A terminal is disclosed including a receiver a receiver that receives a radio resource control (RRC) reconfiguration message including comprising information regarding reconfiguration with synchronization; and a processor that monitors a quasi co-location of a demodulation reference signal antenna port for a downlink control channel in a control resource set based on information regarding random access resources within the information regarding the reconfiguration with synchronization. In other aspects, a radio communication method, a base station, and a system are also disclosed.

A terminal is disclosed including a receiver a receiver that receives a radio resource control (RRC) reconfiguration message including comprising information regarding reconfiguration with synchronization; and a processor that monitors a quasi co-location of a demodulation reference signal antenna port for a downlink control channel in a control resource set based on information regarding random access resources within the information regarding the reconfiguration with synchronization. In other aspects, a radio communication method, a base station, and a system are also disclosed.

A method and an apparatus for entering a connected state with a network for continuing transmission in a wireless communication system is provided. The method may include starting a Time Alignment Timer (TAT). The method may include leaving a connected state with a network. The method may include performing transmission with a configured grant, wherein the configured grant is received from the network, while in leaving the connected state. The method may include performing a random access (RA) to the network, after the TAT is expired.

A random access method and device. The method includes receiving, by user equipment, a radio resource control (RRC) connection reconfiguration message from a first network device, the RRC connection reconfiguration message indicating a primary serving cell of the second network device for a user equipment, an active uplink bandwidth part (BWP) in the primary serving cell, and an active downlink BWP in the primary serving cell, the RRC connection reconfiguration message includes an uplink BWP identifier indicating the active uplink BWP and a downlink BWP identifier indicating the active downlink BWP, the uplink BWP identifier corresponds to the active uplink BWP, the downlink BWP identifier corresponds to the active downlink BWP, and initiating, by the user equipment, a random access procedure to the second network device on the active uplink BWP and the active downlink BWP.

A random access method and device. The method includes receiving, by user equipment, a radio resource control (RRC) connection reconfiguration message from a first network device, the RRC connection reconfiguration message indicating a primary serving cell of the second network device for a user equipment, an active uplink bandwidth part (BWP) in the primary serving cell, and an active downlink BWP in the primary serving cell, the RRC connection reconfiguration message includes an uplink BWP identifier indicating the active uplink BWP and a downlink BWP identifier indicating the active downlink BWP, the uplink BWP identifier corresponds to the active uplink BWP, the downlink BWP identifier corresponds to the active downlink BWP, and initiating, by the user equipment, a random access procedure to the second network device on the active uplink BWP and the active downlink BWP.

Methods, systems, and devices for wireless communications are described. A user equipment (UE) may determine its position based on one or more position reference signals (PRSs), which the UE receives via different component carriers (CCs). The UE may maintain an active state with a first CC transmitting a PRS, while activating and deactivating a secondary CC that may transmit PRSs based on a periodic interval. Additionally, the UE may apply similar techniques for inactive BWPs where a PRS spans multiple BWPs. In some implementations, the position of the UE may enhance a UE mobility procedure based on determining a resource to use for the UE mobility procedure that is dependent upon the position of the UE. For example, the UE mobility procedure may include a random access procedure or a handover procedure. Additionally, the resources used for the mobility procedures may be quasi co-located with PRSs.

Methods, systems, and devices for wireless communications are described. A user equipment (UE) may determine its position based on one or more position reference signals (PRSs), which the UE receives via different component carriers (CCs). The UE may maintain an active state with a first CC transmitting a PRS, while activating and deactivating a secondary CC that may transmit PRSs based on a periodic interval. Additionally, the UE may apply similar techniques for inactive BWPs where a PRS spans multiple BWPs. In some implementations, the position of the UE may enhance a UE mobility procedure based on determining a resource to use for the UE mobility procedure that is dependent upon the position of the UE. For example, the UE mobility procedure may include a random access procedure or a handover procedure. Additionally, the resources used for the mobility procedures may be quasi co-located with PRSs.

A method for accessing a wireless channel by a device (112, 113) that intends to transmit data, wherein access to channel is controlled by a wireless channel controller (111), the method comprising: registering the device (112, 113) at the wireless channel controller (111) as an authorized device; synchronizing (201) a timer of the device (112, 113) indicating time windows; determining (202) a designated time window during which the device (112, 113) can transmit data; performing (203) a clear channel assessment procedure during the preceding time window such that the clear channel assessment ends at the end of the time window preceding the designated time window; and beginning transmission (204) of data at the beginning of the designated time window.

A method for accessing a wireless channel by a device (112, 113) that intends to transmit data, wherein access to channel is controlled by a wireless channel controller (111), the method comprising: registering the device (112, 113) at the wireless channel controller (111) as an authorized device; synchronizing (201) a timer of the device (112, 113) indicating time windows; determining (202) a designated time window during which the device (112, 113) can transmit data; performing (203) a clear channel assessment procedure during the preceding time window such that the clear channel assessment ends at the end of the time window preceding the designated time window; and beginning transmission (204) of data at the beginning of the designated time window.

Excessive latencies and power consumption are avoided when a large number of leaf nodes (LNs) contend simultaneously to join a time slotted channel hopping wireless communication network having a root node (RN) interfaced to LNs by one or more intermediate nodes (INs). A first plurality of shared transmit/receive slots (STRSs) is allocated for at least one IN, and a second plurality of STRSs is advertised for use by contending LNs, where the first plurality is larger than the second plurality. When a LN joins, its STRSs are re-defined such that most become shared transmit-only slots (STOSs) and no STRSs remain. The numbers of STRSs allocated to INs may vary inversely with their hop counts from the RN. One or more STOSs may be added for each of one or more INs in response to a predetermined network condition.