An analog-to-digital converter (ADC) for converting an analog signal into a digital signal includes an amplifier circuit configured to receive the analog signal, and to generate a plurality of amplifier signals by amplifying the analog signal; a comparison circuit configured to compare a plurality of voltage levels corresponding to the plurality of amplifier signals with a positive reference voltage level and a negative reference voltage level, and to output conversion target signals based on a result of the comparison; and a converter circuit configured to convert the conversion target signals into a plurality of digital signals.

An analog-to-digital circuit that digitizes an analog voltage. The analog-to-digital circuit includes plural comparators functionally connected to form a tree that has levels i, and each level i has branches j, and an encoder connected to the plural comparators and configured to generate a digitized value of an input analog voltage. Each comparator from a level i has first and second outputs, and each of the first and second outputs is electrically connected to an input of different comparators from a next level i+1 of the tree.

Provided is an analog to digital converter configured to receive a continuous input signal. The analog to digital converter includes an integrating block, comprising at least an integrating stage, which output is coupled to a flash analog to digital converter. The analog to digital converter apparatus includes a feedback path coupled to the output of said flash analog to digital converter. The feedback path includes at least a digital to analog conversion block which output is compared at least to the input signal to obtain an error signal which is brought as input to said integrating block. A control block is configured to perform control comprising at least a digital integration, is coupled between the output of said flash analog to digital converter and said feedback path.

Provided is an analog to digital converter configured to receive a continuous input signal. The analog to digital converter includes an integrating block, comprising at least an integrating stage, which output is coupled to a flash analog to digital converter. The analog to digital converter apparatus includes a feedback path coupled to the output of said flash analog to digital converter. The feedback path includes at least a digital to analog conversion block which output is compared at least to the input signal to obtain an error signal which is brought as input to said integrating block. A control block is configured to perform control comprising at least a digital integration, is coupled between the output of said flash analog to digital converter and said feedback path.

A comparator circuit outputs first and second digital signals corresponding to differential signals to a flip-flop having a predetermined forbidden input combination. A converter circuit performs differential amplification for the differential signals and converts the resultant signals to first and second signals that are complementary digital signals. A logic circuit performs predetermined logical operation, and when the logical values of the first and second signals are different from each other, outputs the first and second digital signals corresponding to the logical values of the first and second signals, and when the logical values of the first and second signals are the same, outputs the first and second digital signals having a same value other than the predetermined forbidden input combination.

A comparator circuit outputs first and second digital signals corresponding to differential signals to a flip-flop having a predetermined forbidden input combination. A converter circuit performs differential amplification for the differential signals and converts the resultant signals to first and second signals that are complementary digital signals. A logic circuit performs predetermined logical operation, and when the logical values of the first and second signals are different from each other, outputs the first and second digital signals corresponding to the logical values of the first and second signals, and when the logical values of the first and second signals are the same, outputs the first and second digital signals having a same value other than the predetermined forbidden input combination.

A sensing circuit includes a first input selecting circuit connected to a first sensing line and a second sensing line, a first path setting circuit that sets a path of a first sensing signal received from the first sensing line or a path of a second sensing signal received from the second sensing line, a second path setting circuit that sets a path of a sensing reference voltage, a first switch matrix connected to the first path setting circuit and the second path setting circuit, a first mode setting circuit connected to a first output terminal of the first switch matrix, a first common sensing amplifier connected to the first mode setting circuit, a second mode setting circuit connected to a second output terminal of the first switch matrix, and a second common sensing amplifier connected to the second mode setting circuit.

A sensing circuit includes a first input selecting circuit connected to a first sensing line and a second sensing line, a first path setting circuit that sets a path of a first sensing signal received from the first sensing line or a path of a second sensing signal received from the second sensing line, a second path setting circuit that sets a path of a sensing reference voltage, a first switch matrix connected to the first path setting circuit and the second path setting circuit, a first mode setting circuit connected to a first output terminal of the first switch matrix, a first common sensing amplifier connected to the first mode setting circuit, a second mode setting circuit connected to a second output terminal of the first switch matrix, and a second common sensing amplifier connected to the second mode setting circuit.

Systems, devices, and methods related to low-noise, high-accuracy single-ended continuous-time sigma-delta (CTSD) analog-to-digital converter (ADC) are provided. An example single-ended CTSD ADC includes a pair of input nodes to receive a single-ended input signal and input circuitry. The input circuitry includes a pair of switches, each coupled to one of the pair of input nodes; and an amplifier to provide a common mode signal at a pair of first nodes, each before one of the pair of switches. The single-ended CTSD ADC further includes digital-to-analog converter (DAC) circuitry; and integrator circuitry coupled to the input circuitry and the DAC circuitry via a pair of second nodes.

Certain aspects provide an apparatus for signal processing in a neural network. The apparatus generally includes a first set of computation in memory (CIM) cells configured as a first kernel for a neural network computation, the first set of CIM cells comprising on one or more first columns and a first plurality of rows of a CIM array, and a second set of CIM cells configured as a second kernel for the neural network computation, the second set of CIM cells comprising on one or more second columns and a second plurality of rows of the CIM array. In some aspects, the one or more first columns are different than the one or more second columns, and the first plurality of rows are different than the second plurality of rows.