Various systems and methods for network optimization or bandwidth conservation may use plugin migration or mirroring to access a plugin utilizing a first network protocol in the cloud. A cloud-based plugin allows for routing optimization to leverage resource directory from the first network protocol to provide discovery or access to the plugin. The plugin may be used when a device operating the first network protocol communicates with a device operating a second, different, network protocol.

Various systems and methods for network optimization or bandwidth conservation may use plugin migration or mirroring to access a plugin utilizing a first network protocol in the cloud. A cloud-based plugin allows for routing optimization to leverage resource directory from the first network protocol to provide discovery or access to the plugin. The plugin may be used when a device operating the first network protocol communicates with a device operating a second, different, network protocol.

An embodiment is directed to switchover operations with a mobile virtualized network device in a mobile device. The mobile virtualized hardware switchover operations may be used to selectively and temporarily provide virtualized control-plane operations to the data-plane of a non-redundant network device undergoing an upgrade or a reboot of its control plane. A non-redundant network device may operate hitless, or near hitless, operation even when its control plane is unavailable.

An embodiment is directed to switchover operations with a mobile virtualized network device in a mobile device. The mobile virtualized hardware switchover operations may be used to selectively and temporarily provide virtualized control-plane operations to the data-plane of a non-redundant network device undergoing an upgrade or a reboot of its control plane. A non-redundant network device may operate hitless, or near hitless, operation even when its control plane is unavailable.

A protocol converter is configured to be connectable between a field device and a device control apparatus and includes a converter controller and a converter storage. The converter controller acquires field data from the field device, writes the field data to the converter storage as a data set formed by a plurality of pieces of data and changes the value of a first counter controlled by the converter controller when the value of the first counter and the value of a second counter controlled by the device control apparatus are equal, and stops an operation to write the field data to the converter storage when the value of the first counter and the value of the second counter are different.

A protocol converter is configured to be connectable between a field device and a device control apparatus and includes a converter controller and a converter storage. The converter controller acquires field data from the field device, writes the field data to the converter storage as a data set formed by a plurality of pieces of data and changes the value of a first counter controlled by the converter controller when the value of the first counter and the value of a second counter controlled by the device control apparatus are equal, and stops an operation to write the field data to the converter storage when the value of the first counter and the value of the second counter are different.

Described are techniques for data ingestion including determining a respective moving average streaming rate for each of a plurality of incoming data streams to a cluster-computing framework. The techniques further include determining a respective ingestion frequency for each of the plurality of incoming data streams by dividing a platform-preferred ingestion rate of the cluster-computing framework by a respective moving average streaming rate of each of the plurality of incoming data streams. The techniques further include ingesting each of the plurality of incoming data streams to the cluster-computing framework at the respective ingestion frequency.

Described are techniques for data ingestion including determining a respective moving average streaming rate for each of a plurality of incoming data streams to a cluster-computing framework. The techniques further include determining a respective ingestion frequency for each of the plurality of incoming data streams by dividing a platform-preferred ingestion rate of the cluster-computing framework by a respective moving average streaming rate of each of the plurality of incoming data streams. The techniques further include ingesting each of the plurality of incoming data streams to the cluster-computing framework at the respective ingestion frequency.

A system for determining the servicing needs of a vehicle. In various embodiments, the system includes a remote server and a vehicle control module of the vehicle. The vehicle control module includes a first communication interface to enable communications with at least one vehicle device via a network fabric of the vehicle. The vehicle control module is configured to receive status data, from the vehicle device, relating to a performance status or operational status of the vehicle. The vehicle control module further includes a second communication interface that enables wireless communications with the remote server. The wireless communications include sending status data to the remote server. The remote server is configured to receive and interpret the status data to determine if the vehicle requires service, and send a response to the vehicle. When service is required, the response may cause the vehicle to provide a service indication.

A system for determining the servicing needs of a vehicle. In various embodiments, the system includes a remote server and a vehicle control module of the vehicle. The vehicle control module includes a first communication interface to enable communications with at least one vehicle device via a network fabric of the vehicle. The vehicle control module is configured to receive status data, from the vehicle device, relating to a performance status or operational status of the vehicle. The vehicle control module further includes a second communication interface that enables wireless communications with the remote server. The wireless communications include sending status data to the remote server. The remote server is configured to receive and interpret the status data to determine if the vehicle requires service, and send a response to the vehicle. When service is required, the response may cause the vehicle to provide a service indication.