An electronic device may include digital circuitry that operates via digital signals and a digital to analog converter (DAC) to convert a digital signal into a modulated analog signal. The DAC may include multiple unit cells to generate an analog signal and multiple local oscillator (LO) tiles to modulate the analog signal and generate the modulated analog signal. The electronic device may also include LO circuitry to dynamically adjust an LO enable signal based at least in part on the digital signal. The LO enable signal may enable a reduced number of LO tiles supporting one or more respective sets of unit cells operatively enabled based on the digital signal.

A semiconductor circuit and a method of operating the same are provided. The semiconductor circuit comprises a first digital-to-analog converter configured to generate a first output current in response to a first binary code, and a second digital-to-analog converter configured to generate a second output current in response to a second binary code associated with the first binary code. The semiconductor circuit further comprises a first current-to-voltage converter configured to generate a first candidate voltage based on the first output current, and a second current-to-voltage converter configured to generate a second candidate voltage based on the second output current. The semiconductor circuit further comprises a multiplexer configured to output the target voltage based on the first candidate voltage or the second candidate voltage. The target voltage includes a configurable range associated with the second binary code.

Systems and methods of implementing a mixed-signal integrated circuit includes sourcing, by a reference signal source, a plurality of analog reference signals along a shared signal communication path to a plurality of local accumulators; producing an electrical charge, at each of the plurality of local accumulators, based on each of the plurality of analog reference signals; adding or subtracting, by each of the plurality of local accumulators, the electrical charge to an energy storage device of each of the plurality of local accumulators over a predetermined period; summing along the shared communication path the electrical charge from the energy storage device of each of the plurality of local accumulators at an end of the predetermined period; and generating an output based on a sum of the electrical charge from each of the plurality of local accumulators.

A system for analog computing, an analog computing system with sub-binary radix weight representation is provided. The analog computing system comprises an input node, a multiplexer (MUX), a digital to analog converter (DAC), a SRAM-based Sub-Binary Multiplier (SSBM), an analog to digital converter (ADC), a switch, an output node and a calibration module. The calibration module is configured to control the analog computing system to switch between a calibration mode and a normal operation mode. Prior to being switched to the normal operation mode, the analog computing system is configured to perform a process to calibrate a weight parameter stored in the SSBM. The ADC comprises a plurality of multipliers associated with a plurality of sub-binary weight radixes. The weight parameter stored in the SSBM and the plurality of sub-binary weight radixes are configured to represent a plurality of weights for the analog computing system.

An analog-to-digital converter system includes a digital-to-analog converter for generating calibration voltages based on digital input codes, and an analog-to-digital converter, connected to the digital-to-analog converter, for receiving the calibration voltages from the digital-to-analog converter, for receiving sampled voltages, for generating digital output codes based on the calibration voltages, and for generating digital output codes based on the sampled voltages. The analog-to-digital converter system may have a lookup table, connected to the analog-to-digital converter, for storing the first digital output codes in association with the digital input codes. A method of calibrating an analog-to-digital converter system is also disclosed.

A multi-level signal generator includes a receiving circuit, a setting circuit, a data bit generating circuit and a digital-to-analog converter. The receiving circuit generates a first data bit based on an input data signal having two voltage levels that are different from each other. The setting circuit generates a flag signal based on a command signal. The flag signal is changed depending on an operation mode. The data bit generating circuit generates a plurality of internal bits based on the first data bit, selects at least one of the plurality of internal bits based on the flag signal, and outputs the selected internal bit as at least one additional data bit. The digital-to-analog converter generates an output data signal that is a multi-level signal having three or more voltage levels different from each other based on the first data bit and the at least one additional data bit.

A measurement system includes a source unit to provide a source signal to a sample and a voltage source and/or a current source and a memory. The system also includes a measurement unit configured to acquire from the sample an measurement signal that may be responsive to the source signal and a voltage measuring unit, a current measuring unit, and/or a capacitance measuring unit, and a memory. The system also includes a control unit including a digital signal processing unit; a source converter; a measurement converter. The system further includes a synchronization unit configured to synchronize clocks of the digital signal processing unit, the source converter, the measurement converter, the source unit, and the measurement unit; a calibration unit for calibrating aspects of the system including the control unit; and a reference voltage supply configured to supply a common reference voltage for the control unit.

An apparatus is configured to generate, from a stream of periodic digital samples, a first sub-stream of periodic analog samples and a second sub-stream of periodic analog samples, each sub-stream comprising substantially stable time intervals. The apparatus is further configured to generate a sign-modulated sub-stream by applying to the second sub-stream a sign modulation operation effecting a sign transition during a stable time interval of the second sub-stream. The apparatus is further configured to generate an output stream of periodic analog samples based on a sum of the first sub-stream and the sign-modulated sub-stream, wherein a period of the output stream is shorter than periods of the first and second sub-streams.

A sigma delta modulator device includes a sampling circuit, a digital to analog converter circuit, an integrator circuit, and an analog to digital converter circuit. The sampling circuit is configured to sample an input signal, in order to generate a first signal. The digital to analog converter circuit is configured to convert a first digital signal to be a combination of a first reference voltage and a common mode voltage, in order to generate a second signal, in which the first reference voltage is one of a positive reference voltage and a negative reference voltage. The integrator circuit is configured to perform integration according to the first signal and the second signal, in order to generate a third signal. The analog to digital converter circuit is configured to quantize the third signal to generate an output signal, and to generate the first digital signal according to the output signal.

A digital-to-analog converter (“DAC”) converts digital image data into analog image signals. The DAC includes a stage outputting different voltages to a first output terminal and a second output terminal based on a voltage supplied to a first input terminal, a voltage supplied to a second input terminal, and a first input bit. The stage includes a switch circuit including switches that are alternately turned on by a control signal, and outputting an intermediate output voltage to a third output terminal based on a first input voltage supplied to the first input terminal and a second input voltage supplied to the second input terminal, and a selector outputting one of the first input voltage and the second input voltage, and the intermediate output voltage.