Systems and methods for clock recovery are disclosed. The method comprises generating, by a first dynamic phase interpolator, a first center clock signal, and generating, by a second dynamic phase interpolator, a second center clock signal. The method further comprises outputting, by a static phase interpolator, an edge clock signal based on the first and second center clock signals.

Described is an apparatus which comprises: a first die including: a processing core; a crossbar switch coupled to the processing core; and a first edge interface coupled to the crossbar switch; and a second die including: a first edge interface positioned at a periphery of the second die and coupled to the first edge interface of the first die, wherein the first edge interface of the first die and the first edge interface of the second die are positioned across each other; a clock synchronization circuit coupled to the second edge interface; and a memory interface coupled to the clock synchronization circuit.

An approach to obtain low latency association of the audio clock in a smartphone with an incoming RF message is to use an interrupt driven routine, where the receipt of the RF message preamble generates an interrupt that reads the audio clock counter since the start of the audio session. In some embodiments such an approach may be implemented on the specialized processing cores found in smartphones that control RF communication, sensor or audio processing.

An approach to obtain low latency association of the audio clock in a smartphone with an incoming RF message is to use an interrupt driven routine, where the receipt of the RF message preamble generates an interrupt that reads the audio clock counter since the start of the audio session. In some embodiments such an approach may be implemented on the specialized processing cores found in smartphones that control RF communication, sensor or audio processing.

Disclosed herein is a method, a computer program product, and a carrier for indicating one-way latency in a data network (N) between a first node (A) and a second node (B), wherein the data network (N) lacks continuous clock synchronization, comprising: a pre-synchronisation step, a measuring step, a post-synchronisation step, an interpolation step, and generating a latency profile. The present invention also relates to a computer program product incorporating the method, a carrier comprising the computer program product, and a method for indicating server functionality based on the first aspect.

A memory controller component includes transmit circuitry and adjusting circuitry. The transmit circuitry transmits a clock signal and write data to a DRAM, the write data to be sampled by the DRAM using a timing signal. The adjusting circuitry adjusts transmit timing of the write data and of the timing signal such that an edge transition of the timing signal is aligned with an edge transition of the clock signal at the DRAM.

A memory controller component includes transmit circuitry and adjusting circuitry. The transmit circuitry transmits a clock signal and write data to a DRAM, the write data to be sampled by the DRAM using a timing signal. The adjusting circuitry adjusts transmit timing of the write data and of the timing signal such that an edge transition of the timing signal is aligned with an edge transition of the clock signal at the DRAM.

An electronic device includes a substrate including an upper surface, a clock output pad formed in a control device mounting area of the upper surface, a command/address output pad formed in the control device mounting area, a clock signal main wiring connected to the clock output pad, a command/address signal main wiring connected to the command/address output pad, a first clock signal branch wiring branched from the clock signal main wiring at a first branch point of the clock signal main wiring, and a second clock signal branch wiring branched from the clock signal main wiring at a second branch point of the clock signal main wiring, which is located at a downstream side of the clock signal main wiring than the first branch point of the clock signal main wiring.

An electronic device includes a substrate including an upper surface, a clock output pad formed in a control device mounting area of the upper surface, a command/address output pad formed in the control device mounting area, a clock signal main wiring connected to the clock output pad, a command/address signal main wiring connected to the command/address output pad, a first clock signal branch wiring branched from the clock signal main wiring at a first branch point of the clock signal main wiring, and a second clock signal branch wiring branched from the clock signal main wiring at a second branch point of the clock signal main wiring, which is located at a downstream side of the clock signal main wiring than the first branch point of the clock signal main wiring.

A computer-implemented method includes an act of configuring hardware to cause at least a part of the hardware to operate as a double data rate (DDR) memory controller, and to produce a capture clock to time a read data path, where a timing of the capture clock is based on a first clock signal of a first clock, delay the first clock signal to produce a delayed first clock signal, adjust the delay such that at least one clock edge of the delayed first clock signal is placed nearer to at least one clock edge of at least one data strobe (DQS), or at least one signal dependent on a DQS timing, and produce a modified timing of the capture clock based on the delay of the first clock signal.