The invention provides a phase difference generator error compensation method of a digital frequency generator, wherein the digital frequency generator comprises a phase difference generator, the phase difference generator comprises a phase compensation module and an adjusting module, the phase compensation module provides at least two clock signals, the at least two clock signals comprise a first clock signal and a second clock signal, and a phase difference exists between the first clock signal and the second clock signal; the phase compensation module outputs a third clock signal according to the first clock signal and the second clock signal, and the third clock signal is a difference signal of the first clock signal and the second clock signal; the adjusting module compensates the error of the third clock signal according to the clock phase difference. The method has the benefits that process errors in the phase difference generator are compensated.

A sub-sampling phase-locked loop is described, which comprises a digital-to-time converter, a sampler module, an interpolator, and a voltage controlled oscillator. The digital-to-time converter is configured to provide a first delay signal SDLY1 at a first point t1 in time and a second delay signal SDLY2 at a second point in time t2. The sampler module is configured to provide a first sample S1 of the oscillator output signal SOUT at the first point in time t1 and a second sample S2 of the oscillator output signal SOUT at the second point in time t2. The interpolator is configured to provide a sampler signal SSAMPL by interpolating the first sample S1 and the second sample S2. The voltage controlled oscillator is configured to control the oscillator output signal SOUT based on the sampler signal SSAMPL.

An apparatus for providing a clock signal based on a received clock signal includes a time-to-digital converter configured to generate timestamp information based on the received clock signal. The apparatus includes a first filter configured to generate clock period information based on the timestamp information. The apparatus includes a phase monitor circuit. The phase monitor circuit includes a second filter configured to provide a mean period signal of the received clock signal based on the clock period information. The phase monitor includes a phase error detection circuit configured to generate a phase error indicator based on a threshold difference value and a difference between the clock period information and expected clock period information. The expected clock period information is based on the mean period signal.

A PLL frequency synthesizer includes a voltage controlled oscillator that outputs an oscillation signal having a frequency corresponding to a control voltage value, a phase comparison unit that outputs a phase difference signal representing a phase difference between a feedback oscillation signal and a reference oscillation signal, a charge pump that outputs a charge and discharge current according to the phase difference, a loop filter that outputs the control voltage value, which is increased or decreased according to a charge and discharge amount of a capacitive element, to the voltage controlled oscillator, a detection unit that detects a change rate of the control voltage value, and a control unit that adjusts the charge and discharge current, a characteristic of the loop filter, or a characteristic of the voltage controlled oscillator based on a detection result of the detection unit.

An apparatus is provided which comprises: an oscillator to generate a first clock having a first frequency; a divider coupled to the oscillator, wherein the divider is to generate a second clock having a second frequency; and a current reference generator comprising a switched capacitor circuitry which is to receive the second clock directly or indirectly.

A phase locked loop, particularly for or in a beamforming system comprises a loop filter (1) to provide a control signal (FC) to a controllable oscillator (2); a frequency divider (3) configured to provide a first feedback signal (FB) and a second feedback signal (FBD) in response to an oscillator signal (FO), the second feedback signal (FBD) delayed with respect to the first feedback signal (FB); a first comparator path (4) configured to receive the first feedback signal (FB) and a second comparator path (5) configured to receive the second feedback signal (FBD), each of the first and second comparator path (4, 5) configured to provide a respective current signal (CS1, CS2) to the loop filter (1) in response to a respective adjustment signal (FA1, FA2) and a phase deviation between a common reference signal (FR) and the respective feedback signal (FB, FBD).

Apparatus and methods for timing offset compensation of frequency synthesizers are provided herein. In certain embodiments, an electronic system includes a frequency synthesizer, such as a fractional-N phase-locked loop (PLL), which generates an output clock signal based on timing of a reference clock signal. Additionally, the electronic system includes an integer PLL configured to compensate for a timing offset, such as a phase offset and/or frequency offset, of the frequency synthesizer based on timing of the output clock signal.

An output circuit comprises an output terminal (11), a first current mirror (12), a first pass transistor (13) and a first delivering terminal (14) coupled via the first current mirror (12) and the first pass transistor (13) to the output terminal (11).

A method for a radar device is described. According to one example implementation, the method comprises generating an RF signal using a voltage-controlled oscillator (VCO), wherein the frequency of the RF signal depends on a first tuning voltage and a second tuning voltage. The method also comprises setting the second tuning voltage using a phase-locked loop coupled to the VCO, with the result that the frequency of the RF signal corresponds to a desired frequency. The first tuning voltage is changed in such a manner that the second tuning voltage set by the phase-locked loop corresponds approximately to a predefined value. Another example implementation relates to a method for a radar device comprising: generating an RF signal using a VCO, wherein the frequency of the RF signal depends on a tuning voltage, setting the tuning voltage using a phase-locked loop coupled to the VCO, with the result that the frequency of the RF signal corresponds to a desired frequency, and determining a differential VCO gain of the VCO. The bandwidth of the phase-locked loop is set on the basis of the determined VCO gain.

A circuit includes a first signal swapper including a first terminal coupled to a first current source, a second terminal coupled to a second current source, a third terminal coupled to a first current terminal of a first transistor, and a fourth terminal coupled to a third current terminal of a second transistor. The first signal swapper couples the first and second terminals to the third and fourth terminals responsive to a first control signal. First and second switches couple to a gate of the first transistor. The first switch receives the input oscillation signal and the second switch receives a first reference voltage. Third and fourth switches couple to a gate of the second transistor. The third switch receives the input oscillation signal and the fourth switch receives the first reference voltage. A second signal swapper couples to the first signal swapper and to the first and second transistors.