What question did this study set out to answer?

The aim is to develop a low-power voltage reference that maintains performance under varying supply conditions.

February 2, 2026Open Access

A Multi-Self-Cascoded Voltage Reference with 2.73-ppm/V Line Sensitivity and 20.1-ppm/°C Temperature Coefficient at 0.45-V Supply

Key Points

The aim is to develop a low-power voltage reference that maintains performance under varying supply conditions.
Utilized a ΔVGS-based approach for voltage reference design.
Implemented a multi-self-cascoded technique for enhanced stability.
Conducted post-layout simulations on a 0.18-μm CMOS design.
Achieved a line sensitivity of 2.73 ppm/V.
Recorded a temperature coefficient of 20.1 ppm/°C.
Maintained power consumption below 200 pW at a supply voltage of 0.45 V.

Abstract

Recent advancements in low-power and low-voltage integrated circuits have spurred significant research interest, particularly for applications with demanding supply conditions. This work presents a single-branch voltage reference achieving exceptional immunity to supply voltage variations. Leveraging a ΔVGS-based approach, the design utilizes transistors with differentchannel lengths to exploit geometry-dependent threshold voltage differences, enabling effective temperature compensation.Additionally, a multi-self-cascoded technique enhances immunity to supply voltage variations. Post-layout simulations of a 0.18-μm CMOS design, operating with supply voltage as low as 0.45 V, demonstrate a line sensitivity of 2.73 ppm/V and a temperature coefficient of 20.1 ppm/◦C, with power consumption below 200 pW. The proposed architecture is shown to be a robust solution for implementing

A Multi-Self-Cascoded Voltage Reference with 2.73-ppm/V Line Sensitivity and 20.1-ppm/°C Temperature Coefficient at 0.45-V Supply

Key Points

Abstract

Cite This Study