An analog-to-digital converter (ADC) including: a signal input adapted to receive an analog signal; a first reference voltage input adapted to receive a first reference voltage; a second reference voltage input adapted to receive a second reference voltage, the second reference voltage is different than the first reference voltage; a first delay circuit having a first delay input coupled to the signal input, a second delay input coupled to the first reference voltage input, a first delay output and a second delay output; a second delay circuit having a third delay input coupled to the signal input, a fourth delay input coupled to the second reference voltage input; a third delay output and a fourth delay output; a first comparator having a first comparator input coupled to the first delay output, a second comparator input coupled to the second delay output and a first comparator output; and a second comparator having a third comparator input coupled to the third delay output, a fourth comparator input coupled to the fourth delay output and a second comparator output.

The present invention pertains to a high-speed successive approximation analog-to-digital converter of two bits per circle, includes three switches, two capacitor arrays, three comparators, an encoding circuit, a first switch array corresponding to the first capacitor array, a second switch array corresponding to the second capacitor array, a shifting register and a digital correction unit. The analog-to-digital converter, featuring doubled speed, realizes a successive approximation process without any fault when a high-bit large capacitor is unsettled. Thus no redundancy bit capacitor is required to compensate for unsettled pre-stage large capacitor. By using the encoding circuit, a thermometer code is converted into a binary code effectively, and inherent errors of comparators are reduced by the randomization of three comparators.

A system for converting a voltage into output codes includes logic gates for processing delay signals based on earlier and later arriving signals generated by preamplifiers, delay comparators for generating digital signals representative of most significant bits of respective codes, and for transmitting delay residue signals representative of less significant bits of the codes, and an auxiliary delay comparator for generating an auxiliary digital signal for use in generating the output codes. A system may include logic gates for generating delay signals based on earlier and later arriving signals, delay comparators for generating digital signals representative of most significant bits of respective codes, and for transmitting delay residue signals representative of less significant bits, and a multiplexer system for transmitting a selected one of the residue signals.

A receiver having analog-to-digital converters (ADC) is disclosed. The ADCs may be reconfigured based on the data rate of the receiver. For example, more portions of each time-interleaved ADC may be enabled to support a higher data rate of the receiver and less portions of the ADCs may be used to support a lower data rate of the receiver.

An analog-to-digital converter (ADC) having an input operable to receive an input voltage, V.sub.IN, and an output operable to output a digital code representative of V.sub.IN, the ADC including: a voltage-to-delay circuit having an input and an output, the input of the voltage-to-delay circuit coupled to the input of the ADC; a folding circuit having an input and an output, the input of the folding circuit coupled to the output of the voltage-to-delay circuit; and a time delay-based analog-to-digital converter backend having an input and a digital code output coupled to the output of the ADC, the input of the time delay-based analog-to-digital converter backend coupled to the output of the folding circuit.

A system for converting a voltage into output codes includes logic gates for processing delay signals based on earlier and later arriving signals generated by preamplifiers, delay comparators for generating digital signals representative of most significant bits of respective codes, and for transmitting delay residue signals representative of less significant bits of the codes, and an auxiliary delay comparator for generating an auxiliary digital signal for use in generating the output codes. A system may include logic gates for generating delay signals based on earlier and later arriving signals, delay comparators for generating digital signals representative of most significant bits of respective codes, and for transmitting delay residue signals representative of less significant bits, and a multiplexer system for transmitting a selected one of the residue signals.

A system including a circuit, including a first preamplifier, a sampling switch, a regenerative latch, and a second preamplifier aligned in a pipelined sequence with the first preamplifier, wherein the first and second preamplifier are associated with dynamic comparator and configured to gain signal utilizing multiple cascaded gains and sample-and-hold stages including a plurality of phases.

An analog-to-digital converter (ADC) including: a signal input adapted to receive an analog signal; a first reference voltage input adapted to receive a first reference voltage; a second reference voltage input adapted to receive a second reference voltage, the second reference voltage is different than the first reference voltage; a first delay circuit having a first delay input coupled to the signal input, a second delay input coupled to the first reference voltage input, a first delay output and a second delay output; a second delay circuit having a third delay input coupled to the signal input, a fourth delay input coupled to the second reference voltage input; a third delay output and a fourth delay output; a first comparator having a first comparator input coupled to the first delay output, a second comparator input coupled to the second delay output and a first comparator output; and a second comparator having a third comparator input coupled to the third delay output, a fourth comparator input coupled to the fourth delay output and a second comparator output.

An analog-to-digital converter (ADC) having an input operable to receive an input voltage, V.sub.IN, and an output operable to output a digital code representative of V.sub.IN, the ADC including: a voltage-to-delay circuit having an input and an output, the input of the voltage-to-delay circuit coupled to the input of the ADC; a folding circuit having an input and an output, the input of the folding circuit coupled to the output of the voltage-to-delay circuit; and a time delay-based analog-to-digital converter backend having an input and a digital code output coupled to the output of the ADC, the input of the time delay-based analog-to-digital converter backend coupled to the output of the folding circuit.

A method of converting an analog signal to a digital code, comprising: using a first comparator to receive an input signal and a first comparison signal, and to generate a first output as a function of the input signal and the first comparison signal; using a second comparator to receive the input signal and a second comparison signal, and to generate a second output as a function of the input signal and the second comparison signal; and using an interpolation comparator to receive the first and second outputs, and to generate a third output based on relative timing of the first and second outputs; further including multiplexing to permit a second-level comparator to receive timing signals from the interpolation comparator and only one of two dummy comparators.