Abstract: A simple SCM (Self Cascode MOSFET) structure to generate a sub-1V reference voltage in the SCM intermediate node. The structure requires only 2 transistors to create a temperature-compensated reference voltage. When sized correctly, the transistors in the SCM will operate both at weak, moderate or strong inversion, and in the saturation region or saturation and triode regions, providing good correspondence and low part to part variation. The following proposal innovates by operating with supply voltages on a broad variation range, from 3.6V through below 1V (sub-1V operation), with bias currents in the range of tens of nA (nano Amperes) and temperature variation smaller than ±1% from ?40° C. through 85° C. This is an extremely low cost implementation (in terms of area and complexity), compatible with standard CMOS manufacturing processes, and very robust (in terms of fab-to-fab transference, technology mapping, and also well controlled part-to-part variation).

Abstract: A simple SCM (Self Cascode MOSFET) structure to generate a sub-1V reference voltage in the SCM intermediate node. The structure requires only 2 transistors to create a temperature-compensated reference voltage. When sized correctly, the transistors in the SCM will operate both at weak, moderate or strong inversion, and in the saturation region or saturation and triode regions, providing good correspondence and low part to part variation. The following proposal innovates by operating with supply voltages on a broad variation range, from 3.6V through below 1V (sub-1V operation), with bias currents in the range of tens of nA (nano Amperes) and temperature variation smaller than ±1% from ?40° C. through 85° C. This is an extremely low cost implementation (in terms of area and complexity), compatible with standard CMOS manufacturing processes, and very robust (in terms of fab-to-fab transference, technology mapping, and also well controlled part-to-part variation).