Disclosed are systems and methods for seamlessly redirecting network data between a client and a remote server. In one exemplary aspect, the method comprises receiving, at a remote server, the network data via a first remote desktop protocol (RDP) channel, wherein the network data is encapsulated and transmitted by a client device configured to communicate with the remote server. The method further comprises replacing a MAC address listed in the network data with a MAC address of a logical network adapter on the remote server, and placing received network packets into a network driver of the logical network adapter, wherein the logical network adapter transfers received data in an operating system of the remote server such that a server-side application on the remote server receives network packets from the client device.

Disclosed are systems and methods for seamlessly redirecting network data between a client and a remote server. In one exemplary aspect, the method comprises receiving, at a remote server, the network data via a first remote desktop protocol (RDP) channel, wherein the network data is encapsulated and transmitted by a client device configured to communicate with the remote server. The method further comprises replacing a MAC address listed in the network data with a MAC address of a logical network adapter on the remote server, and placing received network packets into a network driver of the logical network adapter, wherein the logical network adapter transfers received data in an operating system of the remote server such that a server-side application on the remote server receives network packets from the client device.

Provisioning a set of tunnel endpoint aliases for a tunnel endpoint. A request is sent from the first tunnel endpoint to the second tunnel endpoint over a control plane of a network to provision the set of tunnel endpoint aliases. The second tunnel endpoint generates the set of tunnel endpoints and sends a response including the set of tunnel endpoint aliases to the first tunnel endpoint over the control plane. The first tunnel endpoint sends network traffic over the network tunnel that includes a tunnel endpoint alias of the set of tunnel endpoint aliases received.

Provisioning a set of tunnel endpoint aliases for a tunnel endpoint. A request is sent from the first tunnel endpoint to the second tunnel endpoint over a control plane of a network to provision the set of tunnel endpoint aliases. The second tunnel endpoint generates the set of tunnel endpoints and sends a response including the set of tunnel endpoint aliases to the first tunnel endpoint over the control plane. The first tunnel endpoint sends network traffic over the network tunnel that includes a tunnel endpoint alias of the set of tunnel endpoint aliases received.

Techniques described herein register an endpoint device, such as a utility meter, with multiple headend systems. A system described herein includes a utility meter, which measures consumption of a resource, and a Network Management System (NMS) headend system, which manages a network. The utility meter joins the network and obtains an Internet Protocol (IP) address of the NMS headend system. The utility meter transmits a network registration request to the NMS headend system using the IP address of the NMS headend system and receives, from the NMS headend system, network-related settings of the network. The utility meter obtains an IP address of a second headend system configured to provide a service over the network. Further, the utility meter receives, from the second headend system, configuration settings for using the service of the second headend system and, as such, configures the radio with the network-related settings and the configuration settings.

A wireless emergency stop system includes a machine safety device connected to a machine stop circuit for stopping operation of a machine when the machine stop circuit is activated. The machine safety device includes a wireless communication interface. The system also includes a mobile device controller configured to control operation of the machine, and a safety stop device. The safety stop device includes a wireless communication interface for wireless communication with the machine safety device, and an emergency stop switch configured to, when activated, transmit an emergency stop signal to the machine safety device to trigger an emergency stop of the machine. The mobile device controller is configured to link with the safety stop device via short-range wireless communication.

A wireless emergency stop system includes a machine safety device connected to a machine stop circuit for stopping operation of a machine when the machine stop circuit is activated. The machine safety device includes a wireless communication interface. The system also includes a mobile device controller configured to control operation of the machine, and a safety stop device. The safety stop device includes a wireless communication interface for wireless communication with the machine safety device, and an emergency stop switch configured to, when activated, transmit an emergency stop signal to the machine safety device to trigger an emergency stop of the machine. The mobile device controller is configured to link with the safety stop device via short-range wireless communication.

Examples include a computing system having a plurality of processing cores and a memory coupled to the plurality of processing cores. The memory has instructions stored thereon that, in response to execution by a selected one of the plurality of processing cores, cause the following actions. The selected processing core to receive a packet and get an original tuple from the packet. When no state information for a packet flow of the packet exists in a state table, select a new network address as a new source address for the packet, get a reverse tuple for a reverse direction, select a port for the packet from an entry in a mapping table based on a hash procedure using the reverse tuple, and save the new network address and selected port. Translate the packet's network address and port and transmit the packet.

Examples include a computing system having a plurality of processing cores and a memory coupled to the plurality of processing cores. The memory has instructions stored thereon that, in response to execution by a selected one of the plurality of processing cores, cause the following actions. The selected processing core to receive a packet and get an original tuple from the packet. When no state information for a packet flow of the packet exists in a state table, select a new network address as a new source address for the packet, get a reverse tuple for a reverse direction, select a port for the packet from an entry in a mapping table based on a hash procedure using the reverse tuple, and save the new network address and selected port. Translate the packet's network address and port and transmit the packet.

Embodiments of the present invention provide a method and apparatus for allocating a User Equipment (UE) identifier, and a computer readable storage medium. The method comprises: a preset functional entity or module allocates a UE identifier; the UE identifier is associated with an identifier of the UE in a wireless network system for information interaction between a network side device and the preset functional entity or module.