Abstract: The present invention discloses an analog to digital conversion (ADC) apparatus having quick conversion mechanism. Each of ADC circuits receives a previous higher-bit conversion result to perform prediction to generate a current higher-bit conversion result, performs conversion on an input analog signal according to a sampling clock that has a frequency at least twice of the frequency of the input analog signal based on a successive-approximation mechanism to generate a current lower-bit conversion result, and combines the current higher-bits and current lower-bit conversion results to generate a current conversion result and output a remained signal amount as a residue. A noise-shaping circuit performs calculation based on the residue to generate a noise-shaping reference signal. Each of the ADC circuits combines the current conversion result and the noise-shaping reference signal to generate an output digital signal.

Abstract: A digital slope analog to digital converter includes a charge injection digital to analog converter (DAC) circuit, a comparator circuit, a detector circuit, and a control logic circuitry. The charge injection DAC circuit respectively samples input signals via first and second capacitors and generates a first signal via the first capacitor and a second signal via the second capacitor. The comparator circuit compares the first signal with the second signal to generate decision signals. The detector circuit generates a flag signal according to the decision signals. The control logic circuitry generates an enable signal according to the flag signal and generates a digital output when the comparator circuit detects a crossing point of the first and second signals. The charge injection DAC circuit gradually adjusts charges stored in the first and/or the second capacitor according to the enable signal until the crossing point is detected.

Abstract: A method of converting a single-ended signal to a differential-ended signal includes the following steps: providing a first sampling capacitor having a first end and a second end; providing a second sampling capacitor having a third end and a fourth end; at a first time point, controlling the first end to receive a single-ended signal, controlling the second end to receive a reference voltage, controlling the third end to receive the reference voltage or a middle voltage value of the swing of the single-ended signal, and controlling the fourth end to receive the single-ended signal; and at a second time point, controlling the second end and the fourth end to receive the reference voltage. The first end and the third end output a differential signal after the second time point which is later than the first time point.

Abstract: A successive approximation register analog to digital converter includes a charge injection digital to analog converter (DAC) circuit, a comparator circuit, and a control logic circuitry. The charge injection DAC circuit includes capacitors that sample input signals to generate first and second signals and charge injection circuits that selectively adjust the first or the second signals according to enable signals and decision signals. The comparator circuit compares the first and second signals to generate the decision signals. The control logic circuitry controls a circuit of the charge injection circuits to adjust the first and the second signals during an initial phase, in order to adjust a switching sequence of the circuit according to the decision signals corresponding to the initial phase, and generates the enable signals according to the decision signals and the adjusted switching sequence during a conversion phase to generate a digital output.

Abstract: The present invention discloses an analog to digital conversion (ADC) apparatus having quick conversion mechanism. Each of ADC circuits receives a previous higher-bit conversion result to perform prediction to generate a current higher-bit conversion result, performs conversion on an input analog signal according to a sampling clock that has a frequency at least twice of the frequency of the input analog signal based on a successive-approximation mechanism to generate a current lower-bit conversion result, and combines the current higher-bits and current lower-bit conversion results to generate a current conversion result and output a remained signal amount as a residue. A noise-shaping circuit performs calculation based on the residue to generate a noise-shaping reference signal. Each of the ADC circuits combines the current conversion result and the noise-shaping reference signal to generate an output digital signal.

Abstract: A control circuit for a successive approximation register analog-to-digital converter (SAR ADC). The SAR ADC includes a comparator and a switched-capacitor digital-to-analog converter (DAC). The switched-capacitor DAC includes a target capacitor. A first terminal of the target capacitor is coupled to an input terminal of the comparator. A second terminal of the target capacitor is coupled to a first reference voltage through a first switch and coupled to a second reference voltage through a second switch. The control circuit includes a third switch and a buffer circuit. The third switch is coupled between the first reference voltage and the second terminal of the target capacitor. The buffer circuit is coupled to the first switch and the third switch for controlling the first switch and the third switch based on a control signal.

Abstract: A control circuit for a successive approximation register analog-to-digital converter (SAR ADC). The SAR ADC includes a comparator and a switched-capacitor digital-to-analog converter (DAC). The switched-capacitor DAC includes a target capacitor. A first terminal of the target capacitor is coupled to an input terminal of the comparator. A second terminal of the target capacitor is coupled to a first reference voltage through a first switch and coupled to a second reference voltage through a second switch. The control circuit includes a third switch and a buffer circuit. The third switch is coupled between the first reference voltage and the second terminal of the target capacitor. The buffer circuit is coupled to the first switch and the third switch for controlling the first switch and the third switch based on a control signal.