Embodiments herein describe a reference-less CDR circuit that receives electrical signals that may have been transmitted along either an electrical or optical interconnect which are then processed to identify the original data. To do so, the CDR circuit includes a frequency locking loop (FLL) and a phase locking loop (PLL) which generate control signals for a voltage controlled oscillator (VCO). In one embodiment, the FLL generates a coarse adjustment signal which the VCO uses to output a recovered clock that substantially matches the frequency of the received electrical signal. The PLL, on the other hand, generates a fine adjustment signal which the VCO uses to make small adjustments (e.g., half cycle phase shifts) to the recovered clock. The recovered clock outputted by the VCO is then fed back and used as an input in both the FLL and the PLL.

A delay locked loop operates over a wide range of frequencies and has high accuracy, small silicon area usage, low power consumption and a short lock time. The DLL combines an analog domain and a digital domain. The digital domain is responsible for initial lock and operational point stability and is frozen after the lock is reached. The analog domain is responsible for normal operation after lock is reached and provides high accuracy using smaller silicon area and low power.

A receiving device includes a phase-locked loop (PLL) circuit having a current control oscillator, a phase detector, an integral path, and a proportional path. The current control oscillator can generate an oscillation clock based on a first and second current. The phase detector can acquire a phase detection result based on the oscillation clock and a received signal. The integral path can generate the first current based on an integrated value of the phase detection results and supply the first current to the current control oscillator. The proportional path includes a digital-to-current converter to generate the second current based on the phase detection result and supply the second current to the current control oscillator. The receiving device includes a controller configured to adjust the second current based on frequency-current characteristics of the current control oscillator.

A receiving device includes a phase-locked loop (PLL) circuit having a current control oscillator, a phase detector, an integral path, and a proportional path. The current control oscillator can generate an oscillation clock based on a first and second current. The phase detector can acquire a phase detection result based on the oscillation clock and a received signal. The integral path can generate the first current based on an integrated value of the phase detection results and supply the first current to the current control oscillator. The proportional path includes a digital-to-current converter to generate the second current based on the phase detection result and supply the second current to the current control oscillator. The receiving device includes a controller configured to adjust the second current based on frequency-current characteristics of the current control oscillator.

Disclosed is a phase-locked loop circuit, including: a phase-locked loop, a locking detection circuit, an input end for inputting a reference clock signal, a first output end for outputting an oscillator clock signal, and a second output end for outputting a locking signal, wherein the phase-locked loop is configured to output the oscillator clock signal according to the reference clock signal and control the reference clock signal and the oscillator clock signal to be synchronous; and the locking detection circuit is configured to output the locking signal to the second output end when the oscillator clock signal and the reference clock signal are synchronous.

Disclosed is a phase-locked loop circuit, including: a phase-locked loop, a locking detection circuit, an input end for inputting a reference clock signal, a first output end for outputting an oscillator clock signal, and a second output end for outputting a locking signal, wherein the phase-locked loop is configured to output the oscillator clock signal according to the reference clock signal and control the reference clock signal and the oscillator clock signal to be synchronous; and the locking detection circuit is configured to output the locking signal to the second output end when the oscillator clock signal and the reference clock signal are synchronous.

Some embodiments include apparatuses having a first path in a phase locked loop, the first path including a phase frequency detector to receive a first signal having a first frequency and a first node to provide a voltage; an oscillator coupled to a second node and the first node to provide a second signal having a second frequency at the second node; a second path including a frequency divider coupled to the second node and the phase frequency detector; and a circuit to generate digital information having a value based on a value of the voltage at the second node.

Digital delay lock circuits and methods for operating digital delay lock circuits are provided. A phase detector is configured to receive first and second clock signals and generate a digital signal indicating a relationship between a phase of the first clock signal and a phase of the second clock signal. A phase accumulator circuit is configured to receive the digital signal and generate a phase signal based on values of the digital signal over multiple clock cycles. A decoder is configured to receive the phase signal and generate a digital control word based on the phase signal. A delay element is configured to receive the digital control word. The delay element is further configured to change the relationship between the phase of the first clock signal and the phase of the second clock signal by modifying the phase of the second clock signal according to the digital control word.

Digital delay lock circuits and methods for operating digital delay lock circuits are provided. A phase detector is configured to receive first and second clock signals and generate a digital signal indicating a relationship between a phase of the first clock signal and a phase of the second clock signal. A phase accumulator circuit is configured to receive the digital signal and generate a phase signal based on values of the digital signal over multiple clock cycles. A decoder is configured to receive the phase signal and generate a digital control word based on the phase signal. A delay element is configured to receive the digital control word. The delay element is further configured to change the relationship between the phase of the first clock signal and the phase of the second clock signal by modifying the phase of the second clock signal according to the digital control word.

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.