Methods and systems are described for receiving, at a data-driven phase comparator circuit, a plurality of data signals in parallel and one or more phases of a local oscillator signal, the data-driven phase comparator circuit comprising a plurality of partial phase comparators, generating a plurality of partial phase-error signals using the partial phase comparators, each partial phase-error signal generated by receiving (i) a corresponding phase of the local oscillator signal and (ii) a corresponding data signal of the plurality of data signals and responsive to a determination that a transition occurred in the corresponding data signal, generating the partial phase-error signal based on a comparison of the corresponding phase of the local oscillator signal and the corresponding data signal, and generating a composite phase-error signal by summing the plurality of partial phase error signals for setting a local oscillator in a lock condition.

A semiconductor device capable of communicating with a host apparatus includes a symbol generation unit, a coding unit, and a transmission unit. The symbol generation unit includes a random number generation circuit and generates a symbol according to a random number generated by the random number generation circuit. The coding unit performs 8b/10b coding for the symbol. The transmission unit transmits the symbol coded by the 8b/10b coding unit to the host apparatus.

A system and method which compensates for phase mixer circuit non-linearities within a clock and data recovery (CDR) system during active operation. The CDR system includes compensation circuitry and phase accumulation circuitry. The compensation circuitry generates a first compensation signal based on a first compensation value. The phase accumulation circuitry receives the first compensation signal and a phase accumulator input update signal. The phase accumulation circuitry combines the first compensation signal with the phase accumulator input update signal to compensate for a first non-linearity within phase mixer (PMI) circuitry.

A Serializer/Deserializer (SERDES) circuit is disclosed. The circuit includes an input/output (I/O) pad for coupling to a duplex SerDes link. An adjustable delay line provides a first component of a relative phase between a receive signal sampling point and a transmit echo signal. A second delay circuit generates a second component of the relative phase. A timing relationship between the receive signal sampling point and the transmit echo signal is based on the sum of the first and second components.

Various embodiments of the present invention relate to an apparatus and a method for transmitting data between internal modules in an electronic device. Here, a transmission apparatus of a digital interface may comprise: multiple transmission lines connected to a reception apparatus; and multiple transmission circuits connected in parallel to each other and provided for each of the transmission lines, wherein the transmission apparatus may be configured to transmit data having different voltages to the reception apparatus, using at least one transmission circuit among the multiple transmission circuits for each of the transmission lines on the basis of a variation of the voltage of data to be transmitted through each of the transmission lines. Other embodiments are also possible.

Apparatuses for receiving an input signal in a semiconductor device are described. An example apparatus includes a signal receiver that receives information signal; a control circuit that provides a plurality of control signals; and a signal receiver replica circuit that receives a first reference signal. The signal receiver replica circuit includes a plurality of receivers. Each receiver of the plurality of receivers receives the first reference signal and a corresponding control signal of the plurality of control signals, and further provides an output signal.

Methods and systems are described for receiving, at a data-driven phase comparator circuit, a plurality of data signals in parallel and one or more phases of a local oscillator signal, the data-driven phase comparator circuit comprising a plurality of partial phase comparators, generating a plurality of partial phase-error signals using the partial phase comparators, each partial phase-error signal generated by receiving (i) a corresponding phase of the local oscillator signal and (ii) a corresponding data signal of the plurality of data signals and responsive to a determination that a transition occurred in the corresponding data signal, generating the partial phase-error signal based on a comparison of the corresponding phase of the local oscillator signal and the corresponding data signal, and generating a composite phase-error signal by summing the plurality of partial phase error signals for setting a local oscillator in a lock condition.

Methods and systems are described for receiving, at a data-driven phase comparator circuit, a plurality of data signals in parallel and one or more phases of a local oscillator signal, the data-driven phase comparator circuit comprising a plurality of partial phase comparators, generating a plurality of partial phase-error signals using the partial phase comparators, each partial phase-error signal generated by receiving (i) a corresponding phase of the local oscillator signal and (ii) a corresponding data signal of the plurality of data signals and responsive to a determination that a transition occurred in the corresponding data signal, generating the partial phase-error signal based on a comparison of the corresponding phase of the local oscillator signal and the corresponding data signal, and generating a composite phase-error signal by summing the plurality of partial phase error signals for setting a local oscillator in a lock condition.

Methods and systems are described for generating, with a local oscillator and an adjustable phase interpolator, a data-sampling clock and a variable-phase-offset eye-measurement clock, forming a received data signal using a multi-input comparator, generating, using a data slicer and the data sampling clock, a receive sample of the received data signal, and generating, using at least one eye slicer and the variable-phase-offset eye-measurement clock, a plurality of eye characteristic measurements by adjusting a sampling threshold of the at least one eye slicer and a phase offset of the variable-phase-offset eye-measurement clock.

A semiconductor device includes a reception data input terminal configured such that reception data, which is serial data, is input; a transmission data output terminal configured such that transmission data, which is serial data, is output; and a communication part configured to receive the reception data and transmit the transmission data, wherein the communication part includes: a counter; and a synchronization part configured to monitor the transmission data if the semiconductor device is other than a target device set in the reception data, and reset a count by the counter upon detecting a stop bit and a start bit at frame switching in the transmission data.