Low Power High Speed High Resolution Delta Sigma Modulators For Digital Tv Receivers In Nanometer Cmos

"The use of high-speed high-resolution analog-to-digital converters (ADCs) allows part of the signal processing to be done in the digital domain allowing for higher system integration and cheaper fabrication. Becoming more in use, hand-held devices have low-power requirements to allow for longer battery life. Also, designing ADCs in nanometer digital CMOS technologies make them more integrable with digital processing blocks and cheaper. This thesis aims at designing a high-speed (16MS/s conversion rate) high-resolution (12bits) Delta-Sigma modulator with low-power consumption in nanometer CMOS. Delta-Sigma modulators can achieve high resolution in low and medium speed applications. For higher speed applications, the oversampling ratio (OSR) will have to be kept low to avoid inefficient design. However, lowering the OSR requires special care in the design starting from the architecture until the full circuit implementation. In nanometer CMOS technologies, analog properties, such as intrinsic gain, degrade which might result in a higher power consumption. Moreover, the low nominal supply voltages associated with such technologies adds more challenges to the design of a low distortion power-efficient Delta-Sigma modulator. Targeting a specic resolution, lowering the voltage supply usually results in a higher power consumption. This thesis suggests possible solutions to achieve low power consumption while targeting high-speed applications in nanometer low-voltage-supply environment.This thesis presents a low-power Discrete-Time (DT) Delta-Sigma modulator making use of a single-loop multibit DT digital input-feedforward Delta-Sigma architecture. The main feature of this architecture is the reduced signal swings at the output of the integrators which allows the use of a low voltage supply. The low-power Switched-Capacitor (SC) implementation is ensured by using a novel opamp switching technique, optimizing simultaneous opamp's settling in cascaded nondelaying SC integrators, and using non-overlapping clock phases with unequal duty-cycles. The novel opamp switching technique is based on a current-mirror opamp with switchable transconductances. The current-mirror opamp works with full current during the charge-transfer phase while the output current is partially switched off during the sampling phase. Power saving can be achieved while ensuring that the opamp output is available during both phases. The simultaneous settling of series opamps in a two cascaded nondelaying SC integrators scheme is looked at as a two-pole system where power optimization is necessary to ensure minimum power consumption while meeting the settling requirements. The use of clock phases with unequal duty-cycles gives the designer an extra degree of freedom to further power optimize the design. The experimental Delta-Sigma ADC is a 4th-order 5.5bits single-loop Delta-Sigma modulator with an OSR of 8. The design starts with the structural-level aspects in which system-level decisions are made and simulations are carried-out with behavioral models to find the suitable circuit parameters. Circuit-level design in then considered to design each block and simulate the full-system. Fabricated in 1V 65nm CMOS, the Delta-Sigma modulator prototype occupies an active area of 1.2mm2. Although the targeted resolution is about 12bits, the experimental results shows a dynamic range (DR) of 66dB (11bits) over an 8MHz bandwidth while consuming 26mW and a peak SNR/SNDR of 64/58.5dB. The proposed opamp switching technique brings the total power consumption from 29mW to 26mW without affecting the performance (SNDR stays at 58.5dB). The deviation in experimental performance, from simulations, in thought to be due to higher parasitic capacitance requiring higher bias currents which results in drop of opamp dc gain. Compared to state of the art high-speed high-resolution Delta-Sigma modulators operated from 1V supply and fabricated in CMOS, it achieves a reasonable Figure-of-Merit." --