A circuit and method are provided for setting a phase relationship between a first signal and a second signal having a known frequency relationship to a master signal but having an unknown phase relationship to each other. One or more phase signals is generated based on the master signal, the phase signals having different phases from each other. One of these phase signals is selected based on the phase of the first signal and a target phase delay between the first signal and second signal. The second signal is generated based on the phase and frequency of the selected phase signal.

Examples described herein relate to multiple processor nodes which are physically separate with interfaces to a common network interface. A local processor can run a timing recovery algorithm, and tune the master timer to align with the network domain to cause the master timer and network timing domains to be in the same domain. A common master timer can be used to align time stamps of independent processor nodes. A processor node can use the common master timer as a reference and the processor does not need to communicate with another processor to synchronize its timer.

Examples described herein relate to multiple processor nodes which are physically separate with interfaces to a common network interface. A local processor can run a timing recovery algorithm, and tune the master timer to align with the network domain to cause the master timer and network timing domains to be in the same domain. A common master timer can be used to align time stamps of independent processor nodes. A processor node can use the common master timer as a reference and the processor does not need to communicate with another processor to synchronize its timer.

A signal receiving circuit receives a reset configuration signal from an exceptional timing sequence device in a functional module and outputs a trigger signal. A first signal generation circuit generates an idle signal based at least in part on the trigger signal. The idle signal is used to configure a shutdown signal which in turn is used to shut down a first clock signal of the exceptional timing sequence device and a second clock signal in a same clock domain as the first clock signal. A second signal generation circuit generates a reset enable signal based at least in part on the trigger signal. An operational circuit performs an operation based at least in part on the reset enable signal and generates a module-based reset signal based at least in part on an operation result. The module-based reset signal is used to reset the exceptional timing sequence device in the functional module.

A signal receiving circuit receives a reset configuration signal from an exceptional timing sequence device in a functional module and outputs a trigger signal. A first signal generation circuit generates an idle signal based at least in part on the trigger signal. The idle signal is used to configure a shutdown signal which in turn is used to shut down a first clock signal of the exceptional timing sequence device and a second clock signal in a same clock domain as the first clock signal. A second signal generation circuit generates a reset enable signal based at least in part on the trigger signal. An operational circuit performs an operation based at least in part on the reset enable signal and generates a module-based reset signal based at least in part on an operation result. The module-based reset signal is used to reset the exceptional timing sequence device in the functional module.

On-chip spread spectrum synchronization between spread spectrum sources is provided. A spread spectrum amplitude of a signal of a spread spectrum reference clock is obtained using one or more delay lines of one or more delay elements in a skitter circuit. A spread width of the spread spectrum amplitude of the signal is determined, using one or more sticky latches in the skitter circuit, based on one or more edges of the signal. A delay line of the one or more delay elements corresponding to a falling edge of the spread width of the signal is identified using combinational circuitry of the skitter circuit. A spread spectrum signal of a spread spectrum slave clock is synchronized with the signal of the spread spectrum reference clock based on the delay line.

On-chip spread spectrum synchronization between spread spectrum sources is provided. A spread spectrum amplitude of a signal of a spread spectrum reference clock is obtained using one or more delay lines of one or more delay elements in a skitter circuit. A spread width of the spread spectrum amplitude of the signal is determined, using one or more sticky latches in the skitter circuit, based on one or more edges of the signal. A delay line of the one or more delay elements corresponding to a falling edge of the spread width of the signal is identified using combinational circuitry of the skitter circuit. A spread spectrum signal of a spread spectrum slave clock is synchronized with the signal of the spread spectrum reference clock based on the delay line.

A hub may receive event data captured by a body-worn device and store the event data in a memory of the hub. The event data is then backed up from the hub to a memory of an additional hub communicatively connected to the hub. A copy of event data for a predetermined period of time as included in the event data is then transferred from the memory of the hub to a data store of a network operations center (NOC). In response to the transfer being complete, the hub may delete the event data for the predetermined period of time, send a first command to the additional hub directing the additional hub to delete a backup of the event data for the predetermined period of time, or send a second command to the body-worn device directing the body-worn device to delete the event data for the predetermined period of time.

In one embodiment, a network interface card device includes communication interfaces to provide data connection with respective local devices configured to run respective clock synchronization clients, at least one network interface to provide data connection between a packet data network and ones of the local devices, and a hardware clock to maintain a time value, and serve the clock synchronization clients.

In one embodiment, a network interface card device includes communication interfaces to provide data connection with respective local devices configured to run respective clock synchronization clients, at least one network interface to provide data connection between a packet data network and ones of the local devices, and a hardware clock to maintain a time value, and serve the clock synchronization clients.