A semiconductor integrated circuit includes a converter converting an analog signal into a digital signal based on a clock signal; a comparator determining values of data based on the digital signal; a recovery circuit recovering the clock signal based on the digital signal and the data; and a control circuit. The recovery circuit includes a phase detector calculating a sum of a first value and offset, the first value being a value based on the digital signal and the data and relating to a phase of the clock signal; and a loop filter calculating a correction amount of the phase of the clock signal based on the sum. The control circuit is configured to gradually change the offset from a second value to zero after the second value is added as the offset.

A monitoring device includes: an acquisition unit for acquiring a clock signal output from a communication circuit that outputs the clock signal; and a monitoring unit for analyzing the waveform of the clock signal acquired by the acquisition unit, based on a predetermined reference clock signal having a period equal to or shorter than a period of the clock signal to thereby determine whether or not there is a sign of malfunction in the communication circuit.

A method for recovering the symbol time by a receiver to decode a sequence of symbols transmitted by a transmitter when the symbol time of the transmitter is biased with respect to the symbol time of the receiver. When a transition is detected between two consecutive symbols, an absolute error on the instant of the current symbol is measured and a statistical model of the bias is updated. A correction may then be applied to the instants of the subsequent symbols depending on the measured absolute error and/or a bias estimated from the statistical model. During periods in which there are no transitions between symbols, an absolute error cannot be measured, but it is still possible to apply a correction to the instants of the subsequent symbols depending on a relative error extrapolated from the statistical model.

Signal conditioning circuitry includes logic circuitry, a low-pass filter, and comparator circuitry. The logic circuitry is configured to compare a data unit with a preceding data unit, from a sequence of data units, and provide a logic output signal. The low-pass filter is coupled to the logic circuitry, and the low-pass filter is configured to provide a data transition density measurement for the sequence of data units based on the logic output signal. The comparator circuitry is coupled to the low-pass filter, and the comparator circuitry is configured to compare the data transition density measurement to a threshold and, based on the comparison to the threshold, indicate a disruptive pattern in the sequence of data units.

The invention relates to a method for providing a fault-tolerant global time and for the fault-tolerant transport of time-controlled messages in a distributed real-time computer system which comprises external computers and a fault-tolerant message distribution unit, FTMDU. The FTMDU comprises at least four components which supply the global time to the external computers by means of periodic external synchronization messages, wherein the external computers each set their local clock to the received global time, wherein each external sender of a time-controlled message transmits two message copies of the message to be sent via two different communication channels to two different components of the FTMDU at periodic sending times defined a priori in timetables, wherein these two message copies are delivered within the FTMDU via two independent communication paths to those two components of the FTMDU which are connected to an external receiver of the message via communication channels.

Signal conditioning circuitry includes logic circuitry, a low-pass filter, and comparator circuitry. The logic circuitry is configured to compare a data unit with a preceding data unit, from a sequence of data units, and provide a logic output signal. The low-pass filter is coupled to the logic circuitry, and the low-pass filter is configured to provide a data transition density measurement for the sequence of data units based on the logic output signal. The comparator circuitry is coupled to the low-pass filter, and the comparator circuitry is configured to compare the data transition density measurement to a threshold and, based on the comparison to the threshold, indicate a disruptive pattern in the sequence of data units.

A system includes a link having one or more lanes associated with transmitting data and one or more lanes associated with transmitting a clock signal. The system includes a device coupled with the link, the device to receive a signal via the one or more lanes associated with transmitting the clock signal and determine a number of pulses associated with the signal over a period. The device is further to determine the number of pulses associated with the signal fail to satisfy a predetermined condition relating to a specified number of pulses for the period and initiate a power-down sequence in response to determining the number of pulses that fail to satisfy the predetermined condition relating to the specified number of pulses for the period.

Apparatuses and methods of widespread equispatiated phase generation of a clock divided by a non-integer factor are described. One integrated circuit includes a clock divider and a phase generator. The clock divider receives a single-phase clock signal from a clock source and generates a divided clock signal. The phase generator receives the divided clock signal and the single-phase clock signal and generates multiple phase signals using the divided clock signal and the single-phase clock signal. The phase signals are equispatiated.

A system on a chip (SOC) is configured to support multiple time domains within a time-sensitive networking (TSN) environment. TSN extends Ethernet networks to support a deterministic and high-availability communication on Layer 2 (data link layer of open system interconnect “OSI” model) for time coordinated capabilities such as industrial automation and control applications. Processors in a system may have an application time domain separate from the communication time domain. In addition, each type time domain may also have multiple potential time masters to drive synchronization for fault tolerance. The SoC supports multiple time domains driven by different time masters and graceful time master switching. Timing masters may be switched at run-time in case of a failure in the system. Software drives the SoC to establish communication paths through a sync router to facilitate communication between time providers and time consumers. Multiple time sources are supported.

According to one embodiment, a base station apparatus includes: a radio equipment control that generates a baseband signal including data; a microwave apparatus that modulates the baseband signal to a microwave to transmit by radio; a microwave apparatus that demodulates the received first microwave to the baseband signal, then extracts a clock from a cycle of the data included in the baseband signal, imports the baseband signal in synchronization with the clock, and plays back the data; and a radio equipment that modulates the data played back by the microwave apparatus to a high-frequency signal, and the microwave apparatus outputs dummy data instead of the played back data when a frequency fluctuation amount of the clock exceeds a predetermined range.