All MOS sample-and-hold circuits suffer to a greater or lesser extent from clock-feedthrough
(CLFT), also called charge-injection. During the transition from sample to
hold mode, charge is transferred from an MOS transistor switch onto the hold capacitor,
thus the name charge-injection. This error can lead to considerable voltage change across
the capacitor, and predicting the extent of the induced error potentials is important to
circuit designers.
Previous studies have shown a considerable dependency of CLFT on signal voltage, circuit
impedances, clock amplitude and clock fall-time. The focus of this work was on the signal
dependency of the CLFT error and on the CLFT induced signal distortion in open-loop
sample-and-hold circuits. CLFT was found to have a strongly non-linear, signal dependent,
component, which may cause considerable distortion of the sampled signal. The parameters
influencing this distortion were established. It was discovered that distortion could be
reduced by more than 20dB through careful adjustment of the clock fall-rate.
Several circuit solutions that can help reduce the level of distortion arising from CLFT are
presented. These circuits can also reduce the absolute level of CLFT. Simulations showed
their effectiveness, which was also proven in silicon. The CLFT reduction methods used in
these circuits are easily transferable to other switched-capacitor circuits and are suitable for
applications where space is at a premium (as, for example, in analogue neural networks).
A new saturation mode contribution to CLFT was found. It is shown to give rise to
increased CLFT under high injection conditions.
Date of Award | 2001 |
---|
Original language | English |
---|
Awarding Institution | |
---|
Clock-Feedthrough Compensation in MOS Sample-and-Hold Circuits
Fuchs, F. X. (Author). 2001
Student thesis: PhD