Open Access

Ahmet Turan Erozan, Gabriel Cadilha Marques, Mohammad Saber Golanbari, Rajendra Bishnoi, Simone Dehm, Jasmin Aghassi-Hagmann, Mehdi Baradaran Tahoori

• Printed electronics (PE) is a promising technology that provides mechanical flexibility and low-cost fabrication and the key enabler for emerging applications, such as smart sensors, wearables, and Internet of Things. To use printed batteries or printed energy harvesters in the future, electrolyte-gated field-effect transistors (EGFETs) based on inorganic materials enable printed circuitsPrinted electronics (PE) is a promising technology that provides mechanical flexibility and low-cost fabrication and the key enabler for emerging applications, such as smart sensors, wearables, and Internet of Things. To use printed batteries or printed energy harvesters in the future, electrolyte-gated field-effect transistors (EGFETs) based on inorganic materials enable printed circuits requiring small supply voltage and low power. Since these applications need secure communication and/or authentication, it is imperative to embed security primitives for cryptographic key and identification purposes into the applications. Physical unclonable functions (PUFs) have been adopted widely to provide secure keys. In this paper, we present the design, simulation, fabrication, and measurements of a PUF based on EGFETs using inorganic inkjet PE. A comprehensive framework, including Monte Carlo simulations calibrated on real device measurements, is developed. Moreover, a multibit PE-PUF design is proposed to optimize area usage. Our simulation results show that the PE-PUF has ideal uniqueness (50.1%) and good reliability (89%). In addition, the proposed multibit PE-PUF reduces the area usage around 30%. The proposed PE-PUF was fabricated and the experimental results confirm that the PE-PUF can operate reliably as low as 0.5 V, and hence, it is a remarkable candidate to be utilized in low-power applications.…