Abstract—The constraints on the design of CMOS operational amplifiers with rail-to-rail input range for extremely low supply voltage operation, are addressed. Two design approaches for amplifiers based on complementary input differential pairs and a single input pair, respectively, are presented. The first realizes a feedforward action to accommodate the common-mode (CM) component of the input signals to the amplifier input range. The second approach performs a negative feedback action over the input CM signal. Two operational amplifiers based on the proposed approaches have been designed for 1-V total supply operation, and fabricated in a standard 1.2-μm CMOS process. Experimental results are provided and the corresponding performances are discussed and compared. Index Terms—CMOS analog integrated circuits, low voltage, operational amplifiers, rail-to-rail operation. I.

The continued drive toward technology scaling in VLSI design has provided greater integration levels in silicon chips. Thanks to the reduction in minimum feature size and the corresponding decrease in power supply voltage, digital circuits have bene-fited from savings in area and power consumption. This approach presents a number of challenges in Complementary Metal-Oxide Semiconductor (CMOS) analog circuit design. As the gate oxide of transistors becomes thinner and power consumption increases, a lower supply voltage must be used, even though it results in performance degradation of analog circuits. This must be done in order to avoid silicon punch-through. In applications requiring low power consumption and moderate conversion speed, one of the most frequently used analog-to-digital converter (ADC) architec-tures is the successive approximation. As data converters are mixed-signal circuits, containing both analog and digital circuits, they suffer from the same problems just described. This thesis presents the design of a low-voltage successive approximation ADC based on a Switched Opamp comparator. The proposed comparator archi-