Comparison of low-dropout voltage regulators designed with line and nanowire tunnel-FET experimental data including a simple process variability analysis

Abstract

This work presents the comparison between Nanowire Tunnel Field-Effect Transistor (NW-TFET) and Line-TFET applied on the design of Low-Dropout Voltage Regulator (LDO). Both devices have a SiGe source composition in order to enhance the current drive. The transistors were modeled using lookup tables (LUTs) approach based on experimental data using Verilog-A language. The LDOs were designed for two conditions, considering different gm/ID, load currents and load capacitances. In order to compare the TFET LDOs with an established technology, a MOSFET LDO was designed with TSMC 0.18 µm process design kit. Both TFET LDOs reach stability without the presence of a compensation capacitor. For gm/ID = 10.5 V−1 the current consumption of NW-TFET LDO (1.5nA) is near two orders of magnitude lower than Line-TFET LDO (68nA) and three orders of magnitude lower than MOSFET LDO (9 µA). The Line-TFET LDO exhibits better results in almost all parameters despite of the gain-bandwidth product (GBW) that is in the same order of magnitude of the MOSFET LDO, 171 kHz compared to 250 kHz for gm/ID = 10.5 V−1. The comparison between TFET LDOs for gm/ID = 7 V−1 was also performed regarding the transient and process variability analysis. The transient response revealed that the Line-TFET LDO has a pronounced lower settling time, 71 µs compared to 5 ms for a load step, but with a damped oscillatory response, the NW-TFET LDO presented lower undershoot for the load step. The process variability analysis was performed for devices within the wafer and was observed that the Line-TFET LDO suffers a higher impact with a 20 dB variation on the loop gain in comparison to 10 dB in the NW-TFET LDO.