A coarse tuning synthesizer for wireless communication includes a digital control unit, a digital-to-analog converter, and a comparator. The digital control unit includes an output node coupled to a first input node of a VCO (voltage controlled oscillator). The digital-to-analog converter includes a first node coupled to the first input node of the VCO. The comparator includes an output node coupled to an input node of the digital control unit. The comparator also includes a first input node coupled to a second node of the digital-to-analog converter and a second input node coupled to an output node of the VCO.

The variation of the oscillation frequency of an oscillator can be suppressed even in the case where the amount of interference with the oscillator accompanied by an amplifying operation of a power amplifier and the polarity are not constant. An oscillator is configured to be capable of oscillating at an oscillation frequency in accordance with control signals Vcont and FREQ_CTRL. A phase locked loop allows the oscillator to output an oscillation signal Vout in synchronization with a reference signal RELCLK using the control signal Vcont. A power amplifier amplifies the electric power of the oscillation signal Vout. A variation detection unit detects a variation with respect to the time change of the control signal Vcont after an amplifying operation is started by the power amplifier causing 3interference with the oscillator. A variation correction unit generates the control signal FREQ_CTRL on the basis of the variation detected by the variation detection unit, and corrects the variation of the oscillation frequency caused by the interference accompanied by the amplifying operation of the power amplifier.

A flash analog-to-digital converter (ADC) receives an input control signal and performs coarse tuning of a frequency of an output signal, produced between first and second nodes having an inductance coupled therebetween. The flash ADC quantizes an operating frequency range for the output signal produced between the first and second nodes as M.Math.?f, where M is an integer from 0 to N?1, where N is a number of intervals into which a frequency range for the output signal is divided, and where ?f is a resulting frequency step produced by the quantizing. The value of M is generated based upon the input control signal and a word controlling switches of a plurality of switched capacitance circuits associated with the first and second nodes to close ones of those switches associated with the control word to coarsely tune the frequency of the output signal.

An apparatus is disclosed for relocking of a locked loop. In an example aspect, the apparatus includes a locked loop, and the locked loop includes a loop and a locked-loop controller that is coupled to the loop. The loop is configured to run responsive to a run signal. The loop includes a memory state component and signal characteristic adjustment circuitry coupled to the memory state component. The signal characteristic adjustment circuitry is configured to produce an output signal having a characteristic that is based on the memory state component. The locked-loop controller is configured to receive an external power mode signal (EPMS). The locked-loop controller is also configured to generate the run signal to have an enable value at a first time when the EPMS is indicative of an external normal mode and at a second time when the EPMS is indicative of an external standby mode.

A digital phase-locked loop with an automatic calibration function and an automatic calibration method thereof are provided. The digital phase-locked loop includes a frequency and phase detector, a calibration circuit, a frequency and phase locked circuit, and an oscillator circuit. The frequency and phase locked circuit outputs an initial control signal. The calibration circuit calibrates an initial frequency and outputs an initial calibration signal having a calibrated initial frequency when determining that the initial frequency does not fall within an allowable error calibration range. The frequency and phase locked circuit locks the calibrated initial frequency when determining that the calibrated initial frequency falls within a locked frequency range. The oscillator circuit outputs an oscillator signal according to the initial calibration signal and the initial control signal. Therefore, a resolution of the oscillator circuit can be improved by the automatic calibration of frequency drift caused by processes and environments.

A scanning system includes an oscillator structure configured to oscillate about a first axis according to a first oscillation and oscillate about a second axis according to a second oscillation; a reference signal circuit including a digitally controlled oscillator (DCO) configured with a DCO period and configured to divide the DCO period into a plurality of equidistant slices and generate a subtiming signal that indicates the plurality of equidistant slices, a first reference signal generator configured to generate a first reference signal having a first frequency based on the subtiming signal, and a second reference signal generator configured generate a second reference signal having a second frequency based on the subtiming signal; and a driver system configured to drive the first oscillation at the first frequency based on the first reference signal and drive the second oscillation at the second frequency based on the second reference signal.

A digital phased lock loop includes a digital controlled oscillator configured to produce an output signal at an output signal frequency, and a phase comparator configured to compare the output signal or a signal derived from the output signal, with a reference signal at a reference signal frequency or a signal derived from the reference signal to produce a phase error signal. A first loop filter produces a first control signal for the digital controlled oscillator. A frequency error measuring circuit produces a frequency error signal that directly represents a frequency difference between the output signal frequency and the reference signal frequency. A second loop filter produces a second control signal for the digital controlled oscillator from an output of the frequency error measuring circuit. A circuit combines the first and second control signals and providing the combined control signals to the digital controlled oscillator.

A PLL including a VCO with a variable capacitance (such as an LC VCO) including a switched capacitor bank and a varactor, the PLL providing lock range extension over temperature using dynamic capacitor bank switching to dynamically adjust varactor set point based on junction temperature. The varactor is responsive to the Vctrl control voltage to adjust a capacitance of the variable capacitance to control the phase of the PLL signal. Compensation circuitry dynamically adjusts varactor set point by dynamically switching the capacitor bank based in a junction temperature associated with the PLL circuitry, thereby extending PLL lock range over temperature.

The variation of the oscillation frequency of an oscillator can be suppressed even in the case where the amount of interference with the oscillator accompanied by an amplifying operation of a power amplifier and the polarity are not constant. An oscillator is configured to be capable of oscillating at an oscillation frequency in accordance with control signals Vcont and FREQ_CTRL. A phase locked loop allows the oscillator to output an oscillation signal Vout in synchronization with a reference signal RELCLK using the control signal Vcont. A power amplifier amplifies the electric power of the oscillation signal Vout. A variation detection unit detects a variation with respect to the time change of the control signal Vcont after an amplifying operation is started by the power amplifier causing 3interference with the oscillator. A variation correction unit generates the control signal FREQ_CTRL on the basis of the variation detected by the variation detection unit, and corrects the variation of the oscillation frequency caused by the interference accompanied by the amplifying operation of the power amplifier.

A voltage-controlled oscillator in a phase-locked loop circuit is calibrated via a dichotomous search in a set of candidate frequency bands via a sequence of subsequent halving steps that produce reduced subsets of the set of candidate frequency bands. The reduced subsets have respective upper bound values and lower bound values, as well as central values. The central value of the subset resulting from the halving step of index i in the sequence is a function of the average of the upper bound value and the lower bound value of the subset resulting from the halving step of index i?1 in the sequence.