A clock generator circuit includes a charge pump unit, a low-pass filter unit, a current-controlled clock generator and a voltage-to-current converter unit. The charge pump unit provides a pump current at an output terminal thereof. The low-pass filter unit is coupled to the output terminal of the charge pump unit, and develops a control voltage at an output terminal thereof based on the pump current. The voltage-to-current converter unit is coupled to the output terminal of the low-pass filter unit, the current-controlled clock generator and the charge pump unit, and provides a control current to the current-controlled clock generator. Each of the low-pass filter unit and the voltage-to-current converter unit includes a resistive element.

A delay locked loop circuit includes a duty detector configured to detect a duty cycle of a clock signal, and to determine whether to perform a coarse duty cycle correction based on the detected duty, and a delay locked loop core. The delay locked loop core is configured to selectively perform the coarse duty cycle correction for the clock signal according to the determination of the duty detector, perform a coarse lock for the clock signal during a first time period different from a second time period in which the coarse duty cycle correction is performed, and perform a fine duty cycle correction and a fine lock for the clock signal.

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.

A two dimensional charge pump and control circuitry is disclosed. The two dimensional charge pump includes a group of parallel-coupled charge pumps coupled between a DC power source and a first output connection node via a corresponding group of charge pump connection nodes. The group of parallel-coupled charge pumps has a corresponding group of clock connection nodes. Each of the group of parallel-coupled charge pumps includes a corresponding group of series capacitive elements coupled between a corresponding one of the group of charge pump connection nodes and a corresponding one of the group of clock connection nodes.

A voltage-controlled oscillator (VCO) includes an inductor-capacitor (LC) tank circuit, tuning circuitry, and a plurality of first varactors. The LC tank circuit is configured to produce an oscillating signal and is operable in a plurality of frequency bands. The tuning circuitry is configured to tune the LC tank circuit to operate in a first frequency band of the plurality of frequency bands based at least in part on a temperature of the VCO. The plurality of first varactors are coupled to the LC tank circuit for tuning the oscillating signal to a target frequency within the first frequency band based on a control voltage.

An apparatus includes an oscillator circuit that may generate a clock signal with a frequency that is based on a voltage level of a control node, and a charge pump circuit that includes a first current source and a second current source. The first current source may be coupled between a first supply node and a first circuit node. The second current source may be coupled between a second supply node and a second circuit node. The charge pump circuit may be configured to pre-charge the first and second circuit nodes to voltage levels that differ from the control node and the first and second supply nodes. In addition, the charge pump circuit may select, based on phase information, either the first or second circuit node, and then modify, based on a voltage level of the selected circuit node, a voltage level of the control node.

A PLL circuit includes a phase comparator, a charge pump, a loop filter, a voltage-controlled oscillator, a frequency divider, a frequency difference determination unit, and an FV characteristics adjustment unit. The frequency difference determination unit determines whether or not a frequency difference between a feedback oscillation signal and an input signal is equal to or smaller than a threshold value. The FV characteristics adjustment unit selects a frequency band in the voltage-controlled oscillator and adjusts FV characteristics.

The control signal edges of pull-up and pull-down output transistors are aligned by a feedback system. The feedback system works to align the edges of these pull-up and pull-down control pulses while also reducing and/or minimizing any overlap of pull-up and pull-down control pulses. The feedback system uses a proportional feedback loop and an integral feedback loop. The proportional feedback loop controls the crossover voltages of the differential clock signals used to generate the pull-up and pull-down pulses. The integral feedback loop controls the crossover voltages of the differential clock signals output by the delay elements of a delay-locked loop. These crossover voltages are controlled by the feedback loops such that the edges of the pull-down control pulses are aligned to the edges of the pull-up control pulses (and vice versa) without creating excessive overlap.

Embodiments of a clock synchronization unit of an All Digital Phase-Locked Loop (ADPLL), a successive approximation register (SAR) Time-to-Digital Converter (TDC) of an ADPLL and a method for clock synchronization in an ADPLL are disclosed. In one embodiment, a clock synchronization unit of an ADPLL includes a two-flop synchronizer, a phase frequency detector (PFD) connected to the two-flop synchronizer, and a synchronization control circuit configured to control the two-flop synchronizer and the PFD to perform clock synchronization between a reference clock input signal and a divided clock input signal and to control the two-flop synchronizer and the PFD to replace a performance of the clock synchronization between the reference clock input signal and the divided clock input signal with a PFD operation. Other embodiments are also described.

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.