This paper introduces a physical unclonable function (PUF) based on a differential array of minimum-sized PMOS devices. Each response bit is obtained by comparing the two analog outputs of the differential array through a dynamic comparator with a trimmable offset. This offset is effectively used to mask potentially unstable response bits. To further improve PUF reliability, spatial majority voting is also implemented, resulting in a near-zero (< (Formula presented.)) bit error rate (BER) at 1.2 V and 25 (Formula presented.). Under variations in supply voltage (0.8–1.3 V) and temperature (0–75 (Formula presented.)), the native bit error rate of 3.5% is reduced to (Formula presented.) after stabilization, consuming only 1.37 (Formula presented.) per output bit.
A Physical Unclonable Function Based on a Differential Subthreshold PMOS Array with 9.73 × 10−4 Stabilized BER and 1.3 pJ/bit in 65 nm
Garzon E.;Lanuzza M.
2025-01-01
Abstract
This paper introduces a physical unclonable function (PUF) based on a differential array of minimum-sized PMOS devices. Each response bit is obtained by comparing the two analog outputs of the differential array through a dynamic comparator with a trimmable offset. This offset is effectively used to mask potentially unstable response bits. To further improve PUF reliability, spatial majority voting is also implemented, resulting in a near-zero (< (Formula presented.)) bit error rate (BER) at 1.2 V and 25 (Formula presented.). Under variations in supply voltage (0.8–1.3 V) and temperature (0–75 (Formula presented.)), the native bit error rate of 3.5% is reduced to (Formula presented.) after stabilization, consuming only 1.37 (Formula presented.) per output bit.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
