Noise issues in mixed-signal integrated circuits

Complex high-speed digital circuits are commonly integrated together with high performance analog circuits onto the same substrate. In such mixed-signal systems, fast switching transients produced by digital circuits can couple into sensitive analog components through both the substrate and line-to-line capacitances, thereby limiting the achievable analog precision. Furthermore, performance degradation caused by substrate and capacitive coupling noise is difficult to control and even more difficult to predict. The need for highly accurate noise measurement to identify and manage noise has therefore become increasingly evident.; An analysis of clock feedthrough in CMOS analog transmission gate switches is presented in this dissertation. A clock feedthrough mechanism and a related model of a transmission gate switch are established in the current-voltage domain. Region and zone maps of the transmission gate during switch-off are developed and used to efficiently estimate clock feedthrough noise.; The charge-sharing effect (CSE) in switched-capacitor CMOS circuits is studied and evaluated. A technique using Miller capacitance in a sample-and-hold circuit is introduced to reduce the charge sharing effect caused by the parasitic capacitances and clock feedthrough from a sampling switch. A ten-fold reduction in CSE and clock feedthrough is achieved.; An on-chip circuit has also been developed to directly measure substrate and line-to-line coupling noise voltages and waveforms. This test circuit has been manufactured in a 0.35 mum CMOS process and consists of noise generators and switched-capacitor signal processing circuitry. The experimental data show that on-chip generators ranging in area from 1 mum2 to 6 mum2 produce noise at the receiver, decreasing from 3.14 mV/mum to 0.73 mV/mum. The efficiency with which including substrate guard rings reduces substrate noise has also been studied and evaluated in this research effort. Supported by experiment measurement, open loop and closed guard rings reduce the noise by 20% and 85%, respectively. The difference between experimental and analytic models of the line-to-line coupling capacitance ranges from 8.5% to 17.7% for different metal layers.