A receiver with clock phase calibration is disclosed. A first sampling circuit generates first digital data based on an input signal, a sampling phase of the first sampling circuit controlled by a first clock signal. A second sampling circuit generates second digital data based on the input signal, a sampling phase of the second sampling circuit controlled by a second clock signal. Circuitry within the receiver calibrates the clocks in different stages. During a first calibration stage, a phase of the second clock signal is adjusted while the first digital data is selected for generating the output data. During a second calibration stage, a phase of the first clock signal is adjusted while the first digital data is selected for the output data path.

One example includes a master microcontroller in a communication interface system. The microcontroller includes a transmitter configured to generate a clock signal at a selected frequency and to provide the clock signal to a slave microcontroller on a two-wire communication cable during a clock learning mode. The transmitter can be further configured to provide master data signal requests at the selected frequency on the two-wire communication cable during a data transfer mode. The microcontroller also includes a receiver configured to receive slave data signals at the variable frequency via the two-wire communication cable in response to the master data signal requests during the data transfer mode.

This application discloses a decoding method for an OvXDM system, including: generating an augmented matrix B related to a received symbol information sequence; performing singular decomposition on the augmented matrix B; and performing decoding by using a total least square method, to obtain a decoded output information sequence. This application further discloses an OvXDM system. In a specific implementation of this application, decoding is performed by using the total least square method.

Methods and systems are described for generating, using a voltage-controlled oscillator (VCO), a plurality of phases of a local clock signal, generating a phase-error signal using a phase comparator receive a phase of the local clock signal and a reference clock signal, and configured to output the phase-error signal, generating a frequency-lock assist (FLA) signal using a FLA circuit receiving one or more phases of the local clock signal and the reference clock signal, the FLA signal indicative of a magnitude of a frequency error between the reference clock signal and the local clock signal, and generating a VCO control signal using an error accumulator circuit receiving the phase-error signal and the FLA signal, and responsively providing the VCO control signal to the VCO to lock the local clock signal to the reference clock signal.

A memory component includes a memory core comprising dynamic random access memory (DRAM) storage cells and a first circuit to receive external commands. The external commands include a read command that specifies transmitting data accessed from the memory core. The memory component also includes a second circuit to transmit data onto an external bus in response to a read command and pattern register circuitry operable during calibration to provide at least a first data pattern and a second data pattern. During the calibration, a selected one of the first data pattern and the second data pattern is transmitted by the second circuit onto the external bus in response to a read command received during the calibration. Further, at least one of the first and second data patterns is written to the pattern register circuitry in response to a write command received during the calibration.

Various embodiments include apparatus and methods having a data receiver with a real time clock decoding decision feedback equalizer. In various embodiments, a digital decision feedback loop can be implemented in a data receiver circuit, while all analog signals involved are static relative to the input signal data rate. The implemented data receiver circuit can include a number of data latches with different, but static, analog unbalances and a decision-based clock decoder. In an example, the analog unbalances may be different reference voltages. The decision-based clock decoder can be structured to activate only one data latch, the one with the desired analog unbalance. The outputs of the latches attached to the same clock decoder can be combined such that only the active latch drives the final output. Additional apparatus, systems, and methods are disclosed.

A method and system are provided for drift compensation, providing a live data approach to sampler offset calibration, such as for voltage and/or temperature (VT) drift. A serializer/deserializer (SerDes) system includes a SerDes receiver and receiver logic, the receiver logic including a forward error correction (FEC) module. A drift compensation device, or drift compensation engine, receives live error corrections from the FEC module based on FEC operations performed on live traffic passing through the SerDes receiver. A drift compensation command is provided to a data sampler in the SerDes receiver, to adjust a sampling voltage of the data sampler. When the system includes a plurality of data samplers, the drift compensation device determines the data sampler with which an error correction is associated. The drift compensation command can be sent after a threshold criterion is satisfied, such as completion of a statistics collection period, or a threshold number of corrections.

A receiver performs independent packet detection using synchronization words with orthogonality when multiple signals on which frequency-shift keying is performed coexist. The receiver includes a frequency demodulator generating a quasi-amplitude modulation signal that has a value proportional to frequency shift from the first signal or second signal being received, a sign discriminator discriminating a sign of the generated quasi-amplitude modulation signal, and a multi-binary correlator calculating a first correlation value which is a binary correlation value between the discriminated sign and a first synchronization word and calculating a second correlation value which is a binary correlation value between the discriminated sign and a second synchronization word.

A system may include a clock and data recovery circuit that includes one or more analog components. The system may also include processing circuitry configured to control the clock and data recovery circuit. The processing circuitry and the clock and data recovery circuit may be formed on a single substrate.

A Wireless Subterranean Soil Monitoring System. The system measures the complex permittivity around a subterranean antenna, and then responsively adjusts the antenna's tuning circuit according to the measured permittivity. Once tuned, the system will then execute the transmission of the probe data. Furthermore, the antenna design is adapted for subterranean use to further reduce the de-tuning effect of the adjacent soil.