Abstract: A comparator including a preamplifier amplifying a first signal and a second signal to produce a first amplified signal on a first output terminal and a second amplified signal on a second output terminal. The comparator also includes a capacitor, a clamp and a latch coupled in parallel to the first output terminal and the second output terminal of the preamplifier. A control circuit is coupled to the variable capacitor and the clamp and is configured to close the clamp during a first time period to cause the first amplified signal and the second amplified signal to bypass the capacitor and the latch, and open the clamp during a second time period following the first time period to cause the first amplified signal and the second amplified signal to be coupled to the capacitor and the latch. The capacitor filters the amplified signals, and the latch produces a digital output signal of the comparator based on the filtered signals.

Abstract: A comparator including a preamplifier amplifying a first signal and a second signal to produce a first amplified signal on a first output terminal and a second amplified signal on a second output terminal. The comparator also includes a capacitor, a clamp and a latch coupled in parallel to the first output terminal and the second output terminal of the preamplifier. A control circuit is coupled to the variable capacitor and the clamp and is configured to close the clamp during a first time period to cause the first amplified signal and the second amplified signal to bypass the capacitor and the latch, and open the clamp during a second time period following the first time period to cause the first amplified signal and the second amplified signal to be coupled to the capacitor and the latch. The capacitor filters the amplified signals, and the latch produces a digital output signal of the comparator based on the filtered signals.

Abstract: An input-output (I/O) buffer and a method of biasing an I/O buffer that avoids inadvertent conduction of a pull-up transistor included in the buffer when an input signal having a voltage greater than the supply voltage is applied to the I/O buffer in an input mode. Inadvertent conduction of the pull-up transistor is avoided during an input mode by biasing the gate and the body of the pull-up transistor with a supply voltage until the voltage of the input signal exceeds the voltage of the voltage supply, at which time the voltage of the input signal is applied to the gate and the body of the pull-up transistor instead. The I/O buffer includes a driver circuit having a pull-up transistor and an I/O node to receive an input signal. The I/O buffer also includes a pull-up transistor bias circuit to provide the voltage to the gate and the body of the pull-up transistor.

Abstract: An input-output (I/O) buffer and a method of biasing an I/O buffer that avoids inadvertent conduction of a pull-up transistor included in the buffer when an input signal having a voltage greater than the supply voltage is applied to the I/O buffer in an input mode. Inadvertent conduction of the pull-up transistor is avoided during an input mode by biasing the gate and the body of the pull-up transistor with a supply voltage until the voltage of the input signal exceeds the voltage of the voltage supply, at which time the voltage of the input signal is applied to the gate and the body of the pull-up transistor instead. The I/O buffer includes a driver circuit having a pull-up transistor and an I/O node to receive an input signal. The I/O buffer also includes a pull-up transistor bias circuit to provide the voltage to the gate and the body of the pull-up transistor.