Systems and methods for integrating injection-locked oscillators into transceiver arrays are disclosed. In one aspect, there is provided an injection-locked oscillator (ILO) distribution system including a master clock generator configured to generate a master clock signal. The ILO distribution system also includes an ILO distribution circuit including an ILO and configured to receive the master clock signal. The ILO is configured to generate a reference clock signal based on the master clock signal. The ILO distribution circuit is further configured to generate an output signal indicative of an operating frequency of the ILO. The ILO distribution system further includes an injection-locked detector (ILD) configured to receive the master clock signal and the output signal. The ILD is further configured to determine whether the ILO is in a locked state or in an unlocked state based on the master clock signal and the output signal.

A clock and data recovery circuit includes a sampling circuit, a phase detector, a first processing circuit, a second processing circuit and an oscillator circuit. The sampling circuit is configured to sample input data according to an output clock, and generate a sampling result. The phase detector is configured to generate a detection result according to the sampling result. The first processing circuit is configured to process the sampling result to generate a first digital code. The second processing circuit is configured to accumulate a portion of the first digital code to generate a second digital code. A rate of change of a code value of the second digital code is slower than a rate of change of a code value of the first digital code. The oscillator circuit is configured to generate the output clock according to the detection result, the first digital code and the second digital code.

An apparatus having a digitally controlled timing adjustment circuit configured to receive a first clock and a second clock and output a third clock and a fourth clock in accordance with a noise cancellation signal and a gain control signal, an analog phase detector configured to receive the third clock and the fourth clock and output an analog timing error signal, a filtering circuit configure to receive the analog timing error signal and output an oscillator control signal, a controllable oscillator configured to receive the oscillator control signal and output a fifth clock, a clock divider configured to receive the fifth clock and output the second clock in accordance with a division factor, a modulator configured to receive a clock multiplication factor and output the division factor and the noise cancellation signal, wherein a mean value of the division factor is equal to the clock multiplication factor, a digital phase detector configured to receive the third clock and the fourth clock and output a digital timing error signal, wherein the digital phase detector is self-calibrated so that a mean value of the digital timing error signal is zero, and a correlation circuit configured to receive the timing error signal and the noise cancellation signal and output the gain control signal.

A phase locked loop is disclosed comprising: a phase detector, a loop filter, a frequency controller oscillator and a lock detector. The phase detector is operable in a bang-bang mode to provide a binary phase error signal indicating whether there is a positive or negative phase difference between a reference signal and a feedback signal. The loop filter is configured to provide a control signal derived from the binary phase error signal. The frequency controlled oscillator is configured to receive the control signal and provide an output signal with a frequency that varies according to the control signal. The lock/unlock detector is configured to determine a lock/unlock state of the phase locked loop, the lock/unlock state derived from a duty cycle and/or spectral content of the binary phase error signal.

Processing a digital bit stream and systems for implementing the methods are provided. The method includes dividing the digital bit stream into a plurality of data packets. In a first processing block performing a carrier recovery error calculation on a first portion of the plurality of data packets, comprising preforming a first phase locked loop (PLL) function on decimated data of the data packets and performing a carrier recovery operation on the first portion of the plurality of data packets. In a second processing block, in parallel with the processing of the first portion of the plurality of packets, performing the carrier recovery error calculation on a second portion of the plurality of data packets, comprising preforming the first PLL function on decimated data of the data packets and performing the carrier recovery operation on second portion of the plurality of data packets.

An apparatus comprises a digitally controlled circuit having a variable capacitance and a controller configured to adjust a magnitude of the variable capacitance of the digitally controlled circuit. The digitally controlled circuit comprises a plurality of gain elements, the plurality of gain elements comprising one or more positive voltage-to-frequency gain elements and one or more negative voltage-to-frequency gain elements. The controller is configured to adjust the magnitude of the capacitance by adjusting the gain provided by respective ones of the gain elements in an alternating sequence of the positive voltage-to-frequency gain elements and the negative voltage-to-frequency gain elements.

A phase locked loop comprises: a controllable oscillator 102; a variable divider arrangement 108, 110 which takes a signal from the controllable oscillator 102 and divides it by a variable amount to provide a lower frequency signal; a sigma-delta modulator 112 arranged to provide a control input to said variable divider arrangement 108, 110; and a phase detector triggered 104 by said lower frequency signal and a reference clock;
wherein said phase locked loop is arranged to be operable in a normal mode in which the controllable oscillator 102 is controlled by a voltage from said phase detector 104 and a calibration mode in which the controllable oscillator 102 is controlled digitally by a signal from a calibration module 114 which receives an input from said variable divider arrangement 108, 110.

A phase-locked loop comprises a voltage controlled oscillator. The voltage controlled oscillator comprises an inductor and a capacitor, connected in parallel, and also connected in parallel therewith, a negative resistance structure. A first terminal of the negative resistance structure is connected to respective first terminals of the inductor and the capacitor. A second terminal of the negative resistance structure is connected to respective second terminals of the inductor and the capacitor. The negative resistance structure exhibits a tunable capacitance, such that a frequency of an output of the voltage controlled oscillator can be tuned by a control input signal, and the control input signal is generated in the phase-locked loop. The negative resistance structure comprises first and second transistors. There is a first conduction path between the first terminal of the first transistor and the control terminal of the second transistor, and a second conduction path between the control terminal of the first transistor and the first terminal of the second transistor. The control terminal of at least one of the first and second transistors is biased by the control input signal, such that a parasitic capacitance of said at least one of the first and second transistors can be tuned by the control input signal, in order to tune the frequency of the output of the voltage controlled oscillator, and hence the frequency of oscillation of the phase-locked loop.

One or more examples relate to an apparatus includes an error detector, an oscillator, an analog proportional path, and a digital integral path. The oscillator includes an analog proportional input, a digital integral input, and an analog integral input. The analog proportional path to provide a control signal for the analog proportional input of the oscillator. The digital integral path to provide a control for the digital integral input and the analog integral input of the oscillator. A first signal path of an interface includes a direct coupling between the digital phase detector and integrator and the digital integral input of the oscillator. A second signal path of the interface includes a digital-to-analog converter (DAC) with a filtered delta-sigma modulator (DSM) input between the digital phase detector and integrator and the analog integral input of the oscillator.

In a reference signal generator including a synchronization circuit configured to convert a digital signal into an analog signal, supply this signal to a voltage controlled oscillator, and control the voltage controlled oscillator to obtain a signal synchronized with the reference signal, without an accumulation of quantization error in a holdover control in which an acquisition of a reference signal is not available. The reference signal generator includes a phase synchronization circuit and a controller. The phase synchronization circuit controls the reference signal outputted from the oscillator, according to a control signal obtained based on the reference signal. The controller generates a free-running control signal and controls the oscillator when the reference signal becomes unavailable. The oscillator receives discrete values and oscillates accordingly. A digital delta-sigma modulator configured to modulate the free-running control signal of the controller disposed in a subsequent stage of the controller.