An electronic circuit for converting a signal between digital and analog in a burst mode, including a processor configured to utilize a synchronizing clock signal, a converter configured to convert a signal data between digital and analog using a converter clock signal, a phase comparator configured to determine a phase relationship between the synchronizing clock signal and the converter clock signal, and a digital signal processor coupled to the phase comparator and configured to receive an information about the phase relationship, wherein the digital signal processor is configured to apply a delay to the signal data being exchanged between the processor and. The synchronizing clock signal and the converter clock signal have a predetermined frequency relationship.

An electronic circuit for converting a signal between digital and analog in a burst mode, including a processor configured to utilize a synchronizing clock signal, a converter configured to convert a signal data between digital and analog using a converter clock signal, a phase comparator configured to determine a phase relationship between the synchronizing clock signal and the converter clock signal, and a digital signal processor coupled to the phase comparator and configured to receive an information about the phase relationship, wherein the digital signal processor is configured to apply a delay to the signal data being exchanged between the processor and. The synchronizing clock signal and the converter clock signal have a predetermined frequency relationship.

An example apparatus includes: resistor ladder circuitry including a plurality of intermediate voltage nodes; a first plurality of switches having inputs coupled to a plurality of intermediate voltage nodes and having outputs; first level decoder circuitry configured to: receive a set of input bits; and open or close ones of the first plurality of switches based on a first subset of the input bits; a second plurality of switches having inputs coupled to the outputs of the first plurality of switches and having outputs coupled to a common node; and second level decoder circuitry configured to: receive the set of input bits; and open or close ones of the second plurality of switches based on a second subset of the input bits, the first and the second subsets sharing one of the input bits, wherein the output voltage is to be coupled to the common node.

An example apparatus includes: resistor ladder circuitry including a plurality of intermediate voltage nodes; a first plurality of switches having inputs coupled to a plurality of intermediate voltage nodes and having outputs; first level decoder circuitry configured to: receive a set of input bits; and open or close ones of the first plurality of switches based on a first subset of the input bits; a second plurality of switches having inputs coupled to the outputs of the first plurality of switches and having outputs coupled to a common node; and second level decoder circuitry configured to: receive the set of input bits; and open or close ones of the second plurality of switches based on a second subset of the input bits, the first and the second subsets sharing one of the input bits, wherein the output voltage is to be coupled to the common node.

A calibrating device can mitigate the static mismatch error of a digital-to-analog converter (DAC), and includes a digital code generating circuit, the DAC, an analog-to-digital converter (ADC), a filter circuit, an indicating circuit, and a statistical circuit. The digital code generating circuit generates a digital code of N digital codes. The DAC generates an analog signal corresponding to one of N signal levels according to the digital code. The ADC generates a digital signal according to the analog signal. The filter circuit generates a gradient value according to the difference between the digital code and the digital signal. The indicating circuit generates a selection signal according to the digital code. The statistical circuit learns from the selection signal that the gradient value is corresponding to a K.sup.th digital code of the N digital codes, and determines whether the K.sup.th digital code should be adjusted according to the gradient value.

A light emitting device driving circuit according to the present disclosure includes a sawtooth waveform generating unit for generating a sawtooth waveform voltage having a sawtooth waveform voltage change based on at least two reference signals to be input and a comparison unit for comparing an analog signal voltage with the sawtooth waveform voltage. The light emitting device driving circuit drives a light emitting device based on the comparison result of the comparison unit. Accordingly, a comparison operation using a sawtooth waveform voltage having a waveform which is not disturbed is performed.

The present disclosure includes circuits and methods that adjust and correct duty cycles of circuits. The circuits and methods receive a signal from a first circuit and forward the received signal to a second circuit that retrieves a first setting (X) that provides a measure of duty cycle of the received signal. The circuits and methods then invert the received signal, retrain the second circuit based upon the inverted received signal, and retrieve a second setting (Y) of the retrained second circuit. The second setting (Y) provides a measure of duty cycle of the inverted received signal. The circuits and methods then adjust the duty cycle of the received signal based upon the first and second settings (X, Y) and further retrain of the second circuit to provide an improved duty cycle in a direction closer to 50 percent.

A digital-to-analog converter (DAC) controller system may be configured for controlling switching in an associated digital-to-analog converter (DAC), based on a plurality of system inputs that include at least a first system input corresponding to an input applied to the DAC for controlling switching therein, and a second system input that includes a reference control signal. The DAC controller system may include a logic gate circuit that generates a gate output based on two gate inputs that include the first system input and an input set based on the second system input; and a plurality of timing circuits that generate timing outputs for controlling timing of switching in the DAC, which include at least one timing circuit that generates a timing output based on the gate output, with the timing output configured for application in conjunction with and for adjusting a timing output of another timing circuit.

A digital-to-analog converter having a structure that converter may decrease an effect of a mismatch between elements and decrease a quantity of the elements. The digital-to-analog converter includes a multiplexer configured to output a first voltage or a second voltage corresponding to an input bit as an input voltage and a recursive switched circuit configured to alternately receive the input voltage and a reference voltage and to output an average value of the input voltage and the reference voltage as an output voltage.

A calibrating digital to analog converter (calDAC) architecture uses a low voltage memory to store the digital inputs of calDACs. The calDAC architecture includes a low voltage domain and a high voltage domain coupled to the low voltage domain. The low voltage domain includes a calDAC memory and a finite state machine (FSM). The high voltage domain includes a calDAC core, an interface circuit, and a bias control circuit coupled to the interface circuit. The interface circuit may be provided between the calDAC core and the low voltage domain. The bias control circuit is coupled to the interface circuit to generate a bias voltage for the interface circuit to drive switch transistors of the calDAC core.