devices, a class of Magnetoresistive devices employing only Magnetic Tunnel Junction (MTJ) devices, as a building block. In this article a novel nonvolatile latch is proposed to act as an arbiter and generates the responses by comparing the current values instead of delays which leads to increased the reliability by subtracting the constant variation rates ofMTJs under environmental variation without adding hardware overhead. The characteristics of MTJ like nonvolatility, stochastic switching, chaotic magnetization, low power consumption, and low occupied area have made the proposed PUF to a low power, highly reliable, high randomness and ultra-compact pure magnetic arbiter PUF. The Monte Carlo HSPICE simulation results reveal that the uniformity, uniqueness, bit-aliasing, power consumption, and area of the proposed PUF are 49.24%, 49.87%, 48.64%, 10.771 mu W and 0.106 mu m(2), respectively. In addition, the average BER across a wide temperature range (-50 degrees C-150 degrees C) and voltage range (0.05 V-0.1 V) is 0.08% and 0.18%, respectively.