A device for processing digital signals is provided. The device comprises a digital signal source and a converter circuit having a current supply. The digital signal source outputs a codeword. The converter circuit receives the codeword from the digital signal source, receives a current at the current supply, and generates an output signal based on the codeword. The current is generated in accordance with the codeword.

Systems and methods are provided for a clock generator is configured to generate N clock signals evenly spaced by phase. A clock generator includes a poly phase filter configured to utilize a differential clock signal to generate N intermediate signals, the intermediate signals being spaced approximately 360/N degrees apart in phase. A phase error corrector is configured to receive the intermediate signals and to generate N clock output signals, where a phase error is a measure of a difference in phase between consecutive ones of the clock output signals from 360/N degrees, the phase error corrector being configured to reduce phase error among the clock output signals based on a feedback signal. A phase error detection circuit is configured to receive the clock output signals and to generate the feedback signal based on detected phase errors among the clock output signals.

An RF transmitter having one or more common-gate, CG, or common-base, CB, configured output stages, and a digitally controlled current source having a plurality of unit cells connected to the output stages, each of the plurality of unit cells comprising a current source. The digitally controlled current source is configured for driving the output stages with respective driving currents originating from the associated current source in each of the plurality of unit cells, in dependence of one or more input signals. The digitally controlled current source further comprises a current diversion path in each of the plurality of unit cells for providing a diversion current to a voltage source having a voltage lower than drain/collector terminals of transistors provided in the CG/CB configured output stages.

A method for calibrating currents includes performing a first sorting operation on a plurality of first current sources according to current levels generated by the first current sources, performing a second sorting operation on a plurality of second current sources according to current levels generated by the second current sources, determining a first switching sequence for the first plurality of current sources according to a result of the first sorting operation, and determining a second switching sequence for the second plurality of current sources according to a result of the second sorting operation and the first switching sequence. The plurality of first current sources have a same target current value, and the plurality of second current sources have a same target current value.

A digital-to-analog converter (DAC) includes a switching network and built-in-self-test (BIST) circuitry. The DAC, in operation, generates analog output signals in response to input codes of a set of input codes of the DAC. The BIST circuitry sequentially applies codes of a determined subset of codes of the set of input codes to test the plurality of switches. The determined subset of codes has fewer codes than the set of input codes. The BIST circuitry detects failures of switches of the plurality of switches based on responses of the DAC to the applied codes. In response to detecting a failure of a switch, the BIST generates a signal indicating a failure of the switching network.

One or more systems, devices and/or methods of use provided herein relate to a device that can support a signal generation. A current-mode end-to-end signal path can include a digital to analog converter (DAC) operating in current-mode and an upconverting mixer, operating in current-mode and operatively coupled to the DAC. Analog inputs and outputs of the DAC and upconverting mixer can be represented as currents, and the DAC can generate a baseband signal. The DAC and upconverting mixer each can comprise switching transistors of the same type, such as p-type metal-oxide semiconductor (PMOS) switching transistors. In one or more embodiments, a current source and a diode-connected transistor can be arranged in parallel in the current-mode signal path, and the current source passes a static current, while the diode-connected transistor passes both a static current and a dynamic current.

An apparatus can include a digital-to-analog converter (DAC) and calibration circuitry including an oscillator. The calibration circuitry can be coupled to an output of the DAC, the calibration circuitry to sample and count DAC output pulses for at least two consecutive pulses using at least two separate counter circuits. The calibration circuitry can determine error between at least two consecutive pulses and provide a correction value based on the error. The apparatus can further include correction circuitry to provide a calibration signal to the DAC based on the correction value.

A photoelectric conversion device includes a light receiving circuit configured to convert light into an electrical signal, a first hold circuit configured to hold a data signal which represents the electrical signal, a second hold circuit configured to hold a noise signal read out from the light receiving circuit in a reset state, a first resistive element to which a voltage corresponding to a difference between the data signal held by the first hold circuit and the noise signal held by the second hold circuit is applied, an A/D converter configured to convert an analog current flowing in the first resistive element into digital data, a second resistive element, and a temperature detection circuit configured to generate, based on a current flowing in the second resistive element, an analog output corresponding to an internal temperature of the photoelectric conversion device.

An input circuitry for receiving an analog input signal comprises: an input transistor configured to receive the analog input signal on a gate terminal of the input transistor wherein the input transistor is connected to a digital component providing a digital signal, and wherein the input transistor is configured to receive the digital signal on a bulk terminal of the input transistor; wherein the input transistor is configured to provide an output current based on the analog input signal and the digital signal, such that the input transistor provides digital-to-analog conversion of the digital signal received on the bulk terminal.

A DAC-based transmit driver architecture with improved bandwidth and techniques for driving data using such an architecture. One example transmit driver circuit generally includes an output node and a plurality of digital-to-analog converter (DAC) slices. Each DAC slice has an output coupled to the output node of the transmit driver circuit and includes a bias transistor having a drain coupled to the output of the DAC slice and a multiplexer having a plurality of inputs and an output coupled to a source of the bias transistor.