A receiver is configured to receive a series of command signals and a series of data signals. The receiver includes a first clock and data recovery (CDR) circuit, a control circuit and a second CDR circuit. The first CDR circuit is configured to process the series of command signal to generate a clock signal. The control circuit, coupled to the first CDR circuit, is configured to generate a control signal according to the series of command signals and the clock signal received from the first CDR circuit. The second CDR circuit, coupled to the control circuit, is configured to process the series of data signals according to the control signal received from the control circuit.

A receiver is configured to receive a series of command signals and a series of data signals. The receiver includes a first clock and data recovery (CDR) circuit, a control circuit and a second CDR circuit. The first CDR circuit is configured to process the series of command signal to generate a clock signal. The control circuit, coupled to the first CDR circuit, is configured to generate a control signal according to the series of command signals and the clock signal received from the first CDR circuit. The second CDR circuit, coupled to the control circuit, is configured to process the series of data signals according to the control signal received from the control circuit.

Provided is a transmission device including: a transmission circuit that operates, on the basis of a mode signal indicating a first operation mode corresponding to a data transmission period or a second operation mode corresponding to a data transmission pause period, in the first operation mode or the second operation mode, and transmits data in which a clock signal is embedded; and a power supply noise reduction circuit that reduces noise of a power supply that supplies power to the transmission circuit when switching is performed between the first operation mode and the second operation mode.

Provided is a transmission device including: a transmission circuit that operates, on the basis of a mode signal indicating a first operation mode corresponding to a data transmission period or a second operation mode corresponding to a data transmission pause period, in the first operation mode or the second operation mode, and transmits data in which a clock signal is embedded; and a power supply noise reduction circuit that reduces noise of a power supply that supplies power to the transmission circuit when switching is performed between the first operation mode and the second operation mode.

A storage device and a storage system including the same are provided. The storage device includes a reference clock pin configured to receive a reference clock signal from a host, a reference clock frequency determination circuitry configured to determine a reference clock frequency from the reference clock signal received through the reference clock pin, and a device controller circuitry configured to perform a high speed mode link startup between the host and the storage device according to the reference clock frequency.

In some embodiments, a digital clock management system includes input signal conversion circuitry, logic circuitry and output signal conversion circuitry. The input signal conversion circuitry converts input signals to corresponding first digital data streams, each of which contains digital data synchronized to a first data clock. First digital logic circuitry converts the first digital data streams to second digital data streams, each of which contains digital data synchronized to the first data clock, and converts the second digital data streams to third digital data streams, each of which contains digital data synchronized to a common clock. Second digital logic circuitry converts the third digital data streams to a single digital data stream. The output signal conversion circuitry converts the single digital data stream to a modulated output signal.

In some embodiments, a digital clock management system includes input signal conversion circuitry, logic circuitry and output signal conversion circuitry. The input signal conversion circuitry converts input signals to corresponding first digital data streams, each of which contains digital data synchronized to a first data clock. First digital logic circuitry converts the first digital data streams to second digital data streams, each of which contains digital data synchronized to the first data clock, and converts the second digital data streams to third digital data streams, each of which contains digital data synchronized to a common clock. Second digital logic circuitry converts the third digital data streams to a single digital data stream. The output signal conversion circuitry converts the single digital data stream to a modulated output signal.

A receiver device comprises one or more differential receivers configured to respectively output single ended signals, one or more delay compensation circuitries configured to delay the single ended signals, clock recovery circuitry configured to generate a recovered clock signal based on a compensated single ended signals respectively outputted from the delay compensation circuitries, and one or more latch circuitries configured to respectively latch the compensated single ended signals in synchronization with the recovered clock signal.

A receiver system that includes a clock and data recovery (CDR) system for aligning a local clock signal to an incoming data signal to extract correct timing information from the incoming data signal is provided. A timing error detector generates an output phase error signal representing the phase difference between the incoming data signal and the local clock signal. The timing error detector determines the phase difference according to recovered symbols and the difference between the recovered symbols and digital samples of the incoming data signal. The digital samples of the incoming data signal include intersymbol interference. The output timing information is suitable for aligning the local clock signal to the incoming data signal.

A receiver system that includes a clock and data recovery (CDR) system for aligning a local clock signal to an incoming data signal to extract correct timing information from the incoming data signal is provided. A timing error detector generates an output phase error signal representing the phase difference between the incoming data signal and the local clock signal. The timing error detector determines the phase difference according to recovered symbols and the difference between the recovered symbols and digital samples of the incoming data signal. The digital samples of the incoming data signal include intersymbol interference. The output timing information is suitable for aligning the local clock signal to the incoming data signal.