Abstract: Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a user equipment (UE) may receive, from a base station, a request message indicating that the UE is to set particular content for UE capability information. The UE may receive, from the base station, a UE capability enquiry message. The UE may transmit, to the base station, one or more segments of a UE capability information message having the particular content. Numerous other aspects are described.

Abstract: Various aspects of the present disclosure generally relate to wireless communication. In some aspects, a user equipment (UE) may receive, from a base station, a request message indicating that the UE is to set a parameter of a UE assistance information message to a particular value, wherein the particular value indicates a preference for the parameter that is unrelated to an actual preference of the UE. The UE may transmit, to the base station and based at least in part on the request message, the UE assistance information message having the parameter set to the particular value. Numerous other aspects are described.

Abstract: Test entity for verifying user equipment (UE) device layer 2 sustained downlink maximum data rate decoding performance may send a non-access stratum message to the UE device that requests activation of a downlink-only test mode, sending a first Packet Data Convergence Protocol (PDCP) status request to the UE device, send downlink PDCP packets to the UE device during a measurement interval, receive a physical layer (PHY) hybrid acknowledge request (HARQ) acknowledgement (ACK) or non-acknowledgement (NACK) from the UE device and determine expected missed layer 1 packets based on the received PHY HARQ ACK/NACK, send a second PDCP status request to the UE device after the measurement interval, receive a PDCP status report from the UE device, and determine missed layer 2 packets from a First Missing Count (FMC) value or bitmap included in the received PDCP status report.

Abstract: Test entity for verifying user equipment (UE) device layer 2 sustained downlink maximum data rate decoding performance may send a non-access stratum message to the UE device that requests activation of a downlink-only test mode, sending a first Packet Data Convergence Protocol (PDCP) status request to the UE device, send downlink PDCP packets to the UE device during a measurement interval, receive a physical layer (PHY) hybrid acknowledge request (HARQ) acknowledgement (ACK) or non-acknowledgement (NACK) from the UE device and determine expected missed layer 1 packets based on the received PHY HARQ ACK/NACK, send a second PDCP status request to the UE device after the measurement interval, receive a PDCP status report from the UE device, and determine missed layer 2 packets from a First Missing Count (FMC) value or bitmap included in the received PDCP status report.

Abstract: A method for forwarding an alert includes receiving an alert in a first communication device over a first communication network, and forwarding the alert to a second communication device in a second communication network, the second communication network comprising a vehicle-to-vehicle communication network, the second communication device incapable of receiving the alert over the first communication network.

Abstract: Test entity for verifying user equipment (UE) device layer 2 sustained downlink maximum data rate decoding performance may send a non-access stratum message to the UE device that requests activation of a downlink-only test mode, sending a first Packet Data Convergence Protocol (PDCP) status request to the UE device, send downlink PDCP packets to the UE device during a measurement interval, receive a physical layer (PHY) hybrid acknowledge request (HARQ) acknowledgement (ACK) or non-acknowledgement (NACK) from the UE device and determine expected missed layer 1 packets based on the received PHY HARQ ACK/NACK, send a second PDCP status request to the UE device after the measurement interval, receive a PDCP status report from the UE device, and determine missed layer 2 packets from a First Missing Count (FMC) value or bitmap included in the received PDCP status report.

Abstract: Test entity for verifying user equipment (UE) device layer 2 sustained downlink maximum data rate decoding performance may send a non-access stratum message to the UE device that requests activation of a downlink-only test mode, sending a first Packet Data Convergence Protocol (PDCP) status request to the UE device, send downlink PDCP packets to the UE device during a measurement interval, receive a physical layer (PHY) hybrid acknowledge request (HARQ) acknowledgement (ACK) or non-acknowledgement (NACK) from the UE device and determine expected missed layer 1 packets based on the received PHY HARQ ACK/NACK, send a second PDCP status request to the UE device after the measurement interval, receive a PDCP status report from the UE device, and determine missed layer 2 packets from a First Missing Count (FMC) value or bitmap included in the received PDCP status report.

Abstract: A method for forwarding an alert includes receiving an alert in a first communication device over a first communication network, and forwarding the alert to a second communication device in a second communication network, the second communication network comprising a vehicle-to-vehicle communication network, the second communication device incapable of receiving the alert over the first communication network.

Abstract: Methods and systems enable communication devices equipped with software defined radio based chipset modules to seamlessly re-program the communication device to operate on any of a variety of service provider networks. By re-programming a communication device equipped with software defined radio based chipset module, the communication device can support communications over both UMTS and CDMA communication networks. An environment is provided which allows a user to quickly and efficiently switch between service provider accounts supporting communications.

Abstract: Methods and systems enable mobile devices equipped with software defined radio based chipset modules to seamlessly re-program the mobile device to operate on any of a variety of service provider networks. By re-programming a mobile device equipped with software defined radio based chipset module, the mobile device can support communications over both GSM and CDMA communication networks. An environment is provided which allows a user to quickly and efficiently switch between service provider accounts supporting communications.

Abstract: Methods and systems enable mobile devices equipped with software defined radio based chipset modules to seamlessly re-program the mobile device to operate on any of a variety of service provider networks. By re-programming a mobile device equipped with software defined radio based chipset module, the mobile device can support communications over both GSM and CDMA communication networks. The re-programming of the mobile device may commence with the launching of a connection manager supporting a selected service provider. Various embodiment methods and systems are provided to track and monitor a currently activated first connection manager and prevent the launching of a second connection manager while the first connection manager is still active in order to avoid potentially fatal collisions.

Abstract: Methods and systems enable communication devices equipped with software defined radio based chipset modules to seamlessly re-program the communication device to operate on any of a variety of service provider networks. By re-programming a communication device equipped with software defined radio based chipset module, the communication device can support communications over both UMTS and CDMA communication networks. An environment is provided which allows a user to quickly and efficiently switch between service provider accounts supporting communications.

Abstract: Methods and systems enable mobile devices equipped with software defined radio based chipset modules to seamlessly re-program the mobile device to operate on any of a variety of service provider networks. By re-programming a mobile device equipped with software defined radio based chipset module, the mobile device can support communications over both GSM and CDMA communication networks. An environment is provided which allows a user to quickly and efficiently switch between service provider accounts supporting communications.

Abstract: Methods and systems enable mobile devices equipped with software defined radio based chipset modules to seamlessly re-program the mobile device to operate on any of a variety of service provider networks. By re-programming a mobile device equipped with software defined radio based chipset module, the mobile device can support communications over both GSM and CDMA communication networks. The re-programming of the mobile device may commence with the launching of a connection manager supporting a selected service provider. Various embodiment methods and systems are provided to track and monitor a currently activated first connection manager and prevent the launching of a second connection manager while the first connection manager is still active in order to avoid potentially fatal collisions.

Abstract: A method for mobile call testing is provided. The method involves initiating at a test-control module a test call to a mobile unit, and detecting at a ring-detecting module, via a contactless coupling to the mobile unit, whether the mobile unit rings in response to the test call from the test-control module. Further, the method then involves providing a ring indication from the ring-detecting module to the test-control module when a mobile ring is detected in response to the test call. In one example, the contactless coupling is an acoustic coupling.