A system (100) for communicating data packets is provided. The system may include a first device (102) and a second device (104). The first device (102) may include a first processor (112) and a plurality of WWANs (118). The first processor (112) may execute a first MPTCP (204) and a plurality of first VPNs (206). The first device (204) may be configured to receive and segregate a stream of packets of data into a plurality of data blocks (Db). The first MPTCP (204) and the plurality of WWANs (118) may coordinate to provide multiple data paths based on the bandwidth of each of the plurality of WWANs (118) for transmitting the plurality of data block (Db). The plurality of data blocks may be received by the second device (104) to be further processed and sent to a desired destination.

In one form of the present disclosure, vehicle includes: a plurality of electronic devices; a first communication device configured to communicate with a terminal using a first communication method; a second communication device configured to communicate with the terminal using a second communication method; and a control device configured to wake up the plurality of electronic devices when the first communication device wakes up, switch the plurality of electronic devices to a sleep mode when the first communication device is switched to the sleep mode, and selectively control the wake up and the sleep modes of the second communication device based on a message received from the terminal.

In one form of the present disclosure, vehicle includes: a plurality of electronic devices; a first communication device configured to communicate with a terminal using a first communication method; a second communication device configured to communicate with the terminal using a second communication method; and a control device configured to wake up the plurality of electronic devices when the first communication device wakes up, switch the plurality of electronic devices to a sleep mode when the first communication device is switched to the sleep mode, and selectively control the wake up and the sleep modes of the second communication device based on a message received from the terminal.

Methods, systems, and devices for wireless communications are described. In some networks, a user equipment (UE) may perform radio link monitoring according to one or more radio link monitoring configurations. The UE may select a radio link monitoring configuration from a first radio link monitoring configuration associated with radio link monitoring over a duration that a hybrid automatic repeat request (HARQ) process is enabled and a second radio link monitoring configuration associated with radio link monitoring over a duration that the HARQ process is disabled. The UE may monitor reference signals using the selected radio link monitoring configuration, and may determine a radio link failure, a beam failure, or both has occurred based on monitoring the one or more reference signals using the selected radio link monitoring configuration. The UE may subsequently transmit a measurement report based on determining the radio link failure, the beam failure, or both.

Systems and methods for operating a customer premise equipment (CPE) device with agile software stack integrated with OpenSync™ layer for command, control, and telemetry via the operator's cloud network. It includes the configuration of the CPE device to receive traffic from an access network in a first system on chip (SoC) of the CPE device, and to provide 5G edge computing services to a 5G NR user equipment (UE) device via a second SoC of the CPE device. The CPE device may also be configured to receive 5G New Radio (NR) mobile traffic, receive in-home Wi-Fi traffic, and use at least one service flow (or only one service flow) to support both the 5G NR mobile traffic and the in-home Wi-Fi traffic.

Techniques for synthetic transaction for wireless handover are described. According to various embodiments, a synthetic transaction is utilized to determine a signal quality of a wireless network. Based on the signal quality, a decision is made whether to perform a handover of a communication session to a wireless network.

A user terminal according to an embodiment is a user terminal configured to exist in a first cell in a mobile communication system that supports a D2D proximity service between the user terminal configured to exist in the first cell and a user terminal configured to exist in a second cell. The user terminal comprises: a controller configured to measure a timing difference between a timing of a signal received from the first cell and a timing of a signal received from the second cell; and a transmitter configured to notify a base station configured to manage the first cell, of the timing difference.

A user terminal according to an embodiment is a user terminal configured to exist in a first cell in a mobile communication system that supports a D2D proximity service between the user terminal configured to exist in the first cell and a user terminal configured to exist in a second cell. The user terminal comprises: a controller configured to measure a timing difference between a timing of a signal received from the first cell and a timing of a signal received from the second cell; and a transmitter configured to notify a base station configured to manage the first cell, of the timing difference.

Provided are a D2D operation method performed by a terminal in a wireless communication system, and a terminal using said method. The method comprises the steps of: receiving a public land mobile network (PLMN) list and performing a D2D on the basis of the PLMN list, wherein the PLMN list comprises at least one PLMN.

Provided are a D2D operation method performed by a terminal in a wireless communication system, and a terminal using said method. The method comprises the steps of: receiving a public land mobile network (PLMN) list and performing a D2D on the basis of the PLMN list, wherein the PLMN list comprises at least one PLMN.