The present technology relates to a charge pump circuit that enables reduction of a circuit area. Provided is a charge pump circuit including: a first transistor; a second transistor to which a constant current is supplied; a third transistor connected to the first transistor and a voltage source; a fourth transistor group including N transistors arranged in a cascade on the first transistor side, the N transistors all including control terminals connected to the second transistor; a fifth transistor group including N transistors arranged in a cascade on the second transistor side, the N transistors all including control terminals connected to the second transistor; a first switch that connects the first transistor to the second transistor; a second switch that connects the first transistor to a ground node; a third switch that connects the third transistor to the fifth transistor group; and a fourth switch that connects the third transistor to the ground node.

A phase locked loop circuit includes a voltage controlled oscillator configured to output a clock signal having a predetermined frequency based in a control voltage, a phase frequency detector configured to compare the clock signal with a reference signal to output a first control signal and a second control signal, a charge pump configured to output the control voltage based on the first control signal and the second control signal, a voltage supply including an output terminal connected to an output terminal of the charge pump by a transmission switch, and a leakage remover circuit connected to the transmission switch and configured to remove a leakage current flowing through the transmission switch while the transmission switch is turned-off.

A temperature sensor using a poly-phase filter may include: a poly-phase filter suitable for receiving a divided clock, and having passive elements coupled to have one or more negative poles and one or more positive zeros; a comparator suitable for generating a reference clock by comparing potentials of first and second filter voltages outputted from the poly-phase filter; a phase frequency detector suitable for outputting an up or down signal by comparing the phase of the reference clock to the phase of a comparison clock; a current supply unit suitable for supplying and integrating a charge current under control of the up or the down signal; an oscillator suitable for outputting an oscillation signal; a divider suitable for generating the divided clock and the comparison clock; and a buffer suitable for inverting and non-inverting the divided clock and outputting the inverted and non-inverted divided clocks.

The present technology relates to a charge pump circuit that enables reduction of a circuit area.

Provided is a charge pump circuit including: a first transistor; a second transistor to which a constant current is supplied; a third transistor connected to the first transistor and a voltage source; a fourth transistor group including N transistors arranged in a cascade on the first transistor side, the N transistors all including control terminals connected to the second transistor; a fifth transistor group including N transistors arranged in a cascade on the second transistor side, the N transistors all including control terminals connected to the second transistor; a first switch that connects the first transistor to the second transistor; a second switch that connects the first transistor to a ground node; a third switch that connects the third transistor to the fifth transistor group; and a fourth switch that connects the third transistor to the ground node.

The present technology relates to a phase-locked loop that allows a reduction in power consumption.

A SAR-ADC that includes two capacitors and outputs a result of comparison between voltages generated from the two capacitors, a current source that charges the two capacitors with current, a first switch that is disposed between one of the two capacitors and the current source and is provided with a phase difference between a first clock of a reference frequency and a second clock having a higher frequency than the first clock, and a second switch that is disposed between another of the two capacitors and the current source and is provided with the second clock are included. The present disclosure can be applied, for example, to a wireless communication device.

A charge pump circuit includes first and second capacitors, first and second controllable current generating circuits, and an interconnection circuit. A first terminal of the first controllable current generating circuit is coupled to a first plate of the first capacitor. A first terminal of the second controllable current generating circuit is coupled to a first plate of the second capacitor. During a first operation mode, the first controllable current generating circuit refers to a first control input for selectively providing a first current, and the second controllable current generating circuit refers to a second control input for selectively providing a second current. During a second operation mode, the interconnection circuit couples the first plate of the second capacitor to a first power rail, and couples both of the second plate of the second capacitor and the first plate of the first capacitor to an output terminal.

A phase-locked loop (PLL) and a method for calibrating a VCO therein are provided. The PLL comprises a frequency-phase detector, a charge pump, a loop filter, a VCO, a divider and a calibration circuit. The calibration circuit is used to acquire a frequency of an output signal of the VCO, to calibrate the frequency of the output signal according to an expected frequency, and to acquire frequency control parameters of the VCO at the current signal frequency. The amplitude and gain of the output signal are kept constant according to the amplitude control parameters and gain control parameters. The PLL can meet the demands on frequencies of multiple protocols and can adaptively look up and stabilize the suitable frequency. It solves the issue that the amplitude of the output signal of the VCO is not constant when the PLL operates in a large frequency range.

Power consumption of a time-to-digital converter (TDC) used in a phase locked loop (ADPLL) is suppressed. The time-to-digital converter includes an analog-to-digital converter and a current source circuit. The analog-to-digital converter includes a predetermined charge capacitor. The current source circuit supplies a charge current that charges the charge capacitor of the analog-to-digital converter with a charge. The charge current supplied by the current source circuit is supplied so that a charge voltage at the time of charging the charge capacitor of the analog-to-digital converter with the charge current has a constant gradient with respect to a charge time.

Embodiments of a method for operating a charge pump and a charge pump are disclosed. In an embodiment, a method for operating a charge pump involves during a first operating phase of the charge pump, setting a first current source of the charge pump according to a second current source of the charge pump, and, during a second operating phase of the charge pump that is subsequent to the first operating phase, providing current from the first current source to a load of the charge pump.

The present invention provides a clock generating circuit, wherein the clock generating circuit includes a phase detector, an integral path, a proportional path, a bias path and an oscillator. In the operations of the clock generating circuit, the phase detector generates a detection result according to a reference signal and a feedback signal, a first charge pump within the integral path generates a first control signal according to the detection result, a second charge pump within proportional path generates a second control signal according to the detection result, a low-pass filter within the bias path filters the first control signal to generate a third control signal, and the oscillator generates a clock signal according to the first control signal, the second control signal and the third control signal.