The present disclosure relates to a method and apparatus for transmitting and receiving data in a wireless communication system. An operating method of a terminal that is able to communicate with a master node and a secondary node in a wireless communication system includes detecting a master cell group (MCG) failure related to the master node, in response to the detecting of the MCG failure, changing a primary path of a split signaling radio bearer 1 (SRB1) from a radio link control (RLC) bearer of an MCG related to the master node to one RLC bearer from among a plurality of RLC bearers of a secondary cell group (SCG) related to the secondary node, based on a pre-determined criterion, and transmitting a message related to the MCG failure to the master node, by using the RLC bearer of the SCG changed as the primary path.

In some implementations, a radio access provider (RAP), e.g., of a wireless telecommunications network, can identifying matching data in two data flows associated with respective, different terminals. The RAP can determine a common wireless-resource allocation for the matching data, and respective allocation messages for the terminals. Each allocation message can indicate the common resource allocation. The RAP can transmit the allocation messages to the terminals. In some implementations, a wireless communications device can receive two allocation messages, one for a common and one for a terminal-specific resource allocation. The device can receive the common-allocation data before the terminal-specific data, and assemble a packet with at least some of the terminal-specific data before some of the common-allocation data. The device can decrypt the common-allocation data using a key associated with the common allocation.

In some implementations, a radio access provider (RAP), e.g., of a wireless telecommunications network, can identifying matching data in two data flows associated with respective, different terminals. The RAP can determine a common wireless-resource allocation for the matching data, and respective allocation messages for the terminals. Each allocation message can indicate the common resource allocation. The RAP can transmit the allocation messages to the terminals. In some implementations, a wireless communications device can receive two allocation messages, one for a common and one for a terminal-specific resource allocation. The device can receive the common-allocation data before the terminal-specific data, and assemble a packet with at least some of the terminal-specific data before some of the common-allocation data. The device can decrypt the common-allocation data using a key associated with the common allocation.

A wireless quality degradation factor detection method according to an embodiment includes a spectrum generation step of generating a spectrum based on a received radio wave, a determination step of determining whether or not information based on the generated spectrum contains a factor that prevents maintenance of the quality of the received radio wave based on a determination criterion specified in advance, an identification step of identifying the factor that prevents maintenance of the quality of the received radio waves based on the result of the determination and the determination criterion, and an output step of outputting information representing the identified factor.

A wireless quality degradation factor detection method according to an embodiment includes a spectrum generation step of generating a spectrum based on a received radio wave, a determination step of determining whether or not information based on the generated spectrum contains a factor that prevents maintenance of the quality of the received radio wave based on a determination criterion specified in advance, an identification step of identifying the factor that prevents maintenance of the quality of the received radio waves based on the result of the determination and the determination criterion, and an output step of outputting information representing the identified factor.

To provide a communication terminal that ensures the coincidence of Paging timing between a UE and a control device when an eDRX parameter is updated in a control device, a communication terminal (10) according to the present disclosure includes a receiving unit (11) for receiving a Tracking Area Registration Accept message or a Location Registration Accept message sent from a control device (30), and a sending unit (12) for sending a Tracking Area Registration Complete message or a Location Registration Complete message to the control device (30) when a first eDRX (Extended Idle Mode DRX) parameter is contained in the Tracking Area Registration Accept message or the Location Registration Accept message.

To provide a communication terminal that ensures the coincidence of Paging timing between a UE and a control device when an eDRX parameter is updated in a control device, a communication terminal (10) according to the present disclosure includes a receiving unit (11) for receiving a Tracking Area Registration Accept message or a Location Registration Accept message sent from a control device (30), and a sending unit (12) for sending a Tracking Area Registration Complete message or a Location Registration Complete message to the control device (30) when a first eDRX (Extended Idle Mode DRX) parameter is contained in the Tracking Area Registration Accept message or the Location Registration Accept message.

Apparatus and methods of span level TDM PDCCH transmission are disclosed. The apparatus includes: a receiver that receives a capability report from a device, wherein the capability report comprises Physical Downlink Control Channel (PDCCH) monitoring capability and/or beam switching capability of the device; a processor that generates PDCCH transmission parameters, based on the capability report, for transmitting a Downlink Control Information (DCI) with a plurality of PDCCH transmissions with span level repetitions; wherein the processor further configures, based on the PDCCH transmission parameters, a plurality of resources for transmitting the DCI, and a search space set for DCI detection in a PDCCH monitoring occasion set; and a transmitter that transmits the DCI in a plurality of DCI versions with the plurality of PDCCH transmissions using the plurality of resources.

Apparatuses and methods for communication in non-terrestrial networks are provided. Downlink transmission from a satellite node is received (300). Pathloss of uplink transmission to the satellite node is estimated (302). Based on the path loss, it is determined (304) whether uplink transmission of the apparatus can reach the satellite node and uplink transmission suspended (306) if determination indicates that the transmission will not reach the node.

Apparatuses and methods for communication in non-terrestrial networks are provided. Downlink transmission from a satellite node is received (300). Pathloss of uplink transmission to the satellite node is estimated (302). Based on the path loss, it is determined (304) whether uplink transmission of the apparatus can reach the satellite node and uplink transmission suspended (306) if determination indicates that the transmission will not reach the node.