A first base station receives, from a second base station, a next generation radio access network (NG-RAN) configuration update message including a neighbor information evolved universal mobile telecommunications system terrestrial radio access (E-UTRA) information element (IE), a served cells new radio (NR) to add IE, a slice identifier of a first network slice supported by a cell of the second base station, and a second served cell information NR IE indicating that the cell of the second base station is in a second closed access group (CAG). The first base station sends, to the second base station, an NG-RAN configuration update acknowledge message including a first served cell information NR IE indicating that a cell of the first base station is in a first CAG. The first base station sends, to the second base station, a handover request message to the cell of the second base station.

A first base station receives, from a second base station, a next generation radio access network (NG-RAN) configuration update message including a neighbor information evolved universal mobile telecommunications system terrestrial radio access (E-UTRA) information element (IE), a served cells new radio (NR) to add IE, a slice identifier of a first network slice supported by a cell of the second base station, and a second served cell information NR IE indicating that the cell of the second base station is in a second closed access group (CAG). The first base station sends, to the second base station, an NG-RAN configuration update acknowledge message including a first served cell information NR IE indicating that a cell of the first base station is in a first CAG. The first base station sends, to the second base station, a handover request message to the cell of the second base station.

The present disclosure relates to a mobile terminal for performing cell (re-)selection in a system with at least two suitable cells, each with a plurality of beams. The terminal is in a normal- or a high-mobility state. The terminal measures a signal quality of the beams of each of the suitable cells, determines the cell quality based on the respective measured signal qualities of the beams; and (re-)selects that cell based on a cell (re-)selection criterion using the determined cell qualities. The cell quality is determined for each one of the suitable cells as a sum of the measured signal quality of the beam, with the best signal quality, and a combined beam quality value for the other beams. The combined beam quality value is scaled with a scaling factor which changes depending on the mobility state such that the combined beam quality value is scaled-up in the high-mobility state and scaled-down in the normal-mobility state.

The present disclosure relates to a mobile terminal for performing cell (re-)selection in a system with at least two suitable cells, each with a plurality of beams. The terminal is in a normal- or a high-mobility state. The terminal measures a signal quality of the beams of each of the suitable cells, determines the cell quality based on the respective measured signal qualities of the beams; and (re-)selects that cell based on a cell (re-)selection criterion using the determined cell qualities. The cell quality is determined for each one of the suitable cells as a sum of the measured signal quality of the beam, with the best signal quality, and a combined beam quality value for the other beams. The combined beam quality value is scaled with a scaling factor which changes depending on the mobility state such that the combined beam quality value is scaled-up in the high-mobility state and scaled-down in the normal-mobility state.

This document describes techniques and apparatuses for handling Public Land Mobile Network (PLMN) selection while user equipment is in an inactive mode at a radio resource control layer. In aspects, the UE performs a cell-selection procedure that selects a first cell that serves a first Public Land Mobile Network (PLMN). The UE establishes a radio connection to the first PLMN. The UE transitions from a connected mode at a radio resource control layer to an inactive mode at a radio resource control layer. After a period of time, the UE performs a cell-reselection procedure that selects a second cell that serves a second PLMN. The UE determines if the second PLMN is an equivalent PLMN to the first PLMN. If the second PLMN is an equivalent PLMN to the first PLMN, the UE sends an indication to a lower layer that triggers an action.

This document describes techniques and apparatuses for handling Public Land Mobile Network (PLMN) selection while user equipment is in an inactive mode at a radio resource control layer. In aspects, the UE performs a cell-selection procedure that selects a first cell that serves a first Public Land Mobile Network (PLMN). The UE establishes a radio connection to the first PLMN. The UE transitions from a connected mode at a radio resource control layer to an inactive mode at a radio resource control layer. After a period of time, the UE performs a cell-reselection procedure that selects a second cell that serves a second PLMN. The UE determines if the second PLMN is an equivalent PLMN to the first PLMN. If the second PLMN is an equivalent PLMN to the first PLMN, the UE sends an indication to a lower layer that triggers an action.

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.

Systems and methods provide automated generation of neighbor frequency lists for configuration of frequency objects for wireless stations. A computing device selects a target sector carrier of a wireless station of multiple wireless stations in a radio access network and identifies, based on distances from the wireless station, neighboring sector carriers of the target sector carrier. The computing device filters the neighboring sector carriers based on an azimuth of the target sector carrier to form a filtered set of neighboring sector carriers. The computing device calculates a probability of neighboring frequencies for the target sector carrier based on locations of the filtered set of neighboring sector carriers and generates, based on the calculating, a neighbor frequency list for the target sector carrier. The neighbor frequency list is used to configure frequency objects, for the target sector carrier, that ensure seamless handovers within the radio access network.

Systems and methods provide automated generation of neighbor frequency lists for configuration of frequency objects for wireless stations. A computing device selects a target sector carrier of a wireless station of multiple wireless stations in a radio access network and identifies, based on distances from the wireless station, neighboring sector carriers of the target sector carrier. The computing device filters the neighboring sector carriers based on an azimuth of the target sector carrier to form a filtered set of neighboring sector carriers. The computing device calculates a probability of neighboring frequencies for the target sector carrier based on locations of the filtered set of neighboring sector carriers and generates, based on the calculating, a neighbor frequency list for the target sector carrier. The neighbor frequency list is used to configure frequency objects, for the target sector carrier, that ensure seamless handovers within the radio access network.