Abstract: A multi-stage switched capacitor circuit and an operation method thereof are provided. The multi-stage switched capacitor circuit includes a first operational stage, a second operational stage and a third operational stage that are serially connected in order. Each operational stage operates in a sample phase or a hold phase and generates a detection signal indicating an end of the hold phase. The operation method of the multi-stage switched capacitor circuit includes: controlling the second operational stage to operate in the hold phase when the detection signal of the first operational stage indicates the end of the hold phase of the first operational stage, and the detection signal of the third operational stage indicates the end of the hold phase of the third operational stage.

Abstract: An analog-to-digital converter (ADC) device includes an ADC circuitry and a digital slope ADC circuitry. The ADC circuitry is configured to generate first bits and a first voltage according to an input signal. The digital slope ADC circuitry is configured to generate a second voltage at a node according to the first voltage and to gradually adjust the second voltage to generate second bits. After the second bits are generated, the digital slope ADC circuitry is further configured to perform a noise shaping function according to a first residual signal of the node.

Abstract: An analog-to-digital converter (ADC) is provided. The ADC receives an analog input signal and generates a digital code. The ADC includes a sigma-delta modulator (SDM), a decimation filter and a detection circuit. The SDM includes a loop filter, a quantizer and a digital-to-analog converter (DAC). The loop filter receives the analog input signal. The quantizer is coupled to the loop filter and quantizes an output of the loop filter to generate a digital output signal. The DAC is coupled to the quantizer and the loop filter. The decimation filter is coupled to the SDM and converts the digital output signal into the digital code. The detection circuit is coupled to the SDM and detects a node voltage of the SDM and generate a control signal. The control signal is utilized to control the loop filter, the quantizer, a feedback path of the SDM and/or a feedforward path of the SDM.

Abstract: A bootstrapped switch is provided. The bootstrapped switch includes a first transistor, a second transistor, a capacitor and five switches. The first transistor receives an input voltage and outputs an output voltage. A first terminal of the second transistor receives the input voltage, and a second terminal of the second transistor is coupled to a first terminal of the capacitor. In a first clock phase, the capacitor is being charged. In a second clock phase, the control terminal of the first transistor and the control terminal of the second transistor are substantially equipotential with a second terminal of the capacitor. The control terminal of the first transistor and the control terminal of the second transistor are coupled to the power supply voltage within a predetermined time before the terminal of the first clock phase or within a predetermined time after the start of the second clock phase.

Abstract: An analog to digital converter device includes a capacitor array, a digital logic circuit, and a comparator circuit. The capacitor array includes first capacitors, a capacitor to be calibrated, and compensation capacitors. The digital logic circuit performs a calibration on the capacitor to be calibrated, in order to calibrate a weighed value of the capacitor to be calibrated according to a decision signal, and converts an input signal to bits via the capacitor array after the calibration is performed. The comparator circuit compares a testing signal with a predetermined voltage to generate the decision signal. The testing signal is generated by the first capacitors and the capacitor to be calibrated in response to the calibration. The digital logic circuit further selects at least one of the compensation capacitors, in order to adjust a digital code corresponding to a calibrated weighed value to be an integer expressed by the bits.

Abstract: A digital-to-analog converter (DAC) device includes a current-steering DAC circuitry and a calibration circuitry. The current-steering DAC circuitry generates a first signal according to multiple least significant bits of an input signal, and generates a second signal according to multiple most significant bits of the input signal. The calibration circuitry performs a non-binary search algorithm to generate a calibration signal in response to a comparison result of the first signal and the second signal, in order to calibrate the current-steering DAC circuitry according to the calibration signal.

Abstract: A multi-stage switched capacitor circuit and an operation method thereof are provided. The multi-stage switched capacitor circuit includes a first operational stage, a second operational stage and a third operational stage that are serially connected in order. Each operational stage operates in a sample phase or a hold phase and generates a detection signal indicating an end of the hold phase. The operation method of the multi-stage switched capacitor circuit includes: controlling the second operational stage to operate in the hold phase when the detection signal of the first operational stage indicates the end of the hold phase of the first operational stage, and the detection signal of the third operational stage indicates the end of the hold phase of the third operational stage.

Abstract: The present invention provides a voltage difference measurement circuit comprising a level shifting circuit, an ADC and a calculation circuit. In the operations of the voltage difference measurement circuit, the level shifting circuit adjusts levels of a supply voltage and a ground voltage to generate an adjusted supply voltage and an adjusted ground voltage, respectively. The ADC performs an analog-to-digital converting operation upon the adjusted supply voltage and the adjusted ground voltage to generate a first digital value and a second digital value, respectively. The calculation circuit calculates a voltage difference between the supply voltage and the ground voltage according to the first digital value and the second digital value.

Abstract: An analog to digital converting module includes a comparator, at least one digital to analog convertor, and a reference buffer. The comparator is configured to compare a first input signal and a second input signal so as to output a comparing signal. The at least one at least one digital to analog convertor includes at least one capacitor. The reference buffer is configured to provide a reference signal. The at least one digital to analog convertor receives the reference signal such that a ripple signal is generated according to a change of a voltage of the reference signal. The capacitance of the capacitor of the at least one digital to analog convertor is adjusted based on the ripple signal.

Abstract: A bootstrapped switch is provided. The bootstrapped switch includes a first transistor, a second transistor, a capacitor and five switches. The first transistor receives an input voltage and outputs an output voltage. A first terminal of the second transistor receives the input voltage, and a second terminal of the second transistor is coupled to a first terminal of the capacitor. In a first clock phase, the capacitor is being charged. In a second clock phase, the control terminal of the first transistor and the control terminal of the second transistor are substantially equipotential with a second terminal of the capacitor. The control terminal of the first transistor and the control terminal of the second transistor are coupled to the power supply voltage within a predetermined time before the terminal of the first clock phase or within a predetermined time after the start of the second clock phase.

Abstract: An analog-to-digital converter (ADC) device includes an ADC circuitry and a digital slope ADC circuitry. The ADC circuitry is configured to generate first bits and a first voltage according to an input signal. The digital slope ADC circuitry is configured to generate a second voltage at a node according to the first voltage and to gradually adjust the second voltage to generate second bits. After the second bits are generated, the digital slope ADC circuitry is further configured to perform a noise shaping function according to a first residual signal of the node.

Abstract: The present invention provides a voltage difference measurement circuit comprising a level shifting circuit, an ADC and a calculation circuit. In the operations of the voltage difference measurement circuit, the level shifting circuit adjusts levels of a supply voltage and a ground voltage to generate an adjusted supply voltage and an adjusted ground voltage, respectively. The ADC performs an analog-to-digital converting operation upon the adjusted supply voltage and the adjusted ground voltage to generate a first digital value and a second digital value, respectively. The calculation circuit calculates a voltage difference between the supply voltage and the ground voltage according to the first digital value and the second digital value.

Abstract: An analog-to-digital converter (ADC) is provided. The ADC receives an analog input signal and generates a digital code. The ADC includes a sigma-delta modulator (SDM), a decimation filter and a detection circuit. The SDM includes a loop filter, a quantizer and a digital-to-analog converter (DAC). The loop filter receives the analog input signal. The quantizer is coupled to the loop filter and quantizes an output of the loop filter to generate a digital output signal. The DAC is coupled to the quantizer and the loop filter. The decimation filter is coupled to the SDM and converts the digital output signal into the digital code. The detection circuit is coupled to the SDM and detects a node voltage of the SDM and generate a control signal. The control signal is utilized to control the loop filter, the quantizer, a feedback path of the SDM and/or a feedforward path of the SDM.

Abstract: A digital-to-analog converter (DAC) device includes a current-steering DAC circuitry and a calibration circuitry. The current-steering DAC circuitry generates a first signal according to multiple least significant bits of an input signal, and generates a second signal according to multiple most significant bits of the input signal. The calibration circuitry performs a non-binary search algorithm to generate a calibration signal in response to a comparison result of the first signal and the second signal, in order to calibrate the current-steering DAC circuitry according to the calibration signal.

Abstract: The invention discloses a calibration circuit and a calibration method for an analog-to-digital converter (ADC). The calibration method of the ADC includes the following steps: (a) resetting the voltage at the first input of the comparator and the voltage at the second input of the comparator; (b) changing a terminal voltage of at least one capacitor in the first capacitor group; (c) the ADC generating a first digital code; (d) after the first digital code is obtained, resetting the voltage at the first input of the comparator and the voltage at the second input of the comparator; (e) changing a terminal voltage of at least one capacitor in the third capacitor group; and (f) the ADC generating a second digital code. The first digital code and the second digital code are used to correct the output of the ADC.

Abstract: A charge-pump boosting is provided. A first resistor is connected to a first storage capacitor and receives a reference voltage, and a second resistor is connected to a second storage capacitor and receives the reference voltage. A first rectifying device is connected to the first storage capacitor and a voltage output. A first clock signal and the reference voltage are used to charge the first storage capacitor, and the first clock signal is used to selectively turn on the first rectifying device to charge the voltage output by the first storage capacitor. The second rectifying device is connected to the second storage capacitor and the voltage output. A second clock signal and the reference voltage are used to charge the second storage capacitor, and the second clock signal is used to selectively turn on the second rectifying device to charge the voltage output by the second storage capacitor.

Abstract: A charge-pump boosting is provided. A first resistor is connected to a first storage capacitor and receives a reference voltage, and a second resistor is connected to a second storage capacitor and receives the reference voltage. A first rectifying device is connected to the first storage capacitor and a voltage output. A first clock signal and the reference voltage are used to charge the first storage capacitor, and the first clock signal is used to selectively turn on the first rectifying device to charge the voltage output by the first storage capacitor. The second rectifying device is connected to the second storage capacitor and the voltage output. A second clock signal and the reference voltage are used to charge the second storage capacitor, and the second clock signal is used to selectively turn on the second rectifying device to charge the voltage output by the second storage capacitor.

Abstract: The invention discloses a calibration circuit and a calibration method for an analog-to-digital converter (ADC). The calibration method of the ADC includes the following steps: (a) resetting the voltage at the first input of the comparator and the voltage at the second input of the comparator; (b) changing a terminal voltage of at least one capacitor in the first capacitor group; (c) the ADC generating a first digital code; (d) after the first digital code is obtained, resetting the voltage at the first input of the comparator and the voltage at the second input of the comparator; (e) changing a terminal voltage of at least one capacitor in the third capacitor group; and (f) the ADC generating a second digital code. The first digital code and the second digital code are used to correct the output of the ADC.

Abstract: An analog to digital converting module includes a comparator, at least one digital to analog convertor, and a reference buffer. The comparator is configured to compare a first input signal and a second input signal so as to output a comparing signal. The at least one at least one digital to analog convertor includes at least one capacitor. The reference buffer is configured to provide a reference signal. The at least one digital to analog convertor receives the reference signal such that a ripple signal is generated according to a change of a voltage of the reference signal. The capacitance of the capacitor of the at least one digital to analog convertor is adjusted based on the ripple signal.

Abstract: A transmitter, a receiver and a transceiver are provided. The transceiver includes a hybrid transceiving circuit and a common-mode voltage control circuit. The hybrid transceiving circuit includes a digital-to-analog converter (DAC) circuit, a line driver coupled to the DAC circuit, a filtering and/or amplifying circuit coupled to the line driver, and an analog-to-digital converter (ADC) circuit coupled to the filtering and/or amplifying circuit. The common-mode voltage control circuit is electrically connected to a node of the hybrid transceiving circuit and is configured to detect a common-mode voltage of the node and to adjust the common-mode voltage of the node.