Quantum key distribution network security survivability can be provided by receiving, at a software defined networking controller operating in a control layer of a network, a recommendation from a global analytics service operating in an application layer of the network, the recommendation for replacing a failed communication link in a quantum key distribution layer of the network, the failed communication link being detected by a quantum edge computing device operating in the quantum key distribution layer. The software defined networking controller can generate a command to cause a quantum key distribution resource to perform an action to mitigate impact from the failed communication link. The command can be sent to the quantum key distribution resource and the quantum key distribution resource can perform the action to mitigate the impact from the failed communication link.

Quantum key distribution network security survivability can be provided by receiving, at a software defined networking controller operating in a control layer of a network, a recommendation from a global analytics service operating in an application layer of the network, the recommendation for replacing a failed communication link in a quantum key distribution layer of the network, the failed communication link being detected by a quantum edge computing device operating in the quantum key distribution layer. The software defined networking controller can generate a command to cause a quantum key distribution resource to perform an action to mitigate impact from the failed communication link. The command can be sent to the quantum key distribution resource and the quantum key distribution resource can perform the action to mitigate the impact from the failed communication link.

A system for distributing media includes a wide area network (WAN), a media player coupled to the WAN at a first home, and a media server coupled to the WAN at a second home for providing media. A service is coupled to the WAN for receiving a request for media from the media player and for establishing a connection between the first and second homes over the WAN. Media is streamed across the WAN from the second home to the first home. The system may include a storage device coupled to the media player where media is transferred across the WAN for storage at the storage device. A media device may be coupled to the media player for playing the streamed/transferred media where the media player and the media device may comprise a television, stereo, or computer and the media item may comprise video, photographs, or audio.

A system for distributing media includes a wide area network (WAN), a media player coupled to the WAN at a first home, and a media server coupled to the WAN at a second home for providing media. A service is coupled to the WAN for receiving a request for media from the media player and for establishing a connection between the first and second homes over the WAN. Media is streamed across the WAN from the second home to the first home. The system may include a storage device coupled to the media player where media is transferred across the WAN for storage at the storage device. A media device may be coupled to the media player for playing the streamed/transferred media where the media player and the media device may comprise a television, stereo, or computer and the media item may comprise video, photographs, or audio.

A method and apparatus provide for low latency transmissions. A higher layer configuration can be received at a device. The higher layer configuration can be higher than a physical layer configuration. The higher layer configuration can indicate configuring the device with a low latency configuration for a low latency transmission mode in addition to a regular latency configuration for a regular latency transmission mode. The low latency transmission mode can have a shorter latency than the regular latency transmission mode. A packet can be received based on one of the low latency configuration and the regular latency transmission mode in a subframe n. A feedback packet can be transmitted in a following subframe n+p, where p<4 when the received packet is based on the low latency configuration. The following subframe n+p can be the p.sup.th subframe from the subframe n. A feedback packet can be transmitted in a following subframe n+4 when the received packet is based on the regular latency configuration, where the following subframe n+4 is the fourth subframe from the subframe n.

A method and apparatus provide for low latency transmissions. A higher layer configuration can be received at a device. The higher layer configuration can be higher than a physical layer configuration. The higher layer configuration can indicate configuring the device with a low latency configuration for a low latency transmission mode in addition to a regular latency configuration for a regular latency transmission mode. The low latency transmission mode can have a shorter latency than the regular latency transmission mode. A packet can be received based on one of the low latency configuration and the regular latency transmission mode in a subframe n. A feedback packet can be transmitted in a following subframe n+p, where p<4 when the received packet is based on the low latency configuration. The following subframe n+p can be the p.sup.th subframe from the subframe n. A feedback packet can be transmitted in a following subframe n+4 when the received packet is based on the regular latency configuration, where the following subframe n+4 is the fourth subframe from the subframe n.

Systems and methods provide for managing faulting network devices. A first network device can receive an error. The first network device can generate one or more frames including data indicative of the error. The first network device can broadcast the one or more frames to one or more neighboring network devices. It may be determined that the first network device is inaccessible. The first data can be retrieved and presented from a second network device among the one or more neighboring network devices. In some embodiments, a network management system can utilize the first data to generate a machine learning model that classifies whether network devices are instances of network devices designated for a Return Merchandise Authorization (RMA) process. In some embodiments, the network management system can apply the first data to a machine learning classifier to determine whether to initiate the RMA process for the first network device.

Systems and methods provide for managing faulting network devices. A first network device can receive an error. The first network device can generate one or more frames including data indicative of the error. The first network device can broadcast the one or more frames to one or more neighboring network devices. It may be determined that the first network device is inaccessible. The first data can be retrieved and presented from a second network device among the one or more neighboring network devices. In some embodiments, a network management system can utilize the first data to generate a machine learning model that classifies whether network devices are instances of network devices designated for a Return Merchandise Authorization (RMA) process. In some embodiments, the network management system can apply the first data to a machine learning classifier to determine whether to initiate the RMA process for the first network device.

The present disclosure provides a method, system, and apparatus for processing parking and a vehicle controller, and relates to the field of intelligent transportation technology, specifically to the field of automated parking technology. The method is executed by a parking system deployed on a vehicle controller, the parking system including a perception module and other modules except the perception module; the perception module being deployed on a first operating system in the vehicle controller; and the other modules being deployed on a second operating system in the vehicle controller; the method includes: processing an image collected by an image collector through the perception module to obtain perception result data; and controlling a vehicle based on the perception result data obtained from the perception module by the other modules.

System and methods for automatically publishing Representational State Transfer (REST) Application Programming Interface (API) changes in a cloud environment are described. A publish/subscribe server (PSS) may receive from a subscriber a customized request for monitoring a registered REST API supported by a REST service provider (RSP) and registered with the PSS. The subscriber is configured to invoke the registered REST API at the RSP. The PSS may monitor the registered REST API for any changes at the RSP based on the customized request. In response to a determination that the registered REST API is changed at the RSP, the PSS may generate a REST API change report indicating a change event occurred to the registered REST API at the RSP after being registered with the PSS. The PSS may then transmit the REST API change report to the subscriber. The subscriber is configured to not invoke the registered REST API at the RSP based on the REST API change report.