Disclosed are a method and a device for improving an output accuracy of a digital-to-analog converter. The method includes: calculating an output error of the digital-to-analog converter based on output accuracy and an input error of the digital-to-analog converter; obtaining at least one of the output error, comparing the at least one output error against a preset threshold, and adjusting an integer input value of the digital-to-analog converter according to a comparison result.

Exemplary multipath digital microphone described herein can comprise exemplary embodiments of adaptive ADC range multipath digital microphones, which allow low power to be achieved for amplifiers or gain stages, as well as for exemplary adaptive ADCs in exemplary multipath digital microphone arrangements described herein, while still providing a high DR digital microphone systems. Further non-limiting embodiments can comprise an exemplary glitch removal component configured to minimize audible artifacts associated with the change in the gain of the exemplary adaptive ADCs.

A new SARADC has two low resolution SAR (Successive Approximation Register) ADCs coupled together by an amplifier to increase the overall resolution and enhance ADC conversion rate. The gain reduction of amplifier is corrected by shifting the digital binary output position. Two SAR ADC outputs are timing aligned and summed to produce final high-resolution high conversion rate ADC output.

The present invention discloses a SAADC circuit having optimized linearity. A lower-bit capacitor array includes lower-bit capacitors. A higher-bit capacitor array includes unit capacitors. In an initializing mode, a control circuit sorts the unit capacitors according to unit capacitances thereof such that the unit capacitors are configured to be higher-bit capacitors having a linearity parameter within a predetermined range. In an operation mode, the capacitor array receives an analog input signal and a reference voltage to generate an analog output signal, a comparator generates a comparison result according to the analog output signal and the control circuit generates an enabling signal according to the comparison result based on the successive approximation mechanism to selectively enable the higher-bit and the lower-bit capacitors to connect to the reference voltage by using the capacitor enabling circuit and outputs a digital output signal according to the final comparison result.

In a pipelined Successive Approximation Register Analog to Digital Converter, SAR ADC, a Process, Temperature, and Voltage (PVT)-dependent bias voltage is generated and used to bias the inputs of comparators in at least the first SAR stage and residual amplifier (RA). This achieves a stable biasing and an operating point of the comparators and RA input stages that is independent of PVT variations, by tracking PVT variations in such a way that variations in MOS threshold voltage and drain-source voltage are counteracted. Additionally, a threshold common mode voltage is generated from the PVT-dependent voltage, which controls the amplification duration of the RAs such that the final RA output common mode voltage is substantially equal to the PVT-dependent voltage, which is used to bias the inputs of successive SAR stages. The threshold is set to account for logic delays in terminating the amplification based on the threshold comparison, to achieve the desired common mode amplifier output. The dependency on PVT of the threshold additionally cancels temperature variation from a differential stage transconductance of the RA. Further temperature stabilization is achieved by boosting the charge output by the RA to a capacitive load during part of the amplification.

An electronic device may include: a power management integrated circuit (PMIC); and a micro controller unit (MCU) electrically connected to the PMIC. The MCU may be configured to: generate, based on a first driving power signal output from the PMIC to drive the MCU, a digital signal for determining an error in a reference signal of an analog-to-digital converter (ADC) included in the MCU; identify an error rate of the digital signal; and determine a mode for controlling a motor driven power steering system, based on the error rate of the digital signal.

Various embodiments relate to a single slope analog to digital converter (ADC), including: a voltage slope generator configured to generate a voltage slope based upon a fixed current and variable current; an analog comparator configured to compare a voltage to a voltage output from the voltage slope generator; a first register configured to store a first count based upon a reference voltage being input into the analog comparator; a second register configured to store a second count based upon an input voltage being input into the analog comparator, wherein the input voltage is the voltage to be converted to a digital value by the ADC; and a digital to analog converter (DAC) configured to produce a slope trim signal based upon the voltage slope output by the voltage slope generator, the first count, and a count target associated with the voltage reference, wherein the variable current in the voltage slope generator is based upon the slope trim signal.

The value range for which an error in a digital signal can be corrected is expanded. A control unit generates characteristic information indicating the relationship between an input and an output of an A/D converter and sets a value range. The control unit, in a case in which a value indicated by a first digital signal obtained by the A/D converter converting a first analog voltage signal is within the value range, A/D converts the first analog voltage signal and generates corrected digital information on the basis of the first digital signal and characteristic information, and in a case in which a value indicated by the first digital signal is not within the value range, A/D converts the first analog voltage signal and generates corrected digital information on the basis of a second digital signal obtained by the A/D converter converting the second analog voltage signal and characteristic information.

An ADC device includes a DAC circuit, a comparator circuit, a SAR decision circuit, an oscillator circuit having a delay unit, and a processing circuit. The oscillator circuit is used for generating the clock signal according to a reset signal and a delay of the delay unit. The processing circuit is used for sequentially generating multiple bit conversion signals associated with multiple different bits of the decision signal, for generating at least one guard signal which follows the multiple bit conversion signals, and then for comparing the at least one guard signal with the reset signal to adjust the delay generated by the delay unit of the oscillator circuit.

A system has a digital-to-analog converter; a reference signal coupled to the digital-to-analog converter; a differential amplifier for applying gain, and for generating output signals as a function of sampled input signals, the reference signal, digital codes, and the gain applied by the differential amplifier coupled to the digital-to-analog converter; and a multi-bit successive-approximation register for determining the digital codes in successive stages coupled to the differential amplifier; and the gain applied by the differential amplifier is corrected based on previously determined digital codes.