In this paper, we present an efficient approach for technology scaling of MOS analog circuits by using circuit optimization techniques. Our new method is based on matching equivalent circuit parameters between a previously designed circuit and the circuit undergoing redesign. This method has been applied to a MOS operational amplifier. We were able to produce a redesigned circuit with almost the same performance in under 4 hours, making this method 5 times more efficient than conventional methods

A 10-bit 3-Msample/s multibit cyclic A/D converter for mixed-signal LSIs with a small chip-area of 1.5 mm2 and low power consumption of 10.8 mW with a 2.7-V power supply was realized using a 0.8-µm CMOS process. This ADC module is designed for high-speed servo-controller LSIs used in hard-disk-drive systems. We found that three-cycle cyclic conversion (four bit, three bit+(one redundant bit), and three bit+(one redundant bit)) was optimal for achieving 10-bit resolution with a small chip-area and low power consumption given a required conversion time of 0.33 µs. Our multipath architecture cut power consumption by 30% compared to conventional cyclic A/D converters. By adding one signal path between the residue amplifier and the four bit subADC, the settling timing requirement can be relaxed, and the amplifier's power consumption thus reduced.